The follicular placenta of the viviparous fish,Heterandria formosa. I. Ultrastructure and development of the embryonic absorptive surface

Embryos of the poeciliid Heterandria formosa develop to term in the ovarian follicle in which they establish a placental association with the follicle wall (follicular placenta) and undergo a 3,900% increase in embryonic dry weight. This study does not confirm the belief that the embryonic component of the follicular placenta is formed only by the surfaces of the pericardial and yolk sacs; early in development the entire embryonic surface functions in absorption. The pericardial sac expands to form a hood-like structure that covers the head of the embryo and together with the yolk sac is extensively vascularized by a portal plexus derived from the vitelline circulation. The hood-like pericardial sac is considered to be a pericardial amnion-serosa. Scanning and transmission electron microscopy reveal that during the early and middle phases of development (Tavolga's stages 10–18 for Xiphophorus maculatus) the entire embryo is covered by a bilaminar epithelium whose apical surface is characterized by numerous, elongate microvilli and coated pits and vesicles. Electron-lucent vesicles in the apical cytoplasm appear to be endosomes while a heterogeneous group of dense-staining vesicles display many features characteristic of lysosomes. As in the larvae of other teleosts, cells resembling chloride cells are also present in the surface epithelium. Endothelial cells of the portal plexus lie directly beneath the surface epithelium of the pericardial and yolk sacs and possess numerous transcytotic vesicles. The microvillous surface epithelium becomes restricted to the pericardial and yolk sacs late in development when elsewhere on the embryo the non-absorptive epidermis differentiates. We postulate that before the definitive epidermis differentiates, the entire embryonic surface constitutes the embryonic component of the follicular placenta. The absorptive surface epithelium appears to be the principle embryonic adaptation for maternal-embryonic nutrient uptake in H. formosa, suggesting that a change in the normal differentiation of the surface epithelium was of primary importance to the acquisition of matrotrophy in this species. In other species of viviparous poeciliid fishes in which there is little or no transfer of maternal nutrients, the embryonic surface epithelium is of the non-absorptive type.     

Follicular placenta of the viviparous fish,Heterandria formosa: II. Ultrastructure and development of the follicular epithelium

Embryos of the viviparous poeciliid fish, Heterandria formosa, develop to term in the ovarian follicle where they undergo a 3,900% increase in embryonic dry weight. Maternal-embryonic nutrient transfer occurs across a follicular placenta that is formed by close apposition of the embryonic surface (i.e., the entire body surface during early gestation and the pericardial amnionserosa during mid-late gestation) to the follicular epithelium. To complement our recent study of the embryonic component of the follicular placenta, we now describe the development and fine structure of the maternal component of the follicular placenta. Transmission electron microscopy reveals that the ultrastructure of the egg envelope and the follicular epithelium that invests vitellogenic oocytes is typical of that described for teleosts. The egg envelope is a dense matrix, penetrated by microvilli of the oocyte. The follicular epithelium consists of a single layer of cuboidal cells that lack apical microvilli, basal surface specializations, and junctional complexes. Follicle cells investing the youngest embryonic stage examined (Tavolga's and Rugh's stage 5–7 for Xiphophorus maculatus) also lack apical microvilli and basal specializations, but possess junctional complexes. In contrast, follicle cells that invest embryos at stage 10 and later display ultrastructural features characteristic of transporting epithelial cells. Apical microvilli and surface invaginations are present. The basal surface is extensively folded. Apical and basal coated pits are present. The cytoplasm contains a rough endoplasmic reticulum, Golgi complexes, and dense staining vesicles that appear to be lysosomes. The presence of numerous apically located electron-lucent vesicles that appear to be derived from the apical surface further suggests that these follicle cells may absorb and process follicular fluid. The egg envelope, which remains intact throughout gestation and lacks perforations, becomes progressively thinner and less dense as gestation proceeds. We postulate that these ultrastructural features, which are not present in the follicles of the lecithotrophic poeciliid, Poecilia reticulata, are specializations for maternal-embryonic nutrient transfer and that the egg envelope, follicular epithelium, and underlying capillary network form the maternal component of the follicular placenta. © 1994 Wiley-Liss, Inc.     

