Involvement of the gonadal germinal epithelium during sex reversal and seasonal testicular cycling in the protogynous swamp eel,Synbranchus marmoratus Bloch 1795 (Teleostei,Synbranchidae)

The swamp eel, Synbranchus marmoratus, is a protogynous, diandric species. During sex reversal, the ovarian germinal epithelium, which forms follicles containing an oocyte and encompassing follicle cells during the female portion of the life cycle, produces numerous invaginations, or acini, into the ovarian stroma. Within the acini, the gonia that formerly produced oocytes become spermatogonia, enter meiosis, and produce sperm. The acini are bounded by the basement membrane of the germinal epithelium. Epithelial cells of the female germinal epithelium, which formerly became follicle (granulosa) cells, now become Sertoli cells in the developing testis. Subsequently, lobules and testicular ducts form. The swamp eel testis has a lobular germinal compartment in both primary and secondary males, although the germinal compartment in testes of secondary males resides within the former ovarian lamellae. The germinal compartment, supported by a basement membrane, is composed of Sertoli and germ cells that give rise to sperm. Histological and immunohistochemical techniques were used to describe the five reproductive classes that were observed to occur during the annual reproductive cycle: regressed, early maturation, mid-maturation, late maturation, and regression. These classes are differentiated by the presence of continuous or discontinuous germinal epithelia and by the types of germ cells present. Synbranchus marmoratus has a permanent germinal epithelium. Differences between the germinal compartment of the testes of primary and secondary males were not observed.     

Annual changes in germinal epithelium determine male reproductive classes of the cobia

Five reproductive classes of cobia Rachycentron canadum , caught along the Gulf of Mexico and the south-east Atlantic coast of the U.S.A., are described during the annual reproductive cycle. These are based upon changes in the testicular germinal epithelium and the stages of germ cells that are present: early maturation, mid maturation, late maturation, regression and regressed. During early maturation, the germinal epithelium is continuous from the testicular ducts to the periphery of the testis and active spermatogenesis occurs throughout the testis. In mid maturation, the germinal epithelium near the ducts becomes discontinuous, but it remains continuous distally. In late maturation, a discontinuous germinal epithelium extends all along the lobules to the testicular periphery; lobules are swollen with sperm and there is minimal spermatogenesis. The regression class is characterized by a discontinuous epithelium throughout the testis, sperm storage and widely scattered spermatocysts. Spermatogonial proliferation also occurs along the lobule walls and at the periphery of the testis. In regressed testes, spermatogonia exist only in a continuous or discontinuous germinal epithelium, although residual sperm are nearly always present in the lobules and ducts. The presence or absence of sperm is not an accurate indicator of reproductive classes. At the periphery of the testis in the regression and regressed classes, the distal portions of lobules elongate as cords of cells containing spermatogonia and Sertoli cells. All reproductive classes can be identified in paraffin sections, although plastic sections provide better resolution. Using maturation classes defined by changes in the germinal epithelium to describe testicular development and spermatogenesis gives a more accurate picture than does using the traditional terminology.     

The reproductive cycle of male catfish Pseudoplatystoma fasciatum (Teleostei, Pimelodidae) revealed by changes of the germinal epithelium. An approach addressed to aquaculture

The aims of the present study were to analyze the gonadal structure of Pseudoplatystoma fasciatum males during their annual cycle to enhance understanding of their reproductive biology and to improve the hormonally induced reproduction and culture of this species in hatcheries. We adopted the recently proposed method that establishes reproductive classes that are based on variations of the germinal epithelium within the year. Five reproductive classes were established: maturation (early, middle, and late), regression and recrudescence. Our observations revealed that in the spawning season P. fasciatum testes display two main functions: sperm production and sperm storage. We also concluded that the analysis of the variation of germinal epithelium was satisfactory when applied to this freshwater catfish and should be adopted for other fish species.     

