Paedogenesis in the dipteran insect Heteropeza pygmaea: an interpretation

A comparison of the modified oocyte development in paedogenetic reproduction with ‘regular’ oogenesis in imaginal reproduction of H. pygmaea shows that the paedogenetically developing eggs start embryonic development long before the usual processes of oocyte growth have been terminated or even initiated. Under certain experimental conditions, uncoupling of meiotic and growth processes could be observed in eggs cultured in vitro and showing aberrant development. We, therefore, assume that in paedogenetic egg development a meiotic block is not properly established or removed precociously. An interpretation of the evolution of paedogenetic reproduction is given.     

Pulsating oocytes and rotating follicles in an insect ovary

The larval ovaries of the paedogenetic gall midge Heteropeza pygmaea can be cultured in vitro throughout ovary development, follicle formation, and egg growth. Time-lapse films of oogenesis in vitro reveal two kinetic phenomena: (1) All oocytes in the ovary display a swift and continuous pulsating movement, bringing about a periodical deformation of their nuclei. (2) Following their formation in the ovaries, the follicles start to rotate slowly and stop rotating only shortly before embryonic development begins.     

Germ line and oogenesis during paedogenetic reproduction inHeteropeza pygmaea Winnertz (Diptera: Cecidomyiidae)

The germ line during paedogenetic reproduction in the gall midgeHeteropeza pygmaea was followed cell generation by cell generation. There are altogether 8 or 9 successive divisions during one paedogenetic cycle, and all descendants of the primordial germ cell develop into occytes, while the trophocytes are of somatic origin. In the cytological race studied (from southern Finland) the germ-line cells possess 58 chromosomes, the somatic number being 10.     

Ecdysone stimulates and juvenile hormone inhibits follicle formation in a gall midge ovary in vitro

The larval ovaries of the paedogenetic gall midge Heteropeza pygmaea can be cultured in vitro throughout oögenesis. Addition of farnesol or C₁₆ juvenile hormone to the culture medium inhibits follicle formation in the ovaries; addition of ecdysterone, on the other hand, strongly accelerates the formation of follicles. It is suggested that ecdysone triggers or stimulates follicle formation in the ovaries also in vivo, and that juvenile hormone acts on oögenesis in a later stage of development.     

Die Zytologie der bisexuellen und parthenogenetischen Fortpflanzung von Heteropeza pygmaea Winnertz,einer Gallmücke mit pädogenetischer Vermehrung

Heteropeza pygmaea (syn. Oligarces paradoxus) can reproduce as larvae by paedogenesis or as imagines (Fig. 1). The eggs of imagines may develop after fertilization or parthenogenetically. The fertilized eggs give rise to female larvae, which develop into mother-larvae with female offspring (Weibchenmütter). Only a few of the larvae which hatch from unfertilized eggs become motherlarvae with female offspring; the others die. Spermatogenesis is aberrant, as it is in all gall midges studied to date. The primary spermatocyte contains 53 or 63 chromosomes. The meiotic divisions give rise to two sperms each of which contains only 7 chromosomes (Figs. 5–11). The eggs of the imago are composed of the oocyte and the nurse-cell chamber. In addition to the oocyte nucleus and the nurse-cell nuclei there are three other nuclei in the eggs (Figs. 15–17). They are called small nuclei (kleine Kerne). In prometaphase stages of the first cleavage division it could be seen that these nuclei contain about 10 chromosomes. Therefore it is assumed that these nuclei originate from the soma of the mother-larva. The chromosome number of the primary oocyte is approximately 66. The oocyte completes two meiotic divisions. The reduced egg nucleus contains approximately 33 chromosomes. The polar body-nuclei degenerate during the first cleavage divisions. The fertilized egg contains 2–3 sperms. The primary cleavage nucleus is formed by the egg nucleus and usually all of the sperm nuclei and the small nuclei (Figs. 21–29). The most frequent chromosome numbers in the primary cleavage nuclei are about 77 and 67. The first and the second cleavage divisions are normal. A first elimination occurs in the 3rd, 4th, and 5th cleavage division (Fig. 30). All except 6 chromosomes are eliminated from the future somatic nuclei. Following a second elimination (Figs. 33, 34), the future somatic nuclei contain 5 chromosomes. No elimination occurs in the divisions of the germ line nucleus. In eggs which develop parthenogenetically the primary cleavage nucleus is formed by the egg nucleus and 2–3 small nuclei. It's chromosome number is therefore about 53 or 63. After two eliminations, which are similar to the ones which occur in fertilized eggs, the soma contains 5 chromosomes. The somatic nuclei of male larvae which arrise by paedogenesis contain 5 chromosomes; while the somatic nuclei of female larvae of paedogenetic origin contain 10 chromosomes. It was therefore assumed earlier that sex was determined by haploidy or diploidy. But the above results show that larvae from fertilized as well as from unfertilized eggs of imagines have 5 chromosomes in the soma, but are females, and the female paedogenetic offspring of larvae from unfertilized eggs have either 5 or 10 chromosomes in their somatic cells. Therefore sex determination is not by haploidy-diploidy but by some other, unknown, mechanism. The cytological events associated with paedogenetic, bisexual, and parthenogenetic reproduction in Heteropeza pygmaea are compared (Fig. 37). The occurrence and meaning of the small nuclei which are found in the eggs of most gall midges are discussed. It has been shown here that these nuclei function to restore the chromosome number in fertilized eggs; it is suggested that they function similarity in certain other gall midges. Consideration of the mode of restoration of the germ-line chromosome number leads to the conclusion that in Heteropeza few, if any, of the chromosomes are limited to the germ-line, i.e. can never occur in somatic cells (p. 124).     

