JHR 97: 545-589 (2024) ge JOURNAL OF Arment sense

doi: |0.3897/jhr.97. 127702 RESEARCH ARTICLE ) I Tymenopter a
>

https://jhr.pensoft.net ‘The International Society of Hymenopterisss RESEARCH

The genus Acerocephala and observations of the
life history of Acerocephala hanuuanamu sp. nov.
(Hymenoptera, Cerocephalidae) and its bark beetle
host on the island of Ofahu, Hawai‘

David N. Honsberger', Maya Honsberger',
J. Hau‘oli Lorenzo-Elarco**, Mark G. Wright!

| Department of Plant and Environmental Protection Sciences, University of Hawai at Manoa, 3050 Maile
Way #310, Honolulu, HI 96822, USA 2 Ka Haka ‘Ula o Keelikélani, College of Hawaiian Language,
University of Hawaii at Hilo, 200 W. Kawili St., Hilo, HI 96720, Honolulu, USA 3 Honolulu Community
College, 874 Dillingham Blud., Honolulu, HI 96817, USA

Corresponding author: David N. Honsberger (dnh8@hawaii.edu)

Academic editor: Ankita Gupta | Received 20 May 2024 | Accepted 10 July 2024 | Published 24 July 2024
https://zoobank. org/A94BBO1 1-E39F-4B2 1-BB18-B2AF4D8AA2D 1

Citation: Honsberger DN, Honsberger M, Lorenzo-Elarco JH, Wright MG (2024) The genus Acerocephala and
observations of the life history of Acerocephala hanuuanamu sp. nov. (Hymenoptera, Cerocephalidae) and its bark
beetle host on the island of O‘ahu, Hawai‘i. Journal of Hymenoptera Research 97: 545-589. https://doi.org/10.3897/
jhr.97.127702

Abstract

The behavior of Acerocephala hanuuanamu sp. nov. found parasitizing Cryphalus brasiliensis under the
surface of wood in Ficus microcarpa trees on the island of O’ahu in Hawai'i is deduced from observa-
tions in naturally occuring branches, and from direct observation using specially designed “phloem sand-
wich” observation chambers which consist of tree bark peeled through the phloem layer from freshly cut
branches and sandwiched between a sheet of aluminum and a sheet of plexiglass. Cryphalus brasiliensis
beetles, found living in large numbers in the phloem tissues in F microcarpa trees, were collected and
placed into these chambers. They tunneled into the wood and reproduced, producing an active colony
of all life stages. Acerocephala hanuuanamu wasps were then placed into the system and their behavior
observed. Typical behavior, aspects of which were recorded in video and still images, was as follows. A
female A. hanuuanamu enters the tunnels of the bark beetles. She digs through the debris in the tun-
nels in a search for larvae and pupae. Cryphalus brasiliensis prepupae construct a hard pupal chamber
around themselves before they pupate, and upon encountering a larva in the tunnels or the exterior of a
pupal chamber with a pupa inside, she adeptly turns around in the tunnel to sting it, either inserting her
ovipositor directly into the larva or by laboriously pushing it through the hard shell of the pupal chamber.

Copyright David N. Honsberger et al. This is an open access article distributed under the terms of the Creative Commons Attribution License
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546 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

When finished stinging, she withdraws her ovipositor slowly and carefully, often extracting tissue from
the beetle immature as a sheath around her ovipositor. This structure remains projecting from the larva
or pupa, and then the wasp turns around and host feeds through this structure, in the case of a pupa at a
substantial distance through the wall of the pupal chamber. Oviposition occurs on larval stages and pupal
stages. The egg hatches and the larva develops as an ectoparasitoid on the beetle. When finished feeding,
it detaches and pupates in the tunnel. Mating behavior is also described. In addition to C. brasiliensis in
E microcarpa, A. hanuuanamu was also observed attacking Cryphalus mangiferae in mango (Mangifera
indica) branches. Acerocephala ihulena sp. nov. was also found on O‘ahu parasitizing Eidophelus pacificus
in hau (Hibiscus tiliaceus) branches, and is described. The genus Acerocephala is revised given the perspec-
tive resulting from these two new species and aspects of functional morphology observed in the behavioral

studies, Acerocephala indica comb. nov. is transferred to the genus, and a key to the genus is provided.

Keywords

Cerocephalinae, cryptoparasitoids, functional morphology, observation chamber, parasitoids

Introduction

The behavior and life history of insects that live inside wood or other plant parts can
be difficult to observe. Mechanically opening up the plant material usually results in
disrupting many of its inhabitants and their scattering, and it can be difficult to de-
duce their behavior prior to disruption. Simply placing the arthropods themselves or
opened plant parts in a container for observation alters the environment substantially,
and it can be unreliable to connect observed behavior in such circumstances with
natural behavior. In this study we report observations of the behavior of a new species
of cryptoparasitic wasp in tunnels constructed by its host beetles in an observation
chamber as a semi-realistic representation of the environment in which we have found
this species naturally.

This study is far from the only attempt at documenting the behavior of bark beetles
and their natural enemies in concealed habitats. There is a history of making obser-
vation systems similar to the one constructed and used in this study, called “phloem
sandwiches,” which are variations on the idea of compressing natural wood or artificial
diet between two hard sheets, at least one of which is clear to permit observation of
its inhabitants (Beanlands 1966; Gouger et al. 1975; Nagel and Fitzgerald 1975; Kinn
and Miller 1981; Salom et al. 1986; Grosman et al. 1992; Taylor et al. 1992; Aflitto
et al. 2014; Sharma et al. 2016; Vega et al. 2017). These methods create an environ-
ment where wood boring beetles are able to construct their own tunnels and behavior
within the tunnels can be observed. The environment in such systems is, however, still
somewhat manipulated and not totally consistent with systems encountered in nature.
In recent years, observations of wood boring insects in truly natural situations have
also been successfully attempted. Alba-Alejandre et al. (2018) used a series of micro-
CT scans to track the lives of coffee berry borer beetles, Hypothenemus hampei (Ferrari,
1867), inside coffee berries. Rezende et al. (2019) also used x-ray radiographs to track
the movements of a thrips species thought to attack the coffee berry borer inside coffee

The genus Acerocephala and life history under bark 547

berries. These methods produced clear records of the biology and behavior of these
insects, but only in static images.

This study focuses on A. hanuuanamu sp. nov. (Hymenoptera: Cerocephalidae) found
attacking Cryphalus brasiliensis Schedl, 1976 (Coleoptera: Curculionidae: Scolytinae) on
Ficus microcarpa L.f. trees on the island of O‘ahu in Hawai'i. In this study we reared
C. brasiliensis in phloem sandwiches until overlapping generations composed of all life
stages were present, then introduced the wasps and studied and recorded their behavior.

The discovery of this and another species results in perspective that allows for a
revision of the genus Acerocephala Gahan. Cerocephalinae was first described by Ga-
han (1946) as a subfamily of Pteromalidae, Acerocephala described as part of this sub-
family and two species included, A. atroviolacea and A. aenigma. The subfamily was
later revised by Hedqvist (1969). Boucek (1988) added a third species to Acerocephala,
A, pacifica, but stated that it was of uncertain generic identity, appearing substantially
different from the other two previously described species which are morphologically
very close. Cerocephalinae was then raised to the family level, as Cerocephalidae, by
Burks et al. (2022). A key to genera of Cerocephalidae is provided by Blaser et al.
(2015). All Cerocephalidae with known biological information are parasitoids of bee-
tles in cryptic habitats (Boucek 1988).

Methods

Species descriptions

Specimens collected from wood and other plant parts were examined and photographed
using a Leica MZ16 stereomicroscope or Macropod Pro imaging system. Specimens
were also dissected, examined, and photographed using an Olympus CX31 compound
microscope. Terminology relating to morphological characters follows Gibson (1997).

Morphometrics were measured as shown in Fig. 1, morphometrics of the head
all measured in full face view or in lateral view, whichever was less obstructed by the
antennae, except hea.! which was measured in lateral view. Acronyms in Fig. 1 and
descriptions of the measurements, following Klimmek and Baur (2018), are as follows:

vac.l — Full length of head; longitudinal line even with posterior of vertex to antero-
lateral corner of face (excludes mandibles).

vol.l Vertex-ocular line; longitudinal line even with posterior of vertex to even
with top of compound eye.

vey. Length of vertex to bottom of eye; longitudinal line even with vertex to even
with bottom of compound eye.

vsc.l Length of vertex to scrobes; longitudinal line even with vertex to even with
top of scrobal depression.

vto.l Length of vertex to toruli; longitudinal line even with vertex to even with
center of toruli

548 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

eyeh Height of eye; posterior margin to anterior margin of compound eye.

mdb.l_ Length of mandible; straight line distance between protruding lateral corner
at base of mandible and tip of mandible.

hea.b —_ Breadth of head; maximum width of head including eyes

eye.d Eye distance; minimum distance between compound eyes on front of face

hac.d Width of head at anterolateral corner; distance between anterolateral corners
of face.

msp.l Malar space; anterior margin of compound eye to anterolateral corner of face

wot. Width of ocellar triangle; distance between outer margins of posterior ocelli.

pol. = Posterior ocellar line; shortest distance between inner margins of posterior
ocelli.
ool.l Ocellar-ocular line; shortest distance from margin of posterior ocellus to

margin of compound eye.

fcc.l Length of facial concavity; length of mesal line from even with anteriolateral
corners of face to anterior of declivitous region comprising front of face, at
posterior margin of projected clypeus.

cly.1 Length of clypeal projection; length from anterior reach of clypeal projection
to its base at the declivitous region at front of face.

hea.l Thickness of head; in lateral view, thickest part of head perpendicular to gen-
eral plane of face and ventral surface of the head, typically at the level of the
compound eyes for the species described.

prn.l Length of pronotum; base of pronotum on dorsomedian line to occipital
foramen.

prn.b~— Breadth of pronotum; maximum width of pronotum measured in dorsal
view.

msc.b Breadth of mesoscutum; width of mesoscutum just anterior of tegulae, meas-
ured in dorsal view.

tsa.l Length of transscutal articulation; in dorsal view, distance between intersec-
tions of transscutal articulation and axillar carina.

tsm.1 Medial region of transscutal articulation; distance between where scutoscu-
tellar lines join with transscutal articulation.

sct.l Length of scutellum; along median line, transscutal articulation to apex of
scutellum and frenum.

mtn.l Length of metanotum; in dorsal view, distance along median line from apex
of frenum to apex of metanotum.

ppd. Length of propodeal disk; in dorsal view, distance along median line from
metanotum to even with apex of propodeum.

pps-d Width of propodeal disk; in dorsal view, distance between propodeal spira-
cles.

gso.l _—_ Length of gaster excluding ovipositor; apex of petiole to apex of metasoma
not including ovipositor or ovipositor sheaths.

ovi.l Length of ovipositor; apex of metasoma not including ovipositor or oviposi-
tor sheaths, to apex of ovipositor or ovipositor sheaths.

The genus Acerocephala and life history under bark 549

Body length was obtained by adding the length of the head from the anterolatertal
corner of the face to the occipital foramen, the occipital foramen to the anterior of the teg-
ula, the anterior of the tegula to the petiole, and the petiole to the apex of the abdomen.

Morphometric measurements are reported in Suppl. materials 1, 2.

Repositories

Specimens are deposited in the following museums:

UHIM University of Hawai‘i Insect Museum, Honolulu, Hawai'i, USA
BPBM Bernice Pauahi Bishop Museum, Honolulu, Hawai‘i, USA
NMNH — Smithsonian National Museum of Natural History, Washington DC, USA

“Phloem sandwich” observation chambers
(Fig. 10c, d)

An apparatus was constructed for the purpose of observing the parasitoids and their
hosts in an environment resembling the below-bark environment in which they natu-
rally occur (Fig. 10c, d). These observation chambers, a variation on the idea of a
“phloem sandwich,” consist of thin sheets of host wood; bark peeled from a branch
through the phloem or cambium layer, sandwiched between a plexiglass sheet and an
aluminum sheet. Adult C. brasiliensis were introduced to the wood through holes in
the plexiglass, and if the conditions were appropriate, they would then tunnel into the
wood and lay eggs. When the resulting larvae were at a stage suitable for parasitization,
and as the colony developed further, A. hanuuanamu sp. nov. adults were introduced
into the environment and their behavior was observed. The C. brasiliensis beetles this
wasp uses as a host live typically in the thin layer of wood straddling the cambium,
so a two-dimensional representation of their environment such as used here is likely a
reasonably accurate representation of their actual habitat. Videos of behavior were re-
corded using a Dino-Lite Edge Digital Microscope and photos were taken using either
the same Dino-Lite Edge or a Canon DLSR camera with a macro lens.

