Malaria in pregnancy regulates P-glycoprotein (P-gp/Abcb1a) and ABCA1 efflux transporters in the Mouse Visceral Yolk Sac.

Malaria in pregnancy (MiP) induces intrauterine growth restriction (IUGR) and preterm labour (PTL). However, its effects on yolk sac morphology and function are largely unexplored. We hypothesized that MiP modifies yolk sac morphology and efflux transport potential by modulating ABC efflux transporters. C57BL/6 mice injected with Plasmodium berghei ANKA (5 × 105 infected erythrocytes) at gestational day (GD) 13.5 were subjected to yolk sac membrane harvesting at GD 18.5 for histology, qPCR and immunohistochemistry. MiP did not alter the volumetric proportion of the yolk sac's histological components. However, it increased levels of Abcb1a mRNA (encoding P-glycoprotein) and macrophage migration inhibitory factor (Mif chemokine), while decreasing Abcg1 (P < 0.05); without altering Abca1, Abcb1b, Abcg2, Snat1, Snat2, interleukin (Il)-1ß and C-C Motif chemokine ligand 2 (Ccl2). Transcripts of Il-6, chemokine (C-X-C motif) ligand 1 (Cxcl1), Glut1 and Snat4 were not detectible. ABCA1, ABCG1, breast cancer resistance protein (BCRP) and P-gp were primarily immunolocalized to the cell membranes and cytoplasm of endodermic epithelium but also in the mesothelium and in the endothelium of mesodermic blood vessels. Intensity of P-gp labelling was stronger in both endodermic epithelium and mesothelium, whereas ABCA1 labelling increased in the endothelium of the mesodermic blood vessels. The presence of ABC transporters in the yolk sac wall suggests that this fetal membrane acts as an important protective gestational barrier. Changes in ABCA1 and P-gp in MiP may alter the biodistribution of toxic substances, xenobiotics, nutrients and immunological factors within the fetal compartment and participate in the pathogenesis of malaria-induced IUGR and PTL.

Isolation and characterization of mesenchymal stem cells from the yolk sacs of bovine embryos.

The yolk sac (YS) represents a promising source of stem cells for research because of the hematopoietic and mesenchymal cell niches that are present in this structure during the development of the embryo. In this study, we report on the isolation and characterization of YS tissue and mesenchymal stem cells (MSCs) derived from bovine YSs. Our results show that the YS is macroscopically located in the exocoelomic cavity in the ventral portion of the embryo and consists of a transparent membrane formed by a central sac-like portion and two ventrally elongated projections. Immunohistochemistry analyses were positive for OCT4, CD90, CD105, and CD44 markers in the YS of both gestational age groups. The MSCs of bovine YS were isolated using enzymatic digestion and were grown in vitro for at least 11 passages to verify their capacity to proliferate. These cells were also subjected to immunophenotypic characterization that revealed the presence of CD90, CD105, and CD79 and the absence of CD45, CD44, and CD79, which are positive and negative markers of MSCs, respectively. To prove their multipotency, the cells were induced to differentiate into three cell types, chondrocytes, osteoblasts, and adipocytes, which were stained with tissue-specific dyes (chondrogenic: Alcian Blue, osteogenic: Alizarin Red, and adipogenic: Oil Red O) to confirm differentiation. Gene expression analyses showed no differences in the patterns of gene expression between the groups or passages tested, with the exception of the expression of SOX2, which was slightly different in the G1P3 group compared to the other groups. Our results suggest that YS tissue from bovines can be used as a source of MSCs, which makes YS tissue-derived cells an interesting option for cell therapy and regenerative medicine.

Comparative morphology of the oocyte surface and early development in four characiformes from the São Francisco River, Brazil.