Parallel alterations in the timing of ovarian Ecdysone Receptor and Ultraspiracle expression characterize the independent evolution of larval reproduction in two species of gall midges (Diptera: Cecidomyiidae)

Although most insects reproduce in the adult stage, facultative larval or pupal reproduction (paedogenesis) has evolved at least six times indepently in insects, twice in gall midges of the family Cecidomyiidae (Diptera). Paedogenesis in gall midges involves the precocious growth and differentiation of the ovary in an otherwise larval form. We have previously shown that the timing of expression of the Ecdysone Receptor (EcR) and Ultraspiracle (USP), the two proteins that constitute the functional receptor for the steroid hormone 20-hydroxyecdysone, regulates the timing and progression of ovarian differentiation in Drosophila melanogaster (Diptera: Drosophilidae). Here we test the hypothesis that precocious activation of EcR and USP in the ovaries of paedogenetic gall midges allows for precocious ovarian differentiation. Using monoclonal antibodies directed against insect EcR and USP proteins, we first show that when these gall midges are reared under conditions that promote typical, metamorphic development, up- regulation of EcR and USP occurs in the final larval stage. By contrast, in the paedogenetic life cycle, EcR and USP are up-regulated early in the first larval stage. A similar pattern is seen for two independently-evolved paedogenetic gall midges, Heteropeza pygmaea and Mycophila speyeri. We discuss our results in the context of developmental constraints on the evolution of paedogenesis in dipteran insects. Received: 30 July 1999 / Accepted: 23 Feburary 2000     