An examination of the variation in maternal placentae across the genus Poeciliopsis (Poeciliidae)

Placentae show considerable diversity in a number of nonmammalian, viviparous organisms, including amphibians, reptilian sauropsids, teleost fish, and chondrichthyes. However, the evolutionary processes driving the evolution of placenta are still debated. In teleost fishes, the genus Poeciliopsis (Poeciliidae) offers a rare opportunity for studying placental evolution: extensive placentation has evolved three independent times within the last 750,000 years and there is substantial interspecific variation in the degree of embryonic, maternal nutrient provisioning and development of the placenta. In poeciliids, the placenta is composed of a hypertrophied maternal follicular epithelium apposed to a highly vascularized embryonic pericardial sac. To better understand placental evolution, we have undertaken a comprehensive comparative study of the maternal follicle in eight closely related Poeciliopsis species that span the range in postfertilization, embryonic, maternal nutrient provisioning (from lecithotrophs, to moderate matrotrophs, to extensive matrotrophs). Using light and scanning electron microscopy, we found that the species that provide extensive postfertilization maternal nutrient provisioning (extensive matrotrophs) have thicker follicles and more extensive folding of the follicular epithelium compared to the lecithotrophs and moderate matrotrophs. Follicle sections and histology revealed that epithelial folds of the extensive matrotrophs are comprised primarily of cuboidal and columnar cells and are richly supplied with capillaries. Among the extensive matrotrophs, enhancements of follicle traits corresponded with increases in the level of maternal nutrient provisioning. Hypertrophied maternal follicles with richly vascularized folds can serve to increase the surface area and, thus, facilitate the transfer of substances between the mother and developing embryo. Finally, we found egg envelopes in the lecithotrophs and moderate matrotrophs, but not in the extensive matrotrophs. Morphological studies, like this one, can provide a better understanding of the natural variation in the structure and functioning of maternal and offspring traits associated with matrotrophy and, thus, insights into the processes driving placental evolution. J. Morphol. 276:707–720, 2015. © 2015 Wiley Periodicals, Inc.     

An examination of surface epithelium structures of the embryo across the genus Poeciliopsis (Poeciliidae)

In viviparous, teleost fish, with postfertilization maternal nutrient provisioning, embryonic structures that facilitate maternal‐fetal nutrient transfer are predicted to be present. For the family Poeciliidae, only a handful of morphological studies have explored these embryonic specializations. Here, we present a comparative morphological study in the viviparous poeciliid genus, Poeciliopsis . Using microscopy techniques, we examine the embryonic surface epidermis of Poeciliopsis species that vary in their level of postfertilization maternal nutrient provisioning and placentation across two phylogenetic clades and three independent evolutionary origins of placentation. We focus on surface features of the embryo that may facilitate maternal‐fetal nutrient transfer. Specifically, we studied cell apical‐surface morphology associated with the superficial epithelium that covers the body and sac (yolk and pericardial) of embryos at different developmental stages. Scanning electron microscopy revealed common surface epithelial cells across species, including pavement cells with apical‐surface microridges or microvilli and presumed ionocytes and/or mucus‐secreting cells. For three species, in the mid‐stage embryos, the surface of the body and sac were covered in microvillus epithelium. The remaining species did not display microvillus epithelium at any of the stages examined. Instead, their epithelium of the body and sac were composed of cells with apical‐surface microridges. For all species, in the late stage embryos, the surface of the body proper was composed of apical‐surface microridges in a “fingerprint‐like arrangement.” Despite the differences in the surface epithelium of embryos across Poeciliopsis species and embryonic developmental stages, this variation was not associated with the level of postfertilization maternal nutrient provisioning. We discuss these results in light of previous morphological studies of matrotrophic, teleost fish, phylogenetic relationships of Poeciliopsis species, and our earlier comparative microscopy work on the maternal tissue of the Poeciliopsis placenta.     

