JHR 73: 153-200 (2019) ge, JOURNAL OF meine roan
doi: 10.3897/jhr.73.39052 ME Hymenoptera

http://jhr.pensoft.net The Inerrational Society of Hymenoptersts. RESEARCH

A morphological, biological and molecular approach
reveals four cryptic species of Trissolcus Ashmead
(Hymenoptera, Scelionidae), egg parasitoids of
Pentatomidae (Hemiptera)

Francesco Tortorici', Elijah J. Talamas’, Silvia T. Moraglio', Marco G. Pansa',
Maryam Asadi-Farfar’, Luciana Tavella', Virgilio Caleca*

| Dipartimento di Scienze Agrarie, Forestali e Alimentari (DISAFA), Entomologia Generale e Applicata, Uni-
versity of Torino, Largo P Braccini 2, 10095 Grugliasco (TO), Italy 2 Florida Department of Agriculture and
Consumer Service, Division of Plant Industry, Gainesville, Florida, USA 3 Department of Plant Protection,
Faculty of Agriculture, Urmia University, Urmia, Iran 4 Department of Agricultural, Food and Forest Sciences,
University of Palermo, Edificio 5, Viale delle Scienze, 90128 Palermo, Italy

Corresponding author: Elijah J. Talamas (talamas.1@osu.edu)

Academic editor: G. Broad | Received 13 August 2019 | Accepted 1 November 2019 | Published 18 November 2019
http.//zoobank. org/93B22F06-E829-401 C-B2E3-1C08169706FB

Citation: Tortorici E Talamas EJ, Moraglio ST, Pansa MG, Asadi-Farfar M, Tavella L, Caleca V (2019) A morphological,
biological and molecular approach reveals four cryptic species of Trissolcus Ashmead (Hymenoptera, Scelionidae), egg
parasitoids of Pentatomidae (Hemiptera). In: Talamas E (Eds) Advances in the Systematics of Platygastroidea II. Journal
of Hymenoptera Research 73: 153-200. https://doi.org/10.3897/jhr.73.39052

Abstract

Accurate identification of parasitoids is crucial for biological control of the invasive brown marmorated
stink bug, Halyomrpha halys (Stal). A recent work by Talamas et al. (2017) revised the Palearctic fauna
of Trissolcus Ashmead, egg-parasitoids of stink bugs, and treated numerous species as junior synonyms of
T. semistriatus (Nees von Esenbeck). In the present paper, we provide a detailed taxonomic history and
treatment of T° semistriatus and the species treated as its synonyms by Talamas et al. (2017) based on ex-
amination of primary types, molecular analyses and mating experiments. Trissolcus semistriatus, T. belenus
(Walker), 7° colemani (Crawford), and T’ manteroi (Kieffer) are here recognized as valid and a key to spe-
cies is provided. The identification tools provided here will facilitate the use of Trissolcus wasps as biological

control agents and as the subject of ecological studies.

Keywords

Biological control, taxonomy, brown marmorated stink bug

Copyright Francesco Tortorici et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

154 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Table of contents

WAIST EAC Ui ao werden careeanon facut tucueaves aes anseinae ea atone sees saree ninees a oeste as Satta ea ceaeeue niece 153
A SIEAN CONG BUC heen one Aa hale ka se dc cht acs UR eta Pete taht hath rs Sich acts AS cot 154
Taxonomic history of T’ semistriatus and related species .........::esceesceeeeeesceeseeeseeeee 155
Materialanaimetiods=. een. 2a ee ae, ee us Pane ee ocEes ee ER cla nolan Beene 159
ONCE A hana t tical vauty arnt seater teh taste Reread vtnelneeette tian Maer alaeat Weare £5)
Geographical distribution and host assOciation. .. ......0cassdoneceseuanrsonsacnnenwredarettes 160
CSD BEAK ORTON Yan rhs Soret ep eguts dase ep on tears ores rauinsttr oot avon tectevgntearnoncinee Reeeay mar oe eFEee voc 160
PhigtO graphy vescriaesdestgue.UtAbcan sesndsessien Shuceeth hoes pada seand he oecteavitusians Sand 161
IMO EP HG lO myers uaa Bsaieaases abeneseSenietelloa ate. woohus neti aeansa Lele cod ouch sods Mangia? 161
NSE e taSO ISLA OSA CUAL IING sa Madsron vance tdenemarant shade nnn eesmeangssrmaieuy meunr meermindes 162
Molecular-analysesc. Se... ecetivg cactete cesta ca, ttee dee ee eta ee ia J cee 162
Mating tests and reproductive isolation between 7! belenus and T: semistriatus.... 163
Feesuilitge sot rece Be ae ae na tees foe Sete nec ce ee eee oe ee ncnes eRe See etna 164
Morphological analysis ie, aiccc.cteercsvoncasntenen otgensnste sutaite ueacieevitercererecsledencosmmedetens 164
IMfoleculartatial ySiispet dessa We testsurcenet Pibeh seine tne panes Be Sei ite eli nein cane batbons panels 165
IVI UHNE RESTS: Raver ze wea ntet ih SEDO laste pee SL ads ee last anails abe eMancemweertenas 165
Key to: Frisolcusof the Palearctic region (females) .:....sircasoooonnedecsavaeonsoseccsines 167
TrissOLCUS Velentis & WAI CE) ©. su. ode tactesons sect sheets Upto ctebe Seeeste eset nteet déundocebevienwesenecss 170
LTISSOLLVS: COLE TIATLIEE (CLA WIOTO is oe bea snsdicnasteas che cieetbap Cecduan obiaavatseadevredtnansindebidldonshelees 180
Trissolcus manterot (Kiefker) ........ccccccccccccccccccccesecssssssssssscccecccesesccccessseeessssssssssecs 184
Trissolcus semistriatus (Nees von Esenbeck) ..........cccsssssescccecccccescccccessessssssesssssees 187
DISCMSSTO Ms th ita sh suet snneatieee ela ian coll eNs acu sata atetss Saha ASbe tea gdean erst sesese Setanta Peal
FNCKIMOW LEC OCMIETIES a toe. reef. anc Roan toetenc he xan ap teen pe veett seve pus or teats oS ra sno nalucteeotseconste 192
RSTOREIN COS rea Sacco sal niet aweews nd ieapaceduegdehpetaradt a Steep ee ange Sonebad bed tueee ys Steet, 193
Supp lementatyeriate tal W927 hates acer tee ee er aac dl ak 198
SUljg PLE MAGN EAL y, TALC TAD. tele! cremate s Je ey aetaiode eed eat Some Pardee es eight cde cactaet atest 199
Sup plemrenitary:-raate rial 99 2022 eases seuss tossthan segues ayteeestups toeedee cage un hana cagaew dpetagaceenus le
Sup lerienitatey~ Ate ra a. oan ten sn sh P Secreted Saran be Ba spat ees pumnenad Nanna eMaan Buss nu scurseks 200
ASHE] Silt 6atch M1 ee ry ASAE Ng Gt7d lp hy Oe PRMD EIRENE SORE Pine SEADREAM IpDeORRLD eee RP PRI ee gear rte Oa 200
Stieplementaty. material i62..052. 53402 jee ee eee Seeley eel 200
Introduction

Taxonomy of the genus 7rissolcus Ashmead has received renewed attention in recent
years (Talamas et al. 2015, 2017), largely because accurate identification of these wasps
is needed to use them as biological control agents against the invasive brown marm-
orated stink bug (Halyomorpha halys (Stal)) in Europe and North America. Morpho-
logical similarity, sharing of hosts by various species of Trissolcus, and the historical
complications presented in Talamas et al. (2017) and Buffington et al. (2018) are some
of the challenges faced by taxonomists working with this group.

An integrated approach reveas cryptic species of Trissolcus in Europe 159

The revision of Palearctic Trissolcus (Talamas et al. 2017) provided keys to species,
complete redescriptions, illustrations, and the utilization of new morphological char-
acters. Many new synonymies were presented, including 7’ grandis (Thomson), 7. artus
Kozlov & Lé, 7’ colemani (Crawford), T’ djadetshko (Rjachovskij), T’ manteroi (Kief-
fer), I! nigripedius (Nakagawa), T’ pentatomae (Rondani) and T’ pseudoturesis (Rjacho-
vskij) as junior synonyms of 7. semistriatus (Nees von Esenbeck).

In support of studies on the egg-parasitoid complex of European Pentatomoidea,
a survey of egg masses was conducted and previously collected specimens were also
examined. Using the key to species provided by Talamas et al. (2017), Trissolcus speci-
mens that emerged from Aelia rostrata Boheman, Arma custos (E.), Carpocoris spp., Eu-
rygaster maura (L.), Graphosoma lineatum (L.), Palomena prasina (L.) collected between
1996 and 2017 in Piedmont (NW Italy) were identified as T° semistriatus. However,
some consistent morphological differences were detected among the specimens, which
instigated closer examination using multiple methods. The focus of this paper is the
morphological and molecular analysis of species synonymized under J’ semistriatus by
Talamas et al. (2017), and the integration of mating tests, when possible, to confirm
species delimitation.

Taxonomic history of T. semistriatus and related species

Species described by Walker

Telenomus belenus was described by Walker (1836), then transferred by Kieffer (1912)
to Aphanurus Kieffer, then transferred to Microphanurus Kieffer (Kieffer 1926). Walk-
er (1838) described Telenomus arminon but did not provide distinctive characters by
which it could be identified or separated from Telenomus belenus. Kieffer (1912) trans-
ferred Te. arminon to Allophanurus Kieffer and provided a redescription. Kieffer did
not mention if his treatment was based on type material, and we consider it unlikely
that it was. Lectotypes for Te. belenus and Te. arminon were designated by Fergusson
(1984, 1983), respectively, from material housed in the National Museum of Ireland,
Dublin. Despite their antiquity, and thus priority, these species received no further
taxonomic treatment.

Trissolcus semistriatus vs. T. grandis

In taxonomic literature, the distinction between 7. semistriatus and T! grandis has long
been questioned. Mayr (1879) and Nixon (1939) ascertained 7. semistriatus to be a
highly variable species. Masner (1959) wrote “On base of the check of type of Asolcus
grandis (Thomson), the latter species was synonymized with semistriatus”. However,
the meaning of this sentence is unclear because we have not found in the literature
previous synonymy of J! grandis under T. semistriatus, and it is not clear that Masner

156 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

sought to synonymize them for the first time. In this paper, Masner addressed charac-
ters considered to distinguish 7 grandis and T: semistriatus (rugosity of the frons, leg
color, longitudinal sculpture on the posterior mesoscutum, body length) based on the
comparison of ~500 reared specimens and stated that these characters were variable
within 7. semistriatus. Viktorov (1967) considered T’ grandis to be conspecific with 7’
semistriatus, but he did not formally treat it as a junior synonym. Subsequent authors
considered 7! semistriatus and T: grandis as different species, but without clearly defin-
ing the boundaries between them. Delucchi (1961) provided the first reliable character
to distinguish 7’ semistriatus from T’ grandis: the external surface of the hind femur is
almost totally covered by setation in 7’ grandis (Figure 1), and he coupled this character
with the color of the tibiae: reddish yellow in 7’ semistriatus, dark or black in T’ gran-
dis. Most authors continued to distinguish 7’ semistriatus and T. grandis by tibial color
and ignored setation of the hind femora. This color-based distinction was employed
in numerous previous and following papers (Delucchi 1961; Javahery 1968; Kozlov
1968, 1978; Safavi 1968; Voegelé 1969; Fabritius 1972; Kozlov and Lé 1977; Kozlov
and Kononova 1983), and no substantial change was indicated in keys to species by
Kononova (1995, 2014, 2015). Talamas et al. (2017) did not use tibial setation to
differentiate between these species, but listed a new character, the form of the mesos-
cutal humeral sulcus, and mentioned setation of the first laterotergite, which was first
presented as a character for species of Trissolcus by Johnson (1987). Although Talamas
et al. (2017) treated these characters as variable within 7’ semistriatus, analysis of these
characters in light of molecular and mating experiments has allowed us to use them for
species delimitation.

In a study on larval stages, Voegelé (1964) provided information about pigmenta-
tion of the membrane secreted by the larvae of different Trissolcus species reared in eggs
of Eurygaster austriaca (L.). He distinguished T’ semistriatus from T’ grandis by the width
of the pigmented band close to the margin of host egg operculum (see fig. 4 in Voegelé
1964). In his key to species, Safavi (1968) coupled color of the hind tibia (instead of
mid tibia), and width of the pigmented band in larval membrane shown by Voegelé
(1964), also adding different length ratios of the first two flagellomeres in males.

Trissolcus artus was distinguished by Kozlov and Kononova (1983) and Kononova
(1995) from 7. grandis (black tibiae) by its reddish-yellow tibiae, and from T’ semistria-
tus by having a more elongate clava and infuscation in the fore wing. This last feature is
used in the key by Kononova (2014, 2015) to distinguish 7’ artus from both T grandis
and 7. semistriatus.

Trissolcus manteroi

Trissolcus manteroi was described by Kieffer (1909) as having the postmarginal vein
(pm) slightly longer than the stigmal vein (st). In Kozlov and Kononova (1983), Kocak
and Kilincer (2003) and Kononova (2014, 2015), 7’ manteroi was distinguished by
its postmarginal vein 1.3x as long as the stigmal vein, compared to 1.8x in Trissolcus
rufiventris (Mayr), and 2x in T’ grandis (=T’ belenus) and T. semistriatus. Kononova

An integrated approach reveas cryptic species of Trissolcus in Europe 157

Fis, Ll — A. ghorfii DEL. ct Vac. (A - D), A. vassilievi Mayr (E), A. grandis

THOMSON (F - H) et A. semistriatus NEES (I - L). Antennes de la femelle (B, F, K),

antennes du male (A, G, L). Angle formé par les nervures postmarginale et stigmale

de l’aile antérieure (E, C), pubescence de la metapleure (D) et des fémurs
postérieurs (H, I).

Figure |. Illustrations published by Delucchi (1961) where differences in the bare area of the external
side of hind femora of Asolcus semistriatus (Fig II, 1) and A. grandis (Fig. III, H) are shown.

158 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

(2014, 2015) also distinguished 7’ manteroi by the sculpture of T2, in which short
longitudinal rugae are arranged medially and do not extend to the posterior half of the
tergite, contrasting with longitudinal rugae throughout the anterior two thirds of T2
in 7. belenus and T. semistriatus.

Trissolcus colemani

Crawford (1912) described Telenomus colemani from specimens that emerged from an
ege mass of Dolycoris indicus Stal, collected in India. Masner and Muesebeck (1968)
transferred this species into Trissolcus and no other information was recorded until its
treatment as a junior synonym of TZ. semistriatus in Talamas et al. (2017).

