Differentiation of steroid-producing cells and folliculogenesis in the developing ovary of the Nile tilapia Oreochromis niloticus

Differentiation and development of steroid-producing cells (SPCs) and folliculogenesis during ovarian differentiation in the Nile tilapia Oreochromis niloticus were immunohistochemically and ultrastructurally examined. Clusters of immunopositive cells (IPCs) against antibodies (ABs) of cholesterol side-chain cleavage cytochrome P450 (P450scc), 3β-hydroxysteroid dehydrogenase (3βHSD), and cytochrome P450aromatase (P450arom) only appeared in the area near blood vessels in the fish ovaries at 50-60 days after hatching (dah). Ultrastructural results showed that differentiation and development of SPCs from undifferentiated to maturation occurred in the area near blood vessels, indicating that it would be the original site of SPCs. At 70-80 dah, IPC clusters invaded the interstices among oocytes at the perinucleolar stage from the area near the blood vessels. IPCs increased in number in the interstices among the previtellogenic oocytes, and some clusters began to enclose the outer thecal layer of the previtellogenic oocytes at 90 dah. The process of folliculogenesis was ultrastructurally observed. SPCs enclosed by fibroblastic cells invaded the interstitial areas among oocytes and some reached the surfaces of oocytes. The upper portions of these elongations opened and began to enclose the outer surfaces of developed oocytes to become thecal layer. Later, newly migrated SPCs reach the thecal layer to become thecal cells. These results indicate that steroid-producing thecal cells originate from the SPCs in the area near blood vessels. After thecal layer formation, an immunopositive reaction against P450arom AB, but not against P450scc or 3β-HSD ABs, appeared first in the granulosa cells enclosing the vitellogenic oocytes at 100 dah. At this time, estrogen production in serum levels rapidly increased. Thus, folliculogenesis could be essential for active production of estrogen in the ovary.     

Stability in aromatase immunoreactivity of steroid-producing cells during early development of XX gonads of the Nile tilapia, Oreochromis niloticus: an organ culture study

The organ culture system is a useful tool to study the effects of various factors on the development of undifferentiated gonads. In this study, we first established an organ culture system for gonads of all genetic male and female Nile tilapia at 5-122 days after hatching (dah). This short-term (3 days) organ culture system was then used to examine the stability of the immunoreactivity of aromatase (the enzyme which converts androgen to estrogen, thus playing a crucial role in ovarian differentiation) in steroid-producing cells (SPCs). Immunohistochemical analyses revealed that aromatase-positive cells could be initially detected in the vicinity of blood vessels in the XX gonads at 7 dah. These SPCs completely lost their immunoreactivity after 3 days in culture, indicating the instability of SPCs during early ovarian differentiation. In contrast, the immunoreactivity of the SPCs was maintained to some extent even after 3 days in culture, if the gonads were from 15-23 dah. In XX gonads collected at 122 dah, there were two major populations of SPCs: one in the vicinity of the blood vessel and the other near the oocyte. The aromatase immunoreactivity was maintained in SPCs located around the oocytes, but not in those in the vicinity of the blood vessel, after 3 days in culture. These results suggest that the SPCs originate from the cells in the vicinity of the blood vessels prior to the initial ovarian differentiation in tilapia and that the degree of differentiation of SPCs is dependent on their location in the ovary.     

Ultrastructural analysis of the developing follicle during early vitellogenesis in tilapia,Oreochromis niloticus,with special reference to the steroid-producing cells

The development and distribution of steroid producing cells (SPCs) in the ovary of tilapia have been studied by light and electron microscopy. At 40–50 d after hatching, these cells are seen only in the vicinity of blood vessels; there are no SPCs in the interstitial region, nor in the thecal layer enclosing young oocytes at the peri-nucleolus stage. By 70–80 d after hatching, the number of SPCs in the area near blood vessels has increased, and the capillaries have spread among the developing peri-nucleolar stage oocytes, and into the ovarian tunica. Clusters of SPCs have also migrated into the interstitial region and into the tunica along with these capillaries. In the ovary 100 d after hatching, some SPCs can be found in the thecal layer enclosing vitellogenic oocytes. Moreover, masses of SPCs can now be observed infiltrating the thecal layer of the oocyte. Serum testosterone (T) and estradiol-17 (E2) levels at 40–70 d after hatching, are low (T, 0.75–1.10 ng/ml, E2, 0.36–1.08 ng/ml), but at 100 d, plasma E2, but not T, is elevated (T, 1.95 ng/ml, E2, 4.65 ng/ml). These results suggest that SPCs appearing in the vicinity of blood vessels move into the interstitial region between oocytes, and finally enclose the oocytes at an early vitellogenic stage. It is interesting to note that the enclosure of oocytes by SPCs coincides with significant increases in E2 production.     

