The effects of alcohols on pinocytosis and proteolysis in the rat yolk sac in vitro

Steventon, Glyn B.

January 1987

No description available.

572

Rat visceral yolk sac

The 'giant' yolk sac : an in vitro model for studying early placental transport

Dunton, Anne

January 1988

In the rat, before the establishment of the chorioallantoic placenta, the nutritional requirements of the post-implantation embryo, are met solely by the visceral yolk sac and therefore a study of its structure and functions is essential to a full understanding of early embryonic nutrition. A method has been developed for maintaining the rat visceral yolk sac in organ culture over a prolonged period, having first removed the embryo by microsurgery at 9.5 days or alternatively allowing it to die within its own amnion. The yolk sac continues to grow as a closed vesicle, and can reach a diameter of 2cm. The system has been called the 'giant' yolk sac. The 'giant' yolk sac and in vivo yolk sac have been compared using various criteria. A detailed morphological study was made, including a quantitative analysis of the vacuolar compartment. The endocytic capacity of both systems was studied using three different substrates; those used were 125I-polyvinylpyrrolidone (PVP), a non-degradable macromolecule, taken up in the fluid phase and accumulated within the yolk sac tissue, 125I-bovine serum albumin (BSA) taken up by adsorptive pinocytosis and digested within the lysosomes and 125I-IgG (and colloidal gold-IgG) taken up with great efficiency by specific receptor mediated endocytosis. Also a preliminary study of 14C-amino acid uptake was made. In many instances the 'giant' yolk sac functioned very similarly to the in vivo yolk sac and therefore seems an ideal model for studying transport across an epithelial sheet. It is particularly useful as its continuous epithelium separates the exocoelom from the external culture medium. The fluid maintained within the exocoelom of the 'giant' yolk sac should be an excellent source of processed histiotroph essential for embryonic nutrition during organogenesis. Experiments carried out indicate that some of the trophic factors necessary for growth are present in this fluid.

611

Rat visceral yolk sac][Fetal nutrition

LONG-TERM OUTCOME AND PROGNOSTIC FACTORS FOR YOLK SAC TUMOR OF THE OVARY

UMEZU, TOMOKAZU, KAJIYAMA, HIROAKI, TERAUCHI, MIKIO, SHIBATA, KIYOSUMI, INO, KAZUHIKO, NAWA, AKIHIRO, KIKKAWA, FUMITAKA

03 1900

No description available.

Yolk sac tumor

Survival

Prognostic factor

Ontogeny and biological function of epithelial cells in the chicken yolk sac and small intestine