Trissolcus pseudoturesis and T. djadetshko

The original description of Microphanurus (=Trissolcus) pseudoturesis Rjachovskij (Rja-
chovskij 1959) distinguished this species from M. djadetshko Rjachovskij and M.
semistriatus by tibial color: completely yellow in M. pseudoturesis; reddish or yellow
in M. djadetshko; almost black in M. semistriatus. Viktorov (1964) distinguished Asol-
cus (=Trissolcus) djadetshko and A. rufiventris by the lack of longitudinal striae on the
posterior margin of the mesoscutum in contrast to their presence in A. pseudoturesis
and A. semistriatus. Viktorov (1967) then modified his concept, considering the color
of the hind tibia as a valid character to distinguish 7’ djadetshko from T: semistriatus
and the color of femora to distinguish 7’ djadetshko from T’ pseudoturesis. The keys
to species by Kozlov (1968) and Fabritius (1972) distinguished 7’ djadetshko from T.
grandis, T; pseudoturesis and T. semistriatus by the absence of longitudinal striation on
the posterior mesoscutum and an absence of transverse striation on the frons, and 7
pseudoturesis from T! grandis and T. semistriatus by color of the femora. Kozlov and
Kononova (1983) separated 7’ djadetshko from both T. grandis and T. semistriatus
by the absence of longitudinal striation on the posterior mesoscutum. Safavi (1968)
and Voegelé (1969) separated 7’ djadetshko and T. pseudoturesis by their “ochraceous”
femora from 7. semistriatus and T. grandis (black femora), and separated 7! djadetshko
from 7. pseudoturesis by longitudinal striae on the posterior margin of mesoscutum (vs.
striate throughout) and the presence of parapsidal furrows. Kocak and Kilinger (2003)
distinguished 7’ djadetshko by its femora being reddish-yellow in contrast with dark
brown or black femora in 7! semistriatus and T. grandis, and separated T. djadetshko
from 7. pseudoturesis by sculpture on mesoscutum as in Voegelé (1969). Petrov (2013)
again distinguished 7’ djadetshko on the basis of the mesoscutum without longitudinal
wrinkles, contrasting with the clear longitudinal wrinkles of 7’ grandis, T: pseudoturesis
and T° semistriatus, and he separated T’ pseudoturesis from T’ grandis and. T. semistriatus
by the color of femora. Kononova (2014, 2015) differentiated 7’ djadetshko by its yel-
low legs and mesoscutum without longitudinal rugae posteriorly from T’ semistriatus

An integrated approach reveas cryptic species of Trissolcus in Europe 159

and 7. grandis having all femora black and mesoscutum with longitudinal rugae poste-
riorly, and 7! pseudoturesis from T! grandis and T: semistriatus as in Kozlov (1968). Tris-
solcus djadetshko and T: pseudoturesis were treated as junior synonyms of J semistriatus
in Talamas et al. (2017).

Trissolcus waloffae, T. nixomartini and T. silwoodensis

Javahery (1968) described and keyed V7’ waloffae (Javahery) using leg color (predomi-
nantly brownish to reddish-yellow) and weakly indicated parapsidal furrows to sepa-
rate it from T’ grandis, T’ semistriatus, T’ nixomartini and T. silwoodensis, which he
considered to have black femora in both sexes and be without parapsidal furrows.
Characters provided to distinguish each of the last four species from each other were
black vs. brown front tibiae, presence of infuscation of wings, color of wing venation,
ratio between first flagellar segment and pedicel of male, sculpture of the head, distance
between lateral ocelli and compound eye, and ‘weakly concave’ vs. ‘somewhat concave’
head. Trissolcus silwoodensis and T: nixomartini were previously treated as synonyms of

LT. grandis by Kozlov and Lé (1977).

Trissolcus crypticus

During a program for classical biological control of Nezara viridula L. in Australia,
several ‘strains’ of different geographical populations of Trissolcus basalis (Wollaston)
were introduced, starting in the 1930s (Clarke 1990). Of the strains introduced in
subsequent years to the interior of Australia, one population imported from Pakistan
(1961) was not able to efficiently control N. viridula (Clarke 1990). Clarke (1993)
demonstrated that this ‘strain’ was indeed a different species, which he described as
Trissolcus crypticus Clarke. Comparing J! crypticus with T. basalis, he considered the
complete netrion sulcus (figure 1 in Clarke 1993) as the main diagnostic character
for 1! crypticus. Clarke analyzed specimens of Trissolcus rungsi (Voegelé) labelled by
Voegelé and deposited in NHMUK and concluded that they were not the same species
as T. crypticus, but did not present characters to support his hypothesis (Clarke 1993).

Material and methods
Collections

Primary types

Due to the challenge of historic confusion regarding species close to T’ semistriatus, we
treat only species for which the primary types were directly examined, or the diagnostic
characters are clearly visible in photographs.

160 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Images of the primary types of Télenomus colemani Crawford, Microphanurus
djadetshko Rjachovskij, Trissolcus grandis Thomson, Telenomus Manteroi Kiefter, Mi-
crophanurus pseudoturesis Rjachovskij and Teleas semistriatus Nees von Esenbeck were
made available via Specimage (specimage.osu.edu) by Talamas et al. (2017). Images of
the lectotype of Télenomus nigripes Thomson, syntypes of Telenomus ovulorum Thom-
son, and additional images of the lectotype of Télenomus grandis were provided by Dr
Hege Vardal (Naturhistoriska Riksmuseet, Stockholm, Sweden).

Institutional acronyms

CNCI Canadian National Collection of Insects — Ottawa, Canada;

DISAFA Dipartimento di Scienze Agrarie, Forestali e Alimentari, Univer-
sity of Torino — Torino, Italy;

EIHU Hokkaido University Museum, Entomology — Sapporo, Japan;

HMIM Hayk Mirzayans Insect Museum, Plant Pests and Diseases Re-

search Institute — Tehran, Iran;

NHMUK, BMNH. The Natural History Museum — London, United Kingdom;

NHMW Naturhistorisches Museum Wien — Wien, Austria;

NMID National Museum of Ireland — Dublin, Ireland;

MSNG, MCSN Museo Civico di Storia Naturale “Giacomo Doria’ — Genoa, Italy;

MZUF Museo di Storia Naturale di Firenze, Sezione di Zoologia “La
Specola”, Universita degli Studi di Firenze — Florence, Italy;

NHRS Naturhistoriska Riksmuseet, Entomology — Stockholm, Sweden;

UCRC University of California, Riverside — CA, USA;

UNIPA Dipartimento di Scienze Agrarie, Alimentari e Forestali, Univer-
sita degli Studi di Palermo — Palermo, Italy;

USNM National Museum of Natural History, Smithsonian Institution —
Washington, DC, USA;

ZIN Zoological Museum, Academy of Sciences — St. Petersburg, Russia.

Geographical distribution and host association

The identification tools of previous literature are not reliable for identifying the spe-
cies that we treat here. Hence, the geographical distribution and host associations
presented in Material Examined sections derive only from specimens examined as
part of this study.

Cybertaxonomy

Specimens used in this study were assigned collecting unit identifiers (CUIDs) and
their associated collection and host association data were deposited in Hymenoptera

An integrated approach reveas cryptic species of Trissolcus in Europe 161

Online (hol.osu.edu). In addition to the abbreviated Material examined sections, a
DarwinCore archive is provided for each species (Suppl. material: S2-S5). These files
contain the totality of specimens for which data is deposited in Hymenoptera Online,
including specimens for which updated identification has not yet occurred, which can
be assessed by the dates of determination. Taxonomic synopses, descriptions, and ma-
terial examined sections were generated in the online, matrix-based program vSysLab
(vsyslab.osu.edu) with a matrix based on that of Talamas et al. (2017).

Photography

A Leitz Grofsfeld-Stereomikroskop TS with magnification up to 160x, a Stereomi-
croscope Wild M3B with oculars 15x, and a spot light Leica CLS 150x were used for
biometric diagnosis. A semi-transparent light shield was used to reduce glare and to
diffuse the light. The lectotypes of 7’ belenus and T! arminon were photographed with
a Macroscopic Solutions Macropod MicroKit with individual slices rendered in Heli-
con Focus 6. All other images were produced using a Leitz Dialux 20 EB compound
microscope with a Leica DFC 290 Camera with LED spot light or dome light based
on different points of view after techniques summarized in Buffington et al. (2005),
Kerr et al. (2008) and Buffington and Gates (2008). LEICA APPLICATION SUITE
V 3.7.0 software was used to manage image acquisition and ZERENE STACKER was

used for merging of the image series into a single in-focus image.

Morphology

Terminology for surface sculpture follows the glossary by Harris (1979), Miko et al.
(2007), Yoder et al. (2010) and Talamas et al. (2017). Measurements of the head,
mesosoma, metasoma, total body, and wing venation follow Masner (1980) and Tor-
torici et al. (2016). In the wing ratio expressed as st:pm:mg, the stigmal vein is treated
as the benchmark unit (=1). Morphological terms largely follow Miké et al. (2007) and
were matched to concepts in the Hymenoptera Anatomy Ontology (Yoder et al. 2010)
using the text analyzer function and a table of these terms and URI links is provided
in Suppl. material: S1.

Additional abbreviations and terminology used in this paper: HL: head length;
HW: head width; HH: head height, from vertex to distal end of clypeus; FCI: frontal
cephalic index (HW/HH); LCI: lateral cephalic index (HH/HL); OOL:POL:LOL:
ocular distance ratio, OOL as the benchmark unit (=1); IOS: interorbital space
(Mik6 et al. 2010); claval formula: the sequence of sensilla, from the apical anten-
nomere (A11) to the last functional clavomere (Bin 1981), i.e. the last antennomere
bearing one or two multiporous gustatory sensilla, as defined by Isidoro et al. (1996);
compound eye height and width: measured when eye longitudinal axis is parallel to
the focal plane.

162 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Insect collecting and rearing

A host colony of £. maura used for rearing Trissolcus was established from adults col-
lected on wheat in Piedmont (NW Italy) and maintained in cages under laboratory
conditions (climatized chambers at 24 = 1 °C, 65 5% RH, L:D = 16:8). All eggs laid
in the cages were collected and frozen at -20 °C. Because of the short egg-laying period
of E. maura, freezing the eggs allowed the eggs to be used for a much longer time.

To obtain Trissolcus specimens, egg masses of FE. maura and P prasina were collect-
ed in the field in Piedmont (NW Italy) in the spring and summer of 2017. The field-
collected egg masses were reared and checked daily. Trissolcus specimens that emerged
from field-collected egg masses were allowed to mate. Some females were isolated in
small plastic boxes (64.5 x 40.9 x 16 mm), fed with water and honey, and provided
with E. maura frozen egg masses to produce progeny for use in subsequent tests.

For interbreeding experiments, specimens were isolated immediately following
emergence to prevent mating, and females and males were maintained singly in plastic
boxes as described above. When the parasitoids reach the early pupal stage inside the
eggs, their red eyes are clearly visible through the transparent operculum of the host
ege. Following observation of this feature (Figure 2), the eggs were checked at a fre-
quency of 4—5 times per day to ensure that they were isolated prior to mating.

Some of the progeny from isolated, mated females were selected for preservation,
identification and molecular analysis. The remaining progeny were used in breeding
experiments.

Molecular analyses

Molecular analyses were performed to confirm morphological identification and char-
acterize the species. Genomic DNA was extracted from the metasoma of specimens
from rearing experiments and pinned collection specimens according to Kaartinen et
al. (2010), but doubling the proteinase K dose (5 pl of 20 mg ml" proteinase K). The
barcode region of the cytochrome oxidase I (COI) gene was amplified using universal
PCR primers for insects LCO1490 (5’°-GGT CAA CAA ATC ATA AAG ATA TTG
G-3’) and HCO2198 (5’-TAA ACT TCA GGG TGA CCA AAA AAT CA-3’) (Folmer
et al. 1994). The PCR was performed in a 50 ul reaction volume: 2 pl of DNA, 37.9 ul
molecular grade water, 5 pl 10x Qiagen PCR buffer, 3 pl dNTPs (25 mM each), 1.5 ul
MgCl2, 0.2 ul of each primer (0.3 uM each), 0.2 pl Taq DNA Polymerase (Qiagen,
Hilden, Germany). Thermocycling conditions were optimized to shorten reaction
times and included initial denaturation at 94 °C for 300 s, followed by 35 cycles of
94 °C for 30 s, annealing at 52 °C for 45 s and extension at 72 °C for 60 s; then further
600 s at 72 °C for final extension. PCR products were purified using a commercially
available kit (QIAquick PCR Purification Kit, Qiagen GmbH, Hilden, Germany) fol-
lowing the manufacturer's instructions, and sequenced by a commercial service (Gene-
chron S.r.l., Rome, Italy). The sequences were compared with the GenBank database
and each other using the Basic Local Alignment Search Tool (http://www.ncbi.nlm.

An integrated approach reveas cryptic species of Trissolcus in Europe 163

ee oe

Figure 2. Pupal stage of Trissolcus sp. in Halyomorpha halys eggs, clearly indicated by the presence of eyes

and ocelli, which are visible through the semi-transparent host egg.

nih.gov/BLASTn). All sequences were aligned using ClustalW with default settings
as implemented in Mega X. The pairwise nucleotide sequence distances among and
within taxa were estimated using the Kimura 2-parameter model (K2P) of substitution
(Kimura 1980) using Mega X (Kumar et al. 2018). The sequences generated from this
study are deposited in the GenBank database. All residual DNA is archived at DISAFA.

Mating tests and reproductive isolation between 7: belenus and T. semistriatus

For mating experiments, 1—2-day old virgin females and males were used. Four combi-
nations for mating tests were done: 7. semistriatus (2) x T. belenus (¢); T. belenus (Q)
x Tr semistriatus (4); T. semistriatus (2) x T. semistriatus (3); T. belenus (2) x T. belenus
(4). The total number of interbreeding tests was 24: four replicates for each intraspe-
cific mating combination and eight replicates for each interspecific mating combina-
tion. Each pair of wasps was observed at the stereomicroscope until the end of copula-
tion or for 10 minutes if copulation did not occur. The pair then remained together in
isolation for 24 hours. After the mating test, an egg mass of E. maura was provided to
each female wasp for 24 hours of exposure. The egg masses were then moved to other
plastic boxes until offspring emergence. Each mating test was considered successful
when emerged offspring included females, because in all known Trissolcus species, only
mated females can produce female offspring. We compared the percentage of mating
success among the four combinations and the significance of the results was assessed
with a chi-square test.

164 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Results

Morphological analysis

The easiest task regarded the distinction of 7’ manteroi from T’ semistriatus, T. bele-
nus and T! colemani. Trissolcus manteroi clearly has a shorter postmarginal vein, only
slightly longer than the stigmal vein; A7 has only one papillary sensillum instead of
two in the other three species; and 7’ manteroi has no episternal foveae. The holotype
of 7! manteroi is thus morphologically very close to T’ rufiventris, from which it can be
differentiated by the length of the postmarginal vein.

The distinction of 7’ belenus and T’ colemani from T’ semistriatus is more nuanced
and required an integrative approach to determine which morphological characters
were congruent with the biological and molecular data. The results of this in-depth
analysis demonstrate that some of the characters that Talamas et al. (2017) treated as
intraspecifically variable have diagnostic power.

The presence or absence of setation on the external face of the hind femur, de-
scribed in the key and figure III (I) (H) in Delucchi (1961), is a reliable character
to distinguish 7’ grandis from T’ semistriatus. However, in the lectotype of 7! grandis
and neotype of 7. semistriatus this character is opposite to what was stated by Deluc-
chi (1961). Furthermore, the holotype of 7’ colemani has the external surface of hind
femur setose, as in the lectotype of 7’ grandis. The association proposed in Delucchi
(1961): ‘external face of hind femora uncovered by hair’ — ‘reddish yellow tibiae’ is the
typical combination for 7’ colemani, while Delucchi (1961) proposed it for 77 semis-
triatus, and ‘external face of hind femora covered by hair’ — ‘dark or black tibiae’ is the
typical combination for 7. semistriatus. We conclude that this interpretation is contrary
to what is found in type material.