Early development from the egg fertilization to complete resorption of the yolk-sac is a critical period in the life cycle of teleost fish. Knowledge of this process provides essential parameters for aquaculture and identification of spawning sites in the wild. In the present study, a comparative morphological analysis of the oocyte surface as well as early development was performed in four commercially valuable species from the São Francisco River: Brycon orthotaenia, Leporinus obtusidens, Prochilodus argenteus, and Salminus franciscanus. Stripped oocytes, embryo, and yolk-sac larvae were analyzed by scanning electron microscopy (SEM) and histology. A set of 10 lectins was used for investigation of lectin-binding pattern in oocytes. In the four species, the outer layer of the zona radiata reacted to most lectins, indicating complex polysaccharides at the oocyte surface while no reactivity was detected in the inner zona radiata and yolk globules. Typical structural arrangements were recognized at the micropylar region by SEM. The four species showed nonadhesive eggs, short embryonic period (18-20 h at 24 ± 1°C), and poorly developed larvae at hatching. At 24 h posthatching (hph), larvae of the four species had neuromasts on the body surface. Rudimentary cement glands for larval attachment were identified on the cephalic region at 24 and 48 hph in B. orthotaenia and S. franciscanus, and following they were in regression. The time for whole yolk resorption varied among species from 48 to 120 hph, occurring earlier in S. franciscanus, followed by B. orthotaenia, P. argenteus, and L. obtusidens. The formation of the digestive tract and the mouth opening indicated initiation of exogenous feeding 24 h before complete resorption of the yolk. Together, our data indicate similarities in the early development among species that may be related to the life cycle strategies and phylogeny.

Ontogenic change in tissue osmolality and developmental sequence of mitochondria-rich cells in Mozambique tilapia developing in freshwater.

We investigated a change in tissue fluid osmolality and developmental sequences of mitochondria-rich (MR) cells during embryonic and larval stages of Mozambique tilapia, Oreochromis mossambicus, developing in freshwater. Tissue osmolality, representing body fluid osmolality, ranged from 300 to 370 mOsm/kg during embryonic and larval stages. This suggests that tilapia embryos and larvae are also able to regulate body fluid osmolality to some extent, although the levels are somewhat higher and fluctuate more greatly in embryos and larvae than in adults. Na(+)/K(+)-ATPase-immunoreactive MR cells were first detected in the yolk-sac membrane 3 days before hatching (day -3), followed by their appearance in the body skin on day -2. Subsequently, MR cells in both the yolk-sac membrane and body skin increased in number, and most densely observed on days -1 and 0. Whereas yolk-sac and skin MR cells decreased after hatching, MR cells in turn started developing in the gills after hatching. Thus, the principal site for MR cell distribution shifted from the yolk-sac membrane and body skin during embryonic stages to the gills during larval stages, and tilapia could maintain continuously their ion balance through those MR cells during early life stages.

Aspectos morfológicos do saco vitelino em roedores da subordem Hystricomorpha: paca (Agouti paca) e cutia (Dasyprocta aguti) / Morphological aspects of yolk sac from rodents of Hystricomorpha subordem: paca (Agouti paca) and agouti (Dasyprocta aguti)

Este trabalho visou caracterizar macro e microscopicamente o saco vitelino em pacas (Agouti paca) e cutias (Dasyprocta aguti) no início de gestação. Três embriões/fetos de pacas e três de cutias foram utilizados para a análise do saco vitelino, durante as fases iniciais de gestação. Fragmentos do saco vitelino foram removidos do embrião/feto e rotineiramente processados para inclusão em parafina (técnica histológica rotineira) e em resina Spurr (análise ultra-estrutural). Macroscopicamente, a placenta vitelínica em ambas as espécies inseria-se na superfície da placenta principal, com suas margens projetando-se completamente sobre o embrião/fetos. Na microscopia de luz, a placenta vitelínica apresentava-se constituída pelo epitélio endodérmico e um mesenquima com inúmeros vasos vitelínicos. Ultraestruturalmente, a placenta vitelínica visceral da paca era formada por células endodérmicas com núcleos na região mediana e da cutia por núcleos dispostos apicalmente; outra característica foi o grande número de mitocôndrias, vesículas de conteúdo eletrodenso e com microvilosidades. Com base nos resultados concluímos, que (1) a placenta vitelínica das duas espécies apresenta inserção na superfície da placenta principal; (2) a placenta vitelínica de paca se apóia na membrana de Reichert, diferentemente da cutia, que não possui tal membrana; (3) o cório e alantóide apresentam-se fusionados, formando a placenta corioalantoídea; e (4) o saco vitelino em ambas as espécies é invertido e vascularizado.