Identification of Early Oogenetic Cells in the Solitary Ascidians, Ciona savignyi and Ciona intestinalis: An Immunoelectron Microscopic Study

We raised monoclonal antibodies against homogenates of ovaries of Ciona intestinalis . We obtained an antibody named GC-1 which specifically recognized early germ cells in C. intestinalis and C. savignyi . Using GC-1 as a marker in immunoelectron microscopy, we determined the morphological sequence of early oogenesis in the ovaries of Ciona . In the stratified epithelium composing the wall of the ovarian tubes, the oocytes were identifiable at the early stages of meiotic prophase according to nuclear features such as condensed chromatin with synaptonemal complexes. GC-1 recognized these early oocytes. We found round cells with large and homogeneous nuclei clustered at the marginal end of the stratified epithelium. We identified these cells as oogonia on the basis of: (1) features of the nucleus, (2) reactivity to GC-1, and (3) early emergence in the developing ovaries. The oogonia were classified into three types: type A was large (7–9 μm in diameter) and clear, type B was intermediate in size (5–6 μm) and electron-density, and type C was small (4–5 μm) and dark. In the developing ovaries of juvenile C. intestinalis, type A oogonia appeared first (before 11 days after settlement) and types B and C followed (15 days after settlement). Thus we see that the type A is the oogenetic stem cell, type B is the proliferating oogonium, and type C is the final oogonium just before meiosis. The oocytes appeared 18 days after metamorphosis.     

Lectin binding in the ovary of the chick embryo and newborn.

The content, distribution and changes of the glycoconjugates sugar residues in the ovaries of chick embryos, from the 8th day of incubation to hatching and in 1-day old chick, were investigated. For this purpose, a battery of seven HRP-conjugated lectins was used (DBA, SBA, PNA, ConA, WGA, LTA and UEA I). Our data showed that SBA was a marker of the most immature oogonia in the ovarian cortex and medulla. The reactivity with ConA appeared to characterize the cells immediately prior to as well as during the meiotic division, as demonstrated by the presence of alpha-D-mannose at the "Balbiani bodies" in the oogonia of the ovarian cortex. The detection of Con A and SBA reactivity corresponded to maturative stages of the early oogonia in different cortical zones of the chick ovary. Our data also revealed that PNA seemed to be a marker of the degenerating oogonia located in the ovarian medulla. Moreover, PNA binding was a characteristic finding in the endothelial cells of the vessels located in the compact portion of the medulla in the left ovary, from the 8th to the 21st day of incubation and after hatching; PNA reactivity was only seen from the 16th day onwards in the endothelial cells of the cortex. During the whole considered period of incubation and after hatching, reactivity with UEAI, LTA and DBA was never detected.     

Gonadal morphogenesis and sex differentiation in intraovarian embryos of the viviparous fish Zoarces viviparus (Teleostei, Perciformes, Zoarcidae): a histological and ultrastructural study

It is essential to know the timing and process of normal gonadal differentiation and development in the specific species being investigated in order to evaluate the effect of exposure to endocrine-disrupting chemicals on these processes. In the present study gonadal sex differentiation and development were investigated in embryos of a viviparous species of marine fish, the eelpout, Zoarces viviparus, during their intraovarian development (early September to January) using light and electron microscopy. In both sexes of the embryos at the time of hatching (September 20) the initially undifferentiated paired bilobed gonad contains primordial germ cells. In the female embryos, ovarian differentiation, initiated 14 days posthatch (dph), is characterized by the initial formation of the endoovarian cavity of the single ovary as well as by the presence of some early meiotic oocytes in a chromatin-nucleolus stage. By 30 dph, the endoovarian cavity has formed. By 44 dph and onward, the ovary and the oocytes grow in size and at 134 dph, just prior to birth, the majority of the oocytes are at the perinucleolar stage of primary growth and definitive follicles have formed. In the presumptive bilobed testis of the male embryos, the germ cells (spermatogonia), in contrast to the germ cells of the ovary, remain quiescent and do not enter meiosis during intraovarian development. However, other structural (somatic) changes, such as the initial formation of the sperm duct (30 dph), the presence of blood vessels in the stromal areas of the testis (30 dph), and the appearance of developing testicular lobules (102 dph), indicate testicular differentiation. Ultrastructually, the features of the primordial germ cells, oogonia, and spermatogonia are similar, including nuage, mitochondria, endoplasmic reticulum, and Golgi complexes.     