Construction of observation chambers and initiation of beetle colonies with-
in them

The “phloem sandwich” style observation chambers used in this study are shown in
Fig. 10c—f. The bottom layer of the sandwich is a 9.0 cm square of 1/16 inch (approxi-
mately 1.6 mm) sheet aluminum. Above it is a spacer made from a 9.0 cm square of
1/16 inch sheet aluminum with a rectangular hole 5.1 x 6.3 cm cut out of the mid-
dle. The top of the sandwich is a 9.0 cm square sheet of plexiglass. Holes were drilled
at each corner through all three sheets, and 1/4 inch (approximately 6.35 mm) bolts
were used to clamp the sheets together with a piece of host wood in the middle. Two
additional small holes were drilled through the plexiglass to introduce beetles to the

550 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

chamber. This thickness of aluminum was chosen for the separator layer because it is
slightly larger than the width of the C. brasiliensis beetles, which assured that beetles
could move through the apparatus. Because the beetles were most interested in the
phloem and cambium layer facing the plexiglass, they tended to make their tunnels up
against the plexiglass and the full width of the tunnels were usually visible through it.

Using a knife and a chisel, E microcarpa bark was carefully peeled off a branch
down to the xylem layer. Branches with bark just slightly thicker than the 1/16 inch
separator were chosen so the wood would be compressed tightly between the top and
bottom of the sandwich, accounting for slight shrinkage when drying. ‘The resulting
sheets of bark were cut into pieces approximately 4.3 cm by 5.5 cm so that when
placed in the aluminum forms there would be space for the beetles to travel around
the perimeter. The freshly peeled bark was clamped between two % inch x 5 % inch
(1.9 cm x 14 cm) cedar boards with small holes drilled in them for airflow and left to
dry for a few days. The wood, still clamped between the two cedar boards, was then
autoclaved. This process is similar to steam bending wood, and as such, the bark would
maintain its flat shape when the boards were unclamped and the wood was removed.
The aluminum, nuts, bolts, and washers were also autoclaved, and the plexiglass was
soaked and cleaned with a 70% ethanol solution before assembly. The parts were as-
sembled quickly under a laminar flow hood to limit contamination. Parafilm or hot
glue was used to seal any imperfections in the edges of the sandwich.

The correct stage of decay and water content of the wood is important for the
beetles. The wood had been left to age and dry for a few days when clamped between
the cedar boards, and was then reinfused with water during the autoclave treatment.
After the boxes were assembled, the beetles were entered into them through the two
small holes in the plexiglass sheets and then the holes were covered with tape. The
beetles would often remain outside the wood for some time. ‘The two larger holes in
the aluminum on the bottom side of the boxes were initially left uncovered, resulting
in gradual drying of the wood. Beetles entering the wood was assumed to indicate that
the water content and age of the wood was appropriate for them, and when this was
observed, tape was stuck over the holes to prevent further drying. If the wood seemed
to get too dry, the tape was removed and a few drops of water added into the holes to
absorb into the wood. Using these methods, approximately 10 separate colonies were
produced. The apparatus was illuminated for observation using natural sunlight or
fiber optic gooseneck microscope lights powered by a halogen lamp.

Observation in naturally infested wood

Ficus microcarpa branches containing bark beetles were observed in place by peeling
off bark from branches still attached to the tree, or by cutting branches and dissecting
them. To facilitate locating wood at a desired stage of decay, fresh branches were also
cut, suspended off the tree, and later dissected. All such observations were taken from
wood on a large F microcarpa tree located in an unmaintained area of the campus of

the University of Hawai'i at Manoa at (21.2954°N, 157.8145°W, 15 m) (Fig. 10a),

The genus Acerocephala and life history under bark 551

or from other trees in the immediate vicinity. Additional host records were found by
dissecting wood from a variety of tree species and locations as a part of a larger survey
of bark beetle natural enemies on O‘ahu.

Results

Acerocephala Gahan, 1946

Redescription. Head subrectangular in face view, somewhat thin and elongate in
side view, flattened dorsoventrally and not globose (vac.l/hea.! approximately 1.7 or
greater). Anterolateral corner of head a distinct angle, sides of face either progressively
widening to this corner or mildly curved mesally to reach it. Mandibles long and arcing
(mdb.|/hea.b approximately 0.5 or greater), placed widely on face, their lateral corners
at or nearly at anterolateral corners of face. Anterior of face a concave arc; clypeus,
which has its base near the ventral side of this arc, may be visible in dorsal view pro-
jecting into the space between the mandibles. Compound eyes placed nearer back of
head than front, so that vey.|/vac.1 < 0.5. Antennae inserted well anterior of compound
eye, funicle with 5 or 6 segments in female. Scrobes deep and extend posteriorly well
behind toruli. Scrobes separated by interantennal ridge that extends well behind the
toruli to join with the upper face, the ridge flattened or mildly curved dorsally and
protruding or not from plane of the face.

Forewing with or without callus on parastigma, but the callus, if present, without
a tuft of setae. Wing membrane with slightly rippled texture and without setae on its
surface; stigmal vein short, postmarginal vein short if present. Males of some species
may be wingless.

Diagnosis and differential diagnosis. This genus can be distinguished within
Cerocephalidae by the combination of elongate rectangular, thin head shape (vac.!/
hea.l = 1.7); anterolateral corner of face a distinct angle, and with long mandibles
placed with their outer edges near the anterolateral corner of the face; antennae in-
serted distinctly anterior of compound eye; forewing without a tuft of thick setae on
callus on the parastigma, or lacking a callus, and without setae extending from its
membrane; clypeus may project into space between mandibles from near ventral side
of arc that comprises the anterior of the face, dorsal plane of head lacking a distinct
anterior projection into space between mandibles.

Within Cerocephalidae, this genus appears closest to Choetospilisca (Fig. 9),
Paralaesthia, and Muesbeckisia. It can be distinguished from Choetospilisca by the elon-
gate rectangular shape of the head in dorsal view and long arcing mandibles extending
from just inside the anterolateral corner of face; and broad interantennal ridge joining
to the plane of the upper face. (Choetospilisca with head more globose in side view; face
broadly tapers anteriorly, and thick but shorter mandibles extending from well inside
the lateral edge). The overall shape of the face is similar to Paralaesthia, but it can be

552, David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

distinguished by the lack of a tuft of thick setae on the callus of the parastigma; at most
a small projection of the clypeus into the space between the mandibles, which has its
base on the ventral side of the arc that comprises the front of the face; scrobal grooves
posterior to toruli deep and separated by a large, broad interantennal ridge connecting
to the upper face; lack of a mesal groove on the upper face; funicle segments slightly
nodose-bead like or transverse (Paralaesthia with thick setae emerging from the callus;
lower face anteriorly extended into a large triangular region between the mandibles, its
base extending from the dorsal plane of the face; a mesal groove running the length of
the upper face; scrobes shallow and not extended greatly posterior to toruli, interan-
tennal ridge small and similarly not of much consequence posterior to toruli; funicle
segments elongate cylindrical). It can be distinguished from Muesebeckisia by the more
elongate head shape and location of antennal insertion well below the anterior margin
of the eyes, and broad interantennal ridge. (Muesbeckisia with head globose, eye reach-
ing the anterior half of the face, and antennal insertion above anterior margin of eye).

Acerocephala indica comb. nov.
Choetospilisca indica Saraswat & Mukerjee, 1975

Remark. This species was only known from the holotype (female), slide mounted,
from Yercaud, in the Eastern Ghats of Tamil Nadu, India. What appears to be the same
species was found in the NMNH collection, a female and male point mounted with
this collection data: “PUERTO RICO // Santa Isabel // 21-VIII-1991 // S. Medina-
Gand //// ex mango // branch dying // of fire //// #91-9140 // Acerocephala // n. sp.
// det. // E. Grissell 1991” (female) and “PUERTO RICO // Santa Isabel // 21-VIII-
1991 // S. Medina-Gand //// ex mango // branch dying // of fire” (male). See Fig. 6 for
photos, and key for distinguishing characters.

Acerocephala hanuuanamu Honsberger & Lorenzo-Elarco, sp. nov.
https://zoobank.org/IADICC44-408 F-4BE6-AEF 1-73 F5C5626856
Figs 1-3, 10a

Diagnosis. Females of this species can be distinguished from other known Acerocephala
by the antenna with the first four funicular segments transverse and of similar size and
shape, followed by a larger and subcircular fifth segment and the clava; interantennal
ridge flush with face, not elevated in lateral view, and only slightly widened anteriorly;
scrobes reaching more than half the length of the head; submarginal and marginal
veins of forewing join smoothly with no callus; clypeus, to its apex, fills the space
between the mandibles when mandibles are closed. Males are similar to females in
characters of the head with the exception of the antennae, so can be distinguished from
other known species by these characters as well.

‘The genus Acerocephala and life history under bark 553

Figure |. Acerocephala hanuuanamu sp. nov. (paratypes) showing morphometric measurements.

Acronyms explained in text. Scale bars: 1 mm (b, ¢); 500 pm (a).

Differential diagnosis. Females are easily distinguished from A. atroviolacea,
A. aenigma, and A. pacifica by the first four funicular segments much smaller and
shorter than the fifth; overall gracility of the head and body; interantennal ridge not
elevated from the face in lateral view (A. atroviolacea, A. aenigma, and A. pacifica with
fifth funicular segment of similar size to preceding segments; body and head thicker
and more robust; interantennal ridge elevated from the face in lateral view); and from
A. atroviolacea and A. aenigma by lack of callus on the forewing (A. atroviolacea and
A, aenigma with callus present).

A. hanuuanamu is closest to A. ihulena sp. nov. and A. indica. Females can be dis-
tinguished from A. ihulena and A. indica by interantennal ridge not elevated from the
face in lateral view; first four funicular segments of similar size and distinctly smaller
than the fifth; ovipositor sheaths only slightly exerted, extending less than 1/3 the
length of the gaster; scutoscutellar grooves foveolate and meeting the transscutal ar-
ticulation lateral of medial line (A. thulena and A. indica with interantennal ridge
elevated from the face in lateral view; fourth funicular segment slightly but distinctly
larger than the first three; ovipositor sheaths distinctly exerted from the gaster, near
half its length, dark brown at the apex and lighter near the base; scutoscutellar grooves
a subcircular sulcus that reach the transscutal articulation mesally).

554 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Description. Female (Figs 1, 2a—d, 3a—c, ej, 10a; morphometric measurements
in Suppl. material 1). Length: Variable, depending on size of host. On C. brasiliensis
individuals range from 1.18—2.31 mm (Holotype 1.96 mm), the largest individual
collected was 2.50 mm from C. mangiferae, a slightly larger beetle.

Coloration: Head brown; slightly lighter anteriorly in lower face, basal part of
mandibles, and scape and pedicel. Mesosoma brown, prothorax and apex of propo-
deum often somewhat lighter. Petiole yellow. Gaster dark brown except basoventrally
where it is light brown, and the ovipositor sheaths which are light brown. Legs yellow-
brown, pro- and metacoxae somewhat lighter in color than their respective tibiae.

Head: Head subrectangular in full face view; more or less parallel sided, subtly
widest across eyes, of nearly equal width at about half its length, and tapers very slightly
to the anterolateral corner. Anterior of head, excluding the mandibles and project-
ed clypeus, a strongly concave arc. Clypeus projected medially, subrectangular with
slightly rounded base and longer than wide, to its apex occupies all the lateral space
between the mandibles when mandibles are closed. Interantennal ridge flush with the
face lateral of scrobes, not elevated dorsally from the face in lateral view; its anterior
half, to about even with where the scrobes narrow, laterally carinate, dorsally smooth
and slightly convex between the carinae; posterior to this non-carinate, more narrowly
and evenly rounded, along the median line joining smoothly with the upper face. Lat-
eral margins of scrobal depression just above the toruli extend approximately half the
width of the face, lateral margins distinctly taper and at about half the length of the
interantennal ridge where its carina ends; anterior of this the lateral margins are lightly
carinate and the depressions deeper; posterior to this with rounded margins and the
depressions become progressively narrower and shallow before they join with the upper
face. Mandibles long and curved with three apical teeth; dorsal and middle tooth of a
similar conical shape but with a deep groove between them, middle tooth projecting
slightly more than dorsal tooth, ventral tooth projecting about twice this much relative
to the middle tooth. Bottom of toruli adjacent to the dorsoventrally inclined arc that
comprises the anterior of the face. Occipital carina just posterior to posterior ocelli,
subcircular. Dorsal side of the face with smooth and shiny texture and with sparse
setae, the setae increase slightly in length and density anteriorly, more densely placed
short setae around the occipital carina. Ventral side of head generally flat with some
longer setae posteriorly, median suture extends longitudinally from the mouthparts
to the occipital carina, basal area near the suture indented slightly for about 2/5 the
length of the head, the cuticle in this indent with reticulate texture, cuticle on ventral
side of face otherwise smooth and shiny.