The study aimed to characterize gross and microscopic features of the yolk sac in paca (Agouti paca) and agouti (Dasyprocta aguti) in early gestation. Fragments of the yolk sac of 3 paca and 3 agouti fetuses at early gestation were taken and processed for histological and ultrastructural analyses. Gross features of the vitelline placenta in both species showed its insertion over the main placenta surface and projections to the embryos/fetuses. Microscopically, the vitelline placenta was constituted by endoderm epithelium and mesenchyme, in which vitelline vessels are abundant. The ultrastructure of the samples showed that the visceral yolk sac of the paca was formed by endodermic cells with nuclei in the median region, and that the visceral yolk sac of the agouti was formed by nuclei arranged apically; other characteristic was the large number of mitochondrias, eletrodense vesicles with microvilosities We conclude that (1) the vitelline placenta of the two species presents insertion in the surface of the main placenta; (2) the vitelline placenta of paca rests on the Reichert's membrane, whereas the agouti vitelline placenta does not have this membrane; (3) the chorion and allantoic are fusioned; and (4) the chorioallantoic placenta and the yolk sac in both species are reversed and vascularized.

Significance of aquaporins and sodium potassium ATPase subunits for expansion of the early equine conceptus.

Expansion of the equine conceptus can be divided into blastocoel and yolk sac phases. The endodermal layer transforming the blastocoel into the yolk sac is completed around day 8 of pregnancy. From that time, the size of the spherical conceptus increases tremendously due mainly to the accumulation of fluid rather than cell multiplication. In this study, we have investigated the abundance and localisation of Na(+)/K(+)-ATPases and aquaporins (AQP) in the equine conceptus on days 8, 10, 12, 14 and 16 by multiplex reverse transcriptase PCR, Western blot and immunohistochemistry. During conceptus expansion, the ectoderm of the yolk sac exhibited basolateral abundance of alpha1ATPase, apical localisation of AQP5, and membrane and cytoplasmic expression of AQP3. With increasing conceptus size its cells showed an extensive enlargement of the apical membrane surface by microvilli. From day 14 onwards, the yolk sac endoderm forms arc-like structures with attaching sites to the ectodermal layer and shows intensive staining for alpha1ATPase, AQP5 and AQP3 in the membrane as well as in the cytoplasm. In the yolk sac ectoderm, the arrangement of these proteins is comparable with the collecting ducts of kidney with AQP2 being replaced by the closely related AQP5. The detection of phosphorylation sites for protein kinase A suggests a similar AQP5 traffic and regulation as known for AQP2 in the collecting ducts of the kidney. The arrangement of these proteins in equine embryos indicates at least partially the mechanism of conceptus expansion.

SRG3, a core component of mouse SWI/SNF complex, is essential for extra-embryonic vascular development.

The SWI/SNF chromatin-remodeling complex functions as a transcriptional regulator and plays a significant role in cell proliferation, differentiation and embryonic development. SRG3, a homologue of human BAF155, is a core component of the mouse SWI/SNF chromatin remodeling complex. Mutant mice deficient in Srg3 expression are peri-implantation lethal. To investigate the role of SRG3 in the post-implantation stage, we generated SRG3 transgene-rescued (Srg3-/-Tg+) embryos by inducing exogenous gene expression. These Srg3-/-Tg+ embryos overcame early embryonic lethality and extended the life span until mid-gestation. However, the embryos displayed significant defects in blood vessel formation and fetal circulation within the yolk sac around embryonic day 10.5, which led to developmental retardation and death. We found that SRG3 expression was absent in the visceral endoderm of Srg3-/-Tg+ yolk sacs, while SRG3 was normally expressed in wild-type embryos. In addition, expression of angiogenesis-related genes, including Angiopoietin1, Tie2, EphrinB2, Ihh and Notch1, was markedly reduced in Srg3-/-Tg+ yolk sacs. During normal angiogenesis, maturation of the visceral endoderm development is observed in the yolk sac. However, in Srg3-/-Tg+ yolk sacs, the visceral endoderm did not develop normally. Our results indicate that SRG3 is required for angiogenesis and visceral endoderm development in the yolk sac.