Evolution and phylogeny of gonad morphology in bony fishes

Gonad morphology at the gross anatomical or histological levelshas long been studied by fisheries biologists to identify annualreproductive cycles and length of breeding season, among othergoals. Comparative surveys across vertebrate taxa have not beendetailed enough, however, to describe fully the differencesand similarities among gonads of bony fishes and other vertebrates,and to use gonad morphology in phylogenetic systematic analyses.An emerging constant among vertebrates is the presence of agerminal epithelium composed of somatic and germ cells in bothmales and females. In females, the germinal epithelium linesthe ovarian lamellae. In males, arrangement of the germinalepithelium into compartments varies among osteichthyans: basaltaxa have an anastomosing tubular testis, whereas derived taxahave a lobular testis. The lobular testis is proposed as a synapomorphyof the Neoteleostei. The annual reproductive cycle is hypothesizedto be the source of morphological variation among testis types.Elongation of germinal compartments during early maturationmay result in a transition from anastomosing tubular to lobulartestes. In all male atherinomorphs surveyed, spermatogonia arerestricted to the distal termini of lobules rather than beingdistributed along the lobule; there is an epithelioid arrangementof Sertoli and germ cells rather than a germinal epithelium.Arrest of the maturation-regression phases is hypothesized tolead to formation of the atherinomorph testis. Atherinomorphsalso have a distinctive egg with fluid, rather than granular,yolk. Variation among germinal epithelia is interpreted in adeveloping phylogenetic framework to understand evolution ofgonad morphology and to propose gonad characters for phylogeneticanalyses.     

Sexual maturation and seasonal changes in reproductive phenomena of male Japanese monkeys (Macaca fuscata) at Takasakiyama

The authors examined testis tissues and blood which were collected from free-ranging Japanese monkeys of the Takasakiyama troop during four periods in 1971 (mating season: late January-early February; early birth season: June; late birth season: August; and intermediate season between birth season and mating season: October), and studied their sexual maturation and seasonal changes in reproductive phenomena. Results of observations on the testis and plasma testosterone concentration were in agreement with each other. Except in a few cases, the testis was infantile until October at 4 years old and developed rapidly during the following two months, and spermatogenesis started in the mating season at 4 years old (in exceptional cases, it started one year earlier). After the following two-year process of sexual maturation, monkeys attained full maturation in the mating season at 6 years old. For seasonal changes in reproductive phenomena also, results of observations on the testis and the plasma testosterone were in agreement with each other. Activity of the testis repeated an annual cycle of being maximal in the mating season, regressing in the birth season, and redeveloping toward the following mating season. Such seasonal changes were noticeably observed with 4- to 6-year-old animals, which are in the process of sexual maturation.     

Ontogenetic testicular development and spermatogenesis in rays: the Cownose Ray,Rhinoptera bonasus,as a model

An understanding of testicular anatomy, development, and seasonality has implications for studies of morphology, behavior, physiology, and bioenergetics of males. Ontogenetic testicular development and spermatogenesis is essentially unknown for chondrichthyans. We examined embryo, juvenile, and adult male Cownose Rays (Rhinoptera bonasus) during development and throughout the annual reproductive cycle. Spermatogonia and Sertoli cells originated from germ cells and somatic cells, respectively, in the embryonic testicular germinal epithelium. In embryos and small juveniles, discrete regions of spermatocyst production appeared within a series of papillae that projected from the dorsal surface of each testis. Because these papillary germinal zones appeared to proliferate through ontogeny, we hypothesize that (1) the germinal zones of juvenile and adult testes are derived from embryonic testicular papillae that form from the germinal epithelium and (2) the papillae become the dorso-central portion of the distinct testicular lobes that form at maturation due to increased spermatocyst production. Our observations indicate that testicular development and the process of spermatogenesis began during embryonic development and increased in scale through ontogeny until maturation, when distinct testicular lobes formed and began enlarging or shrinking based on the annual reproductive cycle. Gonadosomatic indices peaked corresponding to seasonal increased sperm production between January and April, just prior to the April–June mating period. In all life stages, spermatocysts had efferent ducts associated with them from their formation through all stages of development. Year-round presence in the Charlotte Harbor estuarine system, Florida made R. bonasus a good model for beginning to understand ontogenetic gonad development and spermatogenesis in chondrichthyans, especially viviparous rays.     