Maximization of evolutionary trends for placental viviparity in the spadenose shark,Scoliodon taticaudus

Synopsis Placental viviparity has evolved inScoliodon taticaudus to a degree that rivals some eutherian mammals. Its eggs are the smallest known of any shark. They have a diameter of 1 mm, a dry weight of 0.0654 ± 0.0100 mg and are nearly yolk-free. Implantation takes place at an early (3 mm) stage of development, and gestation is short (5–6 months). Comparison of the dry weight of the egg (0.065 mg) with the estimated dry weights of a mid-late term 90 mm embryo (910 mg) and a 152 mm neonate (3815.4 mg) reveals weight changes of 14219 × and 58338 ×, respectively. Its normalized brood weight, a measure of maternal nutrient investment, is 49.5 g · kg^–1 female body weight for a six-month gestation. Comparisons with other species of placental and nonplacental sharks show thatS. laticaudus has a highly advanced form of matrotrophy. Maternal nutrients appear to be acquired by placental transport and by imbibition of uterine fluid. Hemotrophic placental nutrient transfer occurs across a unique uterine implantation site, termed the trophonematous cup, in which maternal blood appears to bathe the outer epithelium of the embryonic yolksac placenta. The latter is solid and filled with a three-dimensional network of capillaries and many free interstitial cells. The umbilical stalk contains the vitelline vessels but lacks a yolk duct. Its surface is amplified by many long, villous appendiculae, which consist of a vascular core that ramifies into a massive surface capillary network invested by a simple squamous epithelium. The appendiculae ofS. laticaudus most likely are sites of gas exchange and possibly the uptake of small molecules. They are unlike the appendiculae described in any other placental shark and exhibit design principles similar to those of the uterine trophonemata of matrotrophic rays.     

Morphogenesis of the ovarian follicular epithelium during initial stages of embryogenesis of the viviparous earwig,Hemimerus talpoides

Representatives of the highly specialized earwig family Hemimeridae are epizoic and viviparous. Their embryos develop inside terminal ovarian follicles (termed also embryonic follicles) and rely solely on nutrients transferred from mother tissues. In this report, we present results of ultrastructural and histochemical studies of the initial stage of Hemimerus talpoides development. Our results show that the follicular cells surrounding fully grown oocyte of Hemimerus do not degenerate after initiation of embryogenesis, but transform and gradually form the wall of the incubation chamber in which the embryo develops. We also show that amniotic cells of the early embryo remain in direct contact with transformed follicular cells. In the region of contact, short outgrowths of the amniotic cells associate with irregular surface specializations of the transformed follicular cells. We suggest that extended “postfertilization” activity of hemimerid follicular cells represents an adaptation to viviparity and matrotrophy in this insect lineage.     

Development of an avascular region (the stigma) in ovarian follicles of lizards (Anolis)

The architecture of follicular blood vessels in the ovary of lizards (Anolis equestris and Anolis carolinensis) was studied by standard histology and also after vascular perfusion with an orange silicone-rubber compound or with India ink. The theca of the follicular wall contains a netlike arrangement of anastomosing sinusoids, which increase in size as a follicle grows. An avascular stigma forms in very small, growing follicles when a portion of the follicular wall contacts the ovarian surface epithelium. Blood vessels then invade the theca except in the zone of contact. The diameter of the stigma is about 50% of follicular diameter, regardless of follicular size. Although the stigma of smaller follicles is avascular, that of vitellogenic follicles is hypovascular, i.e., a few vessels radiate into the stigma region. The antiangiogenic process involved in stigma formation may continue as the stigma enlarges. The development pattern of stigma formation found in Anolis is displayed by many other vertebrates.     