The chromatin-remodeling enzyme BRG1 plays an essential role in primitive erythropoiesis and vascular development.

ATP-dependent chromatin-remodeling complexes contribute to the proper temporal and spatial patterns of gene expression in mammalian embryos and therefore play important roles in a number of developmental processes. SWI/SNF-like chromatin-remodeling complexes use one of two different ATPases as their catalytic subunit: brahma (BRM, also known as SMARCA2) and brahma-related gene 1 (BRG1, also known as SMARCA4). We have conditionally deleted a floxed Brg1 allele with a Tie2-Cre transgene, which is expressed in developing hematopoietic and endothelial cells. Brg1(fl/fl):Tie2-Cre(+) embryos die at midgestation from anemia, as mutant primitive erythrocytes fail to transcribe embryonic alpha- and beta-globins, and subsequently undergo apoptosis. Additionally, vascular remodeling of the extraembryonic yolk sac is abnormal in Brg1(fl/fl):Tie2-Cre(+) embryos. Importantly, Brm deficiency does not exacerbate the erythropoietic or vascular abnormalities found in Brg1(fl/fl):Tie2-Cre(+) embryos, implying that Brg1-containing SWI/SNF-like complexes, rather than Brm-containing complexes, play a crucial role in primitive erythropoiesis and in early vascular development.

Identification of high proliferative potential precursors with hemangioblastic activity in the mouse aorta-gonad- mesonephros region.

Hemangioblast, a precursor possessing hematopoietic and endothelial potential, is identified as the blast colony-forming cell in the murine gastrulating embryos (E7.0-E7.5). Whether hemangioblast exists in the somite-stage embryos is unknown, even though hemogenic endothelium is regarded as the precursor of definitive hematopoiesis in the aorta-gonad-mesonephros (AGM) region. To address the issue, we developed a unique three-step assay of high proliferative potential (HPP) precursors. The AGM region contained a kind of HPP precursor that displayed hematopoietic self-renewal capacity and was able to differentiate into functional endothelial cells in vitro (i.e., incorporating DiI-acetylated low-density lipoprotein, expressing von Willebrand factors, and forming network structures in Matrigel). The clonal nature was verified by cell mixing assay. However, the bilineage precursor with high proliferative potential-the HPP-hemangioblast (HA)-was not readily detected in the yolk sac (E8.25-E12.5), embryonic circulation (E10.5), placenta (E10.5-E11.5), fetal liver (E11.5-E12.5), and even umbilical artery (E11.5), reflective of its strictly spatial-regulated ontogeny. Expression of CD45, a panhematopoietic marker, distinguished hematopoietic-restricted HPP-colony-forming cell from the bipotential HPP-HA. Finally, we revealed that basic fibroblast growth factor, other than vascular endothelial growth factor or transforming growth factor-beta1, was a positive modulator of the HPP-HA proliferation. Taken together, the HPP-HA represents a novel model for definitive hemangioblast in the mouse AGM region and will shed light on molecular mechanisms underlying the hemangioblast development. Disclosure of potential conflicts of interest is found at the end of this article.

Uterine epithelial changes during placentation in the viviparous skink Eulamprus tympanum.