Synonymy in 7’ belenus

In the analysis of original descriptions and images of lectotype of 7) arminon and T.
grandis, no remarkable characters were recognized to distinguish them from 7. belenus,
which we therefore consider it to be their senior synonym. In the analysis of type mate-
rial of 7 silwoodensis and T! nixomartini, previously considered junior synonym of T
grandis (Kozlov & Lé, 1977), we confirmed the findings of previous authors, and thus
treat these species as junior synonyms of 77 belenus. Mayr (1879) considered Télenomus
ovulorum Thomson to be a junior synonym of Telenomus semistriatus Nees von Esen-
beck, but through analysis of the photographs of type material of 7’ ovulorum Thom-
son, we recognized the character states of 7’ belenus, and therefore treat T’ ovulorum as
a junior synonym of 7! belenus.

Synonymy in 7) colemani

One paratype of 7’ djadetshko and three syntypes of 7’ pseudoturesis were analyzed via
photographs and compared with the original description and photographs of the holo-

An integrated approach reveas cryptic species of Trissolcus in Europe 165

type of 7. colemani. The character states of the two first species matched perfectly with
those of the latter, leading us to treat 7’ colemani as the senior synonym of T. djadetshko
and 7’ pseudoturesis. We conclude that the characters of 7’ crypticus match those in the
holotype of 7’ colemani based on examination of T’ crypticus paratypes collected in
Pakistan and its original description (see figs 1, 3, 5 in Clarke 1993). We thus treat 7’
crypticus as a junior synonym of JT’ colemani.

Clarke (1993) also reported that “Examination of material of 7’ rungsi labelled
by Voegelé (deposited in NHMUK) shows that this species is not the same of 7’ cryp-
ticus’ but he did not provide any distinguishing characters between the two species.
Contrary to what was reported by Clarke (1993), in our analysis of the material de-
posited at NHMUK, 37 specimens labelled as “Asolcus rungsi Voegelé” were identified
as I’ colemani and four specimens labelled as “rungsi 1965 Voegele” were identified
as 7) basalis, while other 25 with the same last cumulative label were identified as 7
colemani. This confirms our interpretation of the description and analysis of figures
regarding A. rungsi and demonstrates confusion of species in the Moroccan rearing
efforts at Ecole Nationale d’Agriculture in Meknés.

The original description of Asolcus rungsi mentioned the presence of short traces of
notauli (fig. 1, c. in Voegelé 1965); these traces are visible in all specimens 7’ colemani
(Figure 23). However, because the location of the holotype of A. rungsi is not known,
we were unable to examine it and at this time do not treat this species name as a syno-
nym. The morphological analyses of the holotype and paratypes of 7’ waloffae showed

the conspecificity of this species with 77 colemani.

Molecular analysis

Barcode sequences were obtained from 17 Trissolcus specimens (Table 1). The Blast
search showed that the sequences of 7’ semistriatus from Italy and from Iran had a 98%
sequence identity with the GenBank sequence from Trissolcus nigripedius (accession
no. AB971830). The sequences from the two specimens of 7. colemani showed a 98%
identity with a GenBank sequence with a Platygastridae sp. (accession no. KY839581),
while the sequences from the specimens of 7’ manteroi, T: belenus and T. rufiventris
showed a lower similarity with GenBank sequences. The final alignment consisted of
548 characters. Pairwise distance values within and among analyzed species are shown
in Table 2. The genetic distances between the specimens identified as of the same spe-
cies (which averaged between 0.000 + 0.000 and 0.005 + 0.002), were much lower
than the mean pairwise distances observed between the specimens identified as of dif-
ferent species (from 0.105 = 0.001 to 0.149 + 0.000).

Mating tests

Specimen pairs tested for intraspecific combination mated within ten minutes; pairs test-
ed for interspecific combination did not mate within the 10-minute observation period.

166

Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Table |. Specimen information and GenBank Accession Number for the sequences generated by this

study.

Species

Trissolcus manteroi

Trissolcus semistriatus

Trissolcus belenus

Trissolcus colemani

Trissolcus rufiventris

Country Year of collection GenBank accession number

ITALY
ITALY
ITALY
IRAN
ITALY
ITALY
ITALY
ITALY
ITALY
ITALY
ITALY
ITALY
ITALY
ITALY
IRAN
TRAN
TRAN

2010 MK906047
2010 MN603796
2017 MK906048
2015 MK906049
2017 MN603799
2017 MN603800
2016 MN603798
2016 MN603797
2017 MK906050
2017 MN603802
2017 MN603803
2017 MNG03804
2017 MN603806
2017 MN603805
2015 MK906051
2015 MN603801
2015 MN603807

Collecting unit identifier
DISAFA-draw1465-HYM-0424
DISAFA-draw1465-HYM-0425
DISAFA-draw1465-HYM-0233

USNMENT01223088
DISAFA-draw1465-HYM-0238
DISAFA-draw1465-HYM-0240
DISAFA-draw1465-HYM-0242
DISAFA-draw1465-HYM-0283
DISAFA-draw1465-HYM-0014
DISAFA-draw1465-HYM-0012
DISAFA-draw1465-HYM-0013
DISAFA-draw1465-HYM-0016
DISAFA-draw1465-HYM-0018
DISAFA-draw1465-HYM-0019

USNMENT01223460

USNMENT01223455

UNIPA-HYM-S01347

Table 2. Barcode mean pairwise genetic distances (+ SE) between 7 manteroi, T. semistriatus, T’ belenus,

T. colemani and T. rufiventris (under the diagonal), and within taxa (along the diagonal). n = number of

sequences.

T. manteroi (n = 2)

T. semistriatus (n = 6)

T. belenus (n = 6)

T. colemani (n = 2)

T. manteroi (n = 2) 0.000 = = =
T. semistriatus (n = 6) 0.139 + 0.000 0.005 + 0.002 s 2
T. belenus (n = 6) 0.139 + 0.000 0.109 + 0.000 0.000 + 0.000 —
T. colemani (n = 2) 0.138 + 0.000 0.105 + 0.001 0.107 + 0.000 0.000
T. rufiventris (n = 1) 0.144 + 0.000 0.141 + 0.001 0.149 + 0.000 0.133 + 0.00
FEMALE AND MALE OFFSPRING PERCENTAGE FOR EACH COMBINATION
100
O
80
<
Z
Ss)
2 60
Lu
oa
2 40
oc
jas
to
i 20
ie)
87 74 0 0
0
Yet %m %f %mM Yt %m %f %m
T. belenus © T. semistriatus 9 T. belenus ° T. semistriatus 9
Xx X X Xx
T. belenus 3 T. semistriatus 3 T. semistriatus 3 T. belenus 3

COMBINATIONS

Figure 3. Sex ratio of emerged specimens. Combinations: 7; belenus (2 x 3), n = 4; T. semistriatus (2
x 6), n= 4; T belenus (Q) x T. semistriatus (3), n = 8; T. semistriatus (2) x T. belenus (3), n = 8. Bars

indicate standard deviation.

An integrated approach reveas cryptic species of Trissolcus in Europe 167

All females used for the two intraspecific combinations successfully produced female
offspring (Figure 3); as expected the sex ratio was similar, in 77 belenus (2 x 3) combina-
tion 31 females and 5 males emerged, and in 7) semistriatus (Q x @) 21 females and 4
males emerged. Females used for the two interspecific combinations produced only male
offspring, 78 males in the 7) belenus (2) x T. semistriatus (¢) combination, and 65 males
in the 7 semistriatus (2) x T. belenus (4) combination. A total of 3 females failed to re-
produce, producing no offspring in either the intraspecific or interspecific combinations.

Key to Trissolcus of the Palearctic region (females)

Modified couplets for the Key to Trissolcus of the Palearctic region (females) in Talamas
et al. (2017)

29)

DES

32A

32B

Ventral mesopleuron distinctly bulging; mesocoxa oriented parallel to long
axis of body; dorsal frons with sculpture effaced, sometimes entirely smooth
and shining; A7 with two papillary (basiconic) sensilla (figures 128-132 in
tealamas-et ale Ol An... teks 1815. be ete bawales Trissolcus perepelovi (Kozlov)
Ventral mesopleuron not distinctly bulging; mesocoxa oriented at an angle of
~45° relative to long axis of body (Figure 6); dorsal frons evenly and densely
covered in microsculpture; A7 with one papillary (basiconic) sensillum (Fig-
HET Vict est eke tose tosis dee atalt th Meeteteate se ieee hoe cote aacieteh weld bon tweacthte ndeenawastertie 29A
Postmarginal vein in fore wing about twice as long as stigmal vein (Figure
14); metasoma yellow to dark brown, typically reddish-brown................e
i Soe nk EER ES PL 8 PR EOS er ee, Ee Trissolcus rufiventris (Mayr)
Postmarginal vein only slightly longer than stigmal vein (Figure 13); meta-
soma dark brown to black (Figure 18)............. Trissolcus manteroi (Kieffer)
Lateral mesoscutum with mesoscutal humeral sulcus present as a smooth fur-
POW AUP TOUS, 29) occa aie ogs uit unc. tet Mate Sabine Sta da Jadase Sb selosea det cescddes deniers 32A
Lateral mesoscutum with mesoscutal humeral sulcus comprised of distinct
FOVEIE EIS EESID OB) cos unoenicnimpd en ame ienenniacebelmbecncbabind.culmednbsranndit 32B
Lateral pronotum with netrion sulcus incomplete dorsally, netrion often
poorly defined; medial part of occipital carina rounded in dorsal view..........
eee a nn Ah tet rent a mance Trissolcus basalis (Wollaston)
Lateral pronotum with netrion sulcus complete dorsally (Figures 5, 50, 53,
55, 60), netrion distinct; medial part of occipital carina angled (Figure 36),
vertex of angle with short carina directed toward median ocellus .................
ache eR Ac TRA Ah Dia an Trissolcus semistriatus (Nees von Esenbeck)
Laterotergite Iwith line of 3:setae (Figures: 30; 45)ii..tSecssneosasvnseroaedenvosoasens
Fh he FS ae ch I coins EE EN Ae Ne oR Trissolcus belenus (Walker)
Laterotergite 1 without setae (Figure 32)..... Trissolcus colemani (Crawford)

A matrix of the diagnostic characters used in this key is provided in Suppl.

material: SG.

Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Figures 4-7. EPS, metapleural epicoxal sulcus, anterolateral extension of metapleuron: 4 Trissolcus
belenus [DISAFA-draw1465-HYM-0009] 5 7 colemani [DISAFA-draw1466-HYM-0484] 6 7? manteroi
[DISAFA-draw1465-HYM-0430] 7 7. semistriatus [DISAFA-draw1465-HYM-0227].

An integrated approach reveas cryptic species of Trissolcus in Europe 169

_
_

=
—
—
ol
==
—
—=
——
=

Figures 8-11. Basiconic sensilla, indicated by arrows, in the ventral surface of female antennal clava:
8 Trissolcus belenus [DISAFA-draw1465-HYM-0009] 9 7. colemani [DISAFA-draw1466-HYM-0484]
10 7. manteroi [DISAFA-draw1465-HYM-0430] II 7 semistriatus [DISAFA-draw1465-HYM-0227].

Figures 12-15. Fore wing venations: 12 Trissolcus belenus [DISAFA-draw1465-0010] 13 7 manteroi
[DISAFA-draw 1465-0430] 14 Z rufiventris [USNMENT01223145] 15 7 semistriatus [DISAFA-
draw1465-0229].

170 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Figures 16-19. Metasomal tergites: 16 Trissolcus belenus [DISAFA-draw1465-HYM-0009] 17 T. colem-

ani [DISAFA-draw1466-HYM-0484] 18 7? manteroi [DISAFA-draw1465-HYM-0430] 19 7 semistriatus
[DISAFA-draw1465-HYM-0227].

Trissolcus belenus (Walker)
https://bioguid.osu.edu/xbiod_concepts/3190
Figures 4, 8, 12, 16, 20, 21, 26, 30, 33, 37, 41, 45-51.

Telenomus Belenus Walker, 1836: 352 (original description).
Telenomus arminon Walker, 1838: 457 (original description).

Telenomus Nigrita Thomson, 1860: 172 (original description, synonymized by Kozlov
(1968)); Kozlov 1968: 214 (junior synonym of Trissolcus grandis (Thomson)).
Telenomus frontalis Thomson, 1860: 170 (original description, synonymized by Kozlov
(1968)); Kozlov 1968: 214 (junior synonym of Trissolcus grandis (Thomson)).

Telenomus grandis Thomson, 1860: 169 (original description).

An integrated approach reveas cryptic species of Trissolcus in Europe

Figures 20-25. Mesonotum; mshs and traces of notauli: 20 Trissolcus belenus [DISAFA-draw1465-
HYM-0009] 21 7° delenus [DISAFA...] after treatment in potassa solution to remove setae 22 T’ colem-
ani [DISAFA-draw1466-HYM-0484] 23 7 colemani [DISAFA-draw1466-HYM-0483] after treatment
in potassa solution to remove setae 24 7! manteroi [DISAFA-draw1465-HYM-0430] 25 7. semistriatus
[DISAFA-draw1465-HYM-0227].

72 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

De

Figures 26-29. Hind femur: 26 Trissolcus belenus [DISAFA-draw1465-HYM-0009] 27 7) colemani
[DISAFA-draw1466-HYM-0484] 28 7. manteroi [DISAFA-draw1465-HYM-0430] 29 7. semistriatus
[DISAFA-draw1465-HYM-0227].

Telenomus nigripes Thomson, 1860: 170 (original description, synonymized by Ko-
zlov (1968)); Kozlov 1968: 214 (junior synonym of Trissolcus grandis (Thom-
son)); Fergusson 1984: 230 (lectotype designation); Johnson 1992: 629 (type
information).

Telenomus ovulorum Thomson, 1860: 171 (original description, synonymized by Mayr
(1879)); Mayr 1879: 704 (junior synonym of Telenomus semistriatus (Nees von
Esenbeck)).

Teleas (2) Pentatomae Rondani: Rondani, 1874: 135 (nomen nudum).

Teleas pentatomae Rondani, 1877: 199 (original description).

Telenomus ovulorum Thomson: Mayr 1879: 704. Junior synonym of Telenomus semis-
triatus (Nees von Esenbeck)

Telenomus nigritus Thomson: Dalla Torre 1898: 517 (emendation).

Telenomus pentatomae (Rondani): Dalla Torre, 1898: 518 (generic transfer).

Allophanurus Arminon (Walker): Kieffer, 1912: 12 (description, generic transfer).

Aphanurus Belenus (Walker): Kieffer, 1912: 83 (description, generic transfer).

Aphanurus Frontalis (Thomson): Kieffer, 1912: 81 (description, generic transfer).

Aphanurus Grandis (Thomson): Kieffer, 1912: 76 (description, generic transfer).

Aphanurus Nigrita (Thomson): Kieffer, 1912: 79 (description, generic transfer).

Aphanurus nigripes (Thomson): Kieffer, 1912: 75 (description, generic transfer).

Liophanurus Pentatomae (Rondani): Kieffer, 1912: 69 (description, generic transfer).

Allophanurus arminon (Walker): Kieffer, 1926: 23 (description, keyed).

Liophanurus pentatomae (Rondani): Kieffer, 1926: 71 (description).

Microphanurus belenus (Walker): Kieffer, 1926: 91, 102 (description, generic trans-
fer, keyed).