Differentiation of ambisexual gonads and immunohistochemical localization of P450 cholesterol side-chain cleavage enzyme during gonadal sex differentiation in the protandrous anemonefish, Amphiprion clarkii

To clarify the relationship between steroid hormones and sex differentiation of the protandrous anemonefish Amphiprion clarkii, we histologically examined its gonadal differentiation. From hatching to 30 days post hatching (dph), all of the gonads surveyed were sexually undifferentiated. The gonads of all fish first differentiated into ovaries at 60 dph, and the oocytes gradually developed and increased in number as the ovaries grew up until 183 dph. Some cysts of differentiated spermatogenic germ cells appeared in the ovaries at 214 dph, and ambisexual gonads with both ovarian and testicular tissues formed by 273 dph. Using immunohistochemistry, we then investigated the expression of cytochrome P450 cholesterol side-chain cleavage enzyme (P450scc), during gonadal sex differentiation. P450scc-immunopositive reactions first appeared in sexually undifferentiated gonads at 30 dph. Beginning at 60 dph, the number of strongly positive cells increased throughout the differentiation of the ovaries and continued to increase during the testicular differentiation until 210 dph. Immunopositive cells were observed more frequently in ovarian tissue than in testicular tissue in the ambisexual gonads at 270 dph. These results suggest that endogenous steroid hormones are important for the sex differentiation, including the primary sex differentiation and subsequent testicular differentiation, of the anemonefish.     

Fetal thymus and thymuline stimulate the in vitro proliferation of oogonia in the fetal rat ovary]

In rat ovaries explanted on day 13.5 p.c. and cultured in vitro for up to 6 days, the number of germ cells is enhanced in thymulin-supplemented medium and/or after co-culture of the ovarian explants with foetal thymic tissue compared to ovaries cultured in synthetic medium. Corticosterone added to the medium prevents the secretion of thymulin by the foetal thymus and in that condition the thymus does not influence the proliferation of oogonia. These results provide additional evidence that the pituitary-adrenal-thymic axis might be involved in the control of oogonia proliferation in vivo, taking into account our previous experimental finding that the number of germ cells is increased in ovaries of hypophysectomized foetuses.     

Histological study of germ cells development and apoptosis in mongolian sheep fetal ovaries

Mammalian germ cells proliferate by mitosis and begin meiotic development in fetal ovaries. The aim of this study is to demonstrate the germ cell proliferation and apoptosis, and elucidated some of the key developmental events and stages in Mongolian sheep fetal ovaries. Fourty three pairs of sheep fetal ovaries at days 37-99 of gestation were collected from local slaughterhouse. Studies in histological structure of ovaries and germ cell apoptosis were achieved by employing light microscopy and terminal deoxynucleotidyl transferase-mediated nick end labeling (TUNEL). Following fetal gestation age increasing, three key development events were detected: oogonia fleetly proliferated by mitosis and clustered at days 37-55 of gestation in ovarian cortex forming oogonia nest; the formation of ovigerous cords (OC) and disorganization took place at day 51-81, especially at days 63-66 more OC developed, and more germ cells in OC entered meiosis prophase; subsequently, with the OC disappeared, primordial follicles gradually prevailed from day 73 of gestation. Another observation was germ cells apoptosis and the number of apoptotic germ cells showed a peak from day 58 to day 73 (P<0.05) and germ cells in OC were prone to apoptosis. The study provides evidence about histological feature and germ cells apoptosis in sheep fetal ovaries.     