We used scanning electron microscopy (SEM) and transmission electron microscopy (TEM) to describe the complete ontogeny of simple placentation and the development of both the yolk sac placentae and chorioallantoic placentae from nonreproductive through postparturition phases in the maternal uterine epithelium of the Australian skink, Eulamprus tympanum. We chose E. tympanum, a species with a simple, noninvasive placenta, and which we know, has little net nutrient uptake during gestation to develop hypotheses about placental function and to identify any difference between the oviparous and viviparous conditions. Placental differentiation into the chorioallantoic placenta and yolk sac placenta occurs from embryonic Stage 29; both placentae are simple structures without specialized features for materno/fetal connection. The uterine epithelial cells are not squamous as previously described by Claire Weekes, but are columnar, becoming increasingly attenuated because of the pressure of the impinging underlying capillaries as gestation progresses. When the females are nonreproductive, the luminal uterine surface is flat and the microvillous cells that contain electron-dense vesicles partly obscure the ciliated cells. As vitellogenesis progresses, the microvillous cells are less hypertrophied than in nonreproductive females. After ovulation and fertilization, there is no regional differentiation of the uterine epithelium around the circumference of the egg. The first differentiation, associated with the chorioallantoic placentae and yolk sac placentae, occurs at embryonic Stage 29 and continues through to Stage 39. As gestation proceeds, the uterine chorioallantoic placenta forms ridges, the microvillous cells become less hypertrophied, ciliated cells are less abundant, the underlying blood vessels increase in size, and the gland openings at the uterine surface are more apparent. In contrast, the yolk sac placenta has no particular folding with cells having a random orientation and where the microvillous cells remain hypertrophied throughout gestation. However, the ciliated cells become less abundant as gestation proceeds, as also seen in the chorioallantoic placenta. Secretory vesicles are visible in the uterine lumen. All placental differentiation and cell detail is lost at Stage 40, and the uterine structure has returned to the nonreproductive condition within 2 weeks. Circulating progesterone concentrations begin to rise during late vitellogenesis, peak at embryonic Stages 28-30, and decline after Stage 35 in the later stages of gestation. The coincidence between the time of oviposition and placental differentiation demonstrates a similarity during gestation in the uterus between oviparous and simple placental viviparous squamates.

Histology and immunology of the placenta in the Atlantic sharpnose shark, Rhizoprionodon terraenovae.

The Atlantic sharpnose shark, Rhizoprionodon terraenovae, is viviparous species that forms a yolk sac placenta to facilitate exchange between mother and embryo. However, very little is known about the immunological aspects of this organ in sharks. To begin to understand this, we used histology, histochemistry and immunohistochemistry to investigate the sharpnose shark placenta throughout gestation. We report the presence of lymphoid aggregates in the maternal portion of the placenta during all stages of gestation, and their increasing size and vascularity near term. Immunoglobulin is found in the maternal tissues of the placenta, but its presence in embryonic tissue and potential transfer from maternal circulation remains unclear. Placental cells resembling mammalian uterine NK cells and melanomacrophages of lower vertebrates are described for the first time. Similarities with mammalian placentae point to shared aspects in the co-evolution of reproductive and immune systems, even between two phylogenetically diverse groups in which placentation arose by convergent evolution.

Chloride turnover and ion-transporting activities of yolk-sac preparations (yolk balls) separated from Mozambique tilapia embryos and incubated in freshwater and seawater.

We have recently established a unique in vitro experimental model for mitochondrion-rich cell (MRC) research, a ;yolk-ball' incubation system, in which the yolk sac is separated from the embryonic body of Mozambique tilapia embryos and subjected to in vitro incubation. To evaluate the ion-transporting property of the yolk balls, we examined Cl- content and turnover in yolk balls incubated in freshwater and seawater for 48 h, and distribution patterns of three ion transporters, Na+/K+-ATPase, Na+/K+/2Cl- cotransporter (NKCC) and cystic fibrosis transmembrane conductance regulator (CFTR), in MRCs in the yolk-sac membrane. The Cl- turnover rate measured by whole-body influx of 36Cl- was about 60 times higher in yolk balls in seawater than in freshwater, while there was no essential difference in Cl- content between them. Na+/K+-ATPase-immunoreactive MRCs were larger in yolk balls from seawater than yolk balls from freshwater. Distribution patterns of ion-transporting proteins allowed us to classify MRCs in freshwater yolk balls into three types: cells showing only basolateral Na+/K+-ATPase, cells showing basolateral Na+/K+-ATPase and apical NKCC, and cells showing basolateral Na+/K+-ATPase and basolateral NKCC. The seawater yolk balls, on the other hand, were characterized by the appearance of MRCs possessing basolateral Na+/K+-ATPase, basolateral NKCC and apical CFTR. Those seawater-type MRCs were considered to secrete Cl- through the CFTR-positive apical opening to cope with diffusional Cl- influx. These findings indicate that the yolk balls preserve the Cl- transporting property of intact embryos, ensuring the propriety of the yolk ball as an in vitro experimental model for the yolk-sac membrane that contains MRCs.

