Morphological patterns of the heteropycnotic chromatin and nucleolar
material in meiosis and spermiogenesis of some Pentatomidae (Heteroptera)

Hederson Vinicius de Souza1, Márcia Maria Urbanin Castanhole1,
Hermione Elly Melara de Campos Bicudo1, Luiz Antônio Alves Costa2 and Mary Massumi Itoyama1

1Laboratório de Citogenética de Insetos, Departamento de Biologia, Instituto de Biociências,

Letras e Ciências Exatas, Universidade Estadual Paulista, São José do Rio Preto, SP, Brazil.
2Departamento de Entomologia, Museu Nacional, Universidade Federal do Rio de Janeiro,

Rio de Janeiro, RJ, Brazil.

Abstract

Pentatomidae is a family of Heteroptera which includes several agriculture pests that have had different aspects of
their meiosis and spermiogenesis analyzed. In the present study we analyzed the morphological patterns of the
heteropycnotic chromatin and the nucleolar material of Mormidea v-luteum, Oebalus poecilus and Oebalus
ypsilongriseus. The three species presented multilobate testes, with three lobes in M. v-luteum and four in the
Oebalus species. A karyotype with 2n = 14 chromosomes (12A + XY) was observed in the three species. Several
characteristics were common to the three species, such as the absence of a testicular harlequin lobe (a lobe which
produces different types of spermatozoa, previously considered a general characteristic of this family), late migration
of the sex chromosomes and semi-persistence of the nucleolus. The three species also shared some characteristics
regarding the patterns of the heteropycnotic chromatin and nucleolar material, but differed in others mainly related to
the location of the heteropycnotic chromatin in the spermatids and the morphology and distribution of the nucleolar
material at zygotene. The differences were always between species from different genera, suggesting a relationship
with their genetic divergence.

Key words: nucleolus semi-persistence, late chromosome migration, multilobed testes.

Received: November 23, 2007; Accepted: March 13, 2008.

Introduction

Most Heteroptera feed on plantations or grains stored
for human consumption during their nymph and adult
stages, causing great economical losses. Heteroptera in-
cludes approximately 37,000 species distributed in eight
infraorders, five of which contain noxious species (Reba-
gliati et al., 2005). The family Pentatomidae (infraorder
Pentatomorpha), with eight subfamilies (Asopinae, Cyrto-
corinae, Discocephalinae, Edessinae, Pentatominae,
Phyllocephalinae, Podopinae and Serbaninae) and 4,112
species is among them (Schaefer and Panizzi, 2000). They
include the “stink bugs” thus called due to their unpleasant
smell produced by a gland that opens up in the metapleural
region.

The presence of testes formed by a number of com-
partments referred to as “lobes” is a characteristic of the

Pentatomidae. In some species, one of these lobes is of the
harlequin type, which is differentiated from the other lobes
by presenting spermatogonial cells with meiotic pairing,
non-specific association of the autosomal bivalents, anom-
alous arrangement of the chromosomes in the metaphase
plate, anomalous chromosome segregation and cell fusion,
resulting in the production of spermatozoa with highly vari-
able chromosome number (Rebagliati et al., 2005). There
are reports of this type of lobe in 15 genera from three
Pentatomidae subfamilies (Discocephalinae, Edessinae
and Pentatominae) (Rebagliati et al., 2005).

In males of Pentatomidae the chromosome number
varies from six to 27, with 14 as the most frequent number
(85%). The sex chromosome system is XX/XY, except in
three species: Macropygium reticulare (X1X2Y);
Rhytidolomia senilis (Neo-XY) and Thyanta calceata

(X1X2Y) (Rebagliatti et al., 2005). Pentatomidae karyo-
types typically lack microchromosomes (Rebagliati et al.,
2005, Lanzone and Souza, 2006; Souza et al., 2007a).

