Control of the eupyrene-apyrene sperm dimorphism in Lepidoptera

Lepidoptera males bear concomitantly nucleate (eupyrene) and anucleate (apyrene) spermatozoa. Both kinds of spermatozoa reach the spermatheca of inseminated females but only the eupyrene ones fertilize the eggs. The functions of the apyrene spermatozoa are still uncertain. Eupyrene spermatogenesis is regular and highly sensitive to genetic and experimental manipulations while apyrene spermatogenesis is irregular and withstands these manipulations. Both kinds of spermatozoa derive from the same kind of bipotential spermatocytes. The shift of spermatocyte commitment from eupyrene to apyrene spermatogenesis is induced by a haemolymph factor that becomes active just before or after pupation, depending on species. Accordingly, eupyrene spermatogenesis starts during larval instars and stops after pupation while apyrene spermatogenesis begins just before or after pupation, depending on the species, and persists in the imago. The shift is related to shortening of meiotic prophases and blocking synthesis of a meiotic lysine-rich protein fraction in apyrene cells. From spermatogonia proliferation to early spermatocytes, spermatogenesis is a quasi-independent process. Afterwards, it becomes discontinuous and is punctuated by predetermined stations. Progress to a subsequent station is an 'all or none' phenomenon, regulated by cues linked to fluctuations of the main morphogenetic hormones titers. In absence of a particular cue, the cells stop advancing towards the next station and eventually degenerate.     

Regular and irregular divisions of Lepidoptera spermatocytes as related to the speed of meiotic prophase

Lepidoptera males bear two kinds of meiotic divisions. One is regular (eupyrene) and leads to nucleate, fertilizing spermatozoa. The other (apyrene) shows metaphase I chromosomes clumping together into irregular masses which later split forming daughter cells with unbalanced sets of chromosomes which are eventually extruded from the cells; hence, the spermatids develop into anucleate spermatozoa of unknown function. The apyrene divisions are induced by a haemolymph factor which becomes functional towards pupation. Using incorporation of tritiated thymidine at the premeiotic S-phase as a marker for timing, it was found that the prophase of the apyrene spermatocyte is shorter than that of the eupyrene spermatocyte. It is proposed that meiosis-specific proteins cannot be synthesized during the shortened apyrene prophase and that this is correlated with the irregular chromosome behaviour during the subsequent metaphase-telophase of these spermatocytes.     

Differential basic nucleoprotein kinetics in the two kinds of lepidoptera spermatids: Nucleate (eupyrene) and anucleate (apyrene)

Normal lepidopteran males produce two kinds of spermatozoa: nucleate (eupyrene) and anucleate (apyrene). Eupyrene spermatozoa have the usual type of elongate nuclei. But in apyrene spermatids, the nuclei never elongate and the chromatin remains in a telophase-like condition until enucleation occurs. The study of the differential nucleoprotein kinetics of the two types of spermatids, using the fluorescent dye sulfoflavine, shows that: (1) In the elongate eupyrene nuclei, lysine-rich nucleoproteins are replaced by arginine-rich ones, while in the non-elongating apyrene nuclei only lysine-rich nucleoproteins are detected. However, nuclear elongation is not causally related to nucleoprotein transitions as transitions occur in the eupyrene spermatids after nuclear elongation. (2) The replacement of the nucleoproteins occurs in the eupyrene nuclei in a polarized manner. This may be correlated with the heterogeneous ultrastructural configuration of the chromatin fibers in elongating spermatid nuclei, as shown in other insect species. (3) Concomitantly with the eupyrene spermatid nucleoprotein transition, the cytoplasm of the head cyst cell shows an increasing amount of cytoplasmic lysine-rich proteins, while no such a phenomenon occurs in apyrene cysts. This differential pattern distribution may reflact functional differences among the two types of cysts and is probably related to the regulation of the dichotomy in lepidopteran spermatogenesis.     