Emergence of a glomus-like body in the human yolk sac: a microanatomical analysis of its structure.

Since the last decade the Yolk sac (YS) has been a topic of increasing interest due to the growing use of high-resolution sonography in early determination of pregnancy. Human YS shape and diameter are indicators of viability of pregnancy during the early embryonic period. Nevertheless, the major interest concerns the vital function it plays in early embryo growth and development. Two compartments are recognized in this organ: the yolk sac proper and the vitelline stalk. In this study we report the identification and partial characterization of a glomus-like body in the wall of the secondary YS in humans. A detailed structural description is also presented on the time course of formation of this new structure, at precisely sequential stages between 4-8 wk post-conception. The significance of this new compartment on the YS function is analyzed. Light and scanning electron microscopy were used to investigate the microstructure of the YS and the vitelline stalk during the first 8 wk of development. Ten YSs were collected from embryos (aged between 24-50 days) obtained from emergency salpingectomies due to tubal ectopic pregnancy. From 5 wk onward a new structure was observed in the YS located near the apex of the pear-shaped yolk vesicle and closed to the connecting stalk. We designate this differentiation as glomus-like body. This structure is 1-1.5 mm long and merged from a pocket-like structure of the extraembryonic splanchnic mesoderm of the YS wall. It likely represents an area of convergence of the vascular network of the YS wall. Our findings underline the remarkable complexity of the human secondary yolk sac during early development. The detailed description of the microanatomy of this vital organ is of theoretical and practical interest in order to unravel the mechanisms used by the yolk sac to transport nutrients to the embryo.

Ultrastructure of the maternal-fetal interface of the yolk sac placenta in sharks.

The blacknose shark, Carcharhinus acronotus, is a viviparous anamniote that develops an epitheliochorial yolk sac placenta. The fetal portion of the uteroplacental complex consists of a proximal portion that forms saccular evaginations. The cells are bilayered stratified squamous with surface microvilli and a high concentration of cytoplasmic filaments. The tertiary egg envelope intervenes between the distal portion of the placenta and uterus. It has delaminations on the uterine surface and is compacted on the placental surface. The uterine epithelium is cuboidal to columnar and is characterized by prominent RER, Golgi, and secretion vesicles. The capillary endothelium is continuous. Nutrient and respiratory exchange is effected between the uterus and distal portion of the yolk sac. The distal portion of the placenta is a bilayer. An elaborate array, of microvilli forms an interface with the egg envelope. Dense non-membrane bound granules occur in the interspace between the egg envelope and the distal placenta. This material, presumably of uterine origin, is endocytosed in smooth-walled vesicles of the placental cells. The endothelium of the capillaries is fenestrated.

Vitellin cleavage products are proteolytically degraded by ubiquitination in stick insect embryos.

Vitellin polypeptides are proteolytically processed in ovarian follicles and embryos of the stick insect Carausius morosus. Data show that vitellin polypeptide A(3) of 54kDa is processed to yield polypeptide A(3)(*) of about 48kDa upon completion of ovarian development, whereas vitellin polypeptide A(2) of 90kDa yields polypeptide E(9) during embryonic development. As vitellin polypeptides are processed, polypeptides A(3)(*) and E(9) are transferred from the yolk granules to the cytosolic space of the vitellophages and start to express a ubiquitin reactivity. At the confocal microscope, anti-ubiquitin antibodies label specifically numerous small yolk granules and the cytosolic space of vitellophages. During embryonic development, ubiquitin carrying granules undergo acidification in much the same way as larger yolk granules. However, only these latter organelles are capable of converting a latent cysteine pro-protease into an active yolk protease upon acidification of their luminal space. These data are interpreted as indicating that ubiquitin-like polypeptides are restricted to small granules throughout ovarian and embryonic development, and that vitellin cleavage products are ubiquitinated following acidification of large yolk granules and transfer to the cytosolic space of the vitellophages.

Genetic analysis of sorting nexins 1 and 2 reveals a redundant and essential function in mice.