A novel pattern of follicular epithelium morphogenesis in higher dipterans

In fly ovaries, the follicular epithelium surrounding germline cells diversifies into several morphologically distinct cell subpopulations. This complex process is crucial for the formation of a regionally complex eggshell and establishment of polarity of the future embryo. Morphogenetic changes accompanying patterning of the follicular epithelium have been best characterized in the model fly, Drosophila melanogaster. Here, we analyze follicular epithelium diversification in the ovaries of Tachypeza nubila, a brachyceran fly closely related to the group Cyclorrhapha, which also includes Drosophila. We provide morphological evidence that in Tachypeza, the diversification process differs from that described in the Drosophila model system in several important respects: (i) follicle cells differentiate into five subpopulations (versus eight in Drosophila); (ii) only one of these subpopulations (i.e. border cells) is migratory (versus four in Drosophila); (iii) the main body follicle cells form a uniform epithelium with no distinct border between follicle cells covering the nurse cell compartment and the oocyte; (iv) chorionic material is deposited not only on the surface of the oocyte but also on the nurse cells; (v) there is no centripetal migration of the follicle cells; (vi) the resulting eggshell is morphologically simple with no regional specializations except for the micropylar apparatus at the anterior pole of the oocyte. Our findings provide novel insights into the evolution of the follicle cell patterning and functioning in dipterans. A critical analysis of these processes in different dipteran groups strongly indicates that in Tachypeza, follicular epithelium diversification follows a distinct pattern, novel for higher dipterans.     

Origin and Differentiation of the Inner Follicular Cells during Oogenesis in Molgula pacifica (Urochordata), an Ascidian without Test Cells

In Molgula pacifica small previtellogenic oocytes are found between cells of the ovarian epithelium. Each oocyte subsequently grows within a compartment of the epithelium known as a primary follicle. The wall of the primary follicle is composed of outer follicular epithelial cells. While growing from about 15–70 μm in diameter, each oocyte gradually recruits a set of about 950 non-epithelial inner follicular cells. These cells co-differentiate in sets with each oocyte, but test cells never appear. The first filamentous components of the vitelline coat appear on the surface of an oocyte in places where it is in contact with undifferentiated (stage 2) inner follicular cells. Each fully differentiated inner follicular cell stores adhesive precursors in a large compartment of the endoplasmic reticulum and probably secretes components of the vitelline coat. There is no evidence that the outer follicular epithelial cells transform into inner follicular cells by dedifferentiation as has often been assumed. Inner follicular cells, in stage 1, are nearly identical to hemoblasts. Hemoblasts may form the inner follicular cells, but to do this they would have to cross the outer follicular epithelium and this phenomenon has not yet been seen.     

Matrotrophic adaptations and early stages of embryogenesis in the desert scorpion Paruroctonus mesaensis (Vaejovidae)

Light and electron microscopy were used to examine the sequential changes in embryos and maternal reproductive tubules in the vaejovid scorpion, Paruroctonus mesaensis. The early stages are described, from oogenesis to the time of embryogenesis just before spiracles and booklungs begin to appear. The oocytes and associated trophic cells originate in the epithelium of the maternal ovariuterine tubules. Each oocyte with follicle (primary trophic) cells forms a protuberance on the tubular surface. After fertilization and cleavage, the morula appears to be pulled into the tubular lumen by tissue invaginated from the wall opposite the protuberance. Secondary trophic cells originating near each oocyte form a trophic layer parallel and connected to the ovariuterine tubules. These cells encircle the tubular epithelium and apparently induce or transform it to a trophic mode. Within the tubules, each embryo develops in a specialized region (uterus) where the embryo abuts a cell mass (follicular placenta). The latter, along with the tubular and uterine epithelia, apparently releases nutrients that are absorbed through the embryo epidermis. The main structures of the embryo body develop from the germinal disc of the blastula. Segments and appendages are formed in an anterior-to-posterior direction. The chelicerae, initially posterior to the stomodeum, are gradually positioned anterior and dorsal. The early abdomen has only a few segments with no separation into meso- and metasoma. The latter structure, when formed, has a ventral flexure and segments of smaller diameter than those in the mesosoma. The telson starts as a broad, bilobed structure, becoming tapered with two openings near the tip. Each pectine appears first as a lobe attached to the body wall. Transverse grooves appear distally and then later along the entire length. In the stages of this study, there was no indication of ventral plates, gills, or sternites in the ventral mesosoma where booklungs and spiracles will eventually form. J. Morphol. 237:187–211, 1998. © 1998 Wiley-Liss, Inc.     