Meiotic chromosome missegregation during apyrene meiosis in the gypsy moth,Lymantria dispar,is preceded by an aberrant prophase I

The gypsy moth, Lymantria dispar, produces two structurally and genetically distinct types of spermatozoa. The eupyrene spermatozoa are genetically haploid and structurally typical. The apyrene spermatozoa are anucleate and structurally different from eupyrene spermatozoa. To understand further the events contributing to meiotic chromosome missegregation in apyrene spermatocytes, we examined the progression of meiosis in these cells with respect to their eupyrene counterparts. Chromosomal bouquet formation and fusion of nucleolar organizing regions are disrupted in apyrene nuclei. In addition, the chromatin of apyrene nuclei is prematurely and extremely condensed compared with that of eupyrene nuclei. An antibody to the conserved synaptonemal complex protein 3 (SCP3) labeled eupyrene pachytene chromosomes, but not apyrene pachytene chromosomes. In addition, apyrene meiotic spindles are missing a subset of microtubules, which likely include kinetochore microtubules. Because the condensation behavior of meiotic chromatin in apyrene spermatocytes deviates from that of eupyrene spermatocytes, we examined the appearance and distribution of the phosphorylated form of histone H3, but no significant differences in histone H3 phosphorylation were found between apyrene and eupyrene spermatocytes. We argue that because a pachytene checkpoint is not initiated in apyrene spermatocytes, this system may provide a way to understand better the underlying biochemical connections between pairing, recombination, synapsis, kinetochore assembly and segregation of chromosomes during meiosis in a higher eukaryote.     

Spermatogenesis in the testes of diapause and non-diapause pupae of the sweet potato hornworm, Agrius convolvuli (L.) (Lepidoptera: Sphingidae)

Dichotomous spermatogenesis was examined in relation to diapause in the sweet potato hornworm, Agrius convolvuli. In non-diapause individuals, eupyrene metaphase began during the fifth larval instar and eupyrene spermatids appeared in wandering larvae. Bundles of mature sperm were found after pupation. Apyrene spermatocytes also appeared during the fifth larval instar, but meiotic divisions occurred irregularly and their nuclei were discarded from the cells during spermiogenesis. Morphometric analyses of flagellar axonemes showed a variable sperm number in apyrene bundles. The variation ranging from 125 to 256 sperm per bundle indicated abnormal divisions or the elimination of apyrene spermatocytes. In diapause-induced hornworms, spermatogenesis progressed similarly during the larval stages. The cessation of spermatogenesis during diapause is characterized by 1) secondary spermatocytes and sperm bundles degenerating gradually as the diapause period lengthens, and 2) spermatogonia or primary spermatocytes appearing throughout diapause. A TUNEL (TdT-mediated dUTP-biotin nick end-labeling) assay revealed that DNA fragmentation occurred in the nuclei of secondary spermatocytes and early spermatids. Aggregates of heterochromatin along the nuclear membrane indicated the onset of apoptosis, and condensed chromatin was confirmed by electron microscopy to be the apoptotic body. These results show that the degenerative changes in spermatogenic cells during pupal diapause were controlled by apoptosis.     

Control of spermatogenesis resumption in post-diapausing larvae of the codling moth

The lepidopteran primary spermatocytes produce first eupyrene (nucleated) and later apyrene (anucleated) spermatozoa. The shift to apyrene commitment of the spermatocytes is related to an apyrene-spermatogenesis-inducing factor (ASIF) becoming active towards pupation. During diapause, the primary spermatocytes lyse and spermatogenesis ceases. The renewal of the dichotomous spermatogenesis in the testes of post-diapausing, last-instar larvae of the codling moth was studied in vivo and in vitro. In vivo, the post-diapausing larvae resume the two types of spermatogenesis. Since ASIF activity is related to pupation, the earliest apyrene spermatids appear one day before pupation, as in non-diapausing larvae. In vitro, renewal of spermatogenesis occurs if 20-hydroxy-ecdysone is added to the medium, but only eupyrene spermatids occur since the testes are explanted before ASIF activity has started. These spermatids are unreduced and develop directly from primary spermatocytes which do not undergo meiotic divisions. Moreover, only flagella develop in these spermatids and the nuclei remain spherical. Post-diapause resumption of spermatogenesis is thus a complex process in which meiosis-blocking and meiosis-deblocking factors, ecdysteroids, and the ASIF play regulative roles.     