Meiosis-inducing and meiosis-preventing effects of sex steroid hormones on hamster fetal ovaries in organ culture

Day 11 to day 15 p.c. female gonads were cultured for 6-8 days in chemically-defined media. In day 11 and day 12 p.c. ovaries grown in a non-hormonal medium, the germ cells were unable to enter meiosis; they were retained at a stage of oogonia or more frequently at a preleptotene stage. Ovaries of the same ages cultured in an estradiol-containing medium showed germ cells progressing through meiotic prophase in a way close to that in ovaries of equivalent age in vivo. That was the case of the germ cells in day 13 to day 15 p.c. ovaries maintained in a non-hormonal medium. In a testosterone-containing medium, the germ cells in day 13 and day 14 p.c. ovaries were prevented from entering meiosis; by contrast, those in day 15 p.c. ovaries underwent meiotic prophase normally. These results indicated that each of both hormones was able to exert its corresponding (meiosis-inducing or meiosis-preventing) effect before a definite critical time of ovarian development. The possibility is suggested that the germ cell differentiation in the female and male gonads in vivo would also depend on estrogens or androgens precociously synthesized in the gonads or supplied from other organs via the fetal blood.     

Morpho-functional changes in the ovaries of the sea urchin Strongylocentrotus intermedius after exposure to cadmium

The ovaries were studied in the sea urchins kept in a sea water added with 1, 50 and 100 micrograms/l cadmium chloride for 5, 15, 40, 72 and 130 days. The gland reaction depended on the drug dose and exposure. A short exposure (5 and 15 days) stimulated the development of a larger, as compared with the control, number of oogonia and raised the activity of acid and alkaline phosphatases. A long exposure decreased the number of germ cells, decelerated their growth, destroyed gametes and accessory cells, inhibited the activity of alkaline phosphatase. The cadmium accumulation in the ovaries was noted only on the 130th day at concentrations of 50 and 100 micrograms/l. The monitoring of morphological and biochemical indices allowed to conclude that cadmium exerted a toxic effect on the sea urchin ovaries.     

Ultrastructure of the ovary of Dermatobia hominis (Diptera: Cuterebridae). III. Gonial cell degeneration.

We studied the ultrastructural aspects of pre-pupae and pupae ovaries of Dermatobia hominis. Physiological degeneration of gonial cells was observed: (a) after the ovarioles differentiation, in the oogonia residing in the apical region of the ovary; (b) at the beginning of vitellogenesis, in the cystoblasts close to the terminal filament. The significance of gonial cell degeneration was correlated with the physiological changes which occur in the ovary during development.     

Histological and ultrastructural investigation of early gonad development and sex differentiation in Adriatic sturgeon (Acipenser naccarii,Acipenseriformes, Chondrostei)

Gonad development and sex differentiation from embryos to 594‐day‐old individuals were investigated in farmed Acipenser naccarii using light and transmission electron microscopy. The migrating primordial germ cells first appear along the dorsal wall of the body cavity in embryos 1.5 days before hatching. The gonadal ridge, containing a few primary primordial germ cells (PGC‐1) surrounded by enveloping cells, appears in 16‐day‐old larvae. At 60 days, the undifferentiated gonad is lamellar and PGC‐1 multiply, producing PGC‐2. In 105‐day‐old juveniles, a distinct germinal area with advanced PGC‐2 appears on the lateral side near the mesogonium and the first blood vessels are visible. At 180 days, putative ovaries with a notched gonadal epithelium and putative testes with a smooth one appear, together with adipose tissue on the distal side. In 210‐day‐old juveniles, active proliferation of germ cells begins in the putative ovaries, whereas putative testes still contain only a few germ cells. The onset of meiosis and reorganization of stromal tissue occurs in ovaries of 292‐day‐old individuals. Ovaries with developed lamellae enclosing early oocyte clusters and follicles with perinucleolar oocytes occur at 594 days. Meiotic stages are never found, even in anastomozing tubular testes of 594‐day‐old individuals. Steroid producing cells are detected in the undifferentiated gonad and in the differentiated ones of both sexes. Anatomical differentiation of the gonad precedes cytological differentiation and female differentiation largely precedes that of the male. Gonad development and differentiation are also associated with structural changes of connective tissue, viz. collagen‐rich areas are massive in developing testes and reduced in ovaries. J. Morphol., 2008. © 2008 Wiley‐Liss, Inc.     