EGG ACTIVATION AND PARTHENOGENETIC REPRODUCTION IN INSECTS

1. Many insects reproduce by parthenogenesis. In one of the largest orders of the animal kingdom, the Hymenoptera, most of its members reproduce by arrhenotokous parthenogenesis. Egg activation in parthenogenetic animals obviously cannot be caused by fertilization of the egg. The question of what initiates egg development in parthenogenetically reproducing animals has been studied for a few insect species and is discussed in this article. 2. The grasshopper Melanoplus differentialis is one of several Orthoptera displaying accidental parthenogenesis. In this species, egg laying provides the stimulus to the completion of meiosis and start of embryonic development in unfertilized and probably also in fertilized eggs. The same holds true for the dipteran insect Drosophila melanogaster which exhibits rudimentary parthenogenesis, and for D. mercatorum showing accidental parthenogenesis. The precise way in which oviposition affects the egg is unknown. 3. The stick insect Carausius morosus reproduces by obligatory thelytoky. The triggering factor for removal of the meiotic block and initiation of embryonic development is oxygen from the air which penetrates to the egg through the micropyle immediately after oviposition. The oviposition act itself is not necessary for activation of the egg. 4. Comparative studies of the different types of oogenesis in the dipteran insect Heteropeza pygmaea show that in paedogenetically developing follicles meiotic arrest in prophase is of very short duration and a meiotic block at the end of oogenesis is absent. It is suggested that in this case triggering events for egg development are dispensable. On the other hand, under certain experimental conditions a meiotic block can be established in some of these follicles. 5. Investigations on the Ichneumonid wasp Pimpla turionellae have shown that unfertilized, male-determined eggs - and most likely also fertilized, femaledetermined eggs - are activated by mechanical stress exerted on the eggs during natural or imitated oviposition. This mechanical stress, in addition, activates a streaming system which is independent of meiotic completion and nuclear multiplication. Egg activation by egg distortion is also found in the Pteromalid species Nasonia vitripennis and occurs presumably in many other Hymenoptera. 6. Carausius morosus, Pimpla turionellae and Nasonia vitripennis are species with parthenogenetic reproduction for which the natural factors responsible for the initiation of egg development have been identified. The cases of Pimpla turionellae and Nasonia vitripennis are of particular interest because of the feasibility of artificially imitating the natural activating mechanism. 7. It is concluded that apart from fertilization various events at oviposition may trigger egg development. In addition, the occurrence of rudimentary parthenogenesis in many sexually reproducing animal species suggests that sperm entry and fertilization may frequently be necessary for the continuation of egg development rather than for its initiation.     

The cytology of paedogenesis in the gall midgeMycophila speyeri

In paedogenetically developing female eggs of the gall midgeMycophila speyeri only one equational meiotic division occurs. The primary cleavage nucleus contains 29 chromosomes. In the fourth cleavage division 23 chromosomes are eliminated from the future somatic nuclei while the primordial germ-line nucleus keeps the high chromosome number.—The paedogenetic development of male eggs begins with two meiotic divisions. The egg nucleus with 14 or 15 chromosomes fuses with two, sometimes only one, somatic nuclei (2n=6) of maternal origin (regulation). Thus the primary cleavage nucleus contains 26 or 27 chromosomes, sometimes only 20 or 21. Elimination in cleavage divisions V and VI leeds to somatic nuclei with 3 chromosomes while the primordial germ-line nucleus keeps the high chromosome number.—Differences between male and female eggs and the evolution of regulation in gall midges are discussed.     

Regulation of growth of nurse nuclei in the development of egg follicles inCecidomyiidae (Diptera)

InCecidomyiidae the number of trophocytes derived from the somatic tissue of the ovary and forming nutritive chambers of egg follicles is variable. The regulation of growth of the whole nutritive chambers and of the nurse nuclei was investigated in two species of the gall midges,Mikiola fagi andBoucheella artemisiae, at two different stages of the egg follicle development during the second period of the oocyte growth. The volume of a nutritive chamber is correlated with the size of the egg follicle as a whole and is not dependent on the number of nurse nuclei it contains. The total volume of nurse nuclei at each stage under investigation was found to have a constant value which is independent of their number. It was established that the growth of the nurse nuclei takes place through endomitosis, and that at a given stage of the egg follicle development the constant value of the total volume of the nurse nuclei reflects the constancy of degree of their total polyploidy. The results obtained indicate that at the early stages of the egg follicle development the rates of growth of the nurse nuclei and of the whole nutritive chambers in the egg follicles differing with respect to the number of their nurse nuclei must be different; the greater the number of nurse nuclei in a given nutritive chamber the slower the rate of growth of the chamber and their nuclei. As a result of this differential rate of growth the volumes of the nutritive chambers and total volumes of nurse nuclei reach at a certain stage of the egg follicle development certain values common for all egg follicles, irrespective of the number of the nurse nuclei they contain. Beginning with this stage the dependence between the endomitotic activity of the nurse nuclei and the rate of growth of the whole nutritive chamber on the one hand, and the number of the nurse nuclei in the chamber on the other, evidently disappears. The available evidence supports the hypothesis that in the egg follicle ofCecidomyiidae the growth regulation of nurse nuclei and, indirectly, also of whole nutritive chambers results from developmental interrelationships between the oocyte and the nutritive chamber, and that the oocyte plays a leading role in this process. In view of a syncytial character of the nutritive chambers inCecidomyiidae and distinctly expressed asynchrony of the growth-duplication cycles of nurse nuclei belonging to a given chamber it is concluded that the control mechanism for DNA synthesis and endomitosis in nurse nuclei must possess the property of a rapid switch. Processes of the growth regulation of the nurse nuclei are discussed in connection with the role of the nutritive chamber in production of RNA and its supply to the growing oocyte. It is suggested that in the egg follicles ofCecidomyiidae there exists a complex interrelationship between the control mechanism for DNA synthesis and endomitosis in the nurse nuclei and the synthetic processes regulated by the supply of the growing oocyte with RNA produced by the nuclei of the nutritive chamber.     