Significance of peristaltic squeezing of sperm bundles in the silkworm, Bombyx mori: elimination of irregular eupyrene sperm nuclei of the triploid

Silkworm (Lepidoptera) males produce dimorphic sperm: nucleate eupyrene sperm and anucleate apyrene sperm. The eupyrene sperm are ordinary sperm to fertilise the eggs, while the function of apyrene sperm remains uncertain. After meiosis, 256 sperm cells are enclosed by a layer of cyst cells, forming a sperm bundle. We have previously documented that the nucleus of eupyrene sperm anchors to the head cyst cell, which locates at the anterior apex of the bundle, by an acrosome tubule-basal body assembly. Neither the basal body attachment to the nucleus nor the acrosome is seen in apyrene sperm, and the nuclei remain in the middle region of the bundle. Peristaltic squeezing starts from the anterior of the bundles in both types of sperm, and cytoplasmic debris of the eupyrene sperm, and both the nuclei and debris of apyrene sperm, are eliminated at the final stage of spermatogenesis. Since the irregularity of meiotic division in apyrene sperm is known, we used triploid silkworm males that show irregular meiotic division even in eupyrene spermatocytes and are highly sterile. The irregular nuclei of the triploid are discarded by the peristaltic squeezing just as those of the apyrene sperm. Transmission electron microscopic observations disclose the abnormality in the acrosome tubule and in the connection to the basal body. The peristaltic squeezing of sperm bundles in the silkworm appears to be the final control mechanism to eliminate irregular nuclei before they enter female reproductive organs.     

Germ cell death in the testis and its relation to spermatogenesis in the wax moth, Galleria mellonella (Lepidoptera: Pyralidae), effects of facultative diapause

The dichotomous spermatogenesis of many Lepidopterans results in the production of two types of sperm: eupyrene sperm possessing a cell nucleus which participates in fertilisation, and apyrene ones, which lose their nuclei during development and whose function remains a mystery. The goal of our study was to analyse spermatogenesis at the end of the larval development of the wax moth, Galleria mellonella, at an optimal temperature of 30 degrees C as well as to describe how they are affected by diapause brought on by a reduction of temperature to 18 degrees C. Spermatogenesis in non-diapausing insects did not differ significantly from that described in other species of Lepidoptera, and any differences found were compared against available literature. Based on the results presented, it may be unequivocally stated that changes in spermatogenesis occur in diapause caused by a suboptimal temperature of 18 degrees C. The main effect of diapause observed in the testes is the degeneration of germ cells, immediately following their differentiation from bipotential spermatocytes. Eupyrene cells seem to reach a more advanced stage of development. Due to the absence of secondary eupyrene spermatocytes in the testis of diapausing insects, it may be surmised that the meiotic divisions, which lead to the formation of secondary spermatocytes and eventually spermatids, do not occur, or are somehow altered. Lastly, terminal deoxynucleotidyl transferase (TdT)-mediated dUTP nick-end labelling (TUNEL) analyses we performed show that the degenerative changes of eupyrene cells are apoptotic in character.     

Peristaltic squeezing of sperm bundles at the late stage of spermatogenesis in the silkworm, Bombyx mori

Silkworm (Lepidoptera) males produce dimorphic sperm, nucleate eupyrene sperm, and anucleate apyrene sperm. The eupyrene sperm is the ordinary sperm fertilizing eggs, while the function of the apyrene sperm, which are about four times as numerous as the eupyrene sperm, is still uncertain. We found the peristaltic phenomenon at the very late stage of spermatogenesis. Peristalsis occurs in both eupyrene and apyrene sperm bundles. Through peristaltic action, cytoplasm of the eupyrene sperm and both cytoplasm and nuclei of the apyrene sperm are discarded from the posterior end of the sperm bundles. Peristaltic squeezing seems to be a process to eliminate the irregular nuclei of apyrene sperm while preserving the nuclei of eupyrene sperm.     

THE EUPYRENE-APYRENE DICHOTOMOUS SPERMATOGENESIS OF LEPIDOPTERA. ORGAN CULTURE STUDY ON THE TIMING OF APYRENE COMMITMENT IN THE CODLING MOTH

Lepidopteran spermatogenesis is dichotomous, producing eupyrene (nucleated) and apyrene (anucleated) spermatozoa. The eupyrene precedes the apyrene spermatogenesis. The timing of the switchover from eupyrene to apyrene spermatogenesis was determined by cultivating testes of accurately aged codling moth larvae in a medium containing mammalian serum but neither hemolymph nor insect hormones. In cultures, eupyrene spermatogenesis occurred in testes dissected from either 4th or 5th instar larvae, probably due to macromolecular factor-like activity of the serum of the medium. But apyrene spermatogenesis occurred only in testes explanted during or after the fourth day of the 5th instar larva. It is concluded that: (1) An apyrene spermatogenesis inducing factor (ASIF) becomes active on the fourth day of the 5th instar larva in addition to the already existing macromolecular factor. (2) Primary spermatocytes can develop into either eupyrene or apyrene spermatozoa. (3) The apyrene spermatogenesis commitment and pupal commitment of other tissues coincide about the fourth day of the 5th instar larva.     