Antennal flagellum composed of 5 funicular segments and a subconical clava. First
four funicular segments transverse cylindrical and of similar size and shape, 5" fu-
nicular segment subspherical and larger than the first four, clava is approximately 1.4
times as long as the first four flagellar segments, rounded subconical. All antennal seg-
ments with thin setae projecting at approximately 45 degrees, the first four funicular

The genus Acerocephala and life history under bark 555

Figure 2. Acerocephala hanuuanamu sp. nov. holotype 2 (a-d) and allotype 3 (eh) a, e side view
b, f head c, g anterior view of head showing mandibles d, h dorsal view. Scale bars: 1 mm (a, d, e, h);
250 um (b, ¢, f, g).

556 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

a

MLE iy CEE

bed

NV

VAN || NN \\\\ \\

Figure 3. Acerocephala hanuuanamu sp. nov. a forewing 2 b hindwing 2 ¢ antenna Q d antenna 3

e dorsal view 2 (paratype) f head 2 (paratype) g anterior view of head showing mandibles 2 (paratype)
h foreleg 2 i midleg 9 j hindleg 9. Scale bars: 1 mm (e); 250 um (f, g).

segments with a single whorl of setae of length slightly less than the width of the seg-
ments, setae becoming progressively shorter towards the apex of the antenna. The 5"
funicular segment with MPS and the clava with three whorls of MPS; the first four
flagellar segments lack MPS. Mean length/mean width (Ratio) of antennal segments,
length and width measured relative to length of Fl (n = 12): Scape 6.0/2.3 (2.7) ;
Pedicel 3:4/1.7-0:0)3 FY 1.0/1.5. (0:7).; F2:0:9/1..5:(0:6).2-F 310/126 (0:6): 2F 4-12 1/18
(0.6) ; F5 2.5/3.0 (0.8) ; Clava 6.5/4.1 (1.6).

The genus Acerocephala and life history under bark 557

Mesosoma: Long prothorax articulates with mesothorax, rotating from in line
with the rest of the mesosoma to approximately 110 degrees. A light longitudinal
carina present laterally on pronotal neck, pronotum otherwise smooth, lacking a trans-
verse pronotal carina. Pronotal neck and collar smooth, collar with scattered mesal
pointing setae except on its dorsal surface near the medial line where there are no
setae. In dorsal view, pronotum very slightly widest near its middle, but at its wid-
est distinctly narrower than the mesonotum. Transscutal articulation deep and well
defined, straight until the lateral section where the sclerites incline vertically. Notauli
and scutoscutellar suture both foveolate and visible relative to the otherwise smooth
and shiny mesonotum, marked by punctures and a mild sulcus, setae on either side of
the sutures, the notauli deepening anteriorly and giving the mesonotum a shouldered
appearance. Lateral of the median line, notaulus and scutoscutellar suture meet the
transscutal articulation at approximately a 45 degree angle and at approximately the
same point, so the medial lobe of the mesoscutum and the scutellum run up against
each other for a distance (see morphometric measurements). In dorsal view, scutoscu-
tellar sutures are fairly straight until they meet the transscutal articulation, notauli are
mildly curved. Posterior margin of scutellum evenly convex. Mesonotum smooth and
glassy, free of setae except on either side of the notauli and on either side of the scutos-
cutellar suture, a few scattered setae on the axillae, and near posterior margin of the
scutellum. Metanotum visible behind scutellum. Propodeum slightly wrinkled at its
anterior margin and on the callus anterior of the spiracle, otherwise smooth and glassy,
flat longitudinally and lightly rounded transversely. Propodeal spiracle slightly recessed
in a small depression, paraspiracular sulcus a very slight and smoothly rounded depres-
sion continuing from the spiracular depression posteromedially and gradually fading.
Sides of the propodeum slightly tapering posteriorly until above attachment of the rear
coxae, where they abruptly taper to about 60 degrees from the anteroventral line, then
curve to be slightly more longitudinally oriented toward their apex at the nucha, top of
petiolar insertion flush with dorsal surface of propodeum. Setae near the lateral mar-
gins of propodeum: on callus anterior of the spiracle, on lateral margin where callus
meets the metapleuron, and just above where the propodeum accommodates the hind
coxal foramen. Mesopleuron with light reticulate texture, mesepisternum with setae.

Wings: Forewing: Length of marginal vein approximately 1.15 x length of sub-
marginal vein. Short postmarginal vein extends to approximately even with the stigma
or somewhat less. Stigmal vein projects from marginal vein at slightly less than 45
degrees and has a slight curve apically. Three dorsal setae on marginal vein, basal one
small and inconspicuous. Marginal setae begin at the base of marginal vein and con-
tinue around apex of wing with approximately consistent length to trailing edge ap-
proximately even with stigmal vein, just apical of retinaculum. Parastigma not swollen,
submarginal and marginal veins joining smoothly and unperturbed with no swollen
area or change in pigmentation; lacking any sign of a tuft of setae on the parastigma.
Membrane subhyaline with slightly rippled texture and without setae; basally to end of
venation lightly infuscated, the area near and posterior to stigma most shaded.

Hindwing: Venation with a concavity at approximately half the distance from the
base to the hamuli, venation hyaline at the culmination of this concavity; anterior

558 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

margin of wing membrane extends mote or less straight in this region so at the apex of
the concavity the venation reaches nearly 2 the distance to the posterior of the wing
membrane. Venation ends at the hamuli but the very anterior of the membrane in line
with venation remains somewhat pigmented beyond the hamuli, to approximately 2/3
the length of the wing. Marginal setae present from the end of this pigmented region
around to base of trailing edge of wing, longest around trailing edge where they are
approximately 34 the maximum width of the wing.

Legs: Fore and rear coxae globose, subequal in size and shape though the fore coxa
hides somewhat under the pronotum. Femora also globose, slightly larger than their
respective coxae in the front and mid, legs, subequal in the back leg. Tibiae of similar
length to their respective femora, also globose apically, but narrower basally. In all legs,
first tarsal segment longest, 2" through 4° segments sequentially decrease in length; 5°
segment not including the claw intermediate between 1“ and 2" in front and middle
legs, subequal to 2" in back legs. Protibial spur deviates from straight with a jog of shape
similar to a logistic function, its base set back on the tibia and extending just past base of
first tarsal segment, tibia beneath the spur with protibial comb. Midleg and back leg with
narrower, straight protibial spur extending from near the apex of the segment. Fore and
midleg with the two basal tarsi of each leg spinose, spines fading on the apical segments;
hindleg with spines smaller except for those at the apex of the tarsal segments. Tibiae
with narrow setae and no additional spines, except for the very apex of the back leg.

Metasoma: Petiole somewhat globose-vase shaped, the widest point marked by
one or two lateral setae on a small knob; somewhat flat dorsally, overall of subequal
length and width. First and second gastral segments emarginate medially, subsequent
segments with straight posterior margin. Gaster in living individuals expands and con-
tracts during feeding, use of the ovipositor, and movement; therefore the following
applies to dried individuals. 1“ and 4% gastral tergites longest, 3“ slightly shorter, 2°4
substantially shorter than 3“; 5" very short; 6" subequal in length to 2™'. Gaster not
heavily sclerotized, shrivels slightly on drying. Gaster with few, small setae on first five
segments, 6" with many setae, some short, some longer than the exserted ovipositor
sheath, but rarely reaching past it due to their angle. Ovipositor sheaths also setose, and
are slightly exserted; ovipositor thin and needle-like.

Male (Figs 2e—h, 3d; morphometric measurements in Suppl. material 1). Length:
Typically, but not always, smaller than females developing in the same colony of hosts.
As with the female, size depends on the size of the host, but the smallest individuals are
nearly always male. Very variable, from 0.83—1.65 mm (allotype 1.60 mm).

Similar to female except: Wingless. Antennae with 6 funicular segments, similar
to that of female except that the four similarly shaped basal flagellar segments in the
female are five in the male, the sixth larger and subcircular; clava with two whorls of
MPS. Mean length/mean width (Ratio) of antennal segments, length and width meas-
ured relative to length of Fl (n = 7): Scape 6.5/2.4 (2.7) ; Pedicel 3.7/1.8 (2.1) ; Fl
1.0/1.4 (0.7) B2: LAS -5 0-8} 9 F3) bel 1eG: (057 )8 F4 1.2/1.8 (07) 3 FS 1 4/2 10-7)
; F6 2.1/2.9 (0.7); Clava 5.3/3.7 (1.5). Ocelli absent and compound eye smaller than

in female, morphometrics of face otherwise similar, mandibles similar. Posterior region

The genus Acerocephala and life history under bark 229

of pronotum tapers slightly to fit around the narrower medial lobe of the mesoscutum.
Notauli nearly meet on the medial line at the transscutal articulation, scutoscutellar
suture meets transscutal articulation lateral to this, similar to the female. Pro- and mes-
oscutum smaller than in female, scutellum much shorter than in female, metanotum
behind it appears in dorsal view nearly straight with nearly parallel anterior and poste-
rior margins. Femora, tibiae, and tarsal segments somewhat stouter than in female, but
their relative lengths remain similar. Posterior margin of propodeal disk with scattered
setae. Gaster shorter, apically truncated-looking in dry specimens.

Materials examined. Holotype (Fig. 2a—d): 2; Hawaiian Islands, O‘ahu, Manoa;
21.2946°N, 157.8136°W; 2.viii.2022; below bark of Ficus microcarpa branch (depos-
ited in UHIM).

Allotype (Fig. 2e-h): @; Hawaiian Islands, O‘ahu, Manoa; 21.2946°N,
157.8136°W3 2.viii.2022; below bark of Ficus microcarpa branch (UHIM).

Paratypes: 65°, 54. Hawaiian Islands, O‘ahu, Manoa; 21.2946°N, 157.8136°W:
2.viii.2022; below bark of Ficus microcarpa branches; 572, 52¢ (199, 183 UHIM;
192, 175 BPBM; 1992, 183° NMNH) « Hawaiian Islands, O‘ahu, Manoa;
21.3060°N, 157.8092°W; 15.xii.2020; below bark of Artocarpus altilis branch; 2 adult
9 and 1 pupa glued to point (UHIM) ¢ Hawaiian Islands, O‘ahu, Manoa; 21.5604°N,
157.8765°W; 31.i.2020; below bark of Mangifera indica branches; 39, 1¢é 9,13
UHIM; 12 BPBM; 12 NMNH) « Hawaiian Islands, O‘ahu, Manoa; 21.2954°N,
157.8145°W; 27.vii.2018; below bark of Ficus microcarpa branches; 39, ig-A2 218
UHIM; 12° BPBM; 12 NMNBH).

Other materials examined. Hawaiian Islands, O‘ahu, Manoa; 21.2952°N,
157.8141°W; 3.xii.2020; below bark of Trema orientalis branch; wasp ex tunnels in-
habited by the beetle; 1 9 and 1 C. brasiliensis adult glued to point (UHIM).

Etymology. The species name is Hawaiian, hanu‘uanamii (lit., flowing between
caves of the insect). This species constructs a feeding tube to host-feed through the
walls of the pupation chamber constructed by its host. Hanu'u represents the continu-
ous action of ebb, flow, and exchange of fluid through the connection bridging the
cavern (ana) and the wasp, and ana mi recognize the system of tunnels and caverns
constructed by the host insect (mi), reminiscent of lava chambers.

Known distribution. This species is known from the island of O'ahu in Hawai'i,
where it is likely adventive.

Known hosts. Cryphalus spp., including C. brasiliensis and C. mangiferae.

Acerocephala ithulena Honsberger & Lorenzo-Elarco, sp. nov.
https://zoobank.org/4C02F85F-8AA5-4847-95F6-01C3C4235F5A
Figs 4, 5

Diagnosis. Females of this species can be distinguished from other known Acerocephala
by the antenna with the first three funicular segments transverse and of similar size and
shape, the fourth segment slightly but distinctly larger, the fifth larger and subcircular;

560 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

internantennal ridge elongate-oval in dorsal view, elevated from face in lateral view; sub-
marginal and marginal veins of forewing join smoothly with no callus; clypeus projected
between the mandibles subrectangular and apically mildly bidentate; ovipositor sheaths
exerted from gaster, approximately half its length, apically dark brown and basally lighter.

Differential diagnosis. Females are easily distinguished from A. atroviolacea, A. ae-
nigma, and A. pacifica by the first four funicular segments transverse and much smaller
and shorter than the fifth; the overall gracility of the head and body; and the elongate-
oval shape of the interantennal ridge (A. atroviolacea, A. aenigma, and A. pacifica with
fifth funicular segment of similar size to preceding segments; body and head thicker
and more robust; interantennal ridge in dorsal view triangular or wedge shaped); and
from A. atroviolacea and A. aenigma by lack of callus on the forewing (A. atroviolacea
and A. aenigma with callus present).