Ovarian maturation and oogenesis in the blue swimmer crab,Portunus pelagicus (Decapoda: Portunidae)

The study was aimed at understanding the process of reproduction and the changes happening in the ovary of Portunus pelagicus during maturation, which would be useful for its broodstock development for hatchery purposes. For that, tissue samples from different regions of the ovary at various stages of maturation were subjected to light and electron microscopy, and based on the changes revealed and the differences in ovarian morphology, the ovary was divided into five stages such as immature (previtellogenic oocytes), early maturing (early vitellogenic oocytes), late maturing (late vitellogenic oocytes), mature (vitellogenic oocytes), and spent (resorbing oocytes). The ovarian wall comprised of an outermost thin pavement epithelium, a middle layer of connective tissue, and an innermost layer of germinal epithelium. The oocytes matured as they moved from the centrally placed germinal zone toward the ovarian wall. The peripheral arrangement of nucleolar materials and the high incidence of cell organelles during the initial stages indicated vitellogenesis I. Movement of follicle cells toward oocytes in the early maturing stage and low incidence of mitochondria and endoplasmic reticulum in the ooplasm during late vitellogenic stage marked the commencement and end of vitellogenesis II, respectively. Yolk granules at various stages of development were seen in the ooplasm from late vitellogenic stage onwards. The spent ovary had an area with resorbing oocytes and empty follicle cells denoting the end of one reproductive cycle and another area with oogonial cells and previtellogenic oocytes indicating the beginning of the next.     

Testicular structure and spawning cycle in the silvery croaker, <Emphasis Type="Italic">Otolithes ruber</Emphasis> (Perciformes: Sciaenidae) in the Kuwaiti waters of the Arabian Gulf

The structure of the testes and maturity stages in the male silvery croaker, Otolithes ruber were investigated from March 1999 to March 2000. Based on the location of spermatogonia within the germinal epithelium, the testis structure is classified as the unrestricted spermatogonial testicular type. Germ cells proliferate through mitotic divisions of spermatogonia, giving rise to primary and secondary spermatocytes, which through meiotic divisions transform into spermatids. As spermatogenesis progresses, an elongation of the testicular lobules takes place. During final spermiogenesis, spermatids are arranged in clusters, with heads in one direction and tails in the opposite. Spermatozoa are then liberated from these structures into the lobula lumina. The testicular lobules further elongate, and many of them form a continuum within the germinal epithelium, extending toward the periphery. The walls of the other lobules fuse, producing anastomosing sperm-filled lobular compartments. A main sperm duct is formed into which spermatozoa from the lobules are voided. A time lapse between sexual maturity and onset of spawning was observed, thus supporting the existing view that the anastomosing compartments are used for sperm storage during the latter part of the maturation process. Six maturity stages of the testis are delineated during the annual reproductive cycle based on macroscopic and histological characteristics. Results show that male O. ruber spawns from March through April in Kuwaiti waters.     

Accumulation cyclique de fer et de quelques autres éléments dans le testicule de Littorina littorea (L.) (Gastéropode Prosobranche)

Iron, the presence of which can be revealed by histochemical techniques and microanalysis X, accumulates in the testis of Littorina littorea (L.). Its accumulation varies in relation to the annual cycle. The highest concentration occurs during the involution period (late summer) and is lowest during gametogenesis (early winter). Besides iron, S, P, Ca, Cl and sometimes Mg and F are found. These elements are contained in lysosomes of “epithelial cells” which develop in the testis following the reproductive stage.     