Behavior of mitochondria during eupyrene and apyrene spermatogenesis in the silkworm,Bombyx mori (Lepidoptera), investigated by fluorescence in situ hybridization and electron microscopy

Summary Changes in the morphology and quantity of mitochondria and mitochondrial DNA during eupyrene and apyrene spermatogenesis in the silkworm were examined by electron microscopy and by fluorescence in situ hybridization with a 2 kb silkworm mitochondrial DNA clone (pBmMtE2). In the eupyrene spermatogenesis, the spermatocytes at early prophase I contained only a small amount of cytoplasm and showed a rather faint signal. As the cells grew larger in the later prophase I, the signal grew stronger. In the eupyrene spermatids, an especially strong signal was evident in the nebenkerns, in which all the cell's mitochondria were aggregated, and the strong fluorescence was maintained in mitochondrial derivatives. On the other hand, the apyrene cells were markedly smaller throughout spermatogenesis, showing much fainter signals for mitochondrial DNA than the eupyrene. Electron microscopy disclosed considerable differences in the behavior of mitochondria between the apýrene and the eupyrene cells. The observed qualitative and/or quantitative differences in the mitochondria may have some physiological bearing on the spermatogenesis of the two types of sperm.Abbreviations FISH fluorescence in situ hybridization - FITC fluorescein isothiocyanate - kb kilo base pair - PI propidium iodide - PBS phosphate-buffered saline     

Cytology of lepidoptera. III. Giant cysts: A morphological trait of apyrene spermatogenesis in an Ephestia kuehniella strain

A comparative investigation of testicular eupyrene cysts (in larvae) and apyrene cysts (in pupae) of Ephestia kuehniella laboratory strains was conducted using light and electron microscopy. Eupyrene cysts in the first meiotic division contained 64 spermatocytes, which showed only moderate asynchrony. In one of the strains, a wild-type strain, L, normal-sized cysts occurred together with abnormally large cysts. These are called giant cysts in this article. One of the premeiotic cysts, early giant cysts, studied in detail, contained approximately a fourfold number of cells compared with the number in a eupyrene cyst of the same stage. In cysts harboring spermatocytes and spermatids, late giant cysts, cell differentiation was highly asynchronous. Failure in one of two control mechanisms in early cyst development may have caused the appearance of the cysts. Control of cell division might have been sloppy in apyrene spermatogonia. Hence, the spermatogonia within the cyst could have passed through additional division cycles. Alternatively, the giant cysts may have originated from more than one predefinitive gonial cell enclosed in a common envelope of sheath cells. As a third possibility, giant cysts could have arisen by fusion of normal cysts at a later stage. In either case, this is evidence that separation of eupyrene and apyrene pathways is earlier than was previously expected. In two other Ephestia strains, apyrene sperm development proceeded without formation of giant cysts. One was a mutant strain, a, and the other one was a recently established wild-type strain, Sbr. Apyrene sperm development is considered an example of degenerate evolution in which enhanced variability between species and even between populations of one species is a common phenomenon.     

In vitro cultivation of spermatocysts to matured sperm in the silkworm Bombyx mori

Bombyx spermatogonia are bipotential, producing nucleate eupyrene sperm and anucleate apyrene sperm. An in vitro cultivation of spermatocysts of Bombyx mori from spermatocytes to matured sperm was established. The present experiment made clear that: (i) spermatocysts must be isolated; (ii) constant shaking at 45 r.p.m. was necessary; and (iii) the addition of Bombyx hemolymph (BH) was indispensable for successful cultivation. In the absence of BH, spermatogenesis proceeded normally for 2 or 3 days and, thereafter, spermatocytes and sperm bundles began to degenerate. The best results for normal eupyrene spermatogenesis were obtained when culture medium containing BH of the corresponding stage was used in every exchange of the medium at 72 h intervals. None or only a small number of apyrene sperm bundles was produced by this culture system when spermatocysts from larval testes were used, although eupyrene spermatogenesis proceeded normally to form matured, or squeezed, sperm bundles.     