Pentatomidae basically share the chromosomal fea-
tures present in other Heteroptera. These include holo-

Genetics and Molecular Biology, 31, 3, 686-691 (2008)
Copyright © 2008, Sociedade Brasileira de Genética. Printed in Brazil
www.sbg.org.br

Send correspondence to MM Itoyama. Laboratório de Citogenética
de Insetos, Departamento de Biologia, Instituto de Biociências,
Letras e Ciências Exatas, Universidade Estadual Paulista, Rua
Cristóvão Colombo 2265, 15054-000 São José do Rio Preto, SP,
Brazil. E-mail: mary@ibilce.unesp.br.

Research Article



kinetic chromosomes, i.e., without a localized centromere,
which causes microtubules to bind to the entire chromo-
some during mitosis leading to a parallel migration of the
sister-chromatids to the cell poles at anaphase (Buck, 1968;
Comings and Okada, 1972). At meiosis, however, the ki-
netic activity is restricted to the telomere regions and chro-
mosomes are therefore called telokinetic (Motzko and
Ruthmann, 1984). Meiotic behavior is different among
autosomal bivalents and sex chromosomes (Ueshima,
1979; Manna, 1984; Papeschi and Mola, 1990; González-
Garcia et al., 1996; Suja et al., 2000). Except for a few spe-
cies, autosomal bivalents are chiasmatic and segregate
pre-reductionally (Nokkala and Grozeva, 2000). On the
other hand, the sex chromosomes are achiasmatic and be-
have as univalents at male meiosis, equationally dividing at
anaphase I and associating to form a pseudobivalent at mei-
osis II (nevertheless, the pre-reduction of sex chromosomes
is also reported in some Pentatomidae species) (Ueshima,
1979; Grozeva and Nokkala, 2001).

More detailed cytogenetic aspects of Pentatomidae,
such as morphological variations of the condensed chro-
matin and nucleolar material during cell division, have re-
ceived little attention. Aiming at contributing to the cyto-
genetic characterization of Pentatomidae of economic
interest, we analyzed some aspects of meiosis and sper-
miogenesis of Mormidea v-luteum, Oebalus poecilus and
O. ypsilongriseus.

Material and Methods

Fifteen adult males of each of the species Mormidea

v-luteum, Oebalus poecilus and Oebalus ypsilongriseus

(Heteroptera, Pentatomidae, Pentatominae, Pentatomini)
were colected from okra trees in São José do Rio Preto
(20°47'32" S, 49°21'37" W), São Paulo State, Brazil. The
specimens were fixed in methanol:acetic acid (3:1), their
testicular lobes were isolated and squashed before staining
with lacto-acetic orcein. The pattern of the heteropycnotic
chromatin in testicular cells was then analyzed. The nucleo-
lar morphology was analyzed after impregnation with sil-
ver nitrate (Howell and Black, 1980). Both kinds of analy-
ses were performed during meiosis and spermiogenesis.
Images were obtained under a Zeiss microscope with the
AXIO VISION software.

Results

The three species presented multilobed testes covered
by a reddish membrane. While three lobes were present in
Mormidea v-luteum, four lobes were observed in the two
Oebalus species. None of these species showed lobes with
morphological characteristics of the harlequin type. In all
of them, the mechanism of sex determination in males was
XY and the karyotype was 2n = 14 (12A + XY).

Morphological variation of the heteropycnotic
chromatin

The term heterochromatin includes some characteris-
tics which were not analyzed in this study and we thus use
‘heteropycnotic’ or ‘condensed chromatin’ to refer to the
regions that are more intensely stained by lacto-acetic
orcein.

In the three analyzed species, the polyploid nuclei of
the nutritive cells were large, with a larger heteropycnotic
region and several much smaller ones (Figure 1A). The
whole process of spermatogenesis occurred in the sperma-
togonial cysts constituted by nine spermatocytes, each
with several heteropycnotic regions (Figure 1B). In the
three species, the cells at the initial prophase I (leptotene,
zygotene and pachytene) exhibited a strongly stained
heteropycnotic region, which was closer to the nucleus pe-
riphery and possibly composed of the X and Y chromo-
somes (Figure 1C-E). During diplotene and diakinesis,
chiasmata were observed in the autosomal bivalents, but
not in the sex chromosomes (Figure 1F-G). The X chro-
mosome was larger than the Y (Figure 1H) and the sex
chromosomes were seen together or separated at meta-
phase I (Figure 1H,I). In a polar view during metaphase I
and II, the autosomes were arranged in a ring surrounding
the sex chromosomes (Figure 1I). Late migration of the
chromosomes was observed at anaphase and telophase I
and II (Figure 1J-L).