Females can be distinguished from A. hanuuanamu by the fourth funicular segment
slightly but distinctly larger than the first three; interantennal ridge elevated from the
plane of the face; ovipositor exerted from the gaster approximately half its length, dark
brown apically and lighter basally; scutoscutellar lines sulcate and form a consistent arc
to meet the transscutal articulation along the mesal line (A. hanuuanamu with the fourth
funicular segment indistinctly larger than the first three; interantennal ridge flush with
the face lateral of the scrobes; ovipositor only slightly exerted from the gaster; scutoscu-
tellar lines foveolate and meet the transscutal articulation lateral of the mesal line).

Females can be distinguished from A. indica by the shape of the interantennal
ridge, in A. ihulena elongate-oval and reminiscent of the nose of a proboscis monkey
(A. indica with interantennal ridge blunt wedge-like, widening posteriorly with some-
what straight margins); by the anterior of the face excluding the clypeus distinctly
concave in A. indica (nearly straight between the anterolatral corners of the face in A.
ihulena); and by the stigmal vein of the forewing, A. ijulena with the stigmal vein very
short, only incompletely separating the stigma from the marginal/postmarginal veins
(A. indica with stigmal vein short, but a distinct vein-like constriction between the
marginal/postmarginal vein and the stigma).

Description. Female (Figs 4a—d, 5a—g; morphometric measurements in Suppl.
material 2). Length: Can be expected to vary depending on the size of the host; the 7
individuals collected range from 1.52—1.84 mm (Holotype 1.80 mm).

Coloration: Head brown, slightly lighter anteriorly in lower face, basal part of
mandibles, and scape. Mesosoma orange, prothorax somewhat lighter. Gaster dark
brown, slightly lighter basally, and ovipositor sheaths yellow in their basal 2/3 and
brown apically. Legs yellow, pro- and metacoxae sometimes nearly translucent.

Head: Head subrectangular in full face view; more or less parallel sided, but subtly
widest across eyes, of nearly equal width at about three quarters its length, and ta-
pers slightly to the anterolateral corner; vertex between posterior ocelli nearly straight,
broadly rounded laterally to eyes. Anterior of head excluding mandibles and projected
clypeus a mildly concave arc. Clypeus projected medially, somewhat square in shape
and mildly bidentate, occupies about half the lateral space between the mandibles when
mandibles are closed. Interantennal ridge widest at about half its length, shape elongate-

The genus Acerocephala and life history under bark 561

Figure 4. Acerocephala ihulena sp. nov. holotype 9 (a=d) and allotype 3 (eh) a, e side view b, f head
c, g anterior view of head showing mandibles d, h dorsal view. Scale bars: 1 mm (a, d); 500 um (e, h);
250 um (b, ¢, f, g).

oval, similar to that of a proboscis monkey; carinate laterally, medially between the
carinae slightly convexely rounded with light longitudinal striations; slightly elevated
from the level of the face lateral of scrobes, in lateral view of head extends tangential to
curve of face at its thickest point disregarding the interantennal ridge, and continues

562 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Figure 5. Acerocephala ihulena sp. nov. a head (paratype 2) b antenna (Q) ¢€ side view (paratype &)
d forewing (2) e hindwing (2) f dorsal view (paratype 2) g anterior view of head showing mandibles
(paratype Q) h head (paratype @) i anterior view of head showing mandibles (paratype @) j dorsal view
(paratype @). Scale bars: 1 mm (ce, f); 250 pm (a, g-j).

straight more or less parallel with ventral profile of the head, giving the head approxi-
mately equal thickness over its length while the face lateral of scrobes thins towards the
mandibles. Interantennal ridge begins a gradual descent to the mouthparts posterior
to the toruli, and at about even with middle of the toruli, somewhat abruptly curves
downward, to connect with the projection of the clypeus, at an approximate 60 degree
angle to the overall plane of its dorsal surface. Lateral margins of scrobal depression a
consistent arc, narrowing posteriorly, and slightly carinate; scrobes decrease in depth
posteriorly. Mandibles long and curved with three apical teeth; dorsal and middle tooth
of a similar conical shape but with a deep groove between them, middle tooth project-
ing only very slightly more than dorsal tooth, ventral tooth joined to middle tooth
more closely and projecting a short way beyond it. Occipital carina just posterior to
posterior ocelli, subcircular. Texture smooth and shiny with sparse setae, on the dorsal

The genus Acerocephala and life history under bark 563

side setae concentrated on the gena anterior of the compound eyes and on the face just
above the scrobes, a few longer setae dorsally around the occipital carina, ventral side of
head posterior of the indented region also with longer setae. Bottom of toruli adjacent
to the dorsoventrally inclined arc that comprises the anterior of the face. Ventral side of
head generally flat, median suture extends longitudinally from the mouthparts to the
occipital carina, basal area near the suture indented slightly for about 2/5 the length of
the head, cuticle posterior of this indent of rougher texture than cuticle within it.

Antennal flagellum composed of 5 funicular segments and a subconical clava. First
three funicular segments transverse cylindrical, progressively becoming subtly coni-
cal, and of similar size, 4" is slightly rounded and slightly but distinctly larger than
first three, 5" is subspherical and larger than the 4"; clava is approximately 1.4 times
as long as the first four flagellar segments together, rounded subconical. All antennal
segments with thin setae projecting at approximately 45 degrees, first four funicular
segments each with a single whorl of longer setae of length subequal to the width of the
segments, setae becoming progressively shorter towards apex of antenna. 5" funicular
segment and claval segments with MPS, clava with 3 whorls of MPS, first four flagel-
lar segments lacking MPS. Mean length/mean width (Ratio) of antennal segments,
length and width measured relative to length of F1 (n = 7): Scape 6.8/1.7 (4.0); Pedicel
2.9/1.4 (2.0); F1 1.0/1.2 (0.8); F2 0.9/1.2 (0.7); F3 1.0/1.4 (0.7); F4 1.3/1.8 (0.7); F5
2.1/2.6 (0.8); Clava 5.8/3.2. (1.8).

Mesosoma: Long prothorax articulates with mesothorax. A light longitudinal ca-
rina present laterally on pronotal neck, pronotum otherwise smooth, neck distinct
from collar but lacking transverse pronotal carina. Pronotal neck with light transversely
ridged texture, and collar smooth; collar with scattered mesal pointing setae except on
its dorsal surface near the median line where there are no setae; one or two longer setae
on its ventral side, of similar length to those on the ventral side of the head. Pronotum
distinctly widest at its middle, but at its widest distinctly narrower than mesonotum
in dorsal view, at its maximum width a little less than 3/4 the width of mesoscutum
not including the tegulae. Transscutal articulation straight, inclines to vertical at its lat-
eral edges. Notauli and scutoscutellar suture both well defined sulci; mesoscutum and
scutellum lacking setae medially, a few setae present near the notauli, scutoscutellar
suture, and transcutal articulation. On each side of the median line, notaulus curves to
meet the transscutal articulation in the vicinity of 60 degrees, and scutoscutellar suture
arcs to meet the transscutal articulation along the medial line, so medial lobe of mesos-
cutum runs up against transscutal articulation but scutellum is separated from it by the
axillae except at its middle point (see morphometric measurements). Posterior margin
of scutellum evenly convex. Mesonotum smooth and glassy, free of setae except on
either side of the notauli and on either side of the scutoscutellar suture, a few scattered
setae on the axillae and near the posterior margin of the scutellum. Metanotum visible
behind scutellum. Propodeum slightly wrinkled at its anterior margin but otherwise
smooth and glassy, flat longitudinally and lightly rounded transversely. Propodeal spir-
acle slightly recessed in a small depression. Sides of propodeum slightly tapering pos-
teriorly until above the attachment of the rear coxae, where its dorsal margin bends to

564 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

run nearly transversely except for at the nucha which is bumped out posteriorly, top of
petiolar insertion flush with disk of propodeum. Setae near lateral margins of the pro-
podeum: on callus anterior of the spiracle, and on lateral margin where the callus meets
the metapleuron. Mesopleuron with light reticulate texture, mesepisternum with setae.

Wings: Forewing: Length of marginal vein approximately 1.1 x length of sub-
marginal vein. Stigmal vein very short, hardly separating stigma from marginal vein,
postmarginal vein also very short or absent, appearing together with stigmal vein as
a slightly thickened apex of the marginal vein. Marginal vein without dorsal setae.
Marginal setae begin at base of marginal vein and continue around apex of the wing
with approximately consistent length to trailing edge approximately even with stigmal
vein, just apical of the retinaculum. Parastigma not swollen, submarginal and marginal
veins joining smoothly and unperturbed with no swollen area or change in pigmenta-
tion; lack of any sign of a tuft of setae on the parastigma. Membrane subhyaline with
a slightly rippled texture and without setae.

Hindwing: Venation with a concavity at approximately half the distance from the
base to the hamuli; anterior margin of wing membrane extends more or less straight
in this region so at the apex of the concavity the venation reaches nearly ¥2 the dis-
tance to the posterior of the wing membrane. Venation ends at hamuli but the very
anterior of the membrane in line with venation remains somewhat pigmented beyond
the hamuli, to approximately 2/3 the length of the wing. Marginal setae present from
the end of this pigmented region around to the base of the trailing edge of the wing,
longest around trailing edge and posterior margin where they are approximately 3/4
the maximum width of the wing.

Legs: Fore and rear coxae globose, rear coxa larger than fore coxa, mid coxa small-
est. Femora also globose, slightly larger than their respective coxae in front and mid
legs, of similar size but more elongate in back legs. Tibiae of similar length to their
respective femora, also globose apically, but narrower basally. In all legs, first tarsal seg-
ment longest, 2"* through 4" segments sequentially decrease in length; 5 segment not
including the claw subequal to 1“in front legs, subequal to the 2°* in mid and back
legs. Protibial spur deviates from straight with a jog of shape similar to a logistic func-
tion, its base set back on tibia and extending near middle of the first tarsal segment,
tibia beneath spur with a protibial comb.

Metasoma: Petiole somewhat narrower medially than basally or apically, one or
two lateral setae on a small knob near its middle; overall somewhat longer than wide.
In dried individuals, 1* gastral tergite longest; 4° tergite a little more than half the
length of 1%; 2°¢ and 3 subequal and about half the 4°; 5" very short; 6" a little
shorter than 4". Gaster not heavily sclerotized, shrivels slightly on drying. Gaster with
few, small setae on first five segments, 6" with many setae, some short, some longer
and reaching about half the length of the exerted ovipositor sheaths. Dried individu-
als have hypopygium distinct. Ovipositor sheaths substantially exserted from apex of
gaster, setae basally present on only ventral side, medially and apically present; longest
setae at about half its length, reaching approximately the apex of the sheaths; ovipositor
thin and needle-like.

The genus Acerocephala and life history under bark 565

Male (Figs 4e—h, 5h—j; morphometric measurements in Suppl. material 2). Length.
Only two individuals collected, allotype 1.14 mm, paratype 0.85 mm.

Similar to female except: Wingless. Antennae with 6 funicular segments, basal four
segments of relatively consistent size, fourth through sixth increasing in size; clava with
two whorls of MPS. Mean length/mean width (Ratio) of antennal segments, length and
width measured relative to length of Fl (n = 2): Scape 9.1/2.7 (3.4) ; Pedicel 4.3/2.3
(1.9) ; F1 1.0/1.8 (0.6) ; F2 1.2/1.9 (0.6) ; F3 1.1/1.9 (0.6) ; F4 1.4/2.1 (0.7) ; F5 2.1/3.2
(0.7) ; F6 2.9/4.1 (0.7); Clava 6.9/4.7 (1.4). Ocelli absent and compound eye smaller
than in female, face very subtly widest about even with middle of scrobes, morphomet-
rics of face otherwise similar, mandibles similar. Body size relative to head size smaller
than in female. Posterior region of pronotum tapers slightly to fit around the narrower
medial lobe of the mesoscutum. Notauli meet on medial line anterior of transscutal
articulation, scutoscutellar suture meets transscutal articulation lateral to this. Pro- and
mesoscutum smaller than in female, scutellum much shorter than in female, metano-
tum behind it appears in dorsal view with nearly straight posterior margin but partially
covered by the scutellum medially. Femora, tibiae, and tarsal segments somewhat stouter
than in female, but their relative lengths remain similar. Posterior margin of propodeal
disk with scattered setae. Gaster shorter, truncated-looking apically in dry specimens.

Materials examined. Holotype (Fig. 4a—d): 2; Hawaiian Islands, O‘ahu, Manoa;
21.5571°N, 157.8783°W; 24.vii.2018; ex Hibiscus tiliaceus branches (deposited in
UHIM).

Allotype (Fig. 4e-h): @; Hawaiian Islands, O‘ahu, Manoa; 21.5571°N,
157.8783°W; 11.xii.2019; pupating next to Eidophelus pacificus dessicated larva in
E. pacificus tunnel in H. tiliaceus branch (deposited in UHIM).