Locale and level of bindin mRNA in maturing testis of the sea urchin, Strongylocentrotus purpuratus

This first study of the onset of spermatogenesis in the sea urchin, Strongylocentrotus purpuratus, was undertaken using individuals reared in the laboratory. Spermatogenesis commences about 11-12 months after metamorphosis in these animals. Bindin message accumulates in late spermatocytes and early spermatids which lie in the luminal germinal layer. Bindin message accumulates later than does the testis-specific histone, H2b-1, suggesting that different classes of genes are sequentially activated during the differentiation of sperm. We correlate the number of bindin mRNA molecules with morphological structure and with quantitative aspects of gonad maturation including the number of nuclei and of sperm. The results suggest that the bindin mRNA concentration in total RNA from testis at different stages of maturation reflects the change in the proportion of expressing cells in the total cell population of the testis.     

Proliferation of Oogonia and folliculogenesis in the viviparous teleost Ilyodon whitei (Goodeidae)

Oogonial proliferation in fishes is an essential reproductive strategy to generate new ovarian follicles and is the basis for unlimited oogenesis. The reproductive cycle in viviparous teleosts, besides oogenesis, involves development of embryos inside the ovary, that is, intraovarian gestation. Oogonia are located in the germinal epithelium of the ovary. The germinal epithelium is the surface of ovarian lamellae and, therefore, borders the ovarian lumen. However, activity and seasonality of the germinal epithelium have not been described in any viviparous teleost species regarding oogonial proliferation and folliculogenesis. The goal of this study is to identify the histological features of oogonial proliferation and folliculogenesis during the reproductive cycle of the viviparous goodeid Ilyodon whitei. Ovaries during nongestation and early and late gestation were analyzed. Oogonial proliferation and folliculogenesis in I. whitei, where intraovarian gestation follows the maturation and fertilization of oocytes, do not correspond to the late oogenesis, as was observed in oviparous species, but correspond to late gestation. This observation offers an example of ovarian physiology correlated with viviparous reproduction and provides elements for understanding the regulation of the initiation of processes that ultimately result in the origin of the next generation. These processes include oogonia proliferation and development of the next batch of germ cells into the complex process of intraovarian gestation. J. Morphol. 275:1004–1015, 2014. © 2014 Wiley Periodicals, Inc.     

Reproductive cycles in a reared strain of the mummichog, a daily spawner

Annual, lunar, and diel samplings were taken from a strain of mummichog (Arasaki strain) reared in outdoor tanks under natural conditions, to examine gonadal maturity. Gonads of yearling fish were quite immature in September. During late autumn and winter, a gradual increase in the GSI of both sexes was observed, and the growth of cortical alveolus phase oocytes in females and basal spermatogenesis in males progressed. In late February, a rapid increase in the GSI of both sexes, vitellogenesis in females, and active spermatogenesis in males, occurred. The spawning period of the yearling fish was from late March to August judging from the presence of milt-producing males and ovulated females. The spawning period of the underyearling fish started in the same month as the yearlings, but terminated 1 month earlier. Plasma levels of oestradiol-17 β (E₂) in females and testosterone in males were high during the spawning period in the yearlings. In the underyearlings, however, E₂ levels peaked in early spring, and declined in the latter part of the spawning period. Neither a lunar nor semilunar cycle was evident in the reproductive activity of this fish, which proved to be a typical daily spawner. Females showed an apparent daily reproductive cycle; oocyte maturation commenced at about 1200 hours, germinal vesicle breakdown (GVBD) occurred at about 2400 hours, and ovulation was completed by 2400 hours, 24 h after GVBD. Such clear annual and daily reproductive cycles make this strain of mummichog a suitable model for the study of environmental and endocrine regulation of reproductive cycles in marine and estuarine teleosts.     

Annual changes in testicular development and plasma sex steroids in the captive male dojo loach <Emphasis Type="Italic">Misgurnus anguillicaudatus</Emphasis>

Testicular development in the captive male dojo loach Misgurnus anguillicaudatus was examined monthly in relation to the levels of plasma sex steroids [testosterone (T), 11-ketotestostrone (11-KT), and 17,20β-dihydroxy-4-pregnen-3-one (DHP)]. On the basis of testicular histology, the annual gonadal cycle was found to be divisible into 3 periods: the recovery and proliferation period, which mainly consists of early spermatogenic testis from August to November (reproductive phase I); the preparation period for the next spawning period, which mainly consists of late spermatogenic testis from December to April (reproductive phase II); and the mature period, characterized by a high proportion of mature testis from May to July (reproductive phase III). Individual variability in testicular development was high, and continuous spermatogenesis was observed throughout the year. High levels of plasma T, 11-KT, and DHP were observed during reproductive phase III. 11-KT began to increase in February, while T was present at low levels in reproductive phase II. These results suggest that the physiologically active season of testis development for breeding in the dojo loach is from May to July, although spermatogenesis occurs throughout the year.     