Ontogeny of immunoreactive Lh and Fsh cells in relation to early ovarian differentiation and development in protogynous hermaphroditic ricefield eel Monopterus albus

Luteinizing hormone (Lh) and follicle-stimulating hormone (Fsh) control many aspects of gonadal development and function in teleosts. In the present paper, the specific antisera against ricefield eel Lhb (Lh beta subunit), Fshb (Fsh beta subunit), and Cga (the common pituitary glycoprotein hormone alpha subunit) were generated, and the cellular localization, initial appearance, and subsequent development of gonadotrophs in relation to early ovarian differentiation and development in the ricefield eel, a protogynous sex-changing teleost, were examined with immunochemistry. Lhb- and Fshb-immunoreactive signals were identified in distinct pituitary cells that occupied primarily the peripheral regions of the adenohypophysis. During ontogeny, Lhb-immunoreactive signals were first detected in the pituitary around 40 days after hatching (dah) when the oogonia transitioned into early primary growth oocytes, and the intensity of immunoreactivity increased concomitantly with the growth of primary oocytes from 60 to 140 dah. During overwintering from 170 to 230 dah, Lhb-immunoreactive signals were significantly decreased when a large proportion of perinucleolus oocytes contained intense Balbiani bodies. In contrast, Fshb-immunoreactive signals were not detectable in the pituitary until around 230 dah (in the spring after hatching) and slightly increased from 285 dah when the late perinucleolus oocytes began to enter the secondary growth phase. Both Lhb- and Fshb-immunoreactive cells were increased when the early cortical alveoli oocytes emerged at 300 dah. The mRNA expression of lhb and fshb coincided with their immunoreactive signals. Taken together, these results suggest that only Lh is involved in primary oocyte growth in ricefield eels, but both Fsh and Lh are important for the secondary ooctye growth.     

Ovarian innervation develops before initiation of folliculogenesis in the rat

Summary Sympathetic neurotransmitters have been shown to be present in the ovary of the rat during early postnatal development and to affect steroidogenesis before the ovary becomes responsive to gonadotropins, and before the first primordial follicles are formed. This study was undertaken to determine if development of the ovarian innervation is an event that antedates the initiation of folliculogenesis in the rat, Rattus norvegicus. Serial sections of postnatal ovaries revealed a negligible frequency of follicles 24 h after birth (about 1 primordial follicle per ovary). Twelve hours later there were about 500 follicles per ovary, a number that more than doubled to about 1300 during the subsequent 12 h, indicating that an explosive period of follicular differentiation occurs between the end of postnatal days 1 and 2. Electron microscopy demonstrated that before birth the ovaries are already innervated by fibers containing clear and dense-core vesicles. Immunohistochemistry performed on either fetal (day 19) or newborn (less than 15h after birth) ovaries showed the presence of catecholaminergic nerves, identified by their content of immunoreactive tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine biosynthesis. While some of these fibers innervate blood vessels, others are associated with primordial ovarian cells, thereby suggesting their participation in non-vascular functions. Since prefollicular ovaries are insensitive to gonadotropins, the results suggest that the developing ovary becomes subjected to direct neurogenic influences before it acquires responsiveness to gonadotropins.     

Morphology and ultrastructure of the somatic cells in Astacus leptodactylus ovary

We defined the somatic environment in which female germinal cells develop, and performed ultrastructural analyses of various somatic cell types, with particular reference to muscle cells and follicle cells, that reside within the ovary at different stages of oogenesis. Our findings show that ovarian wall of the crayfish is composed of long muscle cells, blood cells, blood vessels and hemal sinuses. The follicle and germinal cells lie within a common compartment of ovarian follicles that is defined by a continuous basal matrix. The follicle cells form branching cords and migrate to surround the developing oocytes. A thick basal matrix separates the ovarian interstitium from ovarian follicles compartment. Transmission electron microscopy shows that inner layer of basal matrix invaginates deeply into the ovarian compartment. Our results suggest that before being surrounded by follicle cells to form follicles, oogonia and early previtellogenic oocytes reside within a niche surrounded by a basal matrix that separates them from ovarian interstitium. We found coated pits and coated vesicles in the cortical cytoplasm of previtellogenic and vitellogenic oocytes, suggesting the receptor mediated endocytosis for transfer of material from the outside of the oocytes, via follicle cells. The interstitial compartment between the inner muscular layer of the ovarian wall and the basal matrix of the ovarian follicle compartment contains muscle cells, hemal sinuses, blood vessels and blood cells. Granular hemocytes, within and outside the vessels, were the most abundant cell population in the ovarian interstitium of crayfish after spawning and in the immature ovary. J. Morphol. 277:118–127, 2016. © 2015 Wiley Periodicals, Inc.     