Observations on the spermiogenesis of the three spe-
cies showed that, in the initial round-shaped spermatids, the
heteropycnotic chromatin is C-shaped and located in the in-
ternal part of the nuclear envelope, covering over half of it.
A heteropycnotic corpuscle was also observed inside the
spermatid nucleus of M. v-luteum, but not in the Oebalus

species (Figure 1M, N). During spermatid elongation, the
condensed chromatin remained close to the nuclear enve-
lope in M. v-luteum (Figure 1O), while it became more cen-
tral in O. poecilus and O. ypsilongriseus, resembling a
longitudinal line (Figure 1P).

Morphological variation of the nucleolar material

A large irregular nucleolar mass, apparently formed
by the association of smaller bodies, and some smaller cor-
puscles, were present in the polyploid nuclei of the nutritive
cells of the three species (Figure 2A). A single nucleolar
corpuscle was observed at the nucleus periphery of sper-
matocytes at initial prophase I (leptotene) in the three spe-
cies (Figure 2B). The nucleolar corpuscle at zygotene in
Oebalus increased in size and acquired an unusual mush-
room-like form, with a larger, intensely stained part (the
“hat”) and a smaller fainter portion (the “stem”) (Figure
2C). This morphological type of nucleolar material per-
sisted during pachytene, when another round, smaller and
intensely stained nucleolar body also appeared (Figure 2D).
An apparent disintegration of the nucleolar material started
between pachytene and diplotene, when round corpuscles

Souza et al. 687



of different sizes were seen (Figure 2E). Mormidea

v-luteum differed from the other two species by the absence
of this mushroom-like nucleolar structure. Instead, we only

observed a nucleolar corpuscle and fibrilar structures asso-
ciated with the chromosomes that later became dispersed in
a granular form in this species (Figure 2F, G). In the three

688 Heteropycnotic chromatin and nucleolar material in Pentatomidae (Heteroptera)

Figure 1 - Seminiferous tubule cells of Mormidea v-luteum (D, K, M and O), Oebalus poecilus (A, F, G, H, I, J, L, N and P) and Oebalus ypsilongriseus

(B, C and E) adult males stained with lacto-acetic orcein. A) Polyploid nuclei of nutritive cells containing one large and many small heteropycnotic cor-
puscles (arrows); B) Spermatogonial cyst constituted by nine spermatocytes, each one containing a heteropycnotic body (arrows); C-G) The single
heteropycnotic corpuscle (arrow) persists during the entire prophase I (in the sequence: leptotene, zygotene, pachytene, diplotene and diakinesis); note the
presence of chiasmata in F and G (arrowheads); H) Metaphase I showing 2n = 12A + XY, the X (large) and Y (small) chromosomes are indicated by ar-
rows; I) Polar view of metaphase I, the autosomal bivalents forming a ring around the sex chromosomes (arrow); J-L) Anaphases and telophase I; note the
late migration of the chromosomes (arrows); M) In round spermatids of Mormidea v-luteum, the heteropycnotic chromatin is present in the center of the
nucleus forming a single corpuscle (arrowhead) and around the interior of the nucleus envelope arranged in a C- shaped structure (arrow); N) In the round
spermatid of Oebalus species the heteropycnotic chromatin is exclusively present in the interior of the nucleus (arrow); O) Elongated spermatid of
Mormidea showing the heteropycnotic chromatin maintained at the nucleus periphery (arrow); P) Elongated spermatid of Oebalus showing the hetero-
pycnotic chromatin as a longitudinal line in the interior of the head (arrow). Bar = 10 μm.



species, the nucleolar material could be observed as a round
corpuscle until the end of telophase I (Figure 2H-K) and the
still round spermatids exhibited a variable number of small
nucleoli, some of which were more intensely stained (Fig-

ure 2L-N). When the spermatids started to elongate, the sil-
ver nitrate-stained material concentrated at the posterior re-
gion of the head, where it was seen until the formation of
the spermatozoa (Figure 2O-S).