An integrated approach reveas cryptic species of Trissolcus in Europe 173

Figures 30-36. 30-32 Laterotergite 1 30 Trissolcus belenus [DISAFA-draw1465-HYM-0009] 31 7
colemani [DISAFA-draw1466-HYM-0484] 32 ZT semistriatus [DISAFA-draw1465-HYM-0227] 33=
36 Occipital carina 33 Trissolcus belenus [DISAFA-draw1465-HYM-0009] 34 T° colemani [DISAFA-
draw1466-HYM-0484] 35 77 manteroi [DISAFA-draw1465-HYM-0430] 36 T. semistriatus [DISAFA-
draw1465-HYM-0227].

Microphanurus frontalis (Thomson): Kieffer, 1926: 91, 103 (description, generic trans-
fer, keyed).

Microphanurus grandis (Thomson): Kieffer, 1926: 91, 99 (description, generic transfer,
keyed); Debauche 1947: 256 (description).

Microphanurus nigripes (Thomson): Kieffer, 1926: 91, 98 (description, generic transfer,
keyed).

Microphanurus nigritus (Thomson): Kieffer, 1926: 91, 100 (description, generic trans-
fer, keyed).

Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

f NAY, | , y) \ Aah A g Me ‘Ort: mm

[DISAFA-draw1465-HYM-0009]
38 7. colemani |DISAFA-draw1466-HYM-0484] 39 7 manteroi [DISAFA-draw1465-HYM-0430]
40 7. semistriatus [DISAFA-draw1465-HYM-0227] 41=44 Head in frontal view 41 Trissolcus belenus
[DISAFA-draw1465-HYM-0009] 42 7 colemani [DISAFA-draw1466-HYM-0484] 43 7 manteroi
[DISAFA-draw1465-HYM-0430] 44 7. semistriatus [DISAFA-draw1465-HYM-0227].

Figures 37-44. 37-40 Head; malar area and gena 37 Trissolcus belenus

An integrated approach reveas cryptic species of Trissolcus in Europe 175

Asolcus grandis (Thomson): Masner, 1959: 376. (diagnosis, variation); Delucchi 1961:
44, 60 (description, keyed); Voegelé 1964: 28 (keyed); Javahery 1968: 419 (keyed);
Voegelé 1969: 150 (keyed).

Trissolcus grandis (Thomson) syn. nov.: Viktorov, 1967: 91 (generic transfer, keyed);
Safavi 1968: 416 (keyed); Kozlov 1968: 200, 214 (description, lectotype designa-
tion, synonymy, keyed); Fabritius 1972: 32, 35. (keyed; host catalogue; distribu-
tion); Viggiani and Mineo 1974: 156, 160, 161 (description, keyed); Kozlov and
Lé 1977: 512 (synonymy, keyed); Kozlov 1978: 636 (description); Kozlov 1981:
187 (keyed); Kozlov and Kononova 1983: 110 (description); Johnson 1992: 629
(cataloged, type information); Kononova 1995: 96 (keyed); Doganlar 2001: 112
(description); Kocgak and Kilinger 2003: 302, 307 (keyed, description); Fabritius
and Popovici 2007: 158 (host informations, distribution); Buhl & O’Connor,
2010: 154 (distribution); Ali 2011: 10 (keyed); Ghahari et al. 2011: 596 (host
association, listed); Guz et al. 2013: 87 (description, phylogenetic relationships);
Petrov 2013: 326 (keyed); Kononova 2014: 1424 (keyed); Kononova 2015: 262
(keyed); Talamas et al. 2017: 129, 135 (junior synonym of Trissolcus semistriatus
(Nees von Esenbeck), type information).

Asolcus nixomartini Javahery, 1968: 419, 429 (original description, keyed, synonymized
by Kozlov and Lé (1977)); Kozlov and Lé 1977: 512 (junior synonym of Trissolcus
grandis (Thomson)); Johnson 1992: 629 (type information).

Asolcus silwoodensis Javahery, 1968: 419, 425 (original description, keyed, synonymized
by Kozlov and Lé (1977)); Kozlov and Lé 1977: 512 (junior synonym of Trissolcus
grandis (Thomson)); Johnson 1992: 629 (type information).

Trissolcus pentatomae (Rondani) syn. nov.: Bin, 1974: 463 (generic transfer, lectotype
designation); Johnson 1992: 634 (cataloged, type information); Talamas et al.
2017: 130, 135 (junior synonym of Trissolcus semistriatus (Nees von Esenbeck),
type information).

Trissolcus belenus (Walker): Fergusson, 1978: 120 (generic transfer); Fergusson 1984: 230
(lectotype designation); Johnson 1992: 623 (cataloged, type information); Kononova
2014: 1426 (possibly in Telenomus); Kononova 2015: 264 (possibly in Téelenomus).

Trissolcus nigripes (Thomson) syn. nov.: Fergusson, 1978: 120 (generic transfer).

Trissolcus nixomartini (Javahery) syn. nov.: Fergusson, 1978: 120 (generic transfer);
Fergusson 1984: 230 (type information).

Trissolcus silwoodensis (Javahery) syn. nov.: Fergusson, 1978: 120 (generic transfer);
Fergusson 1984: 230 (type information).

Trissolcus arminon (Walker) syn. nov.: Fergusson 1983: 208 (generic transfer, descrip-
tion, lectotype designation); Fergusson 1984: 230 (type information); Johnson
1992: 622 (cataloged, type information).

Trissolcus ovulorum (Thomson) comb. nov., syn. nov.

Diagnosis. The presence of setae on the first laterotergite (Figures 30, 45) allows 7.
belenus to be easily diagnosed, as only two other Palearctic species share this character:
T. saakowi and T: mitsukurii (Ashmead). Both of these species have distinct notauli,

176 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

which are absent in 7’ belenus (Figures 20, 22). Additionally, the hyperoccipital carina
is entirely absent in 7’ belenus (Figures 33, 47, 49), whereas it is complete in 7 saakowi
and present posterior to the lateral ocellus in 7’ mitsukurii.

Description. Body length: 1.03—1.1 mm, median = 1.06 mm, SD = 0.02, n = 20.
Body color: head, mesosoma, and metasoma black.

Head. FCI = 1.4; LCI = 1.9; IOS = 0.3 mm; OOL:POL:LOL = 1:12:5.8. Color
of radicle: dark brown. Length of radicle: about equal to width of clypeus. Color of
A1—AG in female: distal A2 yellow to light brown, otherwise black. Color of A7—A11
in female: black. Number of papillary sensilla on A6: 0. Number of papillary sensilla
on A7: 2. Facial striae: absent. Number of clypeal setae: 6. Shape of gena in lateral
view: narrow. Genal carina: present only at base of mandible. Malar striae: absent.
Sculpture of malar sulcus: distinctly and sparsely striate. Orbital furrow: uniform in
width between midpoint of eye and malar sulcus. Macrosculpture of frons directly
dorsal to the antennal scrobe: coarsely rugose. Preocellar pit: present. Setation of lateral
frons: sparse; moderately dense. Punctation of lateral frons: sparse. Sculpture directly
ventral to preocellar pit: dorsoventrally fluted. Rugae on lateral frons: weakly devel-
oped to absent. OOL: less than one ocellar diameter. Hyperoccipital carina: absent.
Macrosculpture of posterior vertex: absent. Microsculpture on posterior vertex along
occipital carina: granulate. Anterior margin of occipital carina: crenulate. Medial part
of occipital carina in dorsal view: rounded.

Mesosoma. Epomial carina: present. Macrosculpture of lateral pronotum directly
anterior to netrion: finely rugulose. Netrion sulcus: complete. Pronotal suprahumeral
sulcus in posterior half of pronotum: undifferentiated from sculpture of dorsal prono-
tum. Number of episternal foveae: 2. Course of episternal foveae ventrally: distinctly
separate from postacetabular sulcus. Course of episternal foveae dorsally: distinctly
separate from mesopleural pit. Subacropleural sulcus: present. Speculum: transversely
strigose. Mesopleural pit: extending ventrally into dorsoventral furrow parallel to mes-
opleural carina. Mesopleural carina: well defined anteriorly, poorly defined to absent
posteriorly. Sculpture of femoral depression: smooth. Patch of striae at posteroventral
end of femoral depression: present, striae oblique to long axis of femoral depression.
Setal patch at posteroventral end of femoral depression: present as a line of setae. Mi-
crosculpture of anteroventral mesopleuron: present throughout. Macrosculpture of
anteroventral mesopleuron: absent. Postacetabular sulcus: comprised of large cells.
Mesopleural epicoxal sulcus: comprised of cells. Setation of posteroventral metapleu-
ron: absent. Sculpture of dorsal metapleural area: absent. Posterodorsal metapleural
sulcus: present as a line of foveae. Paracoxal sulcus in ventral half of metapleuron:
indistinguishable from sculpture. Length of anteroventral extension of metapleuron:
elongate, extending to base of mesocoxa. Apex of anteroventral extension of meta-
pleuron: rounded. Metapleural epicoxal sulcus: present as coarse rugae. Mesoscutal
humeral sulcus: comprised of cells. Median mesoscutal carina: absent. Microsculpture
of mesoscutum: imbricate-punctate anteriorly, becoming longitudinally imbricate-
strigate posteriorly. Mesoscutal suprahumeral sulcus: comprised of cells. Length of
mesoscutal suprahumeral sulcus: two-thirds the length of anterolateral edge of mes-
oscutum. Parapsidal line: absent. Notaulus: absent. Median protuberance on anterior

An integrated approach reveas cryptic species of Trissolcus in Europe aes

margin of mesoscutellum: absent. Shape of dorsal margin of anterior lobe of axillar
crescent: acute. Sculpture of anterior lobe of axillar crescent: dorsoventrally strigose.
Area bound by axillar crescent: smooth. Macrosculpture of mesoscutellum: absent.
Microsculpture on mesoscutellum: imbricate-punctate laterally to granulate medially.
Median mesoscutellar carina: absent. Setation of posterior scutellar sulcus: present.
Form of metascutellum: single row of cells. Metanotal trough: foveate, foveae occupy-
ing more than half of metanotal height. Metapostnotum: invaginated near lateral edge
of metascutellum. Length of postmarginal vein: about twice as long as stigmal vein.
Color of legs: coxae dark brown to black, femora and tibia dark brown with yellowish
tips, trochanters and tarsi yellow to pale brown. Anteroventral area of hind femora: not
covered by setae. Anteromedial portion of metasomal depression: smooth.
Metasoma. Width of metasoma: about equal to width of mesosoma. Longitudinal
striae on Tl posterior to basal costae: pair of longitudinal submedial carinae separate
a lateral smooth area from an internal area where striate sculpture starts with basal
grooves. Number of sublateral setae (on one side): 1. Setation of laterotergite 1: present.
Length of striation on T2: extending two-thirds the length of the tergite. Setation of T2:
present in a transverse line and along lateral margin. Setation of laterotergite 2: present.
Host associations. Pentatomidae: Aelia rostrata; Arma custos; Carpocoris sp.; Doly-
coris sp.; Graphosoma italicum Miller; Palomena prasina; Picromerus bidens (L.); Piezo-
dorus sp.; sentinel frozen eggs of Halyomorpha halys. Scutelleridae: Eurygaster integriceps
Puton; Eurygaster maura.
Link to distribution map. [https://hol.osu.edu/map-large.html?id=3 190]
Material examined. Lectotype, male Telenomus Belenus: ENGLAND and WESTERN
Europe: no date, NMINH_2018_11_49 (deposited in NMID); Lectotype, female,
Telenomus arminon: UnrrED Kincpom: England, Dorset County, Lyme Regis, no date,
NMINH_2018_11_46 (deposited in NMID); Holotype, female, Asolcus nixomartini:
Unirep Kincpom: England, Windsor and Maidenhead Unit. Auth., Silwood Park, 1966,
reared from egg, M. Javahery, B.M. TYPE HYM. 9.798 (deposited in BMNH)); Paratypes
of Asolcus nixomartini: UNITED Kincpom: | female, 2 males, UNIPA-HYM-S01317—
S01318 (BMNH); OSUC 17734 (BMNH); Holotype, female, Asolcus silwoodensis:
Unirep Kincpom: England, Windsor and Maidenhead Unit. Auth., Silwood Park, 1966,
reared from egg, M. Javahery, B.M. TYPE HYM. 9.797 (deposited in BMNH)); Paratypes
of Asolcus silwoodensis: UNITED KINGDom: 4 females, 4 males, UNIPA-HYM-S01309-—
S01316 (BMNH). Syntype males, Zélenomus ovulorum Thomson: SWEDEN: no date, Bo-
heman, NHRS-HEVA 000006872 (deposited in NHRS). Lectotype, female, 7élenomus
nigripes. SWEDEN: Vastra Gotaland, no date, Boheman, NHRS-HEVA 000006873 (de-
posited in NHRS). Paratype of 77 nixomartini: UNrrED Kincpom: | male, OSUC 17734
(BMNH). Other material: (437 females, 67 males, 21 pins with multiple specimens).
Curna: 1 female, OSUC 571231 (OSUC). IRAN: 16 females, HMIM-HYM-05-06,
08-09, 011-012, 014, 027, 039 (HMIM); USNMENT01223080—01223082,
01223425, 01223430, 01223435, 01223440 (UNIPA). Iraty: 366 females, 63 males,
17 pins with multiple specimens, DISAFA-draw1465-HYM-0006-0219 (DISAFA);
MSNG_ -HYM-0001-0004, USNMENT01223249-01223258 (MCSN); USN-
MENT01223090—01223130, 01223132—01223139, 01223230-01223246 (UNIPA).

178 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

oe # = - . <

Figures 45-48. Holotype of Trissolcus belenus [|NMINH_2018_11_49]: 45 mesoscutal humeral sulcus and
laterotergite 1 in lateral view 46 body in lateral view 47 body in antero-lateral view 48 body in dorsal view.

An integrated approach reveas cryptic species of Trissolcus in Europe ee)

*
-

Figures 49-51. Holotype of

50 head and mesosoma in antero-lateral view 51 body in postero-lateral view.

Morocco: 24 female, 1 pin with multiple specimens, OSUC 17729 (BMNH); USN-
MENT01223131 (UNIPA). Porrucat: 6 females, 1 male, 1 pin with multiple speci-
mens, USNMENT00916191, 00916210-00916213, 00916217 (BMNH). Russia:
4 females, 2 males, 2 pins with multiple specimens, OSUC 17796-17797 (BMNH).

180 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

SWEDEN: 12 females, 2 males, UNIPA-HYM-S01306—S01307, USNMENT00916047,
USNMENT00916051, © USNMENT00916052, .USNMENT00916070, USN-
MENT00916302—00916309 (BMNH). Swirzertanp: 6 females, DISAFA-draw1465-
HYM-0001—0005 (DISAFA); USNMENT01109059 (USNM). Tanzania: 1 female,
USNMENT01223480 (MZUF). UnrreED Kincpom: | female, 1 male, UNIPA-HYM-
S01308 (BMNH); USNMENT00896318 (CNCI).

Trissolcus colemani (Crawford)
https://bioguid.osu.edu/xbiod_concepts/3203
Figures 5, 9, 17, 22, 23, 27, 31, 34, 38, 42, 52-55

Telenomus colemani Crawford, 1912: 2 (original description).

Microphanurus djadetshko Ryakhovskii, 1959: 84, 87 (original description, keyed).