Production of chicken progeny (Gallus gallus domesticus) from interspecies germline chimeric duck (Anas domesticus) by primordial germ cell transfer

The present study aimed to investigate the differentiation of chicken (Gallus gallus domesticus) primordial germ cells (PGCs) in duck (Anas domesticus) gonads. Chimeric ducks were produced by transferring chicken PGCs into duck embryos. Transfer of 200 and 400 PGCs resulted in the detection of a total number of 63.0 ± 54.3 and 116.8 ± 47.1 chicken PGCs in the gonads of 7-day-old duck embryos, respectively. The chimeric rate of ducks prior to hatching was 52.9% and 90.9%, respectively. Chicken germ cells were assessed in the gonad of chimeric ducks with chicken-specific DNA probes. Chicken spermatogonia were detected in the seminiferous tubules of duck testis. Chicken oogonia, primitive and primary follicles, and chicken-derived oocytes were also found in the ovaries of chimeric ducks, indicating that chicken PGCs are able to migrate, proliferate, and differentiate in duck ovaries and participate in the progression of duck ovarian folliculogenesis. Chicken DNA was detected using PCR from the semen of chimeric ducks. A total number of 1057 chicken eggs were laid by Barred Rock hens after they were inseminated with chimeric duck semen, of which four chicken offspring hatched and one chicken embryo did not hatch. Female chimeric ducks were inseminated with chicken semen; however, no fertile eggs were obtained. In conclusion, these results demonstrated that chicken PGCs could interact with duck germinal epithelium and complete spermatogenesis and eventually give rise to functional sperm. The PGC-mediated germline chimera technology may provide a novel system for conserving endangered avian species.     

Anatomy of the ovaries of the starfish Asterias rubens (Echinodermata)

Summary The ovaries of the starfish Asterias rubens were studied histologically and ultrastructurally. The reproductive system in female specimens consists of ten separate ovaries, two in each ray. Each ovary is made up of a rachis with lateral primary and secondary folds: the acini maiores and acini minores. The ovarian wall is composed of an outer and an inner part, separated by the genital coelomic sinus. The ovarian lumen contains oocytes in various phases of oogenesis, follicle cells, nurse cells, phagocytosing cells and steroid-synthesizing cells.Oogenesis is divided into four phases: (i) multiplication phase of oogonia, (ii) initial growth phase of oocytes I, (iii) growth phase proper of oocytes I, and (iv) post-growth phase of oocytes I. The granular endoplasmic reticulum and the Golgi complex of the oocytes appear to be involved in yolk formation, while the haemal system, haemal fluid and nurse cells may also be important for vitellogenesis. The haemal system is discussed as most likely being involved in synchronizing the development of the ovaries during the annual reproductive cycle and in inducing, stimulating and regulating the function of the ovaries.Steroid-synthesizing cells are present during vitellogenesis; a correlation between the presence of these cells and vitellogenesis is discussed.     

Ontogenetic changes of circulating erythroid cells and haemoglobin components in Esox lucius

Using light microscopy the morphology, the mitotic index and levels of erythroid cell types were detected from 48 h pike Esox lucius embryos before hatching to adult specimens. At the same developmental stages, the haemoglobins and globin chains expressed were electrophoretically characterized. The erythroid cells of the primitive generation were the most abundant from 48 h before hatching until 15–20 days after hatching, then their number decreased and only rare cells remained in the 3 month‐old juvenile specimens. These cells divided and differentiated in the blood and were substituted by the definitive erythrocyte series. As in other vertebrates, the immature cells of the two generations differed in morphological properties and in the synthetized haemoglobin. The circulating erythroid cells of the definitive population cell lineage were, at all differentiation stages, smaller than those of the primitive generation. The definitive erythrocytes appeared in blood smears of 7 days post‐hatching larvae, they increased rapidly and at 20 days they represented the predominant red blood cell population in the circulation of young pike. Electrophoretic analysis of haemolysates obtained from different developmental stages indicated the presence of distinct embryonic, larval and adult haemoglobins. The embryonic haemoglobins differed from those of the older larva and juvenile specimens and were detectable within the first week of post‐hatching development when only primitive erythrocytes were present in the blood.