Placentation and associated aspects of gestation in the bonnethead shark, Sphyrna tiburo

The left ovary of the bonnethead shark, Sphyrna tiburo, is rudimentary, and the right ovary supplies both oviducts which share a common ostium situated in the falciform ligament. Preceding ovulation the nidamental gland of each oviduct hypertrophies and the caudal two-thirds of each oviduct is modified to form a uterus. In the Florida-Caribbean area Sphyrna tiburo probably mates in March and 3–7 eggs are fertilized in the vicinity of the nidamental gland of each oviduct. The developing embryo is nourished during the first 3–4 months of gestation by yolk stored in its extensive yolk sac. Approximately three and one-half months after fertilization, the distal portion of the yolk sac becomes convoluted and interdigitates with deep folds in the uterine wall to form a yolk-sac placenta. As the placenta develops, the maternal uterine epithelium is reduced from columnar cells to squamous cells, and the foetal yolk-sac epithelium is reduced from columnar and cuboidal cells to squamous cells. Exchange between the maternal and foetal blood systems takes place through maternal endothelium, reduced maternal epithelium, egg-case membrane, reduced foetal epithelium, and foetal endothelium.     

Insemination,intrafollicular fertilization and development of the fertilization plug during gestation in Heterandria formosa (Poeciliidae)

The viviparous teleost Heterandria formosa is a remarkable species for its reproductive characters including: (a) the smallest oocyte in viviparous fish species; (b) a high level of matrotrophy with a complex placenta; and (c) the highest level of superfetation. Superfetation involves (d) the continuous development of oocytes and fertilization at the same time with embryos in gestation. The sequential fertilization of oocytes requires (e) storage of spermatozoa in the ovary. Among these characteristics, fertilization is of fundamental interest, specifically the intrafollicular fertilization of poeciliids, species that do not present micropyle, and the consequent formation of the fertilization plug, a structure developed at the periphery of the follicle where the entrance of spermatozoa occurs. Both processes intrafollicular fertilization and formation of the fertilization plug have been rarely described. There is only one study illustrating, the fertilization plug of H. formosa with a drawing. In the context of reproductive aspects of H. formosa, the goal of this study is to describe the morphology of the ovary during insemination, intrafollicular fertilization and development of the fertilization plug. After insemination, spermatozoa enter the ovary and occupy folds of the lamella near follicles of all stages of oogenesis, the delle, where the germinal epithelium establishes contact with the follicular epithelium. The results of the present study provide evidence that both epithelia open at the distal end of the delle, this morphological change allow that the spermatozoa to make contact with the zona pellucida of the oocyte. After fertilization, the delle becomes blocked by proliferation of cells of the germinal epithelium, to form the fertilization plug that persists throughout gestation. Abundant reticular fibers and blood vessels are seen around the fertilization plug. Persistence of the fertilization plug suggests that it could be the site where the juvenile will gain entrance to the ovarian lumen during birth.     

The role of the follicular epithelium in growing eggs of a dipteran insect during late oogenesis and cleavage

The gall midge Heteropeza pygmaea can reproduce by means of paedogenesis (i.e., larval parthenogenesis). In that process, follicles are produced that develop while floating in the hemocoele of the mother larva. A chorion is not formed at the end of oogenesis, and the growing embryos remain enveloped by the follicular epithelium. To investigate possible adaptations of the follicular epithelium to this unusual egg development, its ultrastructure has been studied during late oogenesis and cleavage. Earlier investigations had shown that the follicle cells are provided with a specifically arranged microtubular frame, which may be responsible for the anisometric growth of the egg. The present work shows that the follicle cells are always joined by desmosomes and septate junctions. During development, the septate junctions increase their surface and change their orientation to become parallel to the longitudinal egg axis, thus increasing the resistance of the follicle cells to being torn apart by growth tensions. The total surface of the follicular epithelium increases during development. Well-developed nucleoli in the nuclei and numerous ribosomes in the cytoplasm of follicle cells indicate a high level of synthetic activity. This activity may be required to support the increase in the membrane surface and the establishment of the microtubular frame. Lipid droplets, glycogen, and different inclusions in the follicle cells may represent nutrient and energy reserves. Structures indicating a quantitative significant transfer of nutrients from the follicle cells to the egg were not found.     

Confocal scanning laser microscopy of the follicular epithelium in ovarioles of the stick insect Carausius morosus

Ovarian follicles of the stick insect Carausius morosus were analyzed by confocal laser microscopy and immunocytochemistry with a view to studying cell polarity in the follicular epithelium. Such probes as anti-α-tubulin antibodies and Rh-phalloidin were employed to establish how the follicle cell cytoskeleton changes during ovarian development. Data show that α-tubulin prevails over the basal end, while F-actin appears more abundant along the apical end of the follicle cells. This finding was further corroborated by immunogold cytochemistry, showing that label along the basal end is primarily associated with microtubules, while that along the apical end is due to follicle cell microvilli interdigitating with the oocyte plasma membrane. A monoclonal antibody specifically raised against a vitellin polypeptide was used to investigate the role the follicular epithelium might play in relation to vitellogenin (Vg) uptake by the oocyte. Data show that under these conditions label is restricted to the intercellular channels of the follicular epithelium, thus providing further support to the notion that Vg enters the oocyte through the extracellular pathway leading from the basement lamina to the oocyte surface. By contrast, the use of a monoclonal antibody raised against a fat-body-derived protein of 85 kDa that is specifically sulfated within the follicle cells provides evidence for the existence of an alternative way of gaining access to the oocyte surface, that is by transcytosis through the follicular cell epithelium. These findings confirm our earlier observations on stick insect ovarioles whereby polarization in the follicular epithelium is primarily addressed to sustain a transcytotic vesicular traffic between opposite poles of the follicle cell of Vg toward the oocyte surface.     

Follicle cell development is partly independent of germ-line cell differentiation in Drosophila oogenesis

Summary The developmental potential of the cells of the somatic follicular epithelium (follicle cells) was studied in mutants in which the differentiation of the germ-line cells is blocked at different stages of oogenesis. In two mutants, sn ^36a and kelch, nurse cell regression does not occur, yet the follicle cells around the small oocyte continue their normal developmental program and produce an egg shell with micropylar cone and often deformed operculum and respiratory appendages. Neither the influx of nurse cell cytoplasm into the oocyte nor the few follicle cells covering the nurse cells are apparently required for the formation of the egg shell. In the tumor mutant benign gonial cell neoplasm (bgcn) the follicle cells can also differentiate to some extent although the germ-line cells remain morphologically undifferentiated. Vitelline membrane material was synthesized by the follicle cells in some bgcn chambers and in rare cases a columnar epithelium, which resembled morphologically that of wild-type stage-9 follicles, formed around the follicle's posterior end. The normal polarity of the follicular epithelium that is characteristic for mid-vitellogenic stages may, therefore, be established in the absence of morphologically differentiating germ-line cells. However, the tumorous germ-line cells do not constitute a homogeneous cell population since in about 30% of the analyzed follicles a cell cluster at or near the posterior pole can be identified by virtue of its high number of concanavalin A binding sites. This molecular marker reveals an anteroposterior polarity of the tumorous chambers. In follicles mutant for both bgcn and the polarity gene dicephalic the cluster of concanavalin A-stained germ-line cells shifts to more anterior positions in the follicle.     

Histological and cytological studies on the ovary of Nauphoeta cinerea (Blattaria,Oxyhaloidea) during the first reproductive cycle

Histological studies were performed on the ovary of the ovoviviparous cockroach Nauphoeta cinerea during the first reproductive cycle by means of optical microscopy and histoautoradiography, and electron microscopy. The oöcyte chamber is composed of follicle cells, the oöcyte and a layer of symbiotic bacteria at the level of the microvillous border of the oöcyte. The first reproductive cycle begins with a short inactive period preceding the appearance of vitellogenin. During this period, the follicular epithelium achieves its development by a mitotic flare. From the 3rd day on, vitellogenin is synthesized by the fat body and large intercellular spaces appear between the follicular cells, in conjunction with a rapid growth of the oöcyte, which takes up selectively the vitellogenin by means of pinocytotic vesicles. These coalesce to give the yolk globules. Along with these phenomena, the proteosynthetic apparatus and its activity in the follicular cells increase slowly. After about the 12th day, the intercellular spaces disappear and the follicular epithelium which has now a very well developed proteosynthetic apparatus, begins to synthesize and lay down the egg membranes. After ovulation, the empty oöcyte chamber collapses and the follicular epithelium shows rapid degeneration processes (large cytolysosomes) that destroy the chamber completely during the gestation period. At the beginning of the 2nd cycle, there only remain a cell or two of the previous follicular epithelium and a very large annular piece of basement membrane.     

A fat body derived protein is selectively sulfated in the stick insect ovary by transcytosis through the follicular epithelium

With the onset of vitellogenesis, the follicular epithelium overlying the oocyte in stick insect ovarioles becomes highly polarized and patent by formation of wide intercellular spaces. The aim of the present study was to provide experimental support to the notion that the follicular epithelium in this insect species may be involved in transcytosis. Data demonstrate that the follicular epithelium carries out sulfo-conjugation of a 85 kDa fat body derived protein by allowing it to transit from one cell pole to another. Along the basal end, follicle cells branch into a number of cytoplasmic finger-like projections. At the opposite end facing the oocyte they taper off into lance-head shapes. Different vesicular elements are evident at both these extremities. In vivo exposure to horseradish peroxidase shows that the vesicular elements present along the apical end provide an endocytic entry. In contrast, those present along the basal end are labeled with sodium [³⁵S]-sulfate, suggesting that they may be exocytic vesicles containing a sulfo-conjugated secretory product. In vivo exposure to sodium [³⁵S]-sulfate caused radioactivity to appear over the Golgi apparatus and some nearby vesicles of the follicle cell cytoplasm, including the exocytic vesicles. The intracellular pathway of the follicle cells was also examined by immunogold labeling using a monoclonal antibody raised against a 85 kDa fat body derived protein. Under these conditions, gold particles were consistently detected over the Golgi apparatus and the vesicular elements lying along both poles of the follicle cell membrane. Based on this evidence, it is concluded that follicular cells in stick insect ovarioles are endowed with the ability to undergo transcytosis by providing an endocytic entry along the apical end and by releasing exocytically a sulfo-conjugated 85 kDa protein along the baso-lateral domain of the follicle cell membrane.     

Porcine placental immunoexpression of vascular endothelial growth factor,placenta growth factor,Flt-1 and Flk-1

Porcine embryo mortalities cause economic losses. Development of the placental vascular bed is required for successful gestation and postnatal survival. We studied the temporal and spatial distributions of vascular endothelial growth factor (VEGF), placenta growth factor (PlGF) and their receptors, Flt-1 and Flk-1. We used crossbred swine placental tissues from 30, 60, 80, 90 and 114 (term) days of gestation. Both VEGF and PlGF were present during gestation. At early pregnancy and at term, VEGF probably acts through Flt-1; during intermediate periods, its function is mediated by Flk-1. By day 90, factors other than members of VEGF family appear to be involved.     

Branchial placenta in the viviparous teleost Ilyodon whitei (Goodeidae)

Intraluminal gestation, as it occurs in viviparous goodeids, allows a wide diversity of embryo‐maternal metabolic exchanges. The branchial placenta occurs in embryos developing in intraluminal gestation when ovarian folds enter through the operculum, into the branchial chamber. The maternal ovarian folds may extend to the embryonic pharyngeal cavity. A branchial placenta has been observed in few viviparous teleosts, and there are not previous histological analyses. This study analysis the histological structure in the goodeid Ilyodon whitei. The moterno ovarian folds extend through the embryonic operculum and reach near the gills, occupying part of the branchial chamber. These folds extend also into the pharyngeal cavity. In some regions, the epithelia of the ovarian folds and embryo were in apposition, developing a placental structure in which, maternal and embryonic capillaries lie in close proximity. The maternal epithelium has desquamated cells which may enter through the branchial chamber to the pharyngeal cavity and the alimentary tract. The complex processes that occur in the ovaries of viviparous teleosts, and its diverse adaptations for viviparity, as the presence of branchial placenta, are relevant in the study of the evolution of vertebrate viviparity. J. Morphol. 275:1406–1417, 2014. © 2014 Wiley Periodicals, Inc.