Souza et al. 689

Figure 2 - Seminiferous tubule cells of Mormidea v-luteum (A, B, F, G, I and N), Oebalus poecilus (L, M, P and R) and Oebalus ypsilongriseus (C, D, E,
H, J, K, O, Q and S) adult males, impregnated by silver nitrate. A) Polyploid nuclei of nutritive cells containing a large mass of nucleolar material and sev-
eral small corpuscles (arrows); B) One large nucleolar corpuscle is present in the cell nuclei at leptotene (arrow); C, D) In both Oebalus species two asso-
ciated nucleolar bodies are present at zygotene, one more impregnated than the other and showing a mushroom-like shape (C, arrow); note a small addi-
tional corpuscle in D (arrow); E-G) Beginning of the disorganization process of the nucleolar material at pachytene/diplotene (arrows); H, I) metaphases
I in lateral view with the nucleolar material still present (arrows); J, K) nucleolar material also present at telophase (arrows); L-N) Round spermatids with
a variable number of nucleolar bodies (arrows); O-S) Spermatids with different degrees of elongation; the nucleolar material is located in the posterior re-
gion of the head (arrows). Bar = 10 μm.



Discussion

We studied the morphological changes of the hetero-
pycnotic chromatin and of the nucleolar material during
meiosis and spermiogenesis of Mormidea v-luteum,
Oebalus poecilus and O. ypsilongriseus. Changes in the
amount and distribution of decondensed and condensed
chromatin may reflect genetically active and inactive chro-
mosome regions, respectively, while morphological alter-
ations of the nucleolus (including number and structure)
reflect the pattern of ribosome production, a central process
in the protein synthesis.

We observed similarities and differences among the
species studied. The three species had multilobed testes
with three lobes in M. v-luteum and four in O. poecilus and
O. ypsilongriseus. Multilobed testes are a characteristic of
the Pentatomidae, but the number of lobes observed in the
species analyzed herein was smaller than that typically
found in the family, which is seven. In addition, the three
species differed from the other 27 species of the same fam-
ily and subfamily (Pentatominae) already studied by the ab-
sence of a harlequin lobe (Rebagliati et al., 2005; Lanzone
and Souza, 2006; Souza et al., 2007a). The Pentatomidae
Antiteuchus tripterus also showed less lobes (six) than the
typical seven, but one of them was harlequin (Souza et al.,
2007a).

Rebagliati et al. (2005) considered the development
of harlequin lobes as dependent on the environment in
which the insects live. However, the harlequin lobe was
observed in samples of Antiteuchus tripterus collected in
apparently different environments in several states in
Brazil (São Paulo, Souza et al., 2007a; Pernambuco,
Alagoas and Bahia, Lanzone and Souza, 2006). These ob-
servations suggest that the presence of that lobe is a
genetic characteristic of the species rather than an envi-
ronmental effect.

Another feature shared by the three species was the
2n = 14 karyotype, with XY males, suggesting a XX/XY
sex chromosome system, found in most previously ana-
lyzed Pentatomidae.

The distribution of the heteropycnotic chromatin dur-
ing meiosis and spermiogenesis was common to the three
species, except in the round spermatids, in which M.
v-luteum exhibited an additional corpuscle inside the head,
not observed in the other species. The distribution of the
heteropycnotic chromatin in elongated spermatids in M.

v-luteum also differed from that of the other species, being
close to the membrane in the interior of the head, while it
formed a filament in the central region in Oebalus.