Glucose and ecdysteroid increase apyrene sperm production in in vitro cultivation of spermatocysts of Bombyx mori

Two types of sperm, nucleate eupyrene and anucleate apyrene, occur in the silkworm as in other lepidopteran species. Hormones and other substances have been assumed to play important roles in sperm dimorphism. We established an in vitro cultivation system for silkworm spermatocytes, and found that apyrene sperm are not produced when spermatocytes from larval testes are cultivated, though eupyrene spermatocytes develop normally into mature sperm. Based on the fact that ecdysteroid titers increase rapidly and peak 1 day after spinning, and that the amount of glycogen reaches its peak 1 day before the spinning stage, we studied the effects of adding glucose and/or 20-hydroxyecdysone to the culture medium. The experiments disclosed a significant additive effect of both substances on apyrene sperm production.     

Application of artificial insemination technique to eupyrene and/or apyrene sperm in Bombyx mori

The silkworm, Bombyx mori, has a dimorphic sperm system. The eupyrene sperm is the sperm to fertilize eggs and the apyrene sperm plays a crucial role for assisting fertilization. Heat-treated (33 degrees C for 96h) Daizo (DH) males, one of the strains in the silkworm, produce only eupyrene sperm, while in triploid males only apyrene sperm are functional. Though both types of males are found to be sterile, double copulation of the two males with a single female greatly increases fertility. Here we examined the fertilizing ability of eupyrene and apyrene sperm by means of an artificial insemination technique previously established in B. mori. Neither the eupyrene sperm collected from DH males, nor the apyrene sperm from triploid males have the ability to fertilize eggs. Artificial insemination with the mixture of eupyrene and apyrene sperm leveled up the frequency of fertilized eggs to more than 80%. When cryopreserved DH sperm (eupyrene sperm) were subjected to the same experiment, more than 95% fertilized eggs were obtained. These results confirmed that apyrene sperm play an important and indispensable role in fertilization in B. mori. Separate collection of functional eupyrene sperm and functional apyrene sperm and success of fertilization by means of the artificial insemination technique are applicable for further studies to elucidate the function of apyrene sperm.     

Behavior of centrioles during meiosis in the male silkworm, Bombyx mori (Lepidoptera)

The behavior of centrioles during eupyrene and apyrene meiosis was examined in the silkworm, Bombyx mori , by transmission electron microscopy and indirect immunofluorescence for tubulin. In eupyrene spermatocytes the centrioles, accompanied by axonemes, attached temporarily to the nucleus at diplotene, then detached from the nucleus in diakinesis. After the separation, a beret-shaped structure consisting of a double membrane covered the proximal region of the pair of centrioles. The structure disappeared after breakdown of the nuclear membrane. The centriole, with the axoneme, reattached to the nucleus at telophase I. The process was repeated during meiosis II until the centrioles maintained their nuclear attachment in newly developed spermatids. In stark contrast to their eupyrene counterparts, apyrene spermatocytes were conspicuously devoid of any attachment of the centrioles to the nucleus. These eupyrene-specific and apyrene-specific relationships were consistently and repeatedly found between the nuclear membrane and centrioles, giving rise to suspicion that the behavioral phenomena may be related to differentiation of the dimorphic sperm types.     

The structural mechanism of trypsin-induced intrinsic motility in Manduca sexta spermatozoa in vitro