Studies on the annual reproductive cycle of the female cobra,Naja naja. IV. OVARIAN HISTOLOGY

Morphological changes of the ovary of the Chinese cobra, Naja naja, throughout the annual reproductive cycle are described. A single clutch of between 6 and 22 eggs is produced in late June. From July to the following April the ovary remains quiescent and contains small previtellogenic, hydration stage follicles. The growth of an ovarian follicle from a primary oocyte to maturation and ovulation is estimated to take three years. The histology of the germinal epithelium and the follicular granulosa shows seasonal changes correlated with the growth of the oocyte. During the quiescent period, the germinal epithelium lacks mitotic activity, but during April, when yolk deposition and rapid growth of the preovulatory follicles take place, the germinal epithelium shows intense mitotic activity. The growth of the smallest hydration stage follicles, and the occurrence of cytoplasmic bridges between the pyriform cells of the granulosa and the developing oocyte, also appear to increase during this period. The possible function of the pyriform cell is discussed and the literature on the origin and fate of these cells in the squamate ovary is reviewed. Postovulatory follicles (corpora lutea) and two types of atresia are described and compared with what is known of these structures in other reptiles.     

Cytological evaluation of spermatogenesis within the germinal epithelium of the male European wall lizard, Podarcis muralis

The annual cytological changes to the male germinal epithelium were investigated in an introduced population of European wall lizards (Podarcis muralis). Testicular tissues were collected, embedded, sectioned by an ultramicrotome, and stained with the PAS procedure followed by a toluidine counterstain. Spermatogenesis in the lizard is divided into the proliferative, meiotic, and maturational phases. Wall lizards have a prenuptial pattern of spermatogenesis, where sperm development begins immediately prior to and continues through the months of breeding (April-June). The testis then involutes, undergoes a short period of quiescence, and recrudescence commences in mid-July. Germ cells undergo proliferation, meiosis, and the early stages of spermiogenesis (maturation) from late July through December. However, the late stages of spermiogenesis are retarded from December through February. Spermiogenesis continues at an accelerated pace from March through May, leading to a single massive spermiation event through the month of June. Although spatial relationships are seen between germ cells within the seminiferous epithelium, accumulation of spermatids during winter and acceleration of elongation in spring prevents determination of consistent cellular associations between early and late developing germ cells within the wall lizard testis. This temporal germ cell development is different from the consistent spatial development seen within seasonally breeding birds and mammals and may represent an evolutionary intermediate in terms of amniotic germ cell development.     

Photoperiodic regulation of annual testicular events in the Indian major carp Catla catla

The importance of photoperiods in the regulation of annual testicular events in the carp Catla catla was evaluated by subjecting them to either long (16 h light : 8 h dark) or short (8 h light : 16 h dark) photoperiods for 30 days during the preparatory, prespawning, spawning and postspawning phases of an annual gonadal cycle. In each reproductive phase, testicular responsiveness to subjected photoperiods was determined by comparing the gonadal status in corresponding groups of control or natural photoperiodic fish. The values of testicular weight, gametogenic index, as well as testicular activity of two steroidogenic enzymes (Δ⁵3β‐, and 17β‐hydroxysteroid dehydrogenase), and the serum titre of testosterone were considered as the indices of functional status of the testis in the fish concerned. During the prespawning phase, exposure of fish to a daily long photoperiod schedule resulted in precocious maturation of testis, while retardation of testicular growth was noted under the influences of short photoperiod. However, none of the employed photo‐schedules could influence the gametogenic and steroidogenic functions of the testis in the remaining part of the gonadal cycle. Collectively, the present study provides evidence for the first time that in the case of a commercially important carp, Catla catla, artificial, long photoperiods may be used for advanced testicular maturation, while reductions in maturation‐associated growth and deterioration in flesh quality may be avoided by submitting the fish to shorter day lengths during the prespawning phase of the reproductive cycle.     