Oogenesis in a paedogenetic dipteran insect under normal conditions and after experimental elimination of the follicular epithelium

Summary Paedogenetically developing eggs of the gall midgeHeteropeza pygmaea are not deposited, but develop in the hemocoel of the mother larva. The nurse chamber remains present in the cleaving egg, and the follicular epithelium does not form a chorion but envelops the growing egg during embryonic development. It is possible to obtain naked eggs, i.e. eggs lacking the follicular epithelium, which are able to develop up to the blastoderm stage but remain spherical instead of assuming an elongated shape. Oogenesis of normal and naked eggs has been studied at the ultrastructural level with special reference to the nurse chamber. It is shown that the nurse chamber nuclei develop large nucleoli during oogenesis, indicating that the nurse chamber supplies the oocyte with ribosomal RNA (rRNA). The dense bodies in the nurse chamber may represent an intermediate stage in the transport of the rRNA from the nurse chamber to the oocyte; they are probably not related to the polar granules in the oocyte. It is also shown that the intercellular bridge joining the nurse chamber to the oocyte disappears shortly before cleavage initiation. During egg cleavage the follicular epithelium surrounds the nurse chamber, which degenerates and is gradually absorbed by the growing egg plasmodium. Naked cleaving eggs are never attached to a nurse chamber or to relics of it. Naked oocytenurse chamber complexes frequently aggregate, which may indicate a role of the follicular epithelium in follicle separation during normal development.     

Effects of Gamma-Radiation in Oogenesis of Drosophila Mutants Defective for Repair and Meiotic Recombination

Effects of mutations rad201, mei-9, and mei-41on cell sensitivity to gamma-radiation in Drosophilaoogenesis were studied. Females of the control (Oregon R) and mutant strains were irradiated at a dose of 15 Gy. For 9 days after the irradiation, the number of eggs in consecutive day batches, the frequency of dominant lethals (DLs) among the eggs, and the cytologically recorded distribution of oocytes for stages of their development, and the frequency of egg chamber degeneration in female ovaries were estimated. As a result of joint analysis of the data, different oogenesis stages were characterized with regard to the frequency of two radiation-induced events: appearance of DLs in oocytes and degeneration of egg chambers due to apoptosis of nurse cells. It was shown that the mutations affect these parameters only at particular stages of early oogenesis, at which previtellogenetic growth of egg follicles and meiotic recombination in oocytes occur. Mutation rad201 ^G1increased the frequency of DLs and egg chamber degeneration, mei-41 ^D5affected only the DL frequency, and mei-9 ^a, in addition to enhancing the chamber degeneration frequency, promoted radiation rescue of some oocytes from the DL induction.     