Paratypes: 12°, 14. Hawaiian Islands, O‘ahu, Manoa; 21.5571°N, 157.8783°W;
24.vii.2018; ex Hibiscus tiliaceus branches; 72 point mounted, 19 slide mounted (2
point mounted, 1 slide mounted UHIM; 2 BPBM; 3 NMNH) « Hawaiian Islands,
O‘ahu, Manoa; 21.5571°N, 157.8783°W; 17.x.2018; ex Hibiscus tiliaceus branch-
es; 22 point mounted (1 BPBM; 1 NMNH) ¢ Hawaiian Islands, O'ahu, Manoa;
21.5571°N, 157.8783°W; 2.xii.2019; ectoparasitoid on E. pacificus larva found un-
der bark of H. tiliaceus branch; 12 (BPBM) * Hawaiian Islands, O‘ahu, Manoa;
21.5571°N, 157.8783°W; 11.xii.2019; pupating next to Eidophelus pacificus dessicated
larva in E. pacificus tunnel in H. tiliaceus branch; 13 (NMNH) * labeled “Tapatapao //
Upolu, Samoa // vii-13-40 //// 1000’ //// Beating dead branches //// EC Zimmerman
Collector”; 12 (BPBM).

Etymology. The species name is Hawaiian (lit., yellow nose). The nose-like interan-
tennal ridge appears to be a good distinguishing character in the genus. In this species
the interantennal ridge is distinguished from that in other Acerocephala by its elongate-
oval shape with carinate edges and light longitudinal striations, reminiscent of a banana
cut in half longitudinally. Ihulena is a play on ihu (nose) and iholena, a short and
rounded variety of banana brought by Polynesian ocean voyagers and grown in Hawaii.

Known distribution. This species is known from the island of O’ahu in Hawai'i,
and the island of Upolu in Samoa. It is likely adventive in Hawai'i.

566 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Known hosts. Found developing as an ectoparasitoid of an Eidophelus pacificus
(Schedl, 1941) (Coleoptera: Scolytinae) larva in tunnels under the bark of a Hibiscus
tiliaceus L. log in Kahana Bay, Oahu, 21.5571°N, 157.8783°W, 15 m (Fig. 17b, c).
Also found pupating next to dessicated larvae of E. pacificus in otherwise uninhabited
larval feeding tunnels in the same logs (Fig. 17a, b).

Key to world known Acerocephala spp. females
(See Figs 1-8 for photos)

1 Callus on parastigma of forewing; antennal funicle 6-segmented; mandibles
AE LS EN EALC NA Mei tale ose stn Se Abe casielee We nates Neate ts, ENED Ms) Pet eee Me Roe 8 2
— Submarginal vein of forewing joins smoothly to marginal vein without a cal-
lus or especially thickened region; antennal funicle 5-segmented (males may
be-G-ségmented) smataibles, 3-Aemntate css eteetonpeeterstietnageanventedsdnacdsorspedses 3
2 Interantennal ridge truncate anteriorly, in side view abruptly becomes vertical
relative to the plane of the face; scrobal grooves reach to approximately even
with the middle of the compound eyes ............... A, atroviolacea (Fig. 8a—e)
- Interantennal ridge rounded anteriorly, in side view gently sloped as it nears
the clypeus; scrobal grooves reach to approximately even with the anterior
MMALBINOL the COMMPOUTIA'EVES) 21 eaduasenmeeanatiecuriiees A, aenigma (Fig. 8f—h)
) First two antennal funicle segments distinctly longer than wide; head widest
at eyes and at anterolateral corner, head below eyes progressively widens to
themnterolatcral COREE A. sue toberhe shat inede her a asilagtue A, pacifica (Fig. 7)
— At least first 3 funicle segments distinctly shorter and compressed relative to
distal funicle segments, subequal length and width or transverse; head widest
across eyes and at about half its length, tapers slightly as it approaches the
AITLENO ACL AE COMIC ers. eutasmenediut creas Naos ectak colar ton uteh cat nrdsoteetaden tease ute cate 4
4 First four funicle segments of similar shape and size, much smaller and com-
pressed compared to the fifth which is more round; scrobes reach past half
the length of the face; interantennal ridge not elevated, flush with face lateral
of scrobes; ovipositor sheaths only slightly exerted from apex of gaster, less
than 1/3 the length of the gaster; scutoscutallar grooves meet the transscutal
articulation lateral of the median line, so the scutellum runs up against the
mesoscutum for a short distance ............000. A. hanuuanamu (Figs 1-3, 10a)
= First three funicle segments small and compressed, the fourth and fifth dis-
tinctly progressively larger and more rounded; interantennal ridge slightly
elevated relative to the face lateral of the scrobes; ovipositor sheaths distinctly
exerted from apex of gaster, nearly half or more its length; scutoscullar grooves
arc to meet the transscutal articulation along its midpoint, so the scutellum is
only directly next to the mesoscutum at this midpoint, and is separated from
it lareralloa tagcat newer LACE «nS creesinecrsqureneetee’s Biv sesteney tec tara say Receean pee Peapeame rome oat 5
5 Internantennal ridge elongate-oval shape, narrowed anteriorly and posteriorly
relative to its middle; anterior of the face between the anterolateral corners

The genus Acerocephala and life history under bark 567

excluding the projected clypeus nearly straight; stigmal vein very short, so the
stigma is nearly contiguous with the marginal/postmarginal veins though it
may narrow somewhat between them .............ceseeeeees A, ihulena (Figs 4, 5)
Interantennal ridge blunt-wedge shaped, progressively widening posteriorly
with somewhat straight margins; anterior of the face between the anterolat-
eral corners excluding the clypeus distinctly concave; stigmal vein somewhat
longer, distinctly separating the stigma from the marginal/postmarginal vein

Fee DF ey Ri 1 eh af 6 MER REE Oe hi PD es Bal A. indica (Fig. 6)

Note: Males are only known for A. hanuuanamu, A. ihulena, A. indica, and
A, aenigma, so males of other species must be found before distinguishing characters
are determined with certainty. Males of A. hanuuanamu, A. ihulena, A. indica, and
A, aenigma are, however, very similar to females in characters of the head with the
exception of the antennae in all four species, and the smaller eye and lack of ocelli
associated with aptery in A. hanuuanamu, A. ihulena, and A. indica; the overall shape
of the head and the interantennal ridge very similar between the sexes. If this pattern
holds for other species, males may likely be identified using these same characters of
the head as well, listed in the key. Males are wingless in A. hanuuanamu, A. ihulena,
and A. indica, and winged similar to the females in A. aenigma, so wings and the as-
sociated development of the mesosoma, along with characters of the gaster associated
with their sex, may be expected to differ.

Behavior of C. brasiliensis and A. hanuuanamu in phloem sandwiches

Cryphalus brasiliensis beetle galleries in E microcarpa wood

Some of the C. brasiliensis beetles placed in the phloem sandwiches bored into the
wood and excavated somewhat irregular subovate chambers, much wider than the
entry tunnel, in which they laid their eggs (as in Fig. 12a, see also Fig. 11b for the
corresponding stage of development in natural wood). Adult beetles were observed
to actively clean the inside of these chambers by pushing debris out of the entrance
to the tunnel with their elytral declivity. Larvae hatching from their eggs chewed
tunnels around the perimeter of the chamber and then progressed generally along
the grain of the wood, often moving as a whole in somewhat of a comb pattern but
with staggered progress. On one occasion, an adult beetle was observed using its
head and prothorax to vigorously and repeatedly push a newly emerged larva, the
behavior continuing for a minute or two. The purpose of this behavior was unclear
to us, but two possibilities may be (1) an attempt to assist the larva in starting its
own feeding tunnel off the main gallery, or (2) a transfer of symbiotic organisms
to the larva. If the view boxes were suddenly exposed to high levels of light, adults
were observed to become somewhat agitated and occasionally cannibalize their eggs.
We did not observe any clear differences in the behavior of immature beetles when
exposed to different levels of light.

568 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Moving through the beetle galleries
(Video 1 (https://vimeo.com/717186840))

Female A. hanuuanamu entered wood in the phloem sandwiches through holes drilled
by the beetles. After entering the tunnels, adult beetles with eggs or larvae deeper in their
tunnels were observed to actively attempt to block the wasp from progressing past them
deeper into the tunnel. A beetle did so by sharply moving its posterior to block attempts

Figure 6. Acerocephala indica. Holotype 2 (a-e); non-type Q (f-j); non-type ¢ (k-m) a, h, I head

b antenna c forewing d mesosoma (dorsal view) e gaster f, k side view g, m dorsal view i anterior view

of head showing mandibles j head.

The genus Acerocephala and life history under bark 569

by the wasp to go around. Wasps were observed to grab the elytral declivity or posterior of
the abdomen of beetles with their mandibles when attempting to pass them, though this
was not observed to actually help them progress past the bark beetle. Physically encounter-
ing an adult beetle in an open area, either in a spacious gallery or outside wood, not in the
confined space of a tunnel, resulted in the wasp quickly moving away. Such avoidance be-
havior was potentially for good reason, as when wasps and beetles were placed together in a
confined space such as a tube, it was not uncommon to see wasps missing their entire gaster
which, though this was never actually observed, was presumably bitten off by the beetles.
The beginnings of some tunnels bored by the larvae were very narrow due to the
small size of the larvae in their early development, though small larvae were also ob-
served to sometimes work in small groups of two or three larvae that would move
through the wood side by side and create a wider tunnel (e.g. Fig. 12c and the two
larvae on the right side in Fig. 12a). Though A. hanuuanamu adults vary substantially
in size depending on size of the host on which they develop, even some of the small-
est female wasps were not able to fit through these smaller larval tunnels. As time
progressed, more space opened up as beetle larvae and adults developed and created

Figure 7. Acerocephala pacifica. Holotype 2 (a-c) and paratype 9 (d—g) a, g side view b, d dorsal view
c, e head f view of head showing mandibles. All photos taken by Lisha Jasper and Jeremy Frank at BPBM.

570 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Figure 8. Acerocephala atroviolacea and Acerocephala aenigma. Acerocephala atroviolacea paratype ° (a-e);
A. aenigma holotype & (f-h) (photos from NMNH database); A. aenigma allotype 3 (j-l) a, f, j side view

b, h, I head c, g, k dorsal view d anterior view of head showing mandibles e side view of head showing

antenna i A. aenigma antenna (paratype 2) m_A. aenigma antenna (paratype ©).

tunnels in the wood, and individual, isolated tunnels formed a network of intersecting
tunnels. Observations in both naturally infested wood (see Fig. 11d, e) and the phloem
sandwiches (see Fig. 10d) showed that this dynamic would progress until eventually
almost all the inner bark had been consumed and the outer bark was only loosely at-

The genus Acerocephala and life history under bark py

Figure 9. Choetospilisca tabida holotype 2 (a-e) and allotype ¢ (f-i) a, f side view b, i dorsal view

c antenna d, g head e, h anterior view of head showing mandibles.

tached to the xylem layer. In a developed tunnel network such as this with a population
of host beetles, A. hanuuanamu adults were able to move around with much more ease,
encounter more potential hosts and fewer one-way tunnels blocked by adult beetles,
and seemed to have the most success.

Such tunnel systems often contained frass and debris from the beetles’ exca-
vation, sometimes packed somewhat densely, and the wasps would dig through it
in pursuit of hosts. Acerocephala hanuuanamu has remarkably large mandibles, for
which one use was to facilitate this digging behavior. Females progressed through
debris-filled tunnels by grabbing a chunk of debris with the mandibles, wrestling it
loose, and then passing it within reach of the front legs. Then using all her legs in
sequence she would quickly roll it back behind her abdomen in a running motion.
In this way, the wasp was able to travel through the tunnels in a way reminiscent of
a bubble in a tube of liquid: surrounded on all sides and moving material around its
margins to progress through.

Acerocephala hanuuanamu females having entered a tunnel seemed to be able to
sense the approximate location of potential host larvae they could not directly see,
shown by apparent deliberate motion in its direction, though the sensory mechanisms
involved were not clear.

572 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

- -~ e . 4%. —_
pe Age S&S Tftefug
as WEN ez &

f

ie k
ag a

Figure 10. Acerocephala hanuuanamu, Cryphatus brasiliensis, and the phloem sandwiches a A. hanuua-
namu © b C. brasiliensis 2 ¢ parts of phloem sandwich style observation chamber d phloem sandwich

with colonies of C. brasiliensis in FE microcarpa wood e, f closeups of additional phloem sandwiches.

The genus Acerocephala and life history under bark Byes:

Figure I 1. Ficus microcarpa wood where observations of behavior in a natural system were made.
Photographs of wood are from naturally infested branches taken after peeling off the bark a the F micro-
carpa tree from which most branches were collected and observations were made, in an unmaintained area
of the University of Hawai‘i at Manoa b wood in an early stage of colonization by C. brasiliensis beetles
c three C. brasiliensis beetle immatures, each parasitized by a feeding A. hanuuanamu larva d Ficus micro-
carpa branch with bark peeled off, showing C. brasiliensis tunnel systems and beetles, and A. hanuuanamu

larvae, prepupae, and pupae e same as (d) except the bark layer of the branch.