Zhang, Haihan

11 October 2018

The chicken yolk sac and small intestine are connected through the yolk stalk and share many biological similarities. During the embryonic stage, the extra-embryonic yolk sac helps the embryo to absorb nutrients primarily in the last two weeks of incubation. The chicken yolk sac physically moves yolk contents from the yolk sac to the small intestine at the end of embryogenesis. This is the time when the small intestine replaces the yolk sac in assimilating nutrients for the embryo and later for the posthatch chicken. Additionally, both chicken small intestinal epithelia and the yolk sac secrete beta defensins for promoting intestinal health. Since there are heterogeneous cell types along the mammalian intestinal villus, which are derived from the intestinal stem cells in the crypts, we investigated if cells of the chicken yolk sac and small intestine have the same ontogeny as mammalian intestinal epithelial cells. In this dissertation, we mainly focused on the spatial expression of nutrient transporters (PepT1 and SGLT1), intestinal stem cell markers (Lgr5 and Olfm4), and avian beta defensins in the chicken yolk sac and small intestine during the embryonic and early posthatch stages. RNAscope in situ hybridization was used to identify the distribution of cells expressing PepT1 mRNA in both the chicken yolk sac and small intestine. PepT1 mRNA was found to be expressed by epithelial cells in both the yolk sac and small intestine. In the yolk sac, PepT1 mRNA was uniformly distributed in each endodermal epithelial cell along the villus-like structure. The pattern of PepT1 mRNA expression observed in the chicken yolk sac during the last 10 days of incubation revealed that PepT1 mRNA was increased from e11 to e13, and decreased from e15 to day of hatch. The peak of PepT1 mRNA expression was between e13 and e15, when the yolk sac reaches maximum absorptive area and the growth of the chicken embryo is at its fastest rate. However, the expression of PepT1 mRNA in the intestine was only detected in columnar enterocytes along the villus and not in goblet cells or cells in the crypts. The immunofluorescence assay confirmed that PepT1 protein was located at the brush border membrane of the enterocytes and that protein expression of PepT1 was restricted to the intestinal epithelial cells from approximately the middle to the tip of the villus. In order to identify intestinal stem cells, we used the known mammalian stem cell markers, Lgr5 and Olfm4. Both Lgr5 and Olfm4 are specifically expressed by cells in the chicken intestinal crypts, suggesting that they can be used as biomarkers for chicken intestinal stem cells. Dual labelling of PepT1 and Olfm4 mRNA on the same chicken intestinal sample revealed that there was a gap between PepT1-expressing enterocytes and Olfm4-expressing intestinal stem cells. The cells in this gap were presumably transit amplifying (TA) cells. Additionally, we also found that the TA cell zone along the intestinal villus was reduced during chicken growth. This TA cell population could be clearly detected at day of hatch and d1 posthatch but not later. The expression of SGLT1 mRNA was localized to yolk sac endodermal epithelial cells and showed a sharp increase at the end of incubation. This increase of SGLT1 mRNA coincided with the increase in glucose in the yolk, indicating that the chicken embryo needs glucose as energy for hatching. The mRNA expression profiles of various avian beta defensins have been examined by qPCR and in situ hybridization to investigate the immune function of the yolk sac and small intestine. We found that AvBD10 mRNA showed the highest expression level in the yolk sac and was expressed predominantly in the yolk sac endodermal epithelial cells. Additionally, the expression of AvBD10 mRNA showed a development-specific pattern, which increased from e9 to e11, and decreased from e13 towards day of hatch. The expression patterns of AvBD1, 2, and 7 mRNA were similar to each other. These three genes were found to be expressed by chicken heterophils distributed in the yolk sac blood islands and small intestinal blood vessels. Only a subset of heterophils, which might be activated, were able to express AvBD1, 2, and 7 mRNA. In the intestine, the expression of AvBD10 mRNA was localized to cells along the villus at e19 and day of hatch, but later to only a few cells located above the intestinal crypts. In summary, the endodermal epithelial cells are responsible for the absorptive and immune functions of the chicken yolk sac. The yolk sac mesoderm is critical for embryonic hematopoiesis and innate immunity. The chicken small intestinal epithelial cells are derived from the intestinal stem cells in the crypts. These epithelial cells have different cell types, which are functioning to absorb nutrients and secrete antimicrobial peptides. / Ph. D. / The chicken yolk sac and small intestine are connected to each other and share many biological similarities. Both chicken small intestinal and yolk sac epithelia play critical roles for nutrient absorption and immune defense. In this dissertation, the mRNA for nutrient transporters such as the peptide transporter, PepT1 and the sodium-glucose co-transporter, SGLT1 were found to be expressed by absorptive epithelial cells in both the yolk sac and small intestine. Additionally, both intestinal and yolk sac epithelial cells expressed avian beta defensins (AvBDs), which are important chicken host defense peptides. In the small intestine, there are a number of differentiated cell types that originate from stem cells in the crypt that express the known mammalian stem cell markers, Olfm4 and Lgr5 mRNA. However, in the chicken yolk sac, only the stem cell marker Lgr5 mRNA was expressed by endothelial cells. In summary, the yolk sac epithelial cells are responsible for the absorptive and immune functions for the embryonic stage. The chicken small intestinal epithelial cells are derived from the intestinal stem cells in the crypts. These epithelial cells have different cell types, which function to absorb nutrients and secrete antimicrobial peptides.

Chicken

Yolk sac

Small intestine

In situ hybridization

Caracterização da célula tronco hematopoética do saco vitelino em embriões bovinos / Characterization of hematopoietic stem cells of the yolk sac of bovine embryos