Microphanurus pseudoturesis Ryakhovskii, 1959: 83, 85 (original description, keyed).

Microphanurus rossicus Ryakhovskii, 1959: 83, 86 (original description, keyed, syn-
onymized by Viktorov (1964)); Viktorov 1964: 1021 (junior synonym of Trissolcus
pseudoturesis (Ryakhovskii)); Johnson 1992: 635 (type information).

Asolcus nigribasalis Voegelé, 1962: 155 (original description); Voegelé 1964: 28 (keyed);
Voegelé 1965: 96, 108 (variation, diagnosis, keyed); Voegelé 1969: 151 (junior
synonym of Asolcus djadetshko (Ryakhovskii)).

Asolcus djadetshko (Ryakhovskii): Viktorov, 1964: 1015, 1021 (description, generic
transfer, removed from synonymy with Télenomus scutellaris Thomson, keyed);
Voegelé 1969: 151 (synonymy, keyed, spelling error).

Asolcus pseudoturesis (Ryakhovskii): Viktorov, 1964: 1013, 1021 (description, generic
transfer, synonymy, keyed); Voegelé 1969: 151 (synonymy, keyed).

Asolcus bennisi Voegelé, 1964: 119 (original description); Voegelé 1965: 96, 108 (varia-
tion, diagnosis, keyed); Voegelé 1969: 151 (junior synonym of Asolcus pseudoturesis
(Ryakhovskii)).

Trissolcus djadetshko (Ryakhovskii) syn. nov.: Viktorov, 1967: 91 (generic transfer,
keyed); Safavi 1968: 415 (keyed); Kozlov 1968: 200 (keyed); Fabritius 1972: 31
(keyed); Kozlov and Lé 1977: 512 (keyed); Kozlov 1978: 636 (description); Kozlov
1981: 187 (keyed); Kozlov and Kononova 1983: 115 (description); Johnson 1992:
626 (cataloged, type information); Kononova 1995: 96 (keyed); Kogak and Kilin-
cer 2000: 171 (description, diagnosis, new distribution record for Turkey); Kocak
and Kilincer 2003: 303, 313 (keyed, description); Fabritius and Popovici 2007:
159 (checklist, host information, distribution); Ghahari et al. 2011: 595 (listed);
Petrov 2013: 326 (keyed); Kononova 2014: 1425 (keyed); Kononova 2015: 263
(keyed); Talamas et al. 2017: 129 (junior synonym of Trissolcus semistriatus (Nees
von Esenbeck)).

Trissolcus pseudoturesis (Ryakhovskii) syn. nov.: Viktorov, 1967: 91 (generic transfer,
keyed); Safavi 1968: 415 (keyed); Kozlov 1968: 200 (keyed); Fabritius 1972: 31
(keyed); Kozlov and Lé 1977: 512 (keyed); Kozlov 1978: 636 (description); Ko-
zlov and Kononova 1983: 114 (description); Johnson 1992: 635 (cataloged, type

An integrated approach reveas cryptic species of Trissolcus in Europe 181

information); Kononova 1995: 96 (keyed); Kocak and Kilincer 2003: 302, 310
(keyed, description); Ghahari et al. 2011: 596 (listed); Petrov 2013: 326 (keyed);
Kononova 2014: 1425 (keyed); Kononova 2015: 263 (keyed).

Trissolcus colemani (Crawford): Masner and Muesebeck 1968: 72 (type information,
generic transfer); Johnson 1992: 625 (cataloged, type information).

Asolcus waloffae Javahery, 1968: 419 (original description, keyed).

Asolcus djadestshko (Ryakhovskii): Voegelé, 1969: 151 (synonymy, keyed, spelling error).

Trissolcus bennisi (Voegelé): Kozlov and Lé 1977: 516 (generic transfer, keyed); Kozlov
1978: 637 (description); Kozlov and Kononova 1983: 122 (description); Johnson
1992: 623 (cataloged, type information); Kononova 2014: 1425 (keyed); Kon-
onova 2015: 263 (keyed).

Trissolcus nigribasalis (Voegelé): Kozlov and Lé 1977: 518 (keyed); Kozlov 1978: 637
(description); Kozlov and Kononova 1983: 124 (description); Johnson 1992: 633
(cataloged, type information); Kononova 2014: 1425 (keyed); Kononova 2015:
263 (keyed).

Trissolcus waloffae (Javahery) syn. nov.: Kozlov and Lé 1977: 516 (keyed, generic trans-
fer); Kozlov 1978: 637 (description); Kozlov and Kononova 1983: 123 (descrip-
tion); Fergusson 1984: 231 (type information); Johnson 1992: 640 (cataloged,
type information); Kononova 2014: 1425 (keyed); Kononova 2015: 263 (keyed).

Trissolcus crypticus Clarke syn. nov., 1993: 524 (original description); Ghahari et al.
2011: 595 (new distribution record for Iran, host association, listed); Kononova
2014: 1426 (status unknown (not examined)); Kononova 2015: 264 (status un-
known (not examined)).

Diagnosis. Trissolcus colemani is identified by a combination of characters more than
by the presence of a distinct feature. The foveate mesoscutal humeral sulcus (Figures 21,
23) separates it from all the species treated here with the exception of 7’ belenus (Figures
20, 22). Trissolcus colemani and T. belenus are very similar in general appearance and
these two species can be separated most reliably by setation of laterotergite 1: present in
T. belenus (Figures 30, 45) and absent in 7’ colemani (Figure 31, 53). The anteroventral
extension of the metapleuron reaches the mesocoxa in lateral view in both 7 belenus
and 7) colemani and exhibits difference in the shape of its apex between these species.
In 7 colemani, the anteroventral extension of the metapleuron is very slender (Figure
5) compared to T’ belenus, in which it is thicker, and the apex is rounded (Figure 4).

Description. Body length: 0.96-1.10 mm, m = 1.01 mm, SD = 0.03, n = 22.
Body color: head, mesosoma, and metasoma black.

Head. ECA —sl52LGl oe alOs* = 033mm; OL POLLO lac lel 3.5-0)
Color of radicle: brown. Length of radicle: about equal to width of clypeus. Color
of Al-A6 in female: variably yellow to brown. Color of A7—A11 in female: brown
to black. Number of papillary sensilla on A6: 0. Number of papillary sensilla on
A7: 2. Facial striae: absent. Number of clypeal setae: 6. Shape of gena in lateral
view: narrow. Genal carina: present only at base of mandible. Malar striae: absent.
Sculpture of malar sulcus: distinctly and sparsely striate. Orbital furrow: uniform in
width between midpoint of eye and malar sulcus. Macrosculpture of frons directly

182 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

dorsal to the antennal scrobe: weakly rugose. Preocellar pit: present. Setation of
lateral frons: sparse; moderately dense. Punctation of lateral frons: sparse. Sculpture
directly ventral to preocellar pit: dorsoventrally fluted. Rugae on lateral frons: coarse.
OOL: less than one ocellar diameter. Hyperoccipital carina: absent. Macrosculpture
of posterior vertex: absent. Microsculpture on posterior vertex along occipital carina:
granulate. Anterior margin of occipital carina: crenulate. Medial part of occipital
carina in dorsal view: rounded.

Mesosoma. Epomial carina: present. Macrosculpture of lateral pronotum directly
anterior to netrion: finely rugulose. Netrion sulcus: complete. Pronotal suprahumeral
sulcus in posterior half of pronotum: undifferentiated from sculpture of dorsal prono-
tum. Number of episternal foveae: 2; 3. Course of episternal foveae ventrally: distinct-
ly separate from postacetabular sulcus. Course of episternal foveae dorsally: distinctly
separate from mesopleural pit. Subacropleural sulcus: present. Speculum: transversely
strigose. Mesopleural pit: extending ventrally into dorsoventral furrow parallel to mes-
opleural carina. Mesopleural carina: well defined anteriorly, poorly defined to absent
posteriorly. Sculpture of femoral depression: smooth. Patch of striae at posteroventral
end of femoral depression: present, striae oblique to long axis of femoral depression.
Setal patch at posteroventral end of femoral depression: present. Microsculpture of anter-
oventral mesopleuron: present throughout. Macrosculpture of anteroventral mesopleu-
ron: absent. Postacetabular sulcus: comprised of large cells. Mesopleural epicoxal sulcus:
comprised of cells. Setation of posteroventral metapleuron: absent. Sculpture of dorsal
metapleural area: absent. Posterodorsal metapleural sulcus: present as a line of foveae.
Paracoxal sulcus in ventral half of metapleuron: indistinguishable from sculpture. Length
of anteroventral extension of metapleuron: elongate, extending to base of mesocoxa.
Apex of anteroventral extension of metapleuron: acute. Metapleural epicoxal sulcus: pre-
sent as coarse rugae. Mesoscutal humeral sulcus: comprised of cells. Median mesoscutal
carina: absent. Microsculpture of mesoscutum: imbricate-punctate anteriorly, becoming
longitudinally imbricate-strigate posteriorly. Mesoscutal suprahumeral sulcus: comprised
of cells. Length of mesoscutal suprahumeral sulcus: two-thirds the length of anterolateral
edge of mesoscutum. Parapsidal line: absent. Notaulus: presence of short traces. Median
protuberance on anterior margin of mesoscutellum: absent. Shape of dorsal margin of
anterior lobe of axillar crescent: acute. Sculpture of anterior lobe of axillar crescent: dor-
soventrally strigose. Area bound by axillar crescent: smooth. Macrosculpture of mesos-
cutellum: absent. Microsculpture on mesoscutellum: imbricate-punctate. Median mes-
oscutellar carina: absent. Setation of posterior scutellar sulcus: present. Form of metas-
cutellum: single row of cells. Metanotal trough: foveate, foveae occupying more than half
of metanotal height. Metapostnotum: invaginated near lateral edge of metascutellum.
Length of postmarginal vein: about twice as long as stigmal vein. Color of legs: coxae
dark brown to black, femora yellow to light brown with yellowish tips, tibia trochanters
and tarsi yellow to pale brown. Anteroventral area of hind femora: not covered by setae.
Anteromedial portion of metasomal depression: smooth.

An integrated approach reveas cryptic species of Trissolcus in Europe 183

eel “ =,

Figures 52-55. Holotype of Trissolcus colemani [USNMENT00989063]: 52 body in dorsal view

53 body in lateral view 54 head in frontal view 55 head in ventral view and mesosoma in lateral view.

184 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Metasoma. Width of metasoma: about equal to width of mesosoma. Longitudinal
striae on Tl posterior to basal costae: pair of longitudinal submedial carinae separate
a lateral smooth area from an internal area where striate sculpture starts with basal
grooves. Number of sublateral setae (on one side): 1. Setation of laterotergite 1: absent.
Length of striation on T2: extending two-thirds the length of the tergite. Setation of T2:
present in a transverse line and along lateral margin. Setation of laterotergite 2: present.

Host associations. Pentatomidae: Dolycoris indicus (Type host); Aelia acuminata
L.; Aelia sp.; Brachynema germarii (Kolenati); Dolycoris sp.; Graphosoma semipunctatum
(E); Graphosoma sp. Scutelleridae: Eurygaster integriceps; Eurygaster maura.

Link to distribution map. [https://hol.osu.edu/map-large.html?id=3203]

Material examined. Holotype, female, 7elenomus colemani: INpia: Karnataka St.,
Hongashenhalli (Hunsmanalli), 6.111909, L. C. Coleman, USNMENT00989063
(deposited in USNM). Syntype, female, Microphanurus pseudoturesis: UKRAINE:
Donetsk (Stalinskaya) Reg., V-1952/1953—VII-1952/1953, V. Rjachovsky, USN-
MENT00954008 (deposited in ZIN). Syntype, female, Microphanurus pseudoturesis:
Uxratne: Donets’k (Stalinskaya) Reg., V-1952/1953—VII-1952/1953, V. Rjachovsky,
USNMENT00954010. Holotype, female, A. waloffae: UNITED KINGDOM: England,
Windsor and Maidenhead Unit. Auth., Silwood Park, VI-1965, reared, B.M. TYPE
HYM. 9.795 (deposited in BMNH). Paratypes of Trissolcus crypticus: PAKISTAN: 3 females,
3 males, OSUC 17744, UNIPA-HYM-S01319-S01323 (BMNH). Paratype of Micro-
phanurus djadetshko: Ukraine: 1 female, USNMENT00954012 (ZIN). Paratypes of
Asolcus waloffae: UNITED KINGDOM: 11 females, 11 males, 1 pin with multiple specimens,
OSUC 17731, UNIPA-HYM-S01324, USNMENT0119671—0119674 (BMNH).

Other material: (144 females, 52 males, 6 pins with multiple specimens) Curna:
1 female, UCRC ENT 142649 (UCRC). France: 1 female, USNMENT00896254
(CNCI). Greece: 1 female, USNMENT00896062 (CNCI). Iran: 17 females,
HMIM-HYM-015, 017-018, 020-021, 025, 028, 031, 036, 042 (HMIM); US-
NMENT01223445, 01223450, 01223455, 01223460, 01223465, 01223470,
01223475 (UNIPA). ITaty: 82 females, 19 males, 2 pins with multiple specimens, DIS-
AFA-draw1466-HYM-0483-—0488 (DISAFA); USNMENT01223144, 01223146-—
01223221, 01223481 (UNIPA). Morocco: 39 females, 31 males, 3 pins with mul-
tiple specimens, OSUC 17728, 17743 (BMNH); UNIPA-HYM-S01325 (BMNH).
Russia: 3 females, 1 pin with multiple specimens, USNMENT01223222-01223223
(MCSN). SwEDEN: 2 males, USNMENT00916067—00916068 (BMNH).

Trissolcus manteroi (Kieffer)
https://bioguid.osu.edu/xbiod_concepts/3260
Figures 6, 10, 13, 18, 24, 28, 35, 39, 43, 56-58

Telenomus Manteroi Kieffer, 1909: 268 (original description).

Aphanurus Manteroi (Kieffer): Kieffer 1912: 84 (description, generic transfer).

Microphanurus manteroi (Kieffer): Kieffer 1926: 91, 102. (description, generic transfer,
keyed); Boldaruyev 1969: 163, 170 (description, keyed)

An integrated approach reveas cryptic species of Trissolcus in Europe 185

Trissolcus manteroi (Kieffer): Kozlov 1968: 199 (keyed); Fabritius 1972: 31 (keyed); Bin
1974: 462 (type information); Kozlov and Lé 1977: 514 (keyed); Kozlov 1978:
636 (description); Kozlov and Kononova 1983: 117 (description); Johnson 1992:
631 (cataloged, type information); Kocak and Kilincer 2000: 174 (description,
diagnosis, new distribution record for Turkey); Kocak and Kilinger 2003: 302, 310
(keyed, description of female); Kocak and Kodan 2006: 41 (description of male);
Fabritius and Popovici 2007: 159. (host information, distribution); Ghahari et al.
2011: 596 (listed); Kononova 2014: 1424 (keyed); Kononova 2015: 262 (keyed);
Talamas et al. 2017: 129, 135 (junior synonym of Trissolcus semistriatus (Nees von
Esenbeck), type information).

Diagnosis. Trissolcus manteroi and T: rufiventris are the only two species of Palearctic
Trissolcus in which females exhibit a 1-2-2-2-1 claval formula (Figure 10). These two
can be separated from each other by the length of the postmarginal vein in the fore
wing: slightly longer than the stigmal vein in 7’ manteroi (Figure 13) and about twice
as long as the stigmal vein in 7’ rufiventris (Figure 14). These two species can also be
separated from each other by the form of the mesopleural epicoxal sulcus, which is
comprised of cells in 7? manteroi and is a smooth furrow in T’ rufiventris.