574 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Turning around
(Fig. 13; Videos 1 (https://vimeo.com/7 17186840), 2 (https://vimeo.com/716967741))

One amazing feat of agility accomplished by A. hanuuanamu with regularity is their
ability to turn around in the tight confines of a tunnel, often not much wider than
the wasp itself. The wasp first articulates its neck to face its head down, then bends its
prothorax down, and in doing so slides its head under the rest of the as-of-yet unmoved
posterior parts of its mesosoma. Bending its body along its points of articulation and
pushing on its own body with its legs while doubled over to assist its progress, the pro-
thorax is followed by the rest of the mesosoma and finally by the flexible gaster, ending
with the wasp being in more or less the same location but facing the opposite direction.
This maneuver is carried out very fluidly and quickly, and usually takes less than a few
seconds, but sometimes longer if the wasp appears not to have a strong purpose for
its movement. The fluidity in this snake-like maneuver is in part made possible by the
head, the prothorax, and the rest of the mesosoma all being subequal in length, and the
ability of the prothorax to articulate with the rest of the mesosoma. A similarly long,

‘=

sl
0” dete eet

Figure 12. Cryphalus brasiliensis in phloem sandwiches a C. brasiliensis adults in a gallery with eggs and
newly hatched larvae feeding and creating tunnels on the margins of the gallery b C. brasiliensis pupa and
prepupa in hard pupal chambers they constructed ¢ C. brasiliensis larvae feeding and moving through
wood.

The genus Acerocephala and life history under bark By)

Figure 13. Acerocephala hanuuanamu turning around in C. brasiliensis tunnels in a phloem sandwich:

sequence showing this agile maneuver frequently used to reverse orientation in the tunnels.

articulating prothorax is a character found in other unrelated taxa, such as much of
the Bethylidae, which also typically attack their hosts in concealed environments. ‘The
agility in a tunnel system or tight space that this trait confers could potentially be what
has resulted in this convergence.

Parasitism and host feeding on larvae in tunnels and construction of a feeding
tube
(Figs 14—16; Videos 1 (https://vimeo.com/7 17186840), 2 (https://vimeo.com/716967741))

When a host larva was encountered in the tunnels, the A. hanuuanamu female would
antennate upon it. Special attention was seemingly placed on the frass and debris around
the larva, suggesting that this is a cue for host location, host acceptance, or both. Once
a host was identified, the wasp would then turn around using the previously described
turning maneuver and back up in the direction of the larva, moving its body backward
in pulses and extending its ovipositor. Sometimes the wasp would contact the larva
with its ovipositor, but other times it would not, and turn around to reexamine the
larva with its antennae. The wasp seemed very cautious when encountering the larva,
especially when backing up into it, presumably because of the danger presented by its
mandibles. If the ovipositor made contact with the larva, the wasp would fully extend it
into the body of the larva (Fig. 14a). The wasp would typically remain with its oviposi-
tor inside the larva for approximately 15 minutes. During this time, the larva would
gradually cease motion, the wasp apparently having injected it with a paralytic venom.

576 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Figure 14. Acerocephala hanuuanamu stinging C. brasiliensis and host feeding in phloem sandwiches

a stinging a C. brasiliensis larva. The ovipositor is visible extending nearly the length of the wasp’s gaster
within the larva b subsequent host feeding on the same larva as in (a), on the same spot where it stung
the larva ¢ stinging a C. brasiliensis pupa through its hard pupal chamber after excavating the loose debris
outside the chamber. The ovipositor is visible in the empty space between the chamber wall and the pupa
d subsequent to stinging the pupa in (c), host feeding through the wall of the pupal chamber. Part of the
feeding tube is marginally visible protruding from the pupa as a small bump between the pupa and the
interior of the chamber wall, on the part of the pupa most proximal to the mouth of the wasp e probing
with the ovipositor to find the pupa inside the chamber. The ovipositor is visible extending towards the
pupa within the chamber. This attempt by the wasp was unsuccessful due to the position of the pupa
within the chamber f an additional subsequent feeding event by the same wasp on the same pupa. The
gaster is distended and the liquid periodically excreted by the wasp as it feeds is visible just past the end

of the wasp’s gaster.

When finally removing its ovipositor from the larva, the wasp would do so slowly
and carefully. In a few observed instances as it withdrew from the larva, tissue from
inside the body of the larva was visibly pulled out as a sheath around the ovipositor.

The genus Acerocephala and life history under bark S77

Figure 15. Feeding tube constructed by Acerocephala hanuuanamu after stinging, in phloem sandwiches

a close-up of a tube constructed on a larva as the wasp host feeds b tube is visible extending from the
posterior end of the larva near the wasp’s mouth. Such tubes constructed for feeding through the hard shell
of the pupal chamber are also marginally visible in Fig. 14d, f.

This sheath would remain projecting from the larva after the wasp had extracted its
ovipositor. The wasp would then turn around in the tunnel and put its mouthparts
on that projection, and host feed on the larva through it, evidently having produced
a drinking straw (Fig. 15). On occasions when construction of such a straw was not
observed, the wasp would still put its mouthparts precisely on the place where it
had stung the larva. The wasp would remain in this position, host feeding typically
for about 15 minutes. The wasp’s body would be still but its mouthparts could be
seen moving slightly, and it would periodically expel a clear liquid from its abdomen
(Fig. 14b). This liquid is likely to be excess fluid excreted for the purpose of concen-
trating nutrients from the host within the body of the wasp. Eventually the wasp
would stop feeding and would then often turn around again, sting the larva for a
similar amount of time as it had initially, and then feed again. This process was often
observed to be repeated three or four times on the same larva. Stinging was always
observed to result in death of the beetle immature. The wasp would most often leave
the larva without laying an egg, and sometimes it would eventually lay an egg on the
same larva upon which it had host-fed.

Feeding and oviposition through a pupal chamber
(Video 2 (https://vimeo.com/716967741))

Cryphalus brasiliensis prepupae were observed to build a hard pupal shell around them-
selves made from bonded tunnel debris before they pupated (Fig. 12b). Upon approach-
ing a pupal chamber, wasps were clearly able to sense the presence of a host and were
stimulated to excavate the loose material in the vicinity of the pupal chamber and dig
into the hard pupal shell as far as possible. This process of excavating appeared to be very
laborious and was observed to last over an hour on occasion. Due to the toughness of the
wall, which seemed to increase in strength near its inner boundary, the wasps were not

578 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Figure 16. Development of A. hanuuanamu on C. brasiliensis in phloem sandwiches a small A. hanu-

uanamu larva on a C. brasiliensis larva b A. hanuuanamu female remaining motionless near a developing
larva on its C. brasiliensis host for a long period of time as if guarding it ¢ A. hanuuanamu larva inside
a C. brasiliensis pupal chamber having consumed all the hemolymph of its host. This is the same pupal
chamber as pictured in Fig. 14c-f, the wasp having oviposited on the pupa subsequent to stinging and

host feeding on it multiple times d A. hanuuanamu pupa inside C. brasiliensis tunnels.

observed to break all the way through the shell to the pupa or prepupa inside. After pro-
eressing as far as it deemed practical, the wasp would stop digging, turn around, place its
back legs on the wall of the pupal shell with its gaster pointing towards the inside of the
chamber, extend its ovipositor, and use its body to push its ovipositor through the shell.
This was a lengthy process. After pushing and pushing, the ovipositor would finally break
through to the other side (Fig. 14c). The wasp would then flex the ovipositor, probing
the space in an attempt to contact the larva or pupa inside. Great flexibility and control
over its ovipositor was observed (Fig. 14e; Video 2 (https://vimeo.com/716967741)). If
able to contact and penetrate the pupa or prepupa inside, it would sting it for about 15
minutes, and then eventually remove its ovipositor, slowly and carefully as it did when
stinging a larva, simultaneously pulling the pupa or prepupa into contact with the wall
of the chamber. The wasp would then turn around and put its mouthparts on the exact
place where it had drilled through the pupal chamber. Physically separated from the
pupa by the wall of the pupal chamber, it would then begin feeding, again through a
tube it had made (Fig. 14d, f). This was observed multiple times. That it was actually
feeding successfully was clear: its abdomen would progressively distend and periodically
excrete clear liquid, and the pupa would noticeably progressively shrink in size. A feed-

The genus Acerocephala and life history under bark 579

Figure 17. Acerocephala ihulena development. Photos are from naturally infested wood taken after peel-

ing off bark a A. ihulena male (paratype) pupa in an E£. pacificus tunnel under the bark of H. tilia-
ceus wood, having developed on the desiccated E. pacificus larva next to it (indicated by yellow arrow)
b A. ihulena female (paratype) pupa found in the same branches, also having developed on the now
desiccated EF. pacificus larva (indicated by yellow arrow) c,d E. pacificus larvae from tunnels under the
bark of H. tiliaceus, with larval A. ihulena males developing as ectoparasitoids (parasitoid larvae indicated

by blue arrows).

ing straw was never observed directly due to its position within the material, but it was
clearly utilizing one as it was feeding from a distance through the wall. Occasionally a
small bump was observed on the pupa or prepupa where it was in contact with the wall
(Fig. 14d, f), presumably comprising the proximal part of the feeding tube. Wasps were
observed repeating this drilling and feeding behavior multiple times on the same pupa
before oviposition, the egg having also passed through its ovipositor and the narrow hole

it had drilled through the wall of the pupal chamber.

Oviposition and development

An egg was never directly observed coming out of the ovipositor but was often later
observed on a larva or pupa, often the same one on which a wasp had previously host
fed. ‘The surface of the eggs appears to be adhesive, and eggs were either stuck directly
to the larva or pupa, or were placed in the tunnel adjacent to it. A wasp larva emerg-
ing from the egg would attach to the beetle larva or pupa (Fig. 16a, b), and over the
next 2 or 3 days the wasp larva would suck the hemolymph out of the beetle larva or
pupa, transferring more or less all of it to its own body, leaving the shriveled cuticle of

its host (Fig. 16c). It would then detach and later pupate (Fig. 16d, Video 3 (https://

580 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

vimeo.com/717187250)). The adult wasp would thus emerge in the tunnel or pupal
chamber. Interestingly, though this was never observed in action, emergent adult wasps
seemed to be able to make their way out from the inside of the beetle pupal chambers.

Mating
(Video 4 (https://vimeo.com/717187205))

A female and male were observed on two occasions to encounter each other and mate.
Upon encounter, the wasps slowed their pace and touched antennae to antennae, main-
taining that position for a few seconds. The female seemed to relax and the male moved
onto the dorsal part of her abdomen, and then curled his abdomen around the female’s
abdomen to copulate. The act of copulation took in the vicinity of one minute. The
wasps then remained near each other, the male often contacting the body of the female
with the antennae, the female remaining calm and slow. This sequence of events, in-
cluding both copulation that appeared successful and attempts that did not seem me-
chanically successful, were repeated multiple times until the female moved away.

Both times mating was observed, it was outside the piece of wood in the open area
of the observation chamber. This should not necessarily be taken to imply that mating
takes place external to the wood in nature, though. ‘The place it occurred both times
was in frass/debris piles pushed out by the beetles during construction and mainte-
nance of their tunnels. Mating was likely observed there because the chance of males
and females encountering each other in the region outside the tunnels was high given
that it was a somewhat open space and there were often wasps present in that region.

Observation in naturally infested wood

In F microcarpa

(Fig. 11)

Cryphalus brasiliensis beetles seem to be some of the first colonizers of the environment
below the surface of E microcarpa wood at the location studied on Oahu (Fig. 11a).
They drill through the bark and form tunnels straddling the phloem and xylem lay-
ers of the wood, but can also be found entirely in the phloem layer on branches with
thicker bark. For healthy wood cut from the tree in the studied environment, initial
colonization of wood typically happens 3—5 weeks after it is separated from the tree.
As multiple generations of beetle adults and larvae feed and tunnel through the wood,
the tunnels become increasingly dense, often forming networks covering nearly the
whole phloem layer underneath the bark. The beetles then begin to leave the branch
at around this stage, and the bark often begins to separate from the rest of the branch,
the phloem layer having largely been removed by the beetles. In sections of branches
still connected to the tree that seemed to have been somewhat abruptly cut off from
the vascular system of the tree, C. brasiliensis beetles were present in large numbers
throughout the phloem layer for a period of time similar to those in the cut branches.

The genus Acerocephala and life history under bark 581

They were also found to infest older branches at the junction between the dead section
and where sap was still flowing. In these, it was difficult to tell whether the beetles were
overcoming the immune defenses of the tree in that area and contributing to death of
the wood progressively down the branch, or only progressing to the point where the
wood had already stopped sap flow for other reasons.