Oliveira, Vanessa Cristina de

17 December 2012

O saco vitelino é uma das membranas extra-embrionárias que desempenha um papel importante para a sobrevivência inicial do embrião, atua como fonte de nutrição durante o período em que a placenta verdadeira ainda não está completamente formada. É uma provável fonte de células tronco, o qual abriga as primeiras células do sangue durante o desenvolvimento em mamíferos, os eritrócitos, os quais expressam fatores de transcrição que especificam estas células a seu destino hematopoiético. O objetivo deste trabalho foi caracterizar as células tronco hematopoéticas provenientes do saco vitelino de embriões bovinos, em diferentes fases gestacionais, sendo estes coletados em abatedouro local. Para descrição da análise macroscópica e cultivo celular das células do saco vitelino, os embriões bovinos foram divididos em grupos de idade gestacional: Grupo I (25 a 29 dias), Grupo II (30 a 34 dias), Grupo III (35 a 39 dias), Grupo IV (40 a 44 dias) e Grupo V (45 a 50 dias) em que permaneceram mais tempo em cultura e apresentaram a formação de aglomerados celulares, diferente dos grupos IV e V (40 a 45 dias) em que permaneceram poucos dias em cultura e não apresentaram aglomerados celulares. Esta divergência relaciona-se à idade gestacional (45 a 50 dias), período em que se inicia a regressão do saco vitelino. Em citometria de fluxo os grupos I, II e III (25 a 39 dias) obtiveram características semelhantes, alta expressão de marcadores hematopoéticos (CD34, CD90 e CD117). Para os grupos IV e V (40 a 50 dias) observa-se um declínio da expressão de CD34 e CD117 (marcadores hematopoéticos) e no grupo V houve um acréscimo da expressão de CD45 (marcador para leucócito) confirmando que estas células não estão mantendo-se indiferenciadas As células demonstraram ser resistentes a criopreservação, capazes de formar colônias em matriz de Metilcelulose, mostraram a formação de colônias após 14 dias em cultivo e a morfologia para células sanguíneas (linfócitos e monócitos) foi confirmada na citologia celular. Na expressão gênica obteve-se baixa expressão do gene GATA3, níveis diferentes de expressão entre os grupos para o marcador RUNX1 e ANXA5. Dessa forma, nossos achados mais significativos comprovaram o isolamento de células hematopoéticas a partir do saco vitelino de embriões bovinos, sugerindo que este é uma fonte laboriosa, porém viável e eficaz para a obtenção de células tronco para futuras aplicações na terapia celular e gênica. / The yolk sac is one of the extra-embryonic membranes which plays an important role in early embryonic survival and serves as source of nutrition during the period where in the placenta is not completely true formed. The yolk sac is a likely source of stem cells, which have first blood cells during development in mammals, the red blood cells, which express transcription factors that specify these hematopoietic cells to their destination. This study aimed to identify and characterize hematopoietic stem cells from the yolk sac of bovine embryos at different stages of pregnancy, which are collected at a local slaughterhouse. For a description of the macroscopic and cellular culture of yolk sac cells, are as follows bovine embryos were divided into groups of gestational age: Group I (25 to 29 days), Group II (30 to 34 days), Group III (35 to 39 days ), Group IV (40 to 44 days) and Group V (45 to 50 days) which stayed longer in culture and showed the formation of cell clusters, different from groups IV and V (40-45 days) in few that remained days in culture and showed no cell clumps. This divergence is related to gestational age (45 to 50 days), during which begins regression of the yolk sac. In flow cytometry groups I, II and III (25 to 39 days) had similar characteristics, high expression of hematopoietic markers (CD34, CD90 and CD117). For the groups IV and V (40 to 50 days) it is observed a decrease in expression of CD117 and CD34 (hematopoietic markers) and in group V were increased expression of CD45 (leukocyte marker), confirming that these cells are not keeping Undifferentiated cells are shown to be resistant to cryopreservation, capable of forming colonies in methylcellulose matrix showed the formation of colonies after 14 days in culture morphology and to blood cells (lymphocytes and monocytes) was confirmed by cytology cell. In gene expression was low GATA3 gene expression, different levels of expression between the groups for the marker and RUNX1 ANXA5. Our most significant findings confirmed the isolation and identification of hematopoietic cells from the bovine embryo yolk sac, therefore, it is feasible and an effective way of obtaining stem cells for future applications in cell therapy and gene.

Célula tronco

Embrião

Embryo

Saco vitelino

Stem cell

Yolk sac

Caracterização da célula tronco hematopoética do saco vitelino em embriões bovinos / Characterization of hematopoietic stem cells of the yolk sac of bovine embryos