Structural characteristics of gonadal development and hermaphroditic phenomenon in freshwater pearl mussel,Sinohyriopisis schlegelii (Hyriopisis schlegelii)

The period of gonads development was first studied from one to five years in the freshwater pearl mussel Hyriopisis schlegelii. It lasted for 36 months and was divided into three main stages: initiation of gonad formation, a stable growth phase, and a reproductive cell development phase. Each reproductive cycle consisted of five stages: proliferative stage (from late January to late February), growth stage (from late February to late March), maturation stage, spawning stage (from early April to late October) and recovery stage (from early November to late January). Interestingly, a hermaphroditic phenomenon was observed in this mussel for the first time, which appears during the development stage from 26 to 32 months. Male and female follicular tissues coexisted in hermaphrodite individuals with the male follicular tissue accounting for more than 90% of the whole gonad tissue. No hermaphroditic phenomenon was observed in matured gonad. We thus speculate that self-fertilization does not exist in H. schlegelii.     

Morphofunctional changes of female germinal epithelium to support spermatozoa along the annual reproductive cycle in an inseminating catfish (Trachelyopterus galeatus,Auchenipteridae)

The reproductive system of some fish species presents elaborate mechanisms by which the females store spermatozoa inside their ovaries, keeping them viable for fertilization for an extended period of time. However, as intriguing as this sperm storage is, it is not yet understood how the sperm can remain viable in the ovary. Aiming to understand this phenomenon, the epithelium covering the ovarian lamellae, that is, the germinal epithelium, of the Cangati (Trachelyopterus galeatus), an inseminating catfish, was evaluated taking into account the different stages of the annual reproductive cycle. The germinal epithelium morphology changed during the annual reproductive cycle, presumably in preparation to receive the spermatozoa and keep them viable until fertilization. There was a progressive increase of the epithelium height. Also the number of intercellular junctions, desmosomes, and extended tight junctions, apparently increased forming chains that could be regarded as a barrier to isolate the sperm from the female immune system. Synthetic organelles were active releasing cytoplasmic granules and secretion in the epithelial enfolds in which the spermatozoa were deeply embedded. Concomitantly, oogonium nests were formed in the germinal epithelium during early folliculogenesis. J. Morphol. 275:65–75, 2014. © 2013 Wiley Periodicals, Inc.     

Changes in protein patterns in sperm and vas deferens during the daily rhythm of sperm release in the gypsy moth

In the gypsy moth, Lymantria dispar, the release of sperm bundles from the testis into the upper vas deferens (UVD) is precisely timed within each 24 h period by a circadian mechanism located in the reproductive system. In males kept under light:dark cycles of 16:8, release of sperm bundles is limited to the 3 h period that starts before lights off. Sperm released from the testis remains in the UVD for about 12 h and then moves into the seminal vesicles, so that the UVD stays empty until the next cycle of sperm release begins. The rhythm of release appears to play a role in the terminal stages of sperm maturation and is essential for the fertility of males. Sperm bundles undergo substantial morphological changes during the release from the testis and while they are retained in the UVD. In this study, using gel electrophoresis, we compared protein patterns in sperm and in the UVD during the daily cycle of sperm release and maturation. Several protein bands evident in the sperm bundles contained in the testis were missing from the sperm bundles that had passed from the testis into the UVD. Furthermore, a number of new proteins appeared in the sperm bundles as they remained in the UVD. Some of these proteins appeared to be secreted from the UVD epithelium into the UVD lumen before being incorporated into sperm bundles. Correlations between changes in protein patterns and ultrastructural changes in sperm during the cycle of sperm release and maturation are discussed. © 1994 Wiley-Liss, Inc.