Where there were reproducing C. brasiliensis in these trees, it was common to find
both female and male A. anuuanamu traveling in their tunnels, especially where there
was a high density of C. brasiliensis larvae and pupae. In fact, in branches both discon-
nected from the tree and still attached to the tree, it was rare to find C. brasiliensis with-
out at least females of these wasps also present. This suggests that the female wasps are
efficient at locating wood newly infested by C. brasiliensis, and likely that they can do
so by flying. The ectoparasitic larvae and pupae of A. hanuuanamu, reared to confirm
their identity, were often found in the tunnels and pupal chambers built by C. bra-
siliensis beetles. Parasitoid larvae were found developing on both early and late instar
larvae, which was reflected in the great size variation found in both female and male
A, hanuuanamu. Parasitized larger larvae seemed to be substantially more common,
which implies a preference for larger larvae given that these wasps are idiobionts. The
parasitism rate seemed very high in some places; many pupal chambers or larval tun-
nels ending with parasitized beetle immatures or wasp prepupae or pupae (Fig. 11d, e).
Two other ectoparasitoids were observed also parasitizing the C. brasiliensis beetles.
These were an Ecphylus sp. (Braconidae) that oviposits into larvae and pupae through
the bark, whose pupae could be distinguished morphologically or by the pupal cocoon
they build when they pupate, and Cerocephala dinoderi Gahan, 1925, which was much
more rare than A. hanuuanamu or the Ecphylus sp., and whose ectoparasitic larvae were
observed feeding on C. brasiliensis larvae. The cerambycid Pterolophia bigibbera (New-
man, 1842) was also common in this wood, and was parasitized by Rhaconotus vagrans
(Bridwell, 1920) (Braconidae), Sclerodermus immigrans Bridwell, 1918 (Bethylidae),
and Allobethylus ewa (Bridwell, 1920) (Bethylidae).

Additional hosts of Acerocephala hanuuanamu

In addition to C. brasiliensis in E microcarpa, A. hanuuanamu was also found para-
sitizing Cryphalus mangiferae Stebbing, 1914 in mango branches (Mangifera indica
L.) in the area of Kahana Bay on O'ahu island (21.5604°N, 157.8765°W), and a
Cryphalus sp. in breadfruit (Artocarpus altilis (Parkinson) Fosberg) branches in Manoa
Valley on O'ahu island (21.2954°N, 157.8145°W). Identities were confirmed by rear-
ing of parasitoid larvae, and when bark beetle larvae could be clearly associated with
the adult beetles in the tunnels. Acerocephala hanuuanamu was also found emerging
from breadfruit fruits with Cryphalus negrosensis Browne, 1979, which presents another
putative host because the beetle was in high numbers and the only scolytid emerging
from the fruits, though this was not confirmed through observation and rearing of
parasitized beetles. Adults were also found with C. brasiliensis in Trema orientalis (L.)

Blume branches in Manoa Valley (21.2952°N, 157.8141°W).

582 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Discussion

Aspects of the behavior of Acerocephala hanuuanamu

Some aspects of the behavior of A. hanuuanamu, as viewed in the phloem sandwiches,
were remarkable. Adult C. brasiliensis were observed to actively attempt to block the
wasps from passing them in the tunnels. Acerocephala hanuuanamu were observed to
move through tunnels packed with debris by removing chunks in their direction of
travel with their large mandibles and using their legs to pass the material posterior to
their bodies. They fluidly and adeptly turned around in narrow tunnels, demonstrating
the morphological advantage of a long articulating prothorax also found convergently
in other unrelated lineages of cryptoparasitoids such as bethylids. Stinging and host
feeding behavior was observed, including, possibly most remarkably, the use of the
ovipositor to construct a feeding tube that allowed the wasps to host feed at a distance

on pupae through the hard shell of a pupal chamber.

Implications about taxonomic position of the new species given functional
aspects of morphology

Especially in taxa where there are few known species, morphological characters of phy-
logenetic significance are not always immediately clearly differentiated from characters
variable within the taxa, nor are meaningful groupings of species into clades. ‘The species
here are close to previously described Acerocephala species but also differ somewhat, and
thus their placement within existing genera, or if a new genus should be constructed,
is not immediately obvious. In the original description of Acerocephala, Gahan (1946)
described the genus consisting of A. aenigma and A. atroviolacea (in part by a 4-dentate
mandible, forewing with callus on the parastigma but lacking a tuft of setae on the cal-
lus, long mandibles, and a 6-segmented antennal funicle in females), and considered
Acerocephala close to the monotypic Paralaesthia, sharing a similarly elongate subrec-
tangular head, but distinguished it by the mandible teeth, callus of the forewing lacking
setae, and lack of a mesal groove extending the length of the frons. Hedqvist (1969)
described the monotypic Muesebeckisia as also close to Acerocephala, distinguishing it
by the mandible teeth and lack of callus on the forewing. Use of the keys provided by
Hedqvist (1969) and Blaser et al. (2015) would guide both of the species described here
to Choetospilisca (Fig. 9) given the number and shape of the antennal funicle segments,
and lack of a setose callus on the forewing. Boucek (1988) grouped A. pacifica from
Australia in with the two previously described Acerocephala from the Americas, iden-
tifying differences from these species in the antennae, shape and placement of features
on the head, callus on the forewing, and characters of the meso- and metasoma, but it
was not determined necessary to describe a new genus for it. The family Cerocephalidae
as a whole is thought to generally be cryptoparasitic on wood boring insects concealed
within the wood. The only known host association previously reported within these
putatively related genera is A. atroviolacea, which is thought to parasitize a scolytid in

The genus Acerocephala and life history under bark 583

pine cones. The two species described here are similarly parasitoids of scolytids, these in
the phloem layer under tree bark and potentially also in fruits. Here, observed aspects
of functional morphology and behavior, in combination with the spectrum of habitats
among tunnel systems of scolytids and other wood-borers, are used to propose hypoth-
eses about traits that may be conserved and traits that may vary among closely related
species. These hypotheses are then used to explain the present revision of the genus.

In observations of the behavior of A. hanuuanamu two functions of the antennae
were of particular note. 1. When the wasp presses its mouthparts against a substrate as
it searches for the spot through which to host feed, whether the opening of a feeding
tube passing through the wall of a pupal chamber, or on the cuticle of a larva, it uses
the antennae to gently probe the area around and between its mandibles and projec-
tion of the clypeus to sense where to place its mouthparts to feed (Videos 1 (https://
vimeo.com/7 17186840), 2 (https://vimeo.com/716967741)). 2. In excavating a path
through the debris-filled tunnel systems, the antennal club was placed at the apex of
the mandibles to inform the manipulation of the debris using the mandibles, and pos-
sibly also to sense promising directions of travel for host searching inferred from chem-
ical characteristics of the debris particles (Video 1 (https://vimeo.com/717186840)).
Additionally, when debris was picked up by the mandibles, the antennae rested on top
of the particle as if further sensing its characteristics. Antennae can, in general, be pre-
dicted to be most mobile, with the least amount of movement of the scape and pedicel
resulting in greatest movement of the terminal antennal segments, when the scape is
positioned approximately perpendicular to the plane of the face and the pedicel is bent
at 90 degrees. In A. hanuuanamu the antennal segments are of such length that, when
in this position, the club of the antenna reaches near the apex of the mandibles. ‘There-
fore, the length of the antennae coincides with their observed function in sensing the
vicinity of the mouthparts to inform host feeding and excavation of debris.

Other than as a mechanism to hold the mandibles and move debris being held by
the mandibles, the head was not observed to be directly used in digging in A. hanu-
uanamu; that is, it was not used to push material or as a wedge to open up space. The
thinness and gracility of the head was observed to be important for the action of turn-
ing around within the tight opening excavated by the wasp. If the head were thicker,
the tunnel would have to be larger to accommodate its size underneath the mesosoma,
and would make turning around in the tight space more difficult.

There is substantial diversity in debris particle size, density, and tunnel geometry
among bark beetles and other wood borers; for example, the converging feeding chambers
produced by Jps typographus (Linnaeus, 1758), clean linear tunnels typical of Xyleborini,
and debris-filled linear tunnels produced by cerambycid larvae. In the C. brasisilensis
tunnel systems observed in this study, the debris is of relatively small particle size. In gen-
erations subsequent to the initial colonizers, the tunnel system develops into a network
of tunnels that have grown together to form a two-dimensional expanse of debris that
the parasitoid must dig its way through to pursue hosts. Cryphalus brasiliensis pupae also
construct hard chambers that are difficult to penetrate. The previously discussed aspects
of morphology of A. hanuuanamu were observed to be useful for navigating the specifics

584 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

of this host-habitat system: the length of the antennae appeared useful in informing host
feeding, debris manipulation, and travel through the tunnels using the mandibles and
legs; and the thin head and long articulating prothorax was useful for turning around in
the tight spaces opened up during its travel through the debris.

In other species that exist in different host-habitats below the surface of wood, the
methods of passing through the tunnel systems to find their hosts may be different,
and this would likely be reflected in morphological differences. Acerocephala pacifica,
A, atroviolacea and A. aenigma have longer antennae and more stout heads. What fol-
lows is speculative, but longer antennae could be useful in more open tunnel systems
not as packed with debris as in C. brasiliensis tunnels, as longer antennae would be
able to sense a larger area around the wasp to inform its direction of movement in the
dark tunnels. The stouter head could be used as a wedge to open a path for movement
through tunnel debris less dense than that found in C. brasiliensis tunnels, and the pro-
truding interantennal ridge would protect the antennae while doing so. In the species
with longer antennae, A. atroviolacea, A. aenigma, and A. pacifica, when the scape is
folded back into the scrobes, the antenna reach just about the apex of the mandibles,
possibly allowing for sensing and manipulation of debris by the mandibles concurrent
with the utilization of the head as a wedge. In C. brasiliensis tunnels, longer antennae
or a larger head would be of little use, and likely a hinderance, because the density of
the debris would typically prevent a wide area for exploration by long antennae, and
the size of the debris is small enough that it is manipulable using the mandibles; use of
the head as a wedge would presumably only cause the particles to jam and would not
effectively open a path for movement. For A. hanuuanamu in C. brasiliensis tunnels,
searching for a host appears to be a tactile process of digging through small particles
in a direction informed by chemical cues in the particles. In linear tunnel systems, in
contrast, there is no option for direction of travel except forward or backwards through
the tunnel, and thus less directional decision making needs to happen. This, combined
with debris of larger grain size, or less debris, would make longer antennae and a stout-
er head possibly more useful for exploring more open space and moving through tun-
nels that contain debris some of which is too large to be picked up using the mandibles.

Therefore, parasitism of hosts that are related but differ in characteristics of their
tunnels such as tunnel geometry, frass/debris size, and other aspects of host biolo-
gy such as the creation of a hard pupal chamber in C. brasiliensis, may incur heavy
selection on characters such as length of antennae, head size, size and protrusion of
the interantennal ridge, and to some extent size of mandibles. These characters, while
they should not be disregarded, should be used with some caution in making phylo-
genetic implications above the level of species. Other characters not observed to be as
functionally relevant based on subtle habitat differences may be better clues to higher
taxonomic relationships. Here are some considerations:

1. The antennae of A. hanuuanamu, A. ihulena, and A. indica have the basal three
or four funicular segments much shorter than those of A. pacifica, A. atroviolacea, and
A, aenigma. Interestingly, the basal funicular segments of A. pacifica, and to some ex-

The genus Acerocephala and life history under bark 585

tent also A. aenigma and A. atroviolacea, may be viewed as a nodose version of those
in A. hanuuanamu, A. ihulena, and A. indica, the terminal portion of the segments of
similar shape; that is, if the neck of the first segments were much shortened and the
segments otherwise remained the same, antennae of the species with elongate anten-
nae would appear similar to those with the compressed funicle segments. It is plausible
that this variation could be in evolutionary response to their function in debris ma-
nipulation and host feeding described above, where the optimal length of the antennae
depends on characteristics of the host-habitat system such as grain size, grain density,
tunnel geometry, and the logistics of host feeding given the existence of pupal chambers
or lack thereof. A. hanuuanamu and A. ihulena are the species for which we know host-
habitat environments. ‘The characteristics of the C. brasiliensis system in FE microcarpa,
and E. pacificus in H. tiliaceus wood, are similar expanses of small grain-size debris in
tunnels having grown together. These could be predicted to be best manipulated and
traversed using the mandibles in combination with shortened antennae.