Sorting nexins 1 (Snx1) and 2 (Snx2) are homologues of the yeast gene VPS5 that is required for proper endosome-to-Golgi trafficking. The prevailing thought is that Vps5p is a component of a retrograde trafficking complex called the retromer. Genetic and biochemical evidence suggest mammals may have similar complexes, but their biological role is unknown. Furthermore, if SNX1 and SNX2 belong to such complexes, it is not known whether they act together or separately. Herein, we show that mice lacking SNX1 or SNX2 are viable and fertile, whereas embryos deficient in both proteins arrest at midgestation. These results demonstrate that SNX1 and SNX2 have a highly redundant and necessary function in the mouse. The phenotype of Snx1(-/-);Snx2(-/-) embryos is very similar to that of embryos lacking another retromer homologue, Hbeta58. This finding suggests that SNX1/SNX2 and Hbeta58 function in the same genetic pathway, providing additional evidence for the existence of mammalian complexes that are structurally similar to the yeast retromer. Furthermore, the viability of Snx1(-/-) and Snx2(-/-) mice demonstrates that it is not necessary for SNX1 and SNX2 to act together. Electron microscopy indicates morphological alterations of apical intracellular compartments in the Snx1(-/-);Snx2(-/-) yolk-sac visceral endoderm, suggesting SNX1 and SNX2 may be required for proper cellular trafficking. However, tetraploid aggregation experiments suggest that yolk sac defects cannot fully account for Snx1(-/-); Snx2(-/-) embryonic lethality. Furthermore, endocytosis of transferrin and low-density lipoprotein is unaffected in mutant primary embryonic fibroblasts, indicating that SNX1 and SNX2 are not essential for endocytosis in all cells. Although the two proteins demonstrate functional redundancy, Snx1(+/-);Snx2(-/-) mice display abnormalities not observed in Snx1(-/-);Snx2(+/-) mice, revealing that SNX1 and SNX2, or their genetic regulation, are not equivalent. Significantly, these studies represent the first mutations in the mammalian sorting nexin gene family and indicate that sorting nexins perform essential functions in mammals.

Ultrastructure of the placenta of the tammar wallaby, Macropus eugenii: comparison with the grey short-tailed opossum, Monodelphis domestica.

The ultrastructure of the tammar placenta was studied throughout pregnancy. The uterine epithelium grows from a columnar to an enlarged, undulating epithelium between early gestation and mid-gestation when the shell coat that surrounds the marsupial conceptus ruptures. Trophectoderm and uterine epithelium do not form syncytia, nor does invasion of the endometrium occur at any stage of pregnancy. Uterine secretion is provided to both the bilaminar and the trilaminar side of the yolk sac placenta up to birth. Fenestrations, abundant vesicles and lumenal processes of maternal capillaries, as well as deep basal folds of the uterine epithelium, suggest that there is transfer of hemotrophes adjacent to both parts of the yolk sac. In contrast, in the grey short-tailed opossum, these structures are lacking. The yolk sacs of adjacent embryos fuse to form a common yolk sac cavity, thus losing most of the bilaminar yolk sac. The bilaminar and trilaminar components of the yolk sac placenta of the tammar are less different in structure and function than those of the grey short-tailed opossum, but both types are fully functional placentas. The extended secretory phase of the tammar uterus and the maternal recognition of early pregnancy appear to be derived characters of macropodid marsupials.

Serosa membrane plays a key role in transferring vitellin polypeptides to the perivitelline fluid in insect embryos.