Description. Female body length: 0.99-1.09 mm, m = 1.04 mm, SD = 0.02, n =
16. Body color: head, mesosoma, and metasoma black.

Head. FCI = 1.4; LCI = 1.8; IOS = 0.3 mm; OOL:POL:LOL = 1:12:5.3. Color of
radicle: dark brown. Length of radicle: less than width of clypeus. Color of A1—AG in
female: distal A2 yellow to light brown, otherwise black. Color of A7—A11 in female:
black. Number of papillary sensilla on AG: 0. Number of papillary sensilla on A7: 1.
Facial striae: absent. Number of clypeal setae: 6. Shape of gena in lateral view: narrow.
Genal carina: present only at base of mandible. Malar striae: absent. Sculpture of malar
sulcus: weakly and densely striate. Orbital furrow: uniform in width between midpoint
of eye and malar sulcus. Macrosculpture of frons directly dorsal to the anterior ocellus:
weakly rugose. Preocellar pit: present. Setation of lateral frons: sparse; moderately dense.
Punctation of lateral frons: sparse. Sculpture directly ventral to preocellar pit: dorsoven-
trally fluted. Rugae on lateral frons: weakly developed to absent. OOL: less than one
ocellar diameter. Hyperoccipital carina: absent. Macrosculpture of posterior vertex: ab-
sent. Microsculpture on posterior vertex along occipital carina: granulate. Anterior mar-
gin of occipital carina: crenulate. Medial part of occipital carina in dorsal view: rounded.

Mesosoma. Epomial carina: present. Macrosculpture of lateral pronotum directly
anterior to netrion: finely rugulose. Netrion sulcus: complete. Pronotal suprahumeral
sulcus in posterior half of pronotum: undifferentiated from sculpture of dorsal prono-
tum. Number of episternal foveae: 0. Subacropleural sulcus: present. Speculum: trans-
versely strigose. Mesopleural pit: extending ventrally into dorsoventral furrow parallel
to mesopleural carina. Mesopleural carina: well defined anteriorly, poorly defined to
absent posteriorly. Sculpture of femoral depression: smooth. Patch of striae at pos-
teroventral end of femoral depression: present, striae oblique to long axis of femoral
depression. Setal patch at posteroventral end of femoral depression: absent. Micros-
culpture of anteroventral mesopleuron: present throughout. Macrosculpture of anter-

186 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

oventral mesopleuron: absent. Postacetabular sulcus: comprised of large cells. Meso-
pleural epicoxal sulcus: comprised of cells. Setation of posteroventral metapleuron:
absent. Sculpture of dorsal metapleural area: absent. Posterodorsal metapleural sulcus:
present as a line of foveae. Paracoxal sulcus in ventral half of metapleuron: indistin-
guishable from sculpture. Length of anteroventral extension of metapleuron: short, not
extending to base of mesocoxa. Metapleural epicoxal sulcus: present as coarse rugae.
Mesoscutal humeral sulcus: present as a simple furrow. Median mesoscutal carina: ab-
sent. Microsculpture of mesoscutum: imbricate-punctate anteriorly, becoming longi-
tudinally imbricate-strigate posteriorly. Mesoscutal suprahumeral sulcus: comprised of
cells. Length of mesoscutal suprahumeral sulcus: two-thirds the length of anterolateral
edge of mesoscutum. Parapsidal line: absent. Notaulus: absent. Median protuberance
on anterior margin of mesoscutellum: absent. Shape of dorsal margin of anterior lobe
of axillar crescent: acute. Sculpture of anterior lobe of axillar crescent: dorsoventrally
strigose. Area bound by axillar crescent: smooth. Macrosculpture of mesoscutellum:

5 ead . ee a
Swear

Figures 56-58. Holotype of Trissolcus manteroi [MCSN 0013]: 56 body in dorsal view 57 head in

antero-lateral view 58 body in lateral view.

An integrated approach reveas cryptic species of Trissolcus in Europe 187

absent. Microsculpture on mesoscutellum: imbricate-punctate laterally to granulate
medially. Median mesoscutellar carina: absent. Setation of posterior scutellar sulcus:
present. Form of metascutellum: single row of cells. Metanotal trough: foveate, foveae
occupying more than half of metanotal height. Metapostnotum: invaginated near lat-
eral edge of metascutellum. Length of postmarginal vein: 1.1—1.2 times as long as stig-
mal vein. Color of legs: coxae dark brown to black, femora and tibia dark brown with
yellowish tips, trochanters and tarsi yellow to pale brown. Anteroventral area of hind
femora: not covered by setae. Anteromedial portion of metasomal depression: smooth.
Metasoma. Width of metasoma: about equal to width of mesosoma. Longitudinal
striae on I'l posterior to basal costae: pair of longitudinal submedial carinae separate
a lateral smooth area from an internal area where striate sculpture starts with basal
grooves. Number of sublateral setae (on one side): 1. Setation of laterotergite 1: absent.
Length of striation on T2: extending one-third the length of the tergite. Setation of T2:
present in a transverse line and along lateral margin. Setation of laterotergite 2: present.
Host associations. Pentatomidae: Carpocoris sp. (Type host); Aelia rostrata Bohe-
man; Dolycoris sp.
Link to distribution map. [https://hol.osu.edu/map-large.html?id=13225]
Material examined. Holotype, female, 7 Manteroi: rary: Liguria, Genoa,
9.VIII.1997, G. Mantero, MCSN 0013 (deposited in MCSN). Paratypes: Traty: 5
females, 1 male, 1 pin with multiple specimens, UNIPA-HYM-S01327, S01328
(MCSN). Other material: (20 females, 2 males, 1 pin with multiple specimens) Ar-
MENIA: 3 females, 1 pin with multiple specimens, USNMENT00979995, 00979997
(ZIN). Iran: 4 females, USNMENT01223224—01223227 (MCSN). Iraty: 13 fe-
males, 2 males, DISAFA-draw1465-HYM-0424—0438 (DISAFA).

Trissolcus semistriatus (Nees von Esenbeck)
https://bioguid.osu.edu/xbiod_concepts/3305
Figures: Zl lel 5, 9,25 229; 52), 36, 40, 44, 59, 60.

Teleas semistriatus Nees von Esenbeck, 1834: 290 (original description); Ratzeburg
1852: 182 (description); Johnson 1992: 519 (cataloged).

Telenomus semistriatus (Nees von Esenbeck): Thomson, 1860: 171 (description, ge-
neric transfer); Mayr 1879: 699, 701, 704 (description, synonymy, keyed).

Asolcus nigripedius Nakagawa, 1900: 17 (original description); Watanabe 1951: 21, 25
(description, type information, keyed); Watanabe 1954: 22 (keyed).

Aphanurus Semistriatus (Nees von Esenbeck): Kieffer, 1912: 74 (description, generic
transfer).

Microphanurus semistriatus (Nees von Esenbeck): Kieffer, 1926: 91, 97 (description,
generic transfer, keyed); Nixon 1939: 131, 134 (description, keyed); Meier 1940:
80 (description, keyed); Ryakhovskii 1959: 84 (keyed).

Microphanurus alexeevi Meier, 1949: 114 (original description, not seen: reference
from Kozlov (1963), synonymized with Asolcus semistriatus (Nees von Esenbeck)

188 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

by Kozlov (1963)); Ryakhovskii 1959: 83 (keyed); Kozlov 1963: 295 (junior syno-
nym of Asolcus semistriatus (Nees von Esenbeck)).

Microphanurus schtepetelnikovae Meier, 1949: 114 (original description, not seen: refer-
ence from Kozlov (1963), synonymized with Asolcus semistriatus (Nees von Esen-
beck) by Kozlov (1963)); Kozlov 1963: 295 (junior synonym of Asolcus semistriatus
(Nees von Esenbeck)).

Asolcus semistriatus (Nees von Esenbeck): Masner 1959: 376 (diagnosis, variation);
Delucchi 1961: 44, 59 (diagnosis, taxonomic status, keyed); Kozlov 1963: 295
(synonymy); Viktorov 1964: 1013, 1020 (variation, keyed); Kochetova 1966: 558
(description of immature stages); Javahery 1968: 419 (keyed); Voegelé 1969: 150
(keyed); Szabé 1976: 176, 178 (description, neotype designation, keyed).

Microphanurus stschepetilnicovae Meier: Ryakhovskii, 1959: 83 (keyed, spelling error).

Trissolcus nigripedius (Nakagawa): Masner, 1964: 146 (generic transfer); Ryu and
Hirashima 1984: 37, 56 (description, keyed); Johnson 1992: 633 (cataloged);
He, Chen, Fan, Li, Liu, Lou, Ma, Wang, Wu, Xu et al. 2004: 321 (description);
Fabritius and Popovici 2007: 157 (host informations, distribution); Kononova
2014: 1424 (keyed); Kononova 2015: 261 (keyed); Talamas et al. 2017: 130
(junior synonym of Trissolcus semistriatus (Nees von Esenbeck), neotype des-
ignation).

Trissolcus semistriatus (Nees von Esenbeck): Safavi, 1968: 416 (keyed); Kozlov 1968:
200 (keyed); Fabritius 1972: 32, 34 (keyed, host catalogue; distribution); Kozlov
and Lé 1977: 512 (keyed); Kozlov 1978: 636 (description); Kozlov and Konon-
ova 1983: 113 (description); Graham 1984: 92 (variation); Johnson 1992: 636
(cataloged, type information); Kononova 1995: 96 (keyed); Kocak and Kilinger
2003: 302, 305 (keyed, description); Ali 2011: 10 (keyed); Ghahari et al. 2011:
597 (listed); Guz et al. 2013: 87 (description, phylogenetic relationships); Petrov
2013: 326 (keyed); Kononova 2014: 1425 (keyed); Kononova 2015: 262 (keyed);
Talamas et al. 2017: 20, 25, 128 (description, keyed, synonymy, type information,
distribution).

Trissolcus artus Kozlov and Lé 1977: 512, 519 (original description, keyed); Kozlov
1978: 636 (description); Kozlov and Kononova 1983: 112 (description); Johnson
1992: 622 (cataloged, type information); Kononova 1995: 96 (keyed); Kononova
2014: 1424 (keyed); Kononova 2015: 262 (keyed); Talamas et al. 2017: 128, 135
(junior synonym of Trissolcus semistriatus (Nees von Esenbeck), type information).

Diagnosis. Trissolcus semistriatus is most similar to 7’ belenus and T! colemani, with
which it overlaps in distribution and host range. It can be separated from both by the
mesoscutal humeral sulcus present as a smooth furrow (Figure 25) and the short an-
teroventral extension of the mesopleuron, which does not extend to the base mesocoxa
(Figure 7). Additionally, the angular form of the occipital carina in dorsal view, with a
short carina extending toward the median ocellus, is found only in this species (Figure
36). The anteroventral area of the hind femur that is covered by setae (Figure 29) is

An integrated approach reveas cryptic species of Trissolcus in Europe 189

useful when separating 7. semistriatus from T’ belenus (Figure 26), 7. colemani (Figure
27) and T’ manteroi (Figure 28).

Description. Body length: 1.07—1.11 mm, median = 1.08 mm, SD = 0.01, n =
20. Body color: head, mesosoma, and metasoma black.

Head. FCI = 1.4; LCI = 1.9; IOS = 0.33 mm; OOL:POL:LOL = 1:12:5.4. Length
of radicle: less than width of clypeus. Color of A1-AG in female: distal A2 yellow to
light brown, otherwise black. Color of A7-A11 in female: black. Number of papillary
sensilla on AG: 0. Number of papillary sensilla on A7: 2. Facial striae: absent. Number
of clypeal setae: 6. Shape of gena in lateral view: narrow. Genal carina: present only at
base of mandible. Malar striae: absent. Sculpture of malar sulcus: weakly and densely
striate. Orbital furrow: uniform in width between midpoint of eye and malar sulcus.
Macrosculpture of frons directly dorsal to the antennal scrobe: coarsely rugose. Preo-
cellar pit: present. Setation of lateral frons: sparse; moderately dense. Punctation of
lateral frons: sparse. Sculpture directly ventral to preocellar pit: dorsoventrally fluted.
Rugae on lateral frons: weakly developed to absent. OOL: less than one ocellar diam-
eter. Hyperoccipital carina: absent. Macrosculpture of posterior vertex: absent. Mi-
crosculpture on posterior vertex along occipital carina: granulate. Anterior margin of
occipital carina: crenulate. Medial part of occipital carina in dorsal view: angled, vertex
of angle with short carina directed toward median ocellus.

Mesosoma. Epomial carina: present. Macrosculpture of lateral pronotum directly
anterior to netrion: finely rugulose. Netrion sulcus: complete. Pronotal suprahumeral
sulcus in posterior half of pronotum: undifferentiated from sculpture of dorsal prono-
tum. Number of episternal foveae: 2. Course of episternal foveae ventrally: distinctly
separate from postacetabular sulcus. Course of episternal foveae dorsally: distinctly
separate from mesopleural pit. Subacropleural sulcus: present. Speculum: transversely
strigose. Mesopleural pit: extending ventrally into dorsoventral furrow parallel to mes-
opleural carina. Mesopleural carina: well defined anteriorly, poorly defined to absent
posteriorly. Sculpture of femoral depression: smooth. Patch of striae at posteroventral
end of femoral depression: present, striae oblique to long axis of femoral depression.
Setal patch at posteroventral end of femoral depression: absent. Microsculpture of an-
teroventral mesopleuron: present throughout. Macrosculpture of anteroventral meso-
pleuron: absent. Postacetabular sulcus: comprised of large cells. Mesopleural epicoxal
sulcus: comprised of cells. Setation of posteroventral metapleuron: absent. Sculpture
of dorsal metapleural area: absent. Posterodorsal metapleural sulcus: present as a line of
foveae. Paracoxal sulcus in ventral half of metapleuron: indistinguishable from sculp-
ture. Length of anteroventral extension of metapleuron: short, not extending to base
of mesocoxa. Metapleural epicoxal sulcus: present as coarse rugae. Mesoscutal humeral
sulcus: present as a simple furrow. Median mesoscutal carina: absent. Microsculpture
of mesoscutum: imbricate-punctate anteriorly, becoming longitudinally imbricate-stri-
gate posteriorly. Mesoscutal suprahumeral sulcus: comprised of cells. Length of mesos-
cutal suprahumeral sulcus: two-thirds the length of anterolateral edge of mesoscutum.
Parapsidal line: absent. Notaulus: absent. Median protuberance on anterior margin
of mesoscutellum: absent. Shape of dorsal margin of anterior lobe of axillar crescent:

190 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

acute. Sculpture of anterior lobe of axillar crescent: dorsoventrally strigose. Area bound
by axillar crescent: smooth. Macrosculpture of mesoscutellum: absent. Microsculpture
on mesoscutellum: imbricate-punctate laterally to smooth medially. Median mesoscu-
tellar carina: absent. Setation of posterior scutellar sulcus: present. Form of metascutel-

Figures 59, 60. Zrissolcus semistriatus [DISAFA-draw1465-HYM-0227]: 59 body in dorsal view
60 body in lateral view.