Vanessa Cristina de Oliveira

17 December 2012

O saco vitelino é uma das membranas extra-embrionárias que desempenha um papel importante para a sobrevivência inicial do embrião, atua como fonte de nutrição durante o período em que a placenta verdadeira ainda não está completamente formada. É uma provável fonte de células tronco, o qual abriga as primeiras células do sangue durante o desenvolvimento em mamíferos, os eritrócitos, os quais expressam fatores de transcrição que especificam estas células a seu destino hematopoiético. O objetivo deste trabalho foi caracterizar as células tronco hematopoéticas provenientes do saco vitelino de embriões bovinos, em diferentes fases gestacionais, sendo estes coletados em abatedouro local. Para descrição da análise macroscópica e cultivo celular das células do saco vitelino, os embriões bovinos foram divididos em grupos de idade gestacional: Grupo I (25 a 29 dias), Grupo II (30 a 34 dias), Grupo III (35 a 39 dias), Grupo IV (40 a 44 dias) e Grupo V (45 a 50 dias) em que permaneceram mais tempo em cultura e apresentaram a formação de aglomerados celulares, diferente dos grupos IV e V (40 a 45 dias) em que permaneceram poucos dias em cultura e não apresentaram aglomerados celulares. Esta divergência relaciona-se à idade gestacional (45 a 50 dias), período em que se inicia a regressão do saco vitelino. Em citometria de fluxo os grupos I, II e III (25 a 39 dias) obtiveram características semelhantes, alta expressão de marcadores hematopoéticos (CD34, CD90 e CD117). Para os grupos IV e V (40 a 50 dias) observa-se um declínio da expressão de CD34 e CD117 (marcadores hematopoéticos) e no grupo V houve um acréscimo da expressão de CD45 (marcador para leucócito) confirmando que estas células não estão mantendo-se indiferenciadas As células demonstraram ser resistentes a criopreservação, capazes de formar colônias em matriz de Metilcelulose, mostraram a formação de colônias após 14 dias em cultivo e a morfologia para células sanguíneas (linfócitos e monócitos) foi confirmada na citologia celular. Na expressão gênica obteve-se baixa expressão do gene GATA3, níveis diferentes de expressão entre os grupos para o marcador RUNX1 e ANXA5. Dessa forma, nossos achados mais significativos comprovaram o isolamento de células hematopoéticas a partir do saco vitelino de embriões bovinos, sugerindo que este é uma fonte laboriosa, porém viável e eficaz para a obtenção de células tronco para futuras aplicações na terapia celular e gênica. / The yolk sac is one of the extra-embryonic membranes which plays an important role in early embryonic survival and serves as source of nutrition during the period where in the placenta is not completely true formed. The yolk sac is a likely source of stem cells, which have first blood cells during development in mammals, the red blood cells, which express transcription factors that specify these hematopoietic cells to their destination. This study aimed to identify and characterize hematopoietic stem cells from the yolk sac of bovine embryos at different stages of pregnancy, which are collected at a local slaughterhouse. For a description of the macroscopic and cellular culture of yolk sac cells, are as follows bovine embryos were divided into groups of gestational age: Group I (25 to 29 days), Group II (30 to 34 days), Group III (35 to 39 days ), Group IV (40 to 44 days) and Group V (45 to 50 days) which stayed longer in culture and showed the formation of cell clusters, different from groups IV and V (40-45 days) in few that remained days in culture and showed no cell clumps. This divergence is related to gestational age (45 to 50 days), during which begins regression of the yolk sac. In flow cytometry groups I, II and III (25 to 39 days) had similar characteristics, high expression of hematopoietic markers (CD34, CD90 and CD117). For the groups IV and V (40 to 50 days) it is observed a decrease in expression of CD117 and CD34 (hematopoietic markers) and in group V were increased expression of CD45 (leukocyte marker), confirming that these cells are not keeping Undifferentiated cells are shown to be resistant to cryopreservation, capable of forming colonies in methylcellulose matrix showed the formation of colonies after 14 days in culture morphology and to blood cells (lymphocytes and monocytes) was confirmed by cytology cell. In gene expression was low GATA3 gene expression, different levels of expression between the groups for the marker and RUNX1 ANXA5. Our most significant findings confirmed the isolation and identification of hematopoietic cells from the bovine embryo yolk sac, therefore, it is feasible and an effective way of obtaining stem cells for future applications in cell therapy and gene.

Célula tronco

Embrião

Saco vitelino

Embryo

Stem cell

Yolk sac

Amniote Yolk Sacs: Diversity in Reptiles and a Hypothesis on Their Origin

Elinson, Richard P., Stewart, James R., Bonneau, Laurie J., Blackburn, Daniel G.

08 July 2014

Oviparous amniotes produce a large yolky egg that gives rise to a free-living hatchling. Structural characteristics and functional attributes of the egg are best known for birds, which have a large mass of fluid yolk surrounded by an extraembryonic yolk sac. Yolk nutrients are delivered to the embryo via the vascular yolk sac. This developmental pattern and nutrient transport mechanism is thought to be representative of all other lineages of amniotes. Recent discovery of a snake with cellularized yolk organized around a meshwork of blood vessels reveals an additional pattern for yolk mobilization, which may also occur in other squamate reptiles (lizards and snakes). This complex yolk sac raises interesting questions about developmental mechanisms and suggests a possible model for the transition between the egg of anamniotes and that of amniotes.

cleavage

embryo maintenance

oviparity

yolk

yolk sac

Biological Sciences

The Corn Snake Yolk Sac Becomes a Solid Tissue Filled With Blood Vessels and Yolk-Rich Endodermal Cells

Elinson, Richard P., Stewart, James R.