Effect of gamma-irradiation on oogenesis of Drosophila mutants defective for reparation and meiotic recombination

Effects of mutations rad201, mei-9, and mei-41 on cell sensitivity to gamma-radiation in Drosophila oogenesis were studied. Females of the control (Oregon R) and mutant strains were irradiated at a dose of 15 Gy. For 9 days after the irradiation, the number of eggs in consecutive day batches, the frequency of dominant lethals (DLs) among the eggs, and the cytologically recorded distribution of oocytes for stages of their development, and the frequency of egg chamber degeneration in female ovaries were estimated. As a result of joint analysis of the data, different oogenesis stages were characterized with regard to the frequency of two radiation-induced events: appearance of DLs in oocytes and degeneration of egg chambers due to apoptosis of nurse cells. It was shown that the mutations affect these parameters only at particular stages of early oogenesis, at which previtellogenetic growth of egg follicles and meiotic recombination in oocytes occur. Mutation rad201G1 increased the frequency of DLs and egg chamber degeneration, mei-41D5 affected only the DL frequency, and mei-9a, in addition to enhancing the chamber degeneration frequency, promoted radiation "rescue" of some oocytes from the DL induction.     

In vitro culture of ovaries of a viviparous gall midge

Summary Ovaries of the viviparous pedogenetic gall midgeHeteropeza pygmaea can be cultured in hemolymph obtained from X-ray-sterilized larvae of the same species. In this culture medium, formation of follicles is essentially the same as in vivo, and sometimes female larvae develop from these follicles. The ovaries of such larvae, in their turn, have been cultured in vitro to produce larvae. In this way, in vitro development from oogonium to larva has been maintained for several generations. When using hemolymph obtained from larvae grown under different conditions, the in vitro cultured ovaries produce a second type of egg which probably is male-determined. Ovarian development in vitro has been studied with differential interference contrast optics and time-lapse cinemicrography. This work was supported by the Swiss National Science Foundation Grant No. 3.2010.73.     

Composite eggs in non-paedogenetic gall midges (Cecidomyiidae,Diptera)

Summary A new type of composite eggs was found in the non-paedogenetic gall midgesMikiola fagi andRhabdophaga rosaria. Composite eggs of this type contained two or three nurse chambers and one egg chamber with one oocyte nucleus. In all composite eggs examined only one nurse chamber developed normally, while the others, regardless of their number and position within a composite egg, were arrested in their growth. It is assumed that the arrested nurse chambers, contrary to normally developing ones, are deficient in generative nuclei and thus are derived exclusively from mesodermal cells.This work was supported in part under Contract DPKBN/52/76-II.1.3.10, with the Polish Academy of Sciences     

Male germ line,spermatogenesis and karyotypes of Heteropeza pygmaea winnertz (Diptera: Cecidomyiidae)

The germ line during the development of the male of the gall midge Heteropeza pygmaea was followed cell generation by cell generation. The development of the male egg begins with two meiotic divisions, followed by fusion of one of the resulting nuclei with (usually) two somatic nuclei (regulation), after which the regulated nucleus passes through 9–10 mitoses, and finally a further two meiotic divisions producing the spermatids. The chromosome numbers (determined by colchicine and air-drying techniques) of the race studied are 55 in the female germ line, very variable with a mean near 47–48 in the male germ line after regulation, 5 or 6 in the sperms, 10 in the female somatic nuclei and 5 in the male somatic nuclei. Statistical techniques for analysis of the different karyotypes are developed and a model explaining the known cytological events in Heteropeza is presented.     

Basic aspects of ovarian development in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

Modern views of the development and structural organization of the female reproductive system in Drosophila melanogaster are reviewed. Special emphasis is placed on the generation and development of follicles in the germarium and the interactions of germline and somatic cells in the egg chamber. Detailed consideration is given to the main events that ensure and regulate the transport of mRNA, proteins, and organelles from nurse cells to the oocyte in the germarium and at later stages of egg chamber development.     