An integrated approach reveas cryptic species of Trissolcus in Europe Oe

lum: single row of cells. Metanotal trough: foveate, foveae occupying more than half
of metanotal height. Metapostnotum: invaginated near lateral edge of metascutellum.
Length of postmarginal vein: about twice as long as stigmal vein. Color of legs: coxae
dark brown to black, femora and tibia dark brown with yellowish tips, trochanters
and tarsi yellow to pale brown. Anteroventral area of hind femora: covered by setae.
Anteromedial portion of metasomal depression: smooth.

Metasoma. Width of metasoma: about equal to width of mesosoma. Longitudinal
striae on Tl posterior to basal costae: pair of longitudinal submedial carinae separate
a lateral smooth area from an internal area where striate sculpture starts with basal
grooves. Number of sublateral setae (on one side): 1. Setation of laterotergite 1: absent.
Length of striation on T2: extending two-thirds the length of the tergite. Setation of T2:
present in a transverse line and along lateral margin. Setation of laterotergite 2: present.

Host associations. Pentatomidae: Aelia rostrata; Brachynema germarii (Kolenati);
Carpocoris sp.; Dolycoris baccarum (L.); Graphosoma semipunctatum; Rhaphigaster sp.;
Scutelleridae: Eurygaster maura.

Link to distribution map. [https://hol.osu.edu/map-large.html?id=3305]

Material examined. Neotype, female, 7éleas semistriatus. PALEARCTIC: no date, NHMW
0007A (deposited in NHMW). Paratype of Trissolcus artus: Russia: 1 female, USN-
MENT00916276 (ZIN). Neoparatype: Patzarctic: 1 female, NHMW 0007B (NHMW).

Other material. (183 females, 50 males, 2 pins with multiple specimens) IRAN: 11
females, HMIM-HYM-022, 038 (HMIM); USNMENT01223083—01223089 (UNI-
PA); USNMENT01223228-01223229 (MCSN). Itaty: 189 females, 54 males, 2 pins
with multiple specimen, DISAFA-draw1465-HYM-0226-0240, 0242-0423 (DIS-
AFA); MSNG-HYM-0005-0013 (MCSN); UNIPA-HYM-S01329-01346, USN-
MENT01223140—01223142, 01223482 (UNIPA). Japan: 1 female, EIHU 0003 (EIHU).
Morocco: 1 female, USNMENT01223143 (UNIPA). Porrucat: 3 females, USN-
MENT00916201—00916202, 00916236 (BMNH). SwEpEn: 1 female, UNIPA-HYM-
S01326 (BMNH). SwirzerLanb: | female, DISAFA-draw1465-HYM-0241 (DISAFA).

Discussion

More than 180 years have passed between the original descriptions of 7’ semistriatus
and 7° belenus and the development of identification tools that can reliably distinguish
them. This can be viewed as a glacial rate of progress, but also as an indication that
modern methods can resolve long-standing taxonomic challenges. The taxonomy of
Trissolcus illustrates that the examination of primary types and detailed comparison of
specimens across a broad geographical range is necessary to advance the field, and that
further refinement may be required even when these practices are implemented. Tala-
mas et al. (2017) significantly advanced the taxonomy of Palearctic Trissolcus but ad-
ditional analysis was needed to distill diagnostic characters from those that were treated
as intraspecifically variable. Specifically, setation on the first laterotergite, the form of
the mesoscutal humeral sulcus, and the length of the anteroventral extension of the

192 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

metapleuron were treated as variable within 7’ semistriatus. Although the utility of these
characters for separating 7’ belenus and T: colemani was not recognized, Talamas et al.
(2017) did bring attention to them, as they had not yet been used in the taxonomy
of Palearctic Trissolcus. Setation of the hind femora, not mentioned by Talamas et al.
(2017), represents a case in which a diagnostic character was previously recognized, but
incorrectly associated with a taxon name (Delucchi 1961), and is now treated as useful
for identifying 7! belenus. Trissolcus manteroi is a different matter, in which reexamina-
tion of the type specimen was needed for its diagnostic characters (wing venation, claval
formula, absence of episternal foveae) to be correctly characterized. These features place
TL. manteroi closer to T. rufiventris than to T. semistriatus, T; belenus or T. colemani.

The trail of photographic evidence provided by Talamas et al. (2017) enabled junior
synonyms of T’ semistriatus to be rapidly redistributed among 77 belenus and T’ colemani
once the characters that delimit these species were identified, as well as the resurrection
of 7’ manteroi. Given that producing a natural classification is an iterative process, ex-
plicit presentation of data that underlies taxonomic decisions accelerates further refine-
ment. This is perhaps the only means by which the various quagmires of inadequate
species descriptions in Platygastroidea can be transformed into a useful classification.

The need for reliable identification can be clearly seen in examples where quality
taxonomy was absent. In the early part of the 20" century, Trissolcus specimens identi-
fied as T! semistriatus or T. grandis were reared and released in Russia and Iran as classi-
cal biological contral agents against Eurygaster (Alexandrov 1947; Saakov 1903; Vaezi
1950; Vassiliev 1913; Zomorrodi 1959). Some of these authors did not indicate how
they identified the species, and in any case, the characters that reliably separate these
species were not established. It is only by retroactively identifying voucher specimens,
if they exist, that the results of these efforts can be interpreted in a meaningful way.
The presence of H. /alys in Europe has created a similar situation, with the same spe-
cies involved in studies of its biological control. The refined species concepts presented
here are thus of immediate relevance, given that 7’ belenus was recorded from frozen
sentinel eggs of H. halys in Europe, and was previously identified as 7) semistriatus.

Finally, it should be noted that independent testing of species concepts, ideally using
multiple methods, is the best means by which they can be verified or improved. This study
employed such an approach, using morphology, mating studies and molecular analysis to
resolve four species from the concept of 7’ semistriatus provided in Talamas et al. (2017).
In a manner conforming with this perspective, our results have been confirmed by a con-
comitant study by Talamas et al. (2019), in which a phylogeny of Trissolcus based on five
molecular markers retrieved 7. belenus, T. colemani and T, semistriatus as distinct entities.

Acknowledgements

We are grateful to: Dr. Hege Vardal (NHRS) for photographing a number of Thomson
types: Télenomus frontalis, Telenomus nigripes, Telenomus nigrita, Telenomus ovulorum

and Trissolcus grandis; Dr. Matthew Bufington (USNM, USDA/SEL) for providing

supplemental images of the holotype of Télenomus colemani; Valentina Guerini for

An integrated approach reveas cryptic species of Trissolcus in Europe 193

transliteration from Cyrillic to Latin alphabet of labels; David Notton (BMNH), who
hosted a visit of Virgilio Caleca; Dr. Paolo Visconti, who hosted a visit of Elijah Talamas
to NMID which enabled the lectotypes of 77 belenus and T’ arminon to be studied and
photographed and Dr. Norman Johnson (The Ohio State University), for maintaining
Hymenoptera Online and vSysLab and assisting with data processing. Elijah Talamas
was supported in part by a cooperative agreement with Kim Hoelmer (USDA/BIIRU)
and by the Florida Department of Agriculture and Consumer Services- Division of
Plant Industry. This research was funded by Fondazione Cassa di Risparmio di Cuneo
(project HALY-END) and Regione Piemonte (project BIOHALY).

References

Alexandrov N (1947) Eurygaster integriceps Put. a Varamine et ses parasites. Entomologie et
Phytopathologie Appliquees 5: 29-41.

Ali WH (2011) The level of sunn pest oophagous parasitoids (Hymenoptera: Scelionidae) in
infested wheat fields of northern governorate in Iraq with an identification key of Trissolcus
species. Bulletin of the Iraq Natural History Museum 11: 7-15.

Bin F (1974) The types of Scelionidae [Hymenoptera: Proctotrupoidea] in some Italian collec-
tions (Museums of Genoa and Florence, Institute of Portici). Entomophaga 19: 453-466.
https://doi.org/10.1007/BF02372781

Bin F (1981) Definition of female antennal clava based on its plate sensilla in Hymenoptera
Scelionidae Telenominae. Redia 64: 245-261.

Boldaruyev VO (1969) [Egg parasites of the subfamily Telenominae (Hymenoptera, Scelioni-
dae), reared from the eggs of harmful insects.]. Trudy Buryatskogo Instituta Estestvennykh
Nauk Buryatskii Filial Siirskogo Otdeleniya Akademii Nauk USSR 7: 156-171.

Buffington ML, Burks RA, McNeil LA (2005) Advanced techniques for imaging parasitic Hyme-
noptera (Insecta). American Entomologist 51: 50-54. https://doi.org/10.1093/ae/51.1.50

Buffington ML, Gates M (2008) Advanced Imaging Techniques II: Using a Compound Micro-
scope for Photographing Point-Mount Specimens. American Entomologist 54: 222-224.
https://doi.org/10.1093/ae/54.4.222

Bufhngton ML, Talamas EJ, Hoelmer KA (2018) Team Trissolcus: Integrating Taxonomy and
Biological Control to Combat the Brown Marmorated Stink Bug. American Entomologist
64: 224-232. https://doi.org/10.1093/ae/tmy057

Buhl PN, O’Connor JP (2010) Five species of Ceraphronidae and Scelionidae (Hymenoptera)
new to Ireland. Entomologists Monthly Magazine 146: 1-154.

Clarke AR (1990) The Control of Nezara viridula L. with Introduced Egg Parasitoids in Aus-
tralia. A Review of a “Landmark” Example of Classical Biological Control. Australian Jour-
nal of Agricultural Research 41: 1127-1146. https://doi-org/10.1071/AR9901127

Clarke AR (1993) A new Trissolcus Ashmead species (Hymenoptera: Scelionidae) from Paki-
stan: Species description and its role as a biological control agent. Bulletin of Entomologi-
cal Research 83: 523-527. https://doi.org/10.1017/S0007485300039948

Crawford JC (1912) Descriptions of new Hymenoptera. No. 4. Proceedings of the United
States National Museum 42: 1-10. https://doi.org/10.5479/si.00963801.42-1880.1

194 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Dalla Torre CG de (1898) Catalogus Hymenopterorum Hucusque Descriptiorum Systemati-
cus et Synonymicus (Vol. V). Chalcididae et Proctotrupidae. Sumptibus Guilelmi Engel-
mann, Lipsiae, 598 pp.

Debauche (1947) Scelionidae de la faune belge (Hymenoptera Parasitica). Bulletin et Annales
de la Société Entomologique de Belge 83: 255-285.

Delucchi VL (1961) Le complexe des Asolcus Nakagawa (Microphanurus Kieffer) (Hymenop-
tera, Proctotrupoidea) parasites oophages des punaises des cereales au Maroc et au Moyen-
Orient. Cahiers de la Recherche Agronomique 14: 41-67.

Doganlar M (2001) Egg parazitoids of Rhaphigaster nebulosa (Poda) (Hemiptera; Pentatomi-
dae) with description of a new species of Trissolcus Ashmead (Hymenoptera: Scelionidae).
Turkish Journal of Entomology 25: 109-114.

Fabritius K (1972) Genul Trissolcus Ashmead 1893 (Hymenoptera, Scelionidae) in Romania
si perspectivele utilizarii acestui gen de entomofagi in combaterea biologica si integrata a
plosnitelor cerealelor. Lucrari Stiintifice — Zoologie, Constanta 1972: 27-42.

Fabritius K, Popovici OA (2007) A Catalogue of Scelionidae from Romania (Hymenoptera,
Platygastroidea). Entomologica Romanica 12: 133-161.

Fergusson NDM (1978) Proctotrupoidea and Ceraphonoidea. Pages 110-126 in Fitton, Gra-
ham, Boucek, Fergusson, Huddleston, Quinlan & Richards. 1978. A check list of British
insects by George Sidney Kloet and the late Walter Douglas Hincks, second edition (com-
pletely revised). Pa. Handbooks for the Identification of British Insects 11: 1-159.

Fergusson NDM (1983) The status of the genus Allophanurus Kieffer (Hymenoptera: Proc-
totrupoidea, Scelionidae). Entomologist’s Monthly Magazine 119: 207-209.

Fergusson NDM (1984) ‘The type-specimens and identity of the British species of Trissolcus Ash-
mead (Hym., Proctotrupoidea, Scelionidae). Entomologist’s Monthly Magazine 120: 229-232.

Folmer O, Black M, Hoeh W, Lutz R, Vrijenhoek R (1994) DNA primers for amplification of
mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Mo-
lecular Marine Biology and Biotechnology 3: 294-299.

Ghahari H, Buhl PN, Kogak E (2011) Checklist of Iranian Trissolcus Ashmead (Hymenoptera:
Platygastroidea: Scelionidae: Telenominae). International Journal of Environmental Stud-
ies 68: 593-601. https://doi-org/10.1080/00207233.2011.617531

Graham MWR de V (1984) Madeira insects, mainly Hymenoptera Proctotrupoidea, Cer-
aphronoidea, and Bethyloidea. Boletim do Museu Municipal do Funchal 36: 83-110.

Guz N, Kocak E, Kilincer N (2013) Molecular phylogeny of Trissolcus species (Hymenoptera:
Scelionidae). Biochemical Systematics and Ecology 48: 85-91. https://doi.org/10.1016/j.
bse.2012.12.010

Harris RA (1979) A Glossary of Surface Sculpturing. California Department of Food and Ag-
riculture Division of Plant Industry Laboratory Services 28: 1-31.

He J-H, Chen X-X, Fan J-J, Li Q, Liu C-M, Lou X-M, Ma Y, Wang S-E, Wu Y-R, Xu Z-H, Xu
Z-F, Yao J (2004) [Hymenopteran Insect Fauna of Zhejiang.] Science Press, Beijing. 1373 pp.

Isidoro N, Bin E Colazza S, Vinson SD (1996) Morphology of antennal gustatory sensilla and
glands in some parasitoids Hymenoptera with hypothesis on their role in sex and host

recognition. Journal of Hymenoptera Research 5: 206-239.

An integrated approach reveas cryptic species of Trissolcus in Europe 195

Javahery M (1968) The egg parasite complex of British Pentatomoidea (Hemiptera): taxonomy
of Telenominae (Hymenoptera: Scelionidae). Transactions of the Royal Entomological So-
ciety of London 120: 417-436. https://doi.org/10.1111/j.1365-2311.1968.tb00345.x

Johnson NF (1987) Systematics of New World Trissolcus, a genus of pentatomid egg-parasites
(Hymenoptera: Scelionidae): Neotropical species of the flavipes group. Journal of Natural
History 21: 285-304. https://doi.org/10.1080/00222938700771021

Johnson NF (1992) Catalog of world Proctotrupoidea excluding Platygastridae. Memoirs of
the American Entomological Institute 51: 1-825.

Kaartinen R, Stone G, Hearn J, Lohse K, Roslin T (2010) Revealing secret liaisons: DNA
barcoding changes our understanding of food webs. Ecological Entomology 35: 623-638.
hteps://doi.org/10.1111/j.1365-2311.2010.01224.x

Kerr PH, Fisher EM, Buffington ML (2008) Dome lighting for https://doi-org/10.1093/
ae/54.4.198 insect imaging under a microscope. American Entomologist 54: 198-200.

Kieffer JJ (1909) Description de quelques nouveaux Scelionides d’Europe (Hym.). Bulletin de
la Société Entomologique de France 15: 268-271. https://doi.org/10.5962/bhl.part. 13507

Kieffer JJ (1912) Proctotrypidae (3e partie). Species des Hyménopteéres d’Europe et d’Algérie.
elt 1.60;

Kieffer JJ (1926) Scelionidae. Das Tierreich (Vol. 48). Walter de Gruyter & Co., Berlin, 885 pp.