01 January 2014

The amniote egg was a key innovation in vertebrate evolution because it supports an independent existence in terrestrial environments. The egg is provisioned with yolk, and development depends on the yolk sac for the mobilization of nutrients. We have examined the yolk sac of the corn snake Pantherophis guttatus by the dissection of living eggs. In contrast to the familiar fluid-filled sac of birds, the corn snake yolk sac invades the yolk mass to become a solid tissue. There is extensive proliferation of yolk-filled endodermal cells, which associate with a meshwork of blood vessels. These novel attributes of the yolk sac of corn snakes compared with birds suggest new pathways for the evolution of the amniote egg.

amniote egg

corn snake

endoderm

yolk sac

Biological Sciences

Extraembryonic Membrane Development in a Reproductively Bimodal Lizard, Lacerta (Zootoca) Vivipara

Stewart, James R., Heulin, Benoit, Surget-Groba, Yann

15 December 2004

Reproductive mode has been remarkably labile among squamate reptiles and the evolutionary transition from oviparity to viviparity commonly has been accompanied by a shift in the pattern of embryonic nutrition. Structural specializations for placental transfer of nutrients during intrauterine gestation are highly diverse and many features of the extraembryonic membranes of viviparous species differ markedly from those of oviparous species. However, because of a high degree of evolutionary divergence between the species used for comparisons it is likely that the observed differences arose secondarily to the evolution of viviparity. We studied development of the extraembryonic membranes and placentation in the reproductively bimodal lizard Lacerta vivipara because the influence of reproductive mode on the structural/functional relationship between mothers and embryos can best be understood by studying the most recent evolutionary events. Lecithotrophic viviparity has evolved recently within this species and, although populations with different reproductive modes are allopatric, oviparous and viviparous forms interbreed in the laboratory and share many life history characteristics. In contrast to prior comparisons between oviparous and viviparous species, we found no differences in ontogeny or structure of the extraembryonic membranes between populations with different reproductive modes within L. vivipara. However, we did confirm conclusions from previous studies that the tertiary envelope of the egg, the eggshell, is much reduced in the viviparous population. These conclusions support a widely accepted model for the evolution of squamate placentation. We also found support for work published nearly 80 years ago that the pattern of development of the yolk sac of L. vivipara is unusual and that a function of a unique structure of squamate development, the yolk cleft, is hematopoiesis. The structure of the yolk sac splanchnopleure of L. vivipara is inconsistent with a commonly accepted model for amniote yolk sac function and we suggest that a long standing hypothesis that cells from the yolk cleft participate in yolk digestion requires further study.

chorioallantois

hematopoiesis

lacertilia

placentation

yolk sac

Biological Sciences

Gene Expression of Nutrient Transporters and Digestive Enzymes in the Yolk Sac Membrane and Small Intestine of the Developing Embryonic Chick

Speier, Jacqueline S.

20 September 2011

Chick embryos derive nutrients from the yolk during incubation and transition to intestinal absorption posthatch. Nutrient uptake is mediated by digestive enzymes and membrane bound transporter proteins. The objective of this study was to determine expression profiles of nutrient transporters and digestive enzymes during incubation in the yolk sac membrane (YSM) and small intestine of Leghorn and Cobb chickens derived from 22–30 wk (young) and 45–50 wk (old) breeder flocks. Genes examined included peptide transporter PepT1, amino acid transporters EAAT3, CAT1, and B0AT, monosaccharide transporters SGLT1 and GLUT5, and digestive enzymes APN and SI. Expression of these genes was measured in YSM at embryonic day (e) 11, 13, 15, 17, 19, 20, and 21 and small intestine at e15, e17, e19, e20, and e21. Absolute quantification real-time PCR assessed gene expression. PepT1, APN, and B0AT expression in YSM peaked between e15 and e17 and then decreased until e21, while expression increased over time in the small intestine. SGLT1 and EAAT3 expression increased over time in the small intestine and YSM. There was minimal gene expression of SI in the YSM, while the small intestine had high expression. GLUT5 and CAT1 expression decreased in the YSM, while peaking at e19 then decreasing in the small intestine. Breed and flock age affected expression levels in some genes. These results demonstrate that these genes show tissue- and development-specific patterns of expression and that the YSM expresses many digestive enzymes and nutrient transporters associated with the small intestine. / Master of Science

Digestive Enzymes

Nutrient Transporters

Intestine

Yolk Sac Membrane