Dtsch. Entomol. Z. 71 (1) 2024, 177-183 | DOI 10.3897/dez.71.117640

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BERLIN

The obligate fig-pollinator family Agaonidae in Germany
(Hymenoptera, Chalcidoidea)

Silvan Rehberger!, Jonathan Vogel*, Bjérn Miiller*, Cristina Vasilita?, Lars Krogmann’®,
Stefan Schmidt**, Ralph S. Peters?

1 Feigenparadies, c/o youngbrain GmbH, Sedanstr. 7, 79098 Freiburg im Breisgau, Germany

2 Leibniz Institute for the Analysis of Biodiversity Change (LIB), Museum Koenig Bonn, Arthropoda Department, Adenauerallee 127, 53113
Bonn, Germany

3 Stuttgart State Museum of Natural History, Department of Entomology, Rosenstein 1, 70191 Stuttgart, Germany

4 SNSB-Zoologische Staatssammlung Miinchen, Minchhausenstr. 21, 81247 Munich, Germany

https://zoobank. org/SEOC69D9-5 1 DA-4F 91-8 FB9-56CC6E26EDDI

Corresponding author: Ralph S. Peters (r.peters@leibniz-lib.de)
Academic editor: Silas Bossert # Received 20 December 2023 @ Accepted 22 April 2024 # Published 27 May 2024

Abstract

All native and many cultivated fig plants are pollinated by representatives of the family Agaonidae (fig wasps), which are specialised,
secondarily phytophagous relatives of parasitoid wasps that evolved an obligate mutualism with fig trees. So far, distribution of Aga-
onidae in Europe has been limited to southern, mostly Mediterranean areas, for example, in Greece, Croatia, Hungary, Italy, France,
Spain and Portugal. Here, we report the first four records of the family for Germany, all in the form of the widespread species Blas-
tophaga psenes (Linnaeus, 1758). New verified records are from three States in western and south-western Germany, Baden-Wuert-
temberg (Radolfzell at Lake Constance and Sasbach am Kaiserstuhl near Freiburg), Saarland (Saarbrticken) and Northrhine-Westalia
(Bochum) and all are based on citizen-scientist observations and collections. The new records are considerably more northern than
previously recorded localities and, strikingly, geographically distant from these. All records can be attributed to the presence of large
male caprifig trees (Ficus carica L. var. caprificus), whose three generations of fruits host the development stages of Blastophaga
psenes. We generated DNA barcode data of specimens from three localities and added them to the national GBOL (German Barcode
of Life) database and the international Barcode of Life database (BOLD). The somewhat surprising occurrence of the species/family
in Germany might be attributable to increasing temperatures as a result of global warming, but this needs further investigation. Addi-
tionally, the presence of fig wasps, assuming it stabilises, could offer new opportunities for fig farming in Germany.

Key Words

Fig wasps, Ficus carica, Blastophaga psenes, pollination, first records

Introduction fig wasps, which represent probably about 20-30% of the
existing species (van Noort and Rasplus 2023). Numer-

All species of the genus Ficus (figs) (Moraceae) depend ous additional chalcid wasp species complement the fig

on obligate pollinators of the wasp family Agaonidae (Hy-
menoptera, Chalcidoidea). There are about 880 accepted
species of figs and many more undescribed (POWO 2023),
associated with, so far, 640 described species of agaonid

+ Deceased.

system as facultative pollinators, inquilines or parasitoids
of other fig-associated wasps. Fig fruits are not only vital
food sources in natural environments for many vertebrates
and invertebrates, but also commercially important. The

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

178

commercially most important species is Ficus carica L.,
which produces the well-known eatable fig fruits. More
than 1,200 cultivars of Ficus carica are pomologically
described (e.g. Condit (1955)). The yearly average world-
wide fig production in 2015—2019 was 1,185,768 metric
tonnes on 285,513 ha of cultivated area (Ferrara et al.
2022). The close association with fig plants and its strik-
ing diversity make Agaonidae a group of special ecologi-
cal and economic relevance. In Europe, only few species
are present. Blastophaga psenes (Linnaeus, 1758) is the
most widespread, with populations limited to southern,
mostly Mediterranean areas, for example, in Greece, Cro-
atia, Hungary, Italy, France, Spain and Portugal. It has not
been reported in Germany; the nearest validated records in
France are hundreds of kilometres away from the German
border (Baud 2008, 2023). Here, we report records of the
fig wasp Blastophaga psenes from Ficus carica trees in
four different localities across western and south-western
Germany, these being the first records for the Agaonidae
family in Germany. All recorded specimens were ob-
served and collected by citizen scientists from the fig en-
thusiasts’ community. Wasps were photographed, identi-
fied, DNA-barcoded and vouchered. Blastophaga psenes
and Ficus carica are connected by a complex pollination
and reproduction cycle. In order to discuss and understand
the background of the records of B. psenes reported herein
and to link the entomology and the fig community in this
interdisciplinary paper, we provide an overview of this
complex connection with a little more detail.

Ficus carica shows a special type of inflorescence called
the syconium, which is built as a fleshy fruit from the stem
(Stover et al. 2007). It is urn-shaped and contains multiple
flowers, which can only be accessed through a small hole,
called the ostiolum. Ficus carica is a gynodioecious, but
functionally dioecious plant species (Kjellberg and Vald-
eyron 1990; Aradhya et al. 2010). The caprifig plants, also
known as Ficus carica L. var. caprificus, have bisexual
flowers with both fertile male flowers, which spend pol-
len, and sterile short-styled female flowers, also called gall
flowers. They functionally represent the male plant. The
function of the gall flowers is to host the eggs laid by Blas-
tophaga psenes and then develop the pulpy gall and feed
the fig wasp larvae. The fig plants sensu stricto, also known
as Ficus carica L. var. domestica (Fruit Fig, Edible Fig)
which bear the eatable fig fruits, are unisexual and have
only fertile long-styled female flowers. They functionally
represent the female plant. Ficus carica bears — depend-
ing on the cultivar — up to three generations of fruits ev-
ery year. The first generation are the Profichi (male) and
Breba (female), which start to grow in spring from the
previous year’s wood and buds. The second generation
are the Mammoni (male) and Fichi (female), also called
Main Crop, which start to develop in summer from the
newly-grown wood and buds of the same year. Later in the
year, male figs grow the Mamme as third generation fruits;
these enable the overwintering of Blastophaga psenes.

Female fig cultivars are differentiated by their fruit gen-
erations into two types: Uniferous cultivars grow mainly
Fichi and no or almost no Breba fruits. Biferous cultivars

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Silvan Rehberger et al.: Agaonidae in Germany (Hymenoptera, Chalcidoidea)

grow both Breba and Fichi. Female fig cultivars are also
differentiated by their ability to grow parthenocarpic fruits
(i.e. fruits without pollination). The Smyrna type only
grows fruits with pollination. The Common type, some-
times also referred to as the Adriatic type, grows and ripens
all fruit generations without pollination, though pollination
can occur. The San Pedro type grows ripe Breba without
pollination, but ripe Fichi only after pollination. Since
Blastophaga psenes has, so far, not been present in wide
areas of central and western Europe, including Germany,
figs are almost exclusively grown as a hobby and not as a
commercial fruit. Due to a large number of parthenocarpic
Common and San Pedro cultivars, it is possible to grow
figs without the pollinator. However, in the main produc-
tion areas, the so-called caprification has been actively
aided for centuries by planting caprifig trees or by hang-
ing male caprifig branches in the fig plantations (Prgomet
and Prgomet 2020; Kjellberg et al. 2022). Pollination from
caprification results in less fruit dropping, in larger fruits,
earlier ripening and also in a better taste. The sole polli-
nator of Ficus carica 1s Blastophaga psenes. After winter,
the first generation of B. psenes develops in the gall flow-
ers of the Mamme from the year before. The highly-mod-
ified wingless male wasps emerge first and inseminate
the winged female wasps within the fig. The male wasps
help the females to escape from the syconium by chewing
narrow tunnels. The female wasps carry some of the om-
nipresent male pollen of the Mamme flower. The female
wasps then reach the next fig trees by active or wind-driv-
en flight and enter the figs through the ostiole (Kjellberg
et al. 1987). In the case of a male syconium (Profichi or
Mammon, in the first or second generation, respectively),
the wasp will successfully oviposit into the flowers and the
next generation of fig wasps can develop in the gall flow-
ers. In case of a female syconium (Breba or Fichi, in first
or second generation, respectively), which includes only
long-styled fertile female flowers, the wasps pollinate, but
do not oviposit and then die and are digested, presumably
by the specific enzyme Ficain. In the Mamme as the third
generation of male syconium, B. psenes will overwinter.

Both species, Ficus carica and Blastophaga psenes,
rely on a fine-tuned interaction with three fruit and wasp
generations, with male and female figs and on perfect
timing. The fig trees in central Europe, for example Ger-
many, that are sometimes just ornamental plants, are
usually parthenocarpic female trees. Previously, male fig
trees were found only occasionally in Germany, but in
recent years, their number has been growing (Rehberger
2023). Their presence is a prerequisite for the occurrence
and establishment of fig wasps in Germany.

Methods

Institutional abbreviations

SMNS - Staatliches Museum ftir Naturkunde Stuttgart,
Germany
ZFMK — Museum Koenig Bonn, Germany

Dtsch. Entomol. Z. 71 (1) 2024, 177-183

ZSM — SNSB-Zoologische Staatssammlung Munchen,
Germany

Fig wasps were collected out of male fig tree fruits at
different locations in Germany. They were either immersed
in ethanol or died dry and were shipped to ZFMK for DNA
barcoding or to ZSM for morphological identification.

DNA barcoding

At ZFMK, we processed 21 specimens from three loca-
tions in Baden-Wtrttemberg (Radolfzell and Kaiserstuhl)
and North Rhine-Westphalia (Bochum). We extracted
DNA and amplified the CO1 barcode region at the molec-
ular lab of the ZFMK following the protocols described in
Jafari et al. (2023). Amplification and subsequent sequenc-
ing using forward primer LCO 2198-JJ and reverse prim-
er HCO 2198-JJ (Astrin and Sttiben 2008) did not yield
any sequences. Alternatively, as forward primer, we used
the newly-designed Heloridae-CV-F (primer sequence
5-TATTTGGAATATGAGCAGG-3) (published herein)
and, as reverse primer, the HCO 2198-JJ primer. The am-
plified fragment is 619 bp long. Of the total of 21 speci-
mens, 20 were successfully sequenced. In 18 of these, the
barcodes fulfil all necessary criteria (e.g. chromatogram
quality, < 1% ambiguities or disagreements between the
contig sequences) to meet the defined GBOL gold stan-
dard (see, for example, Jafari et al. (2023)). According-
ly, the sequencing success is 85.7% or 95.2% including
the non-gold standard specimens. Sanger sequencing was
done by BGI BIO Solutions Co, Ltd. (Hong Kong).

We complemented our sequences with one Blastopha-
ga psenes sequence downloaded from BOLD (BOLD
sequence ID: GBMIN30266-13) and outgroup sequences
downloaded from BOLD (Pleistodontes sp., BOLD se-
quence ID: ASMII11091-22; Blastophaga silvestriana,
ID: GBAH19865-19; B. nipponica, ID: GBAH20335-19;

179

B. yeni, 1D: GBAH20406-19). All sequences were aligned
with the MUSCLE (v. 3.9.425) algorithm allowing for a
maximum of eight iterations (Edgar 2004). For the sole
purpose of alpha taxonomical evaluation of conspeci-
ficity, we calculated a Neighbour-Joining tree using the
Tamura-Nei distance model (Tamura and Nei 1993). We
added bootstrap support values, based on 325,235 seed
value (Geneious default) and 1,000 replicates. The final
tree is rooted with Pleistodontes sp. We performed all
steps from alignment to tree reconstruction in Geneious
Prime 2022.1.1 (Biomatters Ltd.). We uploaded all suc-
cessfully produced barcode sequences to BOLD (Ratnas-
ingham and Hebert 2007) to the dataset DS-DEBLPSEN;
the respective BOLD-IDs are listed in Table 1.

Results

Confirmed records of Blastophaga psenes (those comple-
mented by DNA barcodes marked *) in order of discov-
ery date are:

1. Radolfzell*, found by Raphael Gebhard for the first
time on 12.05.22 and also in 2023.

2. Saarbriicken, found by Anja Ruppert for the first
time on 25.05.2022 and also multiple times in 2023.

3. Sasbach im Kaiserstuhl*, found by Stephan Rawer
and Silvan Rehberger for the first time on 16.08.2022
and also in 2023.

4. Bochum*, found by Nikolaj Spiegel for the first
time on 17.08.2022 and also multiple times in 2023.

Note that we do not give more detailed locality data
to prevent vandalism of the respective fig trees. Detailed
locality data are available from the authors upon reason-
able request.

Localities are on display in Fig. 1. Vouchers are de-
posited at ZFMK, SMNS and ZSM (Table 1). In addition,

Table 1. BOLD-IDs of barcoded specimens, along with specimen IDs and depository information.

Specimen ID Locality
ZFMK-TIS-2637655 Bochum
ZFMK-TIS-2637656 Bochum
ZFMK-TIS-2637657 Bochum
ZFMK-TIS-2637658 Bochum
ZFMK-TIS-2637659 Bochum
ZFMK-TIS-2637660 Bochum
ZFMK-TIS-2637661 Bochum
ZFMK-TIS-2637662 Bochum

ZFMK-TIS-2637670
ZFMK-TIS-263767 1
ZFMK-TIS-2637673
ZFMK-TIS-2637674
ZFMK-TIS-2637675
ZFMK-TIS-2637677
ZFMK-TIS-2637679
ZFMK-TIS-2637680
ZFMK-TIS-263768 1
ZFMK-TIS-2637682

Sasbach/Kaiserstuhl
Sasbach/Kaiserstuhl
Sasbach/Kaiserstuhl
Sasbach/Kaiserstuhl
Radolfzell
Radolfzell
Radolfzell
Radolfzell
Radolfzell
Radolfzell

40 40 40 40 Os Oy Oy Oy 40 40 Oy Oy Oy Os 40 40 40 40 J

BOLD-ID bp-Length (ambiguities) Depository
GBHYG1886-23 619(0) SMNS
GBHYG1887-23 619(0) ZSM
GBHYG1888-23 619(0) ZFMK
GBHYG1889-23 619(0) ZFMK
GBHYG1890-23 619(0) ZFMK
GBHYG1891-23 619(0) ZFMK
GBHYG1892-23 619(0) ZFMK
GBHYG1893-23 619(0) ZFMK
GBHYG1894-23 619(0) SMNS
GBHYG1895-23 619(0) ZSM
GBHYG1896-23 619(0) ZFMK
GBHYG1897-23 619(0) ZFMK
GBHYG1898-23 619(0) SMNS
GBHYG1899-23 619(0) ZSM
GBHYG1900-23 619(0) ZFMK
GBHYG1901-23 619(0) ZFMK
GBHYG1902-23 619(0) ZFMK
GBHYG1903-23 619(0) ZFMK

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180

é. .
‘, Essen

; 28 Bochum
__ {, Wattenscheid
ne
-4\ Wiirzburg
. ~\Saarbriicken
SN __/& Karlsruhe
J, Kippenheim
Sasbach {Riegel
a. Freiburg
f Radolfzell
y - B..
/~—? Rheinfelden ro

A

Silvan Rehberger et al.: Agaonidae in Germany (Hymenoptera, Chalcidoidea)

@ Confirmed (morphology, DNA)
© Confirmed (morphology)
A Live observation of adult wasps

» ZN Ripe fruits of varieties
that have been pollinated

Figure 1. Map of records of Blastophaga psenes in Germany. Base Map Licence: CC BY-SA 3.0, Wikimedia Commons, Author:

NordNordWest.

members of the Ficus carica Facebook group have record-
ed observations from 2023 of large numbers of fig wasps
entering the ostiolum or emerging from caprifig fruits in
Wurzburg, Karlsruhe and Kippenheim near Offenburg.
These observations lack detailed species identification
and records are not vouchered. However, because of the
uniqueness of the wasp and system reported here, we con-
sider these records reliable and valuable and, ergo, also
added them to Fig. 1, represented by blue filled triangles.
Finally, pollinated Main Crop fruits from cultivars with
obligatory pollination, indicating successful pollination,
were observed in Riegel am Kaiserstuhl and Freiburg im
Breisgau in 2022 and 2023, as well as in Wattenscheid,
Essen and in Rheinfelden in 2023. These records do not in-
clude observed, identified or vouchered wasps, but are also
shown in Fig. 1, represented by blue outlined triangles.
Analyses of DNA barcodes show conspecificity of
the specimens with sequences generated herein, as well
as with the B. psenes sequence added from BOLD, with

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a maximum intraspecific difference of 1.1%. There is a
notable distance between the specimens from the Kai-
serstuhl and the remaining specimens from Bochum and
Radolfzell (Fig. 2). The barcode sequences between these
two groups differ by 0.6—1.1%. Within the clusters, there
is a maximum difference of 0.5%. Morphologically, all
specimens from Germany we consider conspecific.

Discussion

The records of the agaonid Blastophaga psenes (Fig. 3) in
Germany in 2022 came as a surprise, even more so since
records are from four different, disjunct localities, rang-
ing as far north as the City of Bochum in central-western
Germany. These unexpected records immediately prompt
the question as to why they are now present. Figs do not
belong to the autochthonous flora of central Europe, but
are considered as archaeophytes for Germany and have

Dtsch. Entomol. Z. 71 (1) 2024, 177-183

181

gover ASMII11091-22| Pleistodontes sp.

i 100

100

GBAH19865-19| Blastophaga silvestriana

GBAH20335-19| Blastophaga nipponica

GBAH20406-19| Blastophaga yeni

GBMIN30266-13

ZFMK-TIS-2637674 Sasbach/Kaiserstuhl
ZFMK-TIS-2637673 Sasbach/Kaiserstuhl
ZFMK-TIS-2637670 Sasbach/Kaiserstuhl

ZFMK-TIS-2637671 Sasbach/Kaiserstuhl

0.01

— ZFMK-TIS-2637682 Radolfzell

-—— ZFMK-TIS-2637660 Bochum

| ZFMK-TIS-2637662 Bochum

f+ ZFMK-TIS-2637677 Radolfzell

ZFMK-TIS-2637655 Bochum Blastophaga

psenes
ZFMK-TIS-2637656 Bochum

ZFMK-TIS-2637657 Bochum

ZFMK-TIS-2637658 Bochum

ZFMK-TIS-2637659 Bochum

ZFMK-TIS-2637661 Bochum

ZFMK-TIS-2637675 Radolfzell

| ZFMK-TIS-2637679 Radolfzell

ZFMK-TIS-2637680 Radolfzell

ZFMK-TIS-2637681 Radolfzell

Figure 2. NJ tree, based on DNA barcode data for B. psenes specimens from three localities in Germany, complemented with one
B. psenes sequence, three congeneric sequences and one Pleistodontes sp. (Agaonidae) sequence accessed via BOLD. The dotted
branches that connect Pleistodontes sp. are not to scale. The support values (bootstrap with 1,000 replicates) are indicated on the

respective branches.

been cultivated in Germany for more than 1,200 years
(Gareis 1895; Knorzer 1981). Therefore, a long time has
passed with figs present, but without any records of B.
psenes, 1.e. presumably without the species being present,
in Germany. The nearest known reproducing populations
of B. psenes are located in Provence (France), in Tuscany
(Italy), in Croatia and in Hungary. In France, B. psenes
is present only south of the line between Bordeaux and
Lyon and only in non-mountainous areas (Baud 2008,
2023). Farmers in northern Italy have observed fig wasps
occasionally in the lower warm parts of the valleys in
the southern Alps in recent years, but not with stable
reproducing populations (pers. comm. 2023). By linear
distance, these could be the nearest populations, but the
Alps are certainly a barrier for natural range extension
of B. psenes. The other nearest populations are separat-
ed from the newly-recorded sites in Germany by 400 km
(France) and 600 km (Hungary and Croatia). The intra-
specific differences in DNA barcode sequence (1.e. a max-
imum of 1.1% between two groups; see results) might
indicate that specimens from Kaiserstuhl and from Ra-
dolfzell/Bochum have different originating populations.
It is possible that small populations were already present

in Germany in previous years, but were overlooked. As
outlined in the Introduction, successful reproduction of
B. psenes depends on a complex chronological interplay
with male and female fig trees and their fig fruit genera-
tions. All prerequisites must now be fulfilled at various
locations in Germany, otherwise the records would not
have been possible. Given the complexity of the system,
it is unlikely that the records reported herein are the result
of an immediate change, suddenly bridging hundreds of
kilometres. Unpublished records of fig wasps from the
fig hobbyists’ community in Alsace (France), Gent (Bel-
gium), The Hague (Netherlands), Graz and Klagenfurt
(both Austria) from 2023 indicate a step-by-step change
and spread from both western and eastern populations,
presumably along the rivers Danube, Rhine and Rhone.
It is a task for the future to compare the German popula-
tions with those from other regions of Europe in order to
reconstruct the origins of range extensions.

Higher mean temperatures as a result of climate change
are the first obvious explanation for the new records in
Germany, as 1s well known for many other insect taxa — for
example, the fig-associated lepidopteran Choreutis nemo-
rana (Hubner, 1799) (de Prins et al. 2014). However, con-

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Silvan Rehberger et al.: Agaonidae in Germany (Hymenoptera, Chalcidoidea)

Figure 3. Blastophaga psenes female (collected in Saarbriicken in 2022), displaying the unique habitus of agaonid wasps.

sidering the highly-specialised obligate mutualism with
Ficus carica, increased temperature alone cannot explain
the occurrence of B. psenes in Germany. A necessary, but
not sufficient condition for B. psenes to reproduce is the
presence of male caprifig trees with fruits at all stages of
its range extension routes. In recent years, the occurrence
of male caprifig trees has significantly increased in cen-
tral Europe (Rehberger 2023). The plants grow wild along
the banks of rivers and lakes, in harbours and adjacent to
sewage channels, possibly from seeds distributed by birds
or from remains of figs consumed by humans or they are
— often unintentionally — cultivated in public parks and
also private gardens by people taking wild trees or cut-
tings with them from their holidays, not knowing that they
might not bear eatable fruit. Maybe these occurrences of
male caprifig trees allowed both migration and establish-
ment of new populations of B. psenes.

At the moment, we do not know whether or not these
populations become established. However, since the
2022 generation of the wasps already was the result of a
successful reproduction and since more occurrences were
recorded in 2023, it is well possible that these populations
will establish and even spread further. Statements have
to be made with caution, because B. psenes has not been
known to expand its range, but is known to be difficult
to establish in new areas. One of the best known exam-
ples is the deliberate introduction of B. psenes in southern
California for the purpose of cultivating Turkish Smyrna
fig cultivars. After many failed attempts with other spe-

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cies of Blastophaga and also some failures with B. psenes
they finally succeeded in 1889 (Eisen 1891; Ramirez
1970). After that, no range extension was observed and
attempts for introduction in Texas, southern Arizona and
Florida failed. In China, B. psenes has recently been con-
sidered for a local introduction and local domestication,
as well as de-novo-domestication of wild pollinators via
host-switches (Wang 2023). These activities show the im-
portance of the pollinator for commercial fig production.
Both yield and tasting quality of cultivated figs for some
cultivars improve with the presence of the specialised
pollinator. Cultivars of the Smyrna type fully depend on
pollination by fig wasps. Hence, these new records will
also be of economic interest because establishment of B.
psenes in Germany and other regions of western and cen-
tral Europe might enable future commercial fig farming.

Conclusion

The multiple records of this extraordinary wasp taxon
Agaonidae in Germany are the starting point for more in-
depth studies on the details of the extension of the spe-
cies’ range as well as on their potential to fundamentally
change fig plant cultivation in central Europe. In our team
of citizen and professional scientists, we will curiously
monitor the development over the next years and contin-
ue to study the story of this intriguing plant-insect-inter-
action in Europe.

Dtsch. Entomol. Z. 71 (1) 2024, 177-183

Acknowledgements

This paper is dedicated to the memory of our co-author,
colleague and friend Stefan Schmidt.

We would like to thank Anja Ruppert, Raphael Geb-
hard, Stephan Rawer and Nikolaj Spiegel and many other
people from the Ficus carica Facebook-Group for their
support in searching for Blastophaga psenes populations
at male fig trees in their home regions. Song Miaoyu
and Huiqin Ma (Agricultural University Beying, China)
provided insights into research concerning Ficus carica
and Blastophaga psenes in China. Don Shaw 1s acknowl-
edged for linguistic help. We thank Vera Rduch (Museum
Koenig Bonn) for her constant help with coordination
of the GBOL III: Dark Taxa project. J. Vogel, B. Muller
and R.S. Peters are supported by a grant from the Feder-
al Ministry of Education and Research (BMBF), Berlin,
Germany (FKZ 16LI1901A), for the project “‘“GBOL II:
Dark Taxa’.

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