Kimura M (1980) A simple method for estimating evolutionary rates of base substitutions
through comparative studies of nucleotide sequences. Journal of molecular evolution
16(2): 111-120. https://doi.org/10.1007/BF01731581

Kogak E, Kilinger N (2000) Tiirkiye faydal: faunas: icin yeni kayit Trissolcus (Hym.: Scelioni-
dae) tiirleri. Bitki Koruma Biilteni 40: 169-177.

Kogak E, Kilinger N (2003) Taxonomic studies on Trissolcus sp. (Hymenoptera: Scelionidae),
ege parasitoids of the sunn pest (Hemiptera: Scutelleridae: Eurygaster sp.), in Turkey. Turk-
ish Journal of Zoology 27: 301-317.

Kogak E, Kodan M (2006) Trissolcus manteroi (Kieffer, 1909) (Hymenoptera, Scelionidae):
male nov. with new host from Turkey. Journal of Pest Science 79: 41-42. https://doi.
org/10.1007/s10340-005-0101-x

Kochetova NI (1966) [Development of Asolcus semistriatus Nees (Hymenoptera, Scelionidae)
— egg parasite of the little tortoise bug and other Pentatomoidea (Hemiptera).]. Zoologich-
eskii Zhurnal 45: 558-567.

Kononova SV (1995) [25. Fam. Scelionidae.]. In: Lehr PA (Ed.) Key to Insects of Russian Far
East in Six Volume (Vol. 4). Neuropteroidea, Mecoptera, Hymenoptera. Part 2. Hymenop-
tera.]. Dal’nauka, Vladivostok, 57-121.

Kononova SV (2014) Egg-parasitoids of the genus Trissolcus (Hymenoptera, Scelionidae, Tel-
enominae) from the Palaearctic fauna (the flavipes morphological group). 1. New species
of the genus Trissolcus. Zoologicheskii Zhurnal 93: 1420-1426. https://doi.org/10.1134/
S0013873814070112

Kononova SV (2015) Egg-parasitoids of the genus Trissolcus (Hymenoptera, Scelionidae, Tel-
enominae) from the Palaearctic region. The flavipes morphological group: 2. A key to the
species of the flavipes group. Entomological Review 95: 257-264. https://doi.org/10.1134/
S0013873815020086

196 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Kozlov MA (1963) [New synonyms of species of the genus Asolcus Nak., Gryon Hal. and Tel
enomus Hal. (Hymenoptera, Scelionidae), egg parasites of Eurygaster integriceps Put.]. Zoo-
logicheskii Zhurnal 63: 294-296.

Kozlov MA (1968) Telenomines (Hymenoptera, Scelionidae, Telenominae) of the Caucasus
— egg parasites of the sun pest (Eurygaster integriceps Put.) and other grain bugs. Trudy
Vsesoyuznogo Entomologicheskogo Obshchestva 52: 188-223.

Kozlov MA (1978) [Superfamily Proctotrupoidea]. In: Medvedev GS (Ed.) [Determination of
Insects of the European Portion of the USSR.]. Nauka, Leningrad, 538-664.

Kozlov MA (1981) The system and zoogeography of scelionids (Hymenoptera, Scelionidae).
Entomologicheskoe Obozrenie 60: 174-182.

Kozlov MA, Kononova SV (1983) [Telenominae of the Fauna of the USSR.]. Nauka, Leningrad.

Kozlov MA, Lé XH (1977) Palearctic species of egg parasites of the genus Trissolcus
Ashmead, 1893 (Hymenoptera, Scelionidae, Telenominae). Insects of Mongolia 5:
500-525.

Kumar S, Stecher G, Li M, Knyaz C, Tamura K (2018) MEGA X: molecular evolutionary
genetics analysis across computing platforms. Molecular biology and evolution 35(6):
1547-1549. https://doi.org/10.1093/molbev/msy096

Masner L (1959) Some problems of the taxonomy of the subfamily Telenominae (Hym. Scelio-
nidae). Transactions of the 1* International Conference on Insect Pathology and Biological
Control, Prague 1958: 375-382.

Masner L (1964) A comparison of some Nearctic and Palearctic genera of Proctotrupoidea
(Hymenoptera) with revisional notes. Casopis Ceskoslovenské Spolecnosti Entomologické
61: 123-155.

Masner L (1980) Key to genera of Scelionidae of the Holarctic Region, with descriptions of
new genera and species (Hymenoptera: Proctotrupoidea). Memoirs of the Entomological
Society of Canada 112: 1-54. https://doi.org/10.4039/entm112113fv

Masner L, Muesebeck CFW (1968) The types of Proctotrupoidea (Hymenoptera) in the Unit-
ed States National Museum. Bulletin of the United States National Museum 270: 1-143.
https://doi.org/10.5479/si.03629236.270

Mayr G (1879) Ueber die Schlupfwespengattung Zelenomus. Verhandlungen der Zoologisch-
Botanischen Gesellschaft in Wien 29: 697-714.

Meier NF (1940) [Parasites reared in the USSR in 1938-1939 from eggs of the corn-bug (Eu-
rygaster integriceps Osch.).]. Vestnik Zashchita Rastenii 3: 79-82.

Meier NF (1949) [Toward knowledge of the species of egg-parasites of bugs found in recent
years in the USSR.]. Trudy Vsesoyuznogo Instituta Zashchity Rastenii 2: 114-116.

Miké I, Masner L, Deans AR (2010) World revision of Xenomerus Walker (Hymenop-
tera: Platygastroidea, Platygastridae). Zootaxa 2708: 1-73. https://doi.org/10.11646/
zootaxa.2708.1.1

Miké I, Vilhelmsen L, Johnson NE, Masner L, Pénzes Z (2007) Skeletomusculature of Scelio-
nidae (Hymenoptera: Platygastroidea): Head and mesosoma. Zootaxa 1571: 1-78. https://
doi.org/10.11646/zootaxa.1571.1.1

Nakagawa H (1900) [Illustrations of some Japanese Hymenoptera parasitic on insect eggs. I.].
Special Report of the Agricultural Experiment Station, Tokyo 6: 1-26.

An integrated approach reveas cryptic species of Trissolcus in Europe 197

Nees von Esenbeck CG (1834) Hymenopterorum Ichneumonibus Affnium Monographiae,
Genera Europaea et Species Illustrantes (Vol. 2). J. G. Cotta, Stuttgart, 448 pp. https://doi.
org/10.5962/bhl.title.26555

Nixon GEJ (1939) Parasites of hemipterous grain-pests in Europe (Hymenoptera: Proc-
totrupoidea). Arbeiten tiber Morphologische und Taxonomische Entomologie aus Berlin-
Dahlem 6: 129-136.

Petrov S (2013) Three new species of Trissolcus Ashmead (Hymenoptera: Platygastroidea:
Scelionidae) from Bulgaria. Biologia (Bratislava) 68: 324-329. https://doi.org/10.2478/
s11756-013-0151-0

Ratzeburg JTC (1852) Die Ichneumonen der Forstinsecten in Forstlicher und Entomologis-
cher Beziehung (Vol. 3). Nicolaischen Buchhandlung, Berlin, 272 pp.

Rjachovskij VV (1959) [Egg parasites of the sunn pest in the Ukrainian SSR.]. Ukrainskii
Nauchno-Issledovatel’skii Institut Zashchity Rastenii 8: 76-88.

Rondani C (1874) Nuove osservazioni sugli insetti fitofagi e sui loro parassiti. Bullettino della
Societa Entomologica Italiana 6: 130-136.

Rondani C (1877) Vesparia parasita no vel minus cognita observata et descripta. Bullettino
della Societa Entomologica Italiana 9: 166-213.

Ryu J, Hirashima Y (1984) Taxonomic studies on the genus Trissolcus Ashmead of Japan and
Korea (Hymenoptera, Scelionidae). Journal of the Faculty of Agriculture, Kyushu Univer-
sity 29: 35-58.

Saakov AI (1903) [The artificial breeding of egg parasites of the bread bug.]. Trudy Byuro po
Entomologii 4: 1-12.

Safavi M (1968) Etude biologique et ecologique des hymenopteres parasites des oeufs des pu-
naises de cereales. Entomophaga 13: 381-495.

Szabé JB (1976) Neue Daten zur Kenntnis der Gattung Asolcus Nakagawa, 1900 (Hymenop-
tera: Proctotrupoidea, Scelionidae). Folia Entomologica Hungarica 29: 175-191.

Talamas EJ, Johnson NF, Buffington ML (2015) Key to Nearctic species of Trissolcus Ashmead
(Hymenoptera, Scelionidae), natural enemies of native and invasive stink bugs (Hemiptera,
Pentatomidae). Journal of Hymenoptera Research 43: 45-110. https://doi.org/10.3897/
JHR.43.8560

Talamas EJ, Buffington ML, Hoelmer K (2017) Revision of Palearctic Trissolcus Ashmead
(Hymenoptera, Scelionidae). Journal of Hymenoptera Research 56: 3-185. https://doi.
org/10.3897/jhr.56.10158

Talamas EJ, Bon M-C, Hoelmer KA, Buffington ML (2019) Molecular phylogeny of Trissolcus
wasps (Hymenoptera, Scelionidae) associated with Halyomorpha halys (Hemiptera, Pen-
tatomidae). In: Talamas E (Eds) Advances in the Systematics of Platygastroidea II. Journal
of Hymenoptera Research 73: 201-217. https://doi.org/10.3897/jhr.73.39563

Thomson CG (1860) Sverges Proctotruper. Tribus IX. Telenomini. Tribus X. Dryinini. Ofver-
sigt af Kongliga Vetenskaps-Akadamiens Forhandlingar 17: 169-181.

Tortorici F, Caleca V, van Noort S, Masner L (2016) Revision of Afrotropical Dyscritobaeus Per-
kins, 1910 (Hymenoptera: Scelionidae). Zootaxa 4178: 1-59. https://doi.org/10.11646/
zootaxa.4178.1.1

198 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Vaezi M (1950) Rapport du laboratoire d’elevage des parasites d’Eurygaster integriceps Put. En-
tomologie et Phytopathologie Appliquees 11: 27-41.

Vassiliev JV (1913) [Eurygaster integriceps Put. and New Methods of Fighting it by the Aid of
Parasites]. St. Petersburg, 81 pp.

Viggiani G, Mineo G (1974) Identificazione dei parassitoidi del Gonocerus acuteangulatus
(Goeze). Bollettino dell’ Istituto di Entomologia Agraria e dell’Osservatorio di Fitopatolo-
gia di Palermo 8: 143-163.

Viktorov GA (1964) [Food specialization of egg parasites of Eurygaster integriceps Put. and the
role of this specialization for the diagnostics of species in the genus Asolcus Nakagawa (Micro-
phanurus Kieffer) (Hymenoptera, Scelionidae).]. Zoologicheskii Zhurnal 43: 1011-1025.

Viktorov GA (1967) [Problems in Insect Population Dynamics with Reference to the Sunn
Pest.] Nauka, Moscow, 271 pp.

Voegelé J (1962) Isolement d’une espece jumelle d’Asolcus basalis Wollaston (Hymenoptera,
Proctotrupoidea). Al Awamia 4: 155-161.

Voegelé J (1964) Contribution a la connaissance des stades larvaires des especes du genre Asolcus
Nakagawa (Microphanurus Kieffer) (Hymenoptera, Proctotrupoidea). Al Awamia 10: 19-31.

Voegelé J (1965) Nouvelle methode d’etude systematique des especes du genre Asolcus. Cas
d’Asolcus rungsi. Al Awamia 14: 95-113.

Voegelé J (1969) Les hymenopteres parasites oophages des Ae/ia. Al Awamia 31: 137-323.

Walker F (1836) On the species of Téleas, &c. Entomological Magazine 3: 341-370.

Walker F (1838) Descriptions of some Oxyuri. Entomological Magazine 5: 453-458.

Watanabe C (1951) On five scelionid egg-parasites of some pentatomid and coreid bugs from
Shikoku, Japan (Hymenoptera: Proctotrupoidea). Transactions of the Shikoku Entomo-
logical Society 2: 17-26.

Watanabe C (1954) Discovery of four new species of Telenominae, egg parasites of pentatomid
and plataspid bugs, in Shikoku, Japan. Transactions of the Shikoku Entomological Society
4: 17-22.

Yoder MJ, Mik6 I, Seltmann KC, Bertone MA, Deans AR (2010) A gross anatomy ontology for
Hymenoptera. PLoS ONE 5(12). e15991. https://doi.org/10.137 1/journal.pone.0015991

Zomorrodi A (1959) La lutte biologique contre la Punaise du blé Eurygaster integriceps Put.
Part Microphanurus semistriatus Nees en Iran. Anzeiger Fur Schadlingskunde 3: 167-175.

Supplementary material |

URI table of HAO morphological terms

Authors: Francesco Tortorici, Elijah J. Talamas, Silvia T. Moraglio, Marco G. Pansa,

Maryam Asadi-Farfar, Luciana Tavella, Virgilio Caleca

Data type: species data

Explanation note: This table lists the morphological terms used in this publication and
their associated concepts in the Hymenoptera Anatomy Ontology.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License

An integrated approach reveas cryptic species of Trissolcus in Europe 199

(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.73.39052.suppl1

Supplementary material 2

Trissolcus belenus occurence data

Authors: Francesco Tortorici, Elijah J. Talamas, Silvia T. Moraglio, Marco G. Pansa,

Maryam Asadi-Farfar, Luciana Tavella, Virgilio Caleca

Data type: species data

Explanation note: This table provides a DarwinCore archive of occurence records for
Trissolcus belenus.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.73.39052.suppl2

Supplementary material 3

Trissolcus colemani occurence data

Authors: Francesco Tortorici, Elijah J. Talamas, Silvia T. Moraglio, Marco G. Pansa,

Maryam Asadi-Farfar, Luciana Tavella, Virgilio Caleca

Data type: species data

Explanation note: This table provides a DarwinCore archive of occurence records for
Trissolcus colemani.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.73.39052.suppl3

200 Francesco Tortorici et al. / Journal of Hymenoptera Research 73: 153-200 (2019)

Supplementary material 4

Trissolcus manteroi occurence data

Authors: Francesco Tortorici, Elijah J. Talamas, Silvia T. Moraglio, Marco G. Pansa,

Maryam Asadi-Farfar, Luciana Tavella, Virgilio Caleca

Data type: species data

Explanation note: DarwinCore archive of occurence records for 77 manteroi.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.73.39052.suppl4

Supplementary material 5

Trissolcus semistriatus occurence data

Authors: Francesco Tortorici, Elijah J. Talamas, Silvia T. Moraglio, Marco G. Pansa,

Maryam Asadi-Farfar, Luciana Tavella, Virgilio Caleca

Data type: species data

Explanation note: DarwinCore archive of occurence records for Trissolcus semistriatus.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.73.39052.suppl5

Supplementary material 6

Matrix of diagnostic characters

Authors: Francesco Tortorici, Elijah J. Talamas, Silvia T. Moraglio, Marco G. Pansa,

Maryam Asadi-Farfar, Luciana Tavella, Virgilio Caleca

Data type: species data

Explanation note: This table provides a matrix of diagnostic characters to separate
Palearctic species that are morphologically close to Trissolcus semistriatus.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.73.39052.suppl6