The number of flagellar segments has been used in keys to cerocephalid genera
(Hedqvist 1969; Blaser et al. 2015) and also appears to be different in the overall more
robust A. atroviolacea and A. aenigma (females 6-segmented) as compared to A. hanu-
uanamu, A. ihulena, A. indica, and A. pacifica (females 5-segmented). Slide mounted
antennae of A. hanuuanamu, A. ihulena, A. indica, and A. aenigma females were exam-
ined, and the clava of A. hanuuanamu, A. ihulena, and A. indica were found to have
three distinct whorls of MPS (Figs 3c, 5b, 6b), suggesting that they are formed from 3
fused segments, giving the total number of ancestral flagellar segments at 8. The clava
of female A. aenigma appeared to be composed of two fused segments based on the
distribution of MPS (Fig. 8i), thus also giving a total number of flagellar segments at
8. Therefore the number of ancestral segments appears to be conserved among all the
species, the difference being that one of these segments is in the clava of A. hanuua-
namu, A. ihulena, and A. indica while separate from the clava in A. aenigma. Males of
A, hanuuanamu, A. ihulena, and A. indica also have a 6-segmented funicle and a clava
that appears to be composed of 2 segments based on the whorls of MPS (Figs 3d, 6k),
and thus the same original number of funicle segments as in the female. A. aenigma
males had one more segment, with 6 funicular segments and a clava formed from two
clearly distinct segments, the apical one with two whorls of MPS (Fig. 8m). Overall,
the number of antennal segments therefore does not give a good indication that at
least A. aenigma is phylogenetically distant from the species with one fewer funicular
segment, and because of the overall similarity between A. aenigma and A. atroviolacea,
the same can be said for the group as a whole.

Therefore, length of the antennae given the morphology of the funicular segments
and that length is putatively under strong selection for the host-habitat environment,
and number of funicular segments, does not appear to clearly separate the species into
distinct higher taxa.

2. While the overall shape of the head in full face view is similar among the spe-
cies, there are differences in head thickness. These are largely a result of the elevation
of the interantennal ridge and overall robustness of the head, which may be subject

586 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

to selection as in the above discussion, based on host environment. A. atroviolacea
and A. aenigma, and to some extent, A. pacifica, are more robust wasps with a greatly
protruding interantennal ridge. These are also the species with longer antennae. ‘These
characters together would be consistent with the putative adaptation to manipulating
larger grain-size debris in less densely packed tunnel systems, possibly using the head
as a wedge. The elevation of the interantennal ridge occurs over a gradient among spe-
cies, some being more lifted (A. atroviolacea, A. aenigma, A. pacifica), A. hanuuanamu
flush with the face lateral of the scrobes, A. ihulena and A. indica intermediate. These
characters of the shape of the head are thus used with caution to distinguish clades
above the level of the species.

3. As discussed by Boucek (1988), the petiole is substantially longer in A. aenigma
and A. atroviolacea than it is in A. pacifica. The other species now known have petiole
similarly shorter. The shape of the petiole is, however, somewhat conserved. It is thus
likely of little phylogenetic significance above the species level.

4, Males of A. hanuuanamu, A. ihulena, and A. indica are wingless and have
smaller body size, while males of A. aenigma are fully winged and sized similar to the
females (males of A. pacifica and A. atroviolacea are unknown). In the agaonid subfam-
ily Sycophaginae, aptery in males is known to be variable among and sometimes within
genera likely dependent on life history strategies including brood size and likelihood
of being able to mate without leaving the plant material (Cruaud et al. 2011). Given
that such variability in life history is likely also within Acerocephala, possibly partially
dependent on density and tunneling strategies of hosts (e.g. A. hanuuanamu found
along with its hosts often in high density and in interconnected tunnel systems, and
with apterous males), male aptery and body size relative to the female does not provide
a clear reason to split the genus.

5. An exception to the above considerations that give little reason to divide this
genus is the presence or absence of a callus on the parastigma of the forewing. A
callus is present in A. atroviolacea and A. aenigma, but absent in A. hanuuanamu,
A, ihulena, A. pacifica, and A. indica. Characteristics of the callus or lack of a callus ap-
pear to be good generic characters within Cerocephalidae. While only A. atroviolacea
and A. aenigma have a defined callus, some very subtle variation among individuals
was observed in A. hanuuanamu as to a slight thickening of the parastigma in some
individuals. A. pacifica in other characters seems intermediate between the more robust
A, atroviolacea and A. aenigma and the other species, but lacks a callus. Therefore, pres-
ence or absence of a callus does not seem to clearly separate the species, especially when
other characters are considered as well.

Thus while there are differences among species in the genus, some of which may
suggest grouping into clades, all seem to best be placed in Acerocephala, the differ-
ences appearing not at the level for which we view a new genus to be necessary. A.
atroviolacea and A. aenigma are both larger wasps and overall appear closely related,
and are the only two with a callus. In general, characters of the species included in the
putatively related genera Choetospilisca, Paralaesthia, and Muesbeckisia are distinctly

The genus Acerocephala and life history under bark 587

different and fall well outside such a range of variation between the species placed here
in Acerocephala. Collection of more species, of which there are undoubtedly many in
the world-—cryptoparasitoids within wood are typically little known—will likely illumi-
nate these considerations better.

Acknowledgements

We are thankful for the presence of unmaintained and unmanicured areas on and near
the campus of UH Manoa where many of these wasps were collected and observations
were made. We thank Lisha Jasper, Keith Arakaki, and Jeremy Frank of Bishop Mu-
seum for providing access and assistance in collections and photographing specimens,
and Cecilia Escobar and Michael Gates of the National Museum of Natural History
for access to collections and loaning of specimens. We also thank our coworkers and
lab mates Conrad Gillett, Ali Miarkiani, Michelle Au, Abdullah Ali, Mitchell Logan,
Robert Sakuda, Maisha Lucas, Shannon Wilson, Vanessa Goodman, and Laura Doucet
for their assistance and for creating an enjoyable and productive working environment.
We acknowledge that this research took place on the mokupuni (island) of O‘ahu in
the ahupua‘a (land division) of Waikiki and Kapalama in the moku (district) of Kona,
and Kahana in the moku of Ko‘olauloa, the ancestral and traditional land of Native
Hawaiian people. We are very grateful to HDoA and Hatch project HAW09041-H,
administered by CTAHR, for their funding.

References

Alba-Alejandre I, Alba-Tercedor J, Vega FE (2018) Observing the devastating coffee berry borer
(Hypothenemus hampei) inside the coffee berry using micro-computed tomography. Scien-
tific Reports 8: 17033. https://doi.org/10.1038/s41598-018-35324-4

Aflitto NC, Hofstetter RW, McGuire R, Dunn DD, Potter KA (2014) Technique for studying
arthropod and microbial communities within tree tissues. Journal of Visualized Experi-
ments 93: e50793. https://doi.org/10.3791/50793

Beanlands GE (1966) A laboratory-rearing method for observing adult bark beetles and their
developing brood. The Canadian Entomologist 98: 412—414. https://doi.org/10.4039/
Ent98412-4

Blaser M, Krogmann L, Peters RS (2015) Two new fossil genera and species of Cerocphalinae
(Hymenoptera, Chalcidoidea, Pteromalidae), including the first record from the Eocene.
ZooKeys 545: 89-100. https://doi.org/10.3897/zookeys.545.6470

Burks R, Mitroiu MD, Fusu L, Heraty JM, Jansta P, Heydon S, Dale-Skey Papilloud N, Peters
RS, Tselikh EV, Woolley JB, van Noort S, Baur H, Cruaud A, Darling C, Haas M, Hanson
P, Krogmann L, Rasplus JY (2022) From hell’s heart I stab at thee! A determined approach
towards a monophyletic Pteromalidae and reclassification of Chalcidoidea. Journal of Hy-

menoptera Research 94: 13-88. https://doi.org/10.3897/jhr.94.94263

588 David N. Honsberger et al. / Journal of Hymenoptera Research 97: 545-589 (2024)

Cruaud A, Zahab-Jabbour R, Genson G, Kjellberg F, Kobmoo N, van Noort S, Da-Rong Y,
Yan-Qiong P, Ubaidillah R, Hanson PE, Santos-Mattos O, Farache FHA, Pereira RAS,
Kerdelhué C, Rasplus JY (2011) Phylogeny and evolution of life-history strategies in the
Sycophaginae non-pollinating fig wasps (Hymenoptera, Chalcidoidea). BMC Evolution-
ary Biology 11: 178. https://doi.org/10.1186/147 1-2148-11-178

Gahan AB (1946) Review of some chalcidoid genera related to Cerocephala Westwood. Pro-
ceedings of the United States National Museum 96: 349-378. https://doi.org/10.5479/
si.00963801.96-3203.349

Gibson GAP (1997) Morphology and Terminology. In: Gibson GAP, Huber JT, Woolley JB
(Eds) Annotated Keys to the Genera of Nearctic Chalcidoidea (Hymenoptera). NRC
Research Press, Ottawa, 16-44.

Gouger RJ, Yearian WC, Wilkinson RC (1975) Feeding and reproductive behavior of Jps
avulsus. The Florida Entomologist 58(4): 221-229. https://doi.org/10.2307/3493679
Grosman DM, Salom SM, Payne TL (1992) Laboratory study of conspecific avoidance by
host colonizing Dendroctonus frontalis Zimm. (Coleoptera: Scolytidae). Journal of Insect

Behavior 5: 263-271. https://doi.org/10.1007/BF0 1049293

Hedqvist KJ (1969) Notes on Cerocephalini with descriptions of new genera and species
(Hymenoptera: Chalcidoidea: Pteromalidae). Proceedings of the Entomological Society of
Washington 71: 449-467. https://biostor.org/reference/7 1494

Kinn DN, Miller MC (1981) A phloem sandwich unit for observing bark beetles, associated
predators, and parasites. Southern Forest Experiment Station Research Note SO-269: 1-3.
https://doi.org/10.2737/SO-RN-269

Kirkendall LR, Biedermann PHW, Jordal BH (2015) Evolution and diversity of bark and am-
brosia beetles. In: Vega FE, Hofstetter RW (Eds) Bark beetles: biology and ecology of native
and invasive species. 1‘ ed. Academic Press, London, 85-156. https://doi.org/10.1016/
B978-0-12-417156-5.00003-4

Klimmek E Baur H (2018) An interactive key to Central European species of the Pteromalus
albipennis species group and other species of the genus (Hymenoptera: Chalcidoidea:
Pteromalidae), with the description of a new species. Biodiversity Data Journal 6: e27722.
https://doi.org/10.3897/BDJ.6.e27722

Nagel WP, Fitzgerald TD (1975) Medetera aldrichii larval feeding behavior and prey consump-
tion (Dipt.: Dolichopodidae). Entomophaga 20(1): 121-127. https://doi.org/10.1007/
BF02373458

Rezende MQ, Pantoja G, Coffler T, Cardoso IM, Janssen A, Venzon M (2019) Jnga spp. medi-
ated coffee berry borer predation by an omnivorous thrips. International Entomophagous
Insects Conference 6, Perugia (Italy), 9-13 September 2019.

Salom SM, Stephen FM, Thompson LC (1986) Development of Hylobius pales (Herbst) im-
matures in two types of phloem media. Journal of Entomological Science 21(1): 43-51.
https://doi.org/10.18474/0749-8004-21.1.43

Sharma T, Dedes J, Macquarrie CJK (2016) A modified technique for rearing wood bor-
ing insects permits visualization of larval development. Journal of the Entomological
Society of Ontario 147: 7-14. https://journal.lib.uoguelph.ca/index.php/eso/article/
view/3863

The genus Acerocephala and life history under bark 589

Taylor AD, Hayes JL, Roton L, Moser JC (1992) A phloem sandwich allowing attack and colo-
nization by bark beetles (Coleoptera: Scolytidae) and associates. Journal of Entomological
Science 27(4): 311-316. https://doi.org/10.18474/0749-8004-27.4.311

Vega FE, Infante F, Johnson AJ (2015) The genus Hypothenemus, with emphasis on H. hampei,
the coffee berry borer. In: Vega FE, Hofstetter RW (Eds) Bark beetles: biology and ecol-
ogy of native and invasive species. 1 ed. Academic Press, London, 427-494. https://doi.
org/10.1016/B978-0-12-417156-5.00011-3

Vega FE, Simpkins A, Rodriguez-Soto MM, Infante F, Biedermann PHW (2017) Artificial
diet sandwich reveals subsocial behaviour in the coffee berry borer Hypothenemus hampei
(Coleoptera: Curculionidae: Scolytinae). Journal of Applied Entomology 141: 470-476.
https://doi.org/10.1111/jen.12362

Supplementary material |

Acerocephala hanuuanamu sp. nov. morphometric measurements

Authors: David N. Honsberger, Maya Honsberger, J. Hau‘oli Lorenzo-Elarco, Mark

G. Wright

Data type: csv

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) 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.97.127702.suppl1

Supplementary material 2

Acerocephala ihulena sp. nov. morphometric measurements

Authors: David N. Honsberger, Maya Honsberger, J. Hau‘oli Lorenzo-Elarco, Mark

G. Wright

Data type: csv

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.97.127702.suppl2