Lepidopteran males produce eupyrene (nucleate) and apyrene (anucleate) spermatozoa, but in the female only eupyrene spermatozoa leave the spermatheca and fertilize the eggs. Both kinds of spermatozoa lack intrinsic motility in the male genital duct. They become motile in the spermatophore, in a process involving proteases from the male duct. In vitro, trypsin induces immotile spermatozoa to become motile. We studied the changes spermatozoa of Manduca sexta undergo during trypsin-induced motility and found that (a) they mimick rather closely those occurring in vivo during normal sperm maturation in genital ducts and (b) they are time- and dose-dependent. As in vivo, they comprise, successively, (a) disappearance of an extracellular matrix that maintains the integrity of eupyrene bundles in the seminal vesicle, (b) dispersion of the eupyrene bundles and intermingling of eupyrene and apyrene spermatozoa and (c) "hatching" of eupyrene spermatozoa from individual enclosing envelopes that are formed in the seminal vesicle. "Hatching" may not directly be related to motility since eupyrene spermatozoa become motile before "hatching" and motile apyrene spermatozoa never "hatch". Rather "hatching" may be related to the capacitation of eupyrene spermatozoa to either leave the spermatheca or fertilize the eggs, or both, as neither apyrene spermatozoa, nor those eupyrene spermatozoa that fail to "hatch", leave the spermatheca.     

Immunocytochemical localization of tubulins in spermatids and spermatozoa of Euptoieta hegesia (Lepidoptera: Nymphalidae)

A comparative analysis of the distribution of tubulin types in apyrene and eupyrene sperm of Euptoieta hegesia butterflies was carried out, also verifying the presence of tubulin in lacinate appendages of the eupyrene sperm. Ultrathin sections of LR White embedded spermatids and spermatozoa were labeled for alpha, beta, gamma, alpha-acetylated and alpha-tyrosinated tubulins. Apyrene and eupyrene spermatids show the same antibody recognition pattern for tubulins. All tubulin types were detected in axonemal microtubules. Alpha and gamma tubulins were also detected on the cytoplasmic microtubules. However, for beta and tyrosinated tubulins only scattered labeling was detected on cytoplasmic microtubules and acetylated tubulin was not detected. In apyrene and eupyrene spermatozoa only the axoneme labeling was analyzed since cytoplasmic microtubules no longer exist in these cells. Alpha, beta and tyrosinated tubulins were easily detected on the apyrene and eupyrene axoneme; gamma tubulin was strongly marked on eupyrene axonemes but was scattered on the apyrene ones. Acetylated tubulin appeared with scattered labeling on the axoneme of both sperm types. Our results demonstrate significant differences in tubulin distribution in apyrene and eupyrene axonemal and cytoplasmic microtubules. Extracellular structures, especially the lacinate appendages, were not labeled by antibodies for any tubulin.     

Double copulation of a female with sterile diploid and polyploid males recovers fertility in Bombyx mori

Silkworm males produce dimorphic sperm, nucleate eupyrene sperm and anucleate apyrene sperm. Apyrene sperm have been speculated to have an assisting role in fertilisation. However, the coexistence of eupyrene and apyrene sperm in the testis and female reproductive organs has made it difficult to define the role of apyrene sperm. Polyploid males are highly sterile. Microscopic observation revealed that the elimination of eupyrene nuclei by peristaltic squeezing caused the sterility of polyploids. Heat-shock applied to pupae of Daizo males (DH) also induced high sterility due to the lack of normal apyrene sperm. When eupyrene sperm of sterile DH males and apyrene sperm of sterile polyploid males were mixed by double copulation, a remarkable increase in fertility of the double-mated females was observed. This finding strongly suggests that the apyrene sperm are indispensable in fertilisation of the silkworm and that polyploid apyrene sperm function as a substitute for diploid sperm. We established an experimental system in which we can separate the two types of sperm for further studies on their functions without chemical and/or mechanical treatments.     

Dynamics of eupyrene and apyrene sperm storage in ovipositing females of the swallowtail butterfly Papilio xuthus (Lepidoptera: Papilionidae)

A male swallowtail butterfly, Papilio xuthus, transfers both eupyrene and apyrene sperm during copulation, both of which migrate to the spermatheca via the spermatophore in the bursa copulatrix of the female. Because the spermatheca seems to remain constant in size during the female lifespan, the excess sperm migration may cause the spermatheca to overflow. Approximately 9000 eupyrene and 265 000 apyrene spermatozoa were transferred during a single copulation, and approximately 1000 eupyrene and 1100 apyrene spermatozoa successfully arrived in the spermatheca. The number of both types of spermatozoon decreased in the spermatheca after the onset of oviposition, and no eupyrene spermatozoa were found by 7 days after copulation, partly due to insemination. The spermathecal gland leading from the distal end of the spermatheca was gradually filled by eupyrene spermatozoa. Although the function of the gland remains unclear, the final destination of the sperm is likely to be the gland.