As to the nucleolar activity, in some insects (includ-
ing some Heteroptera) the silver nitrate specifically stains
the previously active nucleolar organizing regions (NORs),
which are chromosome sites of rDNA. In some Heterop-
tera, a single NOR was observed, which could be interstitial
or terminal and located at autosomes or sex chromosomes
(Camacho et al., 1985; Fossey and Liebenberg, 1995; Gon-

zález-García et al., 1996; Papeschi et al., 2003; Rebagliati
et al., 2003).

In the three Pentatomidae species studied herein no
NORs could be evidenced, even after some technical varia-
tions were tried. Nevertheless, after silver staining, the
morphological changes of the nucleolar material could be
analyzed. The three species apparently did not differ as to
the pattern observed in the nutritive cells. The nucleolar
material remained visible in the three species during the en-
tire meiosis and spermiogenesis, a phenomenon called nu-
cleolar semi-persistence (Pickett-Heaps, 1970).

Nucleolar semi-persistence differs from the more
general process in which the disorganization of the nucleo-
lus occurs during prophase, so that from diakinesis until the
end of the meiotic division, this organoid is not visible, sug-
gesting that, at that time, it is already completely disorga-
nized (Risueño and Medina, 1976). Among Heteroptera,
exceptions to this general behavior were described for other
species, such as Nysius californicus (Lygaeidae, Souza et

al., 2007b) and Antiteuchus tripterus (Pentatomidae, Souza
et al., 2007a). In both cases, silver-stained material was ob-
served around the chromosomes until the meiotic meta-
phase I.

Differences in the nucleolar material among the
three species were detected at zygotene and pachytene,
with the Oebalus species showing a “mushroom-like”
structure. In the same meiotic stages, M. v-luteum pre-
sented a single nucleolar corpuscle with size and staining
similar to the fainter part of the “mushroom-like” struc-
ture of Oebalus.

The nucleolar semi-persistence is another structural
characteristic of the meiosis which, similarly to the pres-
ence of the harlequim lobe, has been attributed to environ-
mental effects. According to Cattani and Papeschi (2004),
the nucleolar semi-persistence was detected in individuals
of the Heteroptera Spartocera fusca that spent more time in
the field, being thus longer exposed to environmental fac-
tors such as fluctuations of temperature, humidity and pre-
cipitation. We do not have such information on the species
that we studied, but they were collected in the same place at
the same time.

In the present study, the differences observed were
between species belonging to different genera. They may
thus be part of the genetic features that evolved during the
divergence of the two genera, reflecting physiological dif-
ferences that remain to be understood.

Acknowledgments

Thanks are due to Dr. Sonia Maria Oliani (Depart-
ment of Biology - IBILCE/UNESP) for the opportunity of
capturing cell images and to FAPESP, FUNDUNESP and
CNPq for financial support.

690 Heteropycnotic chromatin and nucleolar material in Pentatomidae (Heteroptera)



References
Buck RC (1968) Mitosis and meiosis in Rhodnius prolixus: The

fine structure of the spindle and diffuse kinetochore. J
Ultrastruct Res 18:489-501.

Camacho JPM, Belda J and Cabrero J (1985) Meiotic behaviour
of the holocentric chromosomes of Nezara viridula (Insecta,
Heteroptera) analyzed C-banding and silver impregnation.
Can J Genet Cytol 27:491-497.

Cattani MV and Papeschi AG (2004) Nucleolus organizing re-
gions and semi-persistent nucleolus during meiosis in
Spartocera fusca (Thunberg) (Coreidae, Heteroptera). Here-
ditas 140:105-111.

Comings DE and Okada TA (1972) Holocentric chromosomes in
Oncopeltus: kinetochore plates are present in mitosis but ab-
sent in meiosis. Chromosoma 37:177-192.

Fossey A and Liebenberg H (1995) Meiosis and nucleolar struc-
tures in the stink bug Carlisis wahlbergi Stal (Coreidae,
Heteroptera). Cytobios 81:7-15.