Oogonial proliferation and early oocyte dynamics during the reproductive cycle of two Clupeiform fish species

Although oogonial proliferation continues in mature females in most teleosts, its dynamics and the transformation of oogonia to early meiotic oocytes during the reproductive cycle have received little attention. In the present study, early oogenesis was examined throughout the reproductive cycle in two Clupeiform fishes, the Mediterranean sardine, Sardina pilchardus, and the European anchovy, Engraulis encrasicolus. Observations using confocal laser scanning microscopy (CLSM) provided extensive information on markers of oogonial proliferation (mitotic divisions, oogonia nests) and meiotic prophase I divisions of oocyte nests (leptotene, zygotene, pachytene, diplotene) in ovaries of different reproductive phases. In sardine, oogonial proliferation persisted throughout the entire reproductive cycle, whereas in anchovy, it was more pronounced prior to (developing ovaries) and after (resting ovaries) the spawning period. Anchovy exhibited a higher rate of meiotic activity in developing ovaries, whereas sardine exhibited a higher rate in resting ovaries. The observed differences between the two species can potentially be attributed to different seasonal patterns of energy allocation to reproduction and the synchronization between feeding and the spawning season.     

Embryonic development of insect eggs formed without follicular epithelium

In the paedogenetic Dipteran insect Heteropeza pygmaea it is possible by physical or chemical means to obtain oocyte-nurse chamber complexes lacking the follicular epithelium. Such oocytes nevertheless complete oogenesis and begin embryonic development. Development of these “naked” eggs has been compared to normal egg development by cinematographic analysis. Eggs which are formed without follicular epithelium are completely spherical in shape and the increase in size which normally occurs during cleavage is much less extensive. Naked eggs show shape changes during the first part of cleavage, in which bulgy cytoplasmic protrusions are formed and disappear continuously. Protrusions which are present during the mitotic divisions are partly cleaved. Cleavage folds occur much earlier in naked eggs than in normal eggs. On the other hand, the duration of the mitotic cycles during nuclear multiplication of normal and naked eggs is similar. Development of naked eggs usually continues for some time after blastoderm formation before degeneration sets in. The events taking place prior to embryonic death are difficult to relate to normal gastrulation events. However, in some cases the morphogenetic movements of naked embryos resemble germ band formation of normal embryos.     

A laboratory method for studying the biology and control of pests in mushroom compost

A Petri dish technique, devised by Eger (1960, 1962) for studying mycelial growth through mushroom compost and casing material, has been modified for pest investigations. The method provides a sensitive test for phytotoxic and insecticidal action of applied chemicals, and experiments are described which indicate that thionazin is a suitable insecticide for use against Heteropeza pygmaea Winnertz (Dipt.: Cecidomyiidae). Examples are also given of the use of this method in the study of the biology and population dynamics of paedogenetic Cecidomyiidae.     

CNP/NPR2 signaling maintains oocyte meiotic arrest in early antral follicles and is suppressed by EGFR‐mediated signaling in preovulatory follicles

Oocyte meiosis is arrested at prophase I by factors secreted from surrounding somatic cells after oocytes acquire meiotic competence at an early antral stage, and meiosis resumes in preovulatory follicles as a result of the luteinizing hormone (LH) surge. Recently, signaling by C‐type natriuretic peptide (CNP) through its receptor, natriuretic peptide receptor 2 (NPR2), was found to be essential for meiotic arrest at the late antral stage. Whether or not CNP/NPR2 signaling maintains oocyte meiotic arrest in earlier follicular stages and how it is associated with meiotic resumption induced by the LH surge is unclear. In this study, we examined the expression of Nppc and Npr2, respectively encoding CNP and NPR2, in the ovaries of immature mice. Nppc and Npr2 mRNA were specifically expressed in the outer and inner granulosa cell layers, respectively, in early antral follicles. Histological analysis of mice with a mutation in Npr2 revealed precocious resumption of oocyte meiosis in early antral follicles. Ovaries of mice treated with excess human chorionic gonadotropin (hCG) exhibited markedly decreased Nppc mRNA levels in granulosa cells of preovulatory follicles. Moreover, we found that amphiregulin, a mediator of LH/hCG activity through epidermal growth factor receptor (EGFR), suppressed Nppc mRNA levels in cultured granulosa cells. These results suggest that CNP/NPR2 signaling is essential for oocyte meiotic arrest in early antral follicles and that activated LH/amphiregulin/EGFR signaling pathway suppresses this signal by downregulating Nppc expression. Mol. Reprod. Dev. 79: 795–802, 2012. © 2012 Wiley Periodicals, Inc.