In mid-embryogenesis, the stick insect Carausius morosus comes to be comprised of three distinct districts: the embryo proper, the yolk sac and the perivitelline fluid. A monolayered epithelium, the so-called serosa membrane, encloses the yolk sac and its content of vitellophages and large yolk granules. During embryonic development, the yolk sac declines gradually in protein concentration due to Vt polypeptides undergoing limited proteolysis to yield a number of Vt cleavage products of lower molecular weights. mAbs 1D1 and 5H11 are monoclonal antibodies raised against some of the Vt cleavage products generated by this process in the yolk sac. At the confocal microscope, antibody fluorescence is initially associated with a few yolk granules, while it is gradually displaced in the cytosolic spaces of the vitellophages. With the proceeding of embryonic development, label appears also in the serosa membrane in the form of clustered dots. At the ultrastructural level, gold particles are initially associated with the vitellophages that are labeled on a few yolk granules and in the cytosolic space flanking the yolk granules. Subsequently, the serosa cells become labeled on vesicles close to the yolk granules or just underneath the plasma membrane. Inside the serosa cells, label is also associated with granules budding from the Golgi apparatus, but never with the intercellular channels percolating the serosa membrane. These observations are interpreted as indicating that Vt cleavage products leak out from the yolk granules into the cytosolic spaces of the vitellophages and are eventually transferred to the perivitelline fluid via transcytosis through the serosa cells.

Yolk utilization in stick insects entails the release of vitellin polypeptides into the perivitelline fluid.

This study investigates the developmental fate of vitellin (Vt) polypeptides generated by limited proteolysis in an insect embryo. To this end, a number of polyclonal (pAb) and monoclonal antibodies (mAb) were raised against the yolk sac and the perivitelline fluid of late embryos of the stick insect Carausius morosus. Two dimensional immuno gel electrophoresis and Western blotting demonstrate that polypeptides resulting from Vt processing are present both in the yolk sac and the perivitelline fluid. At the confocal microscope, different labelling patterns were detected in the ooplasm depending on the stage of development attained by the embryo. At early developmental stages, label is associated with large unsegmented portions of the fluid ooplasm. During embryonic development, the fluid ooplasm is gradually transformed into yolk granules by intervention of vitellophages. Prior to dorsal closure, the yolk sac is separated from the perivitelline fluid by interposition of serosa cells (the so called serosa membrane). Several mAbs raised against the perivitelline fluid react specifically with this membrane suggesting that the release of Vt polypeptides from the yolk sac occurs by intracellular transit through the serosa cells. By immunocytochemistry, gold label appears associated with the cell surface and a number of vacuoles of the serosa membrane. These data are interpreted as suggesting that Vt polypeptides resulting from limited proteolysis in stick insect embryos are not exhaustively degraded within the yolk sac, but are instead transferred transcytotically to the perivitelline fluid through the serosa membrane.

The serosa of Manduca sexta (Insecta, Lepidoptera): ontogeny, secretory activity, structural changes, and functional considerations.

In Manduca sexta, the blastoderm forms successively and becomes immediately cellularized as the cleavage energids reach the surface of the oocyte. Presumptive serosal cells are large and contain 2 or 4 large polyploid nuclei; presumptive embryonic cells are small and mononuclear. All parts of the blastoderm participate in the uptake and digestion of yolk material. About 10 h post-oviposition, the blastoderm breaks at the amnioserosal fold and the extraembryonic part closes above the germ band and constitutes the serosa (12 h post-oviposition, i.e. 10% development completed). At once, the serosa starts to secrete a cuticle consisting of an epi- and a lamellated endocuticle. Detachment of the serosal cuticle, 22h post-oviposition, is reminiscent of apolysis of larval cuticle. Thereafter, the serosa deposits a membranous structure, the serosal membrane. The sercretory process lasts from 23h to 44h post-oviposition. At first a fine granular layer, then an amorphous, spongy-like, fibrillar layer is secreted via microvilli. This persisting membrane is tough, rubbery and very elastic. It may serve to bolster the serosa during katatrepsis (48h post-oviposition) and later embryonic movements. After detachment of the serosal membrane, 44h post-oviposition, a distinct subcellular reorganization of the serosa takes place. The nuclei become still larger and more irregular. Uptake of yolk granules, but not of lipid droplets, ceases, although interaction of serosa and yolk cells are intense. Serosal cells include many mitochondria, large areas of rER, besides some sER, increasing amounts of lysosomal bodies and prominent Golgi complexes. Most conspicuous is the assembly of spindle-shaped, electron-lucent vesicles below the apical surface. These vesicles may contain metabolic products which are released into the peripheral space. The studies show that the serosa assumes changing functions during embryogenesis: digestion of yolk substances, synthesis of a serosal cuticle and a serosal membrane, which may have a protective function, and excretion.