González-Garcia JM, Antonio C, Suja JÁ and Rufas JS (1996)
Meiosis in holocentric chromosomes: Kinetic activity is ran-
domly restricted to the chromatid ends of sex univalents in
Graphosoma italicum (Heteroptera). Chromosome Res
4:124-132.

Grozeva S and Nokkala S (2001) Chromosome numbers, sex de-
termining systems, and patterns of the C-heterochromatin
distribution in 13 species de Lace Bugs (Heteroptera, Tin-
gidae). Folia Biol 49:29-41.

Howell WM and Black DA (1980) Controlled silver staining of
nucleolus organizer regions with protective colloidal devel-
oper: 1-step method. Experientia 36:1014-1015.

Lanzone C and Souza MJ (2006) Chromosome complement and
meiosis in the three species of the Neotropical bug genus
Antiteuchus (Heteroptera, Pentatomidae, Discocephalinae).
Genet Mol Biol 29:49-55.

Manna GK (1984) Chromosomes in evolution in Heteroptera. In:
Sharma AK (ed) Chromosomes in Evolution of Eukaryotic
Groups. CRC Press, Boca Raton, pp 189-225.

Motzko D and Ruthmann A (1984) Spindle membranes in mitosis
and meiosis of the heteropteran insect Dysdercus

intermedius. A study of the interrelationship of spindle ar-
chitecture and the kinetic organization of chromosomes. Eur
J Cell Biol 33:205-216.

Nokkala S and Grozeva S (2000) Achiasmatic male meioses in
Myrmedobia coleoptratal (Fn.) (Heteroptera, Microphy-
sidae). Caryologia 53:5-8.

Papeschi AG and Mola LM (1990) Meiotic studies in Acanonicus

hahni (Coreidae, Heteroptera). I. Behavior of univalents in
desynaptic individuals. Genetica 80:31-38.

Papeschi AG, Mola LM, Bressa MJ, Greizerstein EJ, Lía V and
Poggio L (2003) Behaviour of ring bivalents in holocentric
systems: Alternative sites of spindle attachment in Pachylis

argentinus and Nezara viridula (Heteroptera). Chromosome
Res 11:725-733.

Pickett-Heaps JD (1970) The behavior of the nucleolus during mi-
tosis in plants. Cytobios 6:69-78.

Rebagliati P, Papeschi AG and Mola LM (2003) Meiosis and fluo-
rescent banding in Edessa meditabunda and E.

rufomarginata (Heteroptera, Pentatomidae, Edessinae). Eur
J Entomol 100:11-18.

Rebagliati PJ, Mola LM, Papeschi AG and Grazia J (2005)
Cytogenetic studies in Pentatomidae (Heteroptera): A re-
view. J Zool Syst Evol Res 43:199-213.

Risueño MC and Medina FJ (1976) The nucleolar structure in
plant cells. Rev Biol Cel 7:1-162.

Schaefer WC and Panizzi AR (2000) Heteroptera of economic im-
portance. Boca Raton, CRC Press, 824 pp.

Souza HV, Bicudo HEMC and Itoyama MM (2007b) Study of
chromosomal and nucleolar aspects in testes of Nysius

californicus (Heteroptera, Lygaeidae). Genet Mol Res
6:33-40.

Souza HV, Bicudo HEMC, Costa LAA and Itoyama MM (2007a)
A study of meiosis and spermatogenesis in different testi-
cular lobes of Antiteuchus tripterus (Heteroptera, Penta-
tomidae). Eur J Entomol 104:353-362.

Suja JA, Del Cerro AL, Page J, Rufas JS and Santos JL (2000)
Meiotic sister chromatid cohesion in holocentric sex chro-
mosomes of three heteropteran species is maintained in ab-
sence of axial elements. Chromosoma 109:35-43.

Ueshima N (1979) Animal Cytogenetics. v. 3. Insecta 6. Hemip-
tera, Heteroptera. Gebr. Borntraeger, Berlin, 119 pp.

Associate Editor: Yatiyo Yonenaga-Yassuda

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