Non-pathological Chondrogenic Features of Valve Interstitial Cells in Normal Adult Zebrafish.

In the heart, unidirectional blood flow depends on proper heart valve function. As, in mammals, regulatory mechanisms of early heart valve and bone development are shown to contribute to adult heart valve pathologies, we used the animal model zebrafish (ZF, Danio rerio) to investigate the microarchitecture and differentiation of cardiac valve interstitial cells in the transition from juvenile (35 days) to end of adult breeding (2.5 years) stages. Of note, light microscopy and immunohistochemistry revealed major differences in ZF heart valve microarchitecture when compared with adult mice. We demonstrate evidence for rather chondrogenic features of valvular interstitial cells by histological staining and immunodetection of SOX-9, aggrecan, and type 2a1 collagen. Collagen depositions are enriched in a thin layer at the atrial aspect of atrioventricular valves and the ventricular aspect of bulboventricular valves, respectively. At the ultrastructural level, the collagen fibrils are lacking obvious periodicity and orientation throughout the entire valve.

Conditional loss of hepatocellular Hedgehog signaling in female mice leads to the persistence of hepatic steroidogenesis, androgenization and infertility.

The Hedgehog signaling pathway is known to be involved in embryogenesis, tissue remodeling, and carcinogenesis. Because of its involvement in carcinogenesis, it seems an interesting target for cancer therapy. Indeed, Sonidegib, an approved inhibitor of the Hedgehog receptor Smoothened (Smo), is highly active against diverse carcinomas, but its use is also reported to be associated with several systemic side effects. Our former work in adult mice demonstrated hepatic Hedgehog signaling to play a key role in the insulin-like growth factor axis and lipid metabolism. The current work using mice with an embryonic and hepatocyte-specific Smo deletion describes an adverse impact of the hepatic Hedgehog pathway on female fertility. In female SAC-KO mice, we detected androgenization characterized by a 3.3-fold increase in testosterone at 12 weeks of age based on an impressive induction of steroidogenic gene expression in hepatocytes, but not in the classic steroidogenic organs (ovary and adrenal gland). Along with the elevated level of testosterone, the female SAC-KO mice showed infertility characterized by juvenile reproductive organs and acyclicity. The endocrine and reproductive alterations resembled polycystic ovarian syndrome and could be confirmed in a second mouse model with conditional deletion of Smo at 8 weeks of age after an extended period of 8 months. We conclude that the down-regulation of hepatic Hedgehog signaling leads to an impaired hormonal balance by the induction of steroidogenesis in the liver. These effects of Hedgehog signaling inhibition should be considered when using Hedgehog inhibitors as anti-cancer drugs.

The ductal origin of structural and functional heterogeneity between pancreatic islets.

Islets form in the pancreas after the first endocrine cells have arisen as either single cells or small cell clusters in the epithelial cords. These cords constitute the developing pancreas in one of its earliest recognizable stages. Islet formation begins at the time the cords transform into a branching ductal system, continues while the ductal system expands, and finally stops before the exocrine tissue of ducts and acini reaches its final expansion. Thus, islets continuously arise from founder cells located in the branching and ramifying ducts. Islets arising from proximal duct cells locate between the exocrine lobules, develop strong autonomic and sensory innervations, and pass their blood to efferent veins (insulo-venous efferent system). Islets arising from cells of more distal ducts locate within the exocrine lobules, respond to nerve impulses ending at neighbouring blood vessels, and pass their blood to the surrounding acini (insulo-acinar portal system). Consequently, the section of the ductal system from which an islet arises determines to a large extent its future neighbouring tissue, architecture, properties, and functions. We note that islets interlobular in position are frequently found in rodents (rats and mice), whereas intralobularly-located, peripheral duct islets prevail in humans and cattle. Also, we expound on bovine foetal Laguesse islets as a prominent foetal type of type 1 interlobular neuro-insular complexes, similar to neuro-insular associations frequently found in rodents. Finally, we consider the probable physiological and pathophysiological implications of the different islet positions within and between species.

Dual origin, development, and fate of bovine pancreatic islets.

Endocrine cells are evident at an early stage in bovine pancreatic development when the pancreas still consists of primitive epithelial cords. At this stage, the endocrine cells are interspersed between the precursor cells destined to form the ductulo-acinar trees of later exocrine lobules. We here demonstrate that, in bovine fetuses of crown rump length ≥ 11 cm, the endocrine cells become increasingly segregated from the developing exocrine pancreas by assembly into two units that differ in histogenesis, architecture, and fate. Small numbers of 'perilobular giant islets' are distinguishable from larger numbers of 'intralobular small islets'. The two types of islets arise in parallel from the ends of the ductal tree. Aside from differences in number, location, and size, the giant and small islets differ in cellular composition (predominantly insulin-synthesising cells vs. mixtures of endocrine cells), morphology (epithelial trabeculae with gyriform and rosette-like appearance vs. compact circular arrangements of endocrine cells), and in their relationships to intrapancