JHR 71: 157-161 (2019)

gre JOURN LAT, C)E A peenreviewed open-access journal
doi: 10.3897/jhr.7 1.3595 | SHORT COMMUNICATION ) Hymenopter a

http://jhr.pensoft.net Thelnternaonl Society of Hymenopexriss, RESEARCH

Chromosomes of Eupristina verticillata Waterston, 1921
and an overview of known karyotypes of chalcid wasps
of the family Agaonidae (Hymenoptera)

Vladimir E. Gokhman', Francesco Nugnes*, Umberto Bernardo?

| Botanical Garden, Moscow State University, Moscow, Russia 2 Institute for Sustainable Plant Protection,
Italian National Research Council, Portici (Napoli), Italy

Corresponding author: Viadimir E. Gokhman (vegokhman@hotmail.com)

Academic editor: Petr Jansta | Received 6 May 2019 | Accepted 24 July 2019 | Published 30 August 2019
http://zoobank. ore/14EAED77-EE37-480F-AF1 7-032AC283FF3B

Citation: Gokhman VE, Nugnes FE Bernardo U (2019) Chromosomes of Eupristina verticillata Waterston, 1921 and
an overview of known karyotypes of chalcid wasps of the family Agaonidae (Hymenoptera). Journal of Hymenoptera

Research 71: 157-161. https://doi.org/10.3897/jhr.71.35951

Abstract

The karyotype of Eupristina verticillata Waterston, 1921 (Agaonidae) from Italy was studied for the first
time using chromosome morphometrics. The present study showed that this species has n = 6 and 2n = 12,
with five larger metacentrics and a smaller acrocentric chromosome in the haploid set. A brief overview
of known karyotypes of chalcid wasps of the Agaonidae is given; certain features of karyotype evolution
of this family are discussed.

Keywords

Chalcidoidea, Agaonidae, chromosomes, karyotypes

Introduction

Chalcidoidea are one of the most speciose, taxonomically complicated and economi-
cally important groups of parasitoid Hymenoptera (Godfray 1994, Quicke 1997).
With its exceptionally high morphological and ecological diversity, this superfamily
includes about 23 thousand known species (Huber 2017), but karyotypes of less than

Copyright Vladimir E. Gokhman et al. This is an open access article distributed under the terms of the Creative Commons Attribution License
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158 Vladimir E. Gokhman et al. / Journal of Hymenoptera Research 71: 157-161 (2019)

200 members of this group are studied up to now (Gokhman 2013). For example, in
the family Agaonidae, a highly specialized tropical/subtropical group of Chalcidoidea
exclusively associated with fruits of the plant genus Ficus, chromosomes of only six spe-
cies were previously studied (Gokhman et al. 2010, Liu et al. 2011, Chen et al. 2018).
We have recently examined chromosomes of another member of this family, Eupristina
verticillata Waterston, 1921 collected in Italy about 30 years after its introduction
(Lo Verde et al. 1991, 2007). In addition, we briefly overview the current state of
knowledge of the karyotypic diversity of Agaonidae.

Material and methods

Origin of the material studied

Green syconia of Ficus microcarpa Linnaeus, 1782 (Moraceae) containing immature stag-
es of E. verticillata were collected by the senior author in July 2018 in the Villa Comunale
(city park) of Napoli, Italy (40°49'58.4"N 14°14'3"E). Immediately after collection, the

syconia were dissected in the lab, and wasp prepupae were extracted from the galls.

Preparation of chromosomes

Chromosomal preparations were obtained from cerebral ganglia of prepupae of E.
verticillata generally following the protocol developed by Imai et al. (1988) with cer-
tain modifications. Ganglia were extracted from insects dissected in 0.5% hypotonic
sodium citrate solution containing 0.005% colchicine. The extracted ganglia were then
transferred to a fresh portion of the hypotonic solution and incubated for 30 min at
room temperature. The material was transferred onto a pre-cleaned microscope slide
using a Pasteur pipette and then gently flushed with Fixative I (glacial acetic acid:
absolute ethanol: distilled water 3:3:4). The tissues were disrupted using dissecting
needles in an additional drop of Fixative I. Another drop of Fixative II (glacial acetic
acid: absolute ethanol 1:1) was applied to the center of the area, and the more aqueous
phase was blotted off the edges of the slide. The slides were then dried for approxi-
mately half an hour and stored at room temperature. Chromosome preparations were
stained with freshly prepared 3% Giemsa solution in 0.05M Sorensen’s phosphate
buffer (Na, HPO, + KH,PO,, pH 6.8) for a few hours.

Image acquisition and analysis

Metaphase plates were analyzed under a Zeiss Axioskop 40 FL epifluorescence mi-
croscope (Carl Zeiss, Géttingen, Germany). Images of chromosomes were taken
with Zeiss AxioCam MRc digital camera using Zeiss AxioVision software version

Chromosomes of Eupristina verticillata 159

3.1. To prepare illustrations, the resulting images were arranged and enhanced with
Adobe Photoshop 8.0. KaryoType version 2.0 software was also used for taking
measurements from four diploid metaphase plates of FE. verticillata having well-
defined chromosome morphology. For each chromosome of the haploid set, we
report both its relative length (100 x length of the chromosome divided by total
length of the set) and centromeric index (100 x length of the shorter arm divided by
total length of the chromosome). ‘The chromosomes were classified into metacen-
trics (M), subtelocentrics (ST) and acrocentrics (A) following guidelines provided
by Levan et al. (1964).

Results and discussion

The diploid karyotype of E. verticillata contains the largest pair of metacentric chro-
mosomes, two pairs of shorter metacentrics, two other pairs of considerably smaller
metacentric chromosomes, and the shortest pair of acrocentrics (Fig. 1; Table 1). On
the other hand, its haploid karyotype contains six chromosomes which sizes and shapes
are similar to those of the diploid chromosome set (not shown here); the chromosome
number in this species is therefore n = 6 and 2n = 12.

The karyotype of E. verticillata is structurally similar to that of the only known
member of the family Agaonidae with the same chromosome number (Table 2), Blas-
tophaga psenes (Gokhman et al. 2010), although chromosome sets of these two species
differ in some details. Specifically, diploid karyotypes of both E. verticillata and B.
psenes contain five pairs of metacentrics, but the smallest pairs within their chromo-
some sets are acrocentric and subtelocentric respectively. In addition, the lengths of
most metacentric chromosomes differ substantially in the former species compared to
B. psenes (see Gokhman et al. 2010). Moreover, the smallest pair of chromosomes is
much shorter than the preceding one in the latter species, in contrast to E. verticillata.
These two chalcid wasps belong to different subfamilies of Agaonidae, Blastophaginae
and Agaoninae respectively (Cruaud et al. 2010), and the similar karyotype structure
of these species may be considered a plesiomorphic feature of the family in general
(Gokhman et al. 2010). Furthermore, chromosome sets of all other studied members
of Agaonidae, i.e. two species of the same genus Eupristina Saunders, 1882, E. altissima
and Eupristina sp. with n = 5, as well as three members of the genus Ceratosolen Mayr,
1885 from the subfamily Kradibiinae, C. solmsi, C. gravelyi, and C. emarginatus with
the same chromosome number (Table 2), contain only large metacentrics of similar
size (Liu et al. 2011, Chen et al. 2018). Analogously to the situation observed in a
few other chalcid families, e.g. Eulophidae, Torymidae and Ormyridae, results of the
present study apparently confirm that the karyotypes with n = 5 resulted from the
fusion between the smallest acrocentric/subtelocentric chromosome and a particular
metacentric in an ancestral chromosome set with n = 6 (Gokhman 2013). If this is
true, lower chromosome numbers of corresponding species could represent their puta-
tive synapomorphies within certain genera.

160 Vladimir E. Gokhman et al. / Journal of Hymenoptera Research 71: 157-161 (2019)

ERK ty x

Figure |. Diploid karyotype of E. verticillata. Scale bar: 10 um.

Table |. Relative lengths (RL) and centromeric indices (CI) of chromosomes of E. verticillata (mean + SD).

Chr. no. RL CI
1 23:50'2-135 42.38 + 3.97
2 21,00:°0;77 44.53 + 3.15
3 20.64 + 0.76 43.11 + 5.28
4 15.63 + 0.31 46.72 + 2.71
5 11.51 + 0.78 46.21 + 2.82
6 7.92 = 0.46 0

Table 2. Characteristics of diploid karyotypes of studied species of Agaonidae.

Species 2n Chromosome formula Reference
Blastophaga psenes (Linnaeus, 1758) 12 10M + 2ST Gokhman et al. 2010
Ceratosolen emarginatus Mayr, 1916 10 10M Liu et al. 2011
C. gravelyi Grandi, 1916 10 10M Liu et al. 2011
C. solmsi (Mayr, 1885) 10 10M Liu et al. 2011
Eupristina altissima Balakrishnan & Abdurahiman, 1981 10 10M Chen et al. 2018
E. verticillata Waterston, 1921 12 10M + 2A Present study
Eupristina sp. 10 10M Chen et al. 2018
Acknowledgements

The present study was partly supported by a research grant no. 18-04-00611 from the
Russian Foundation for Basic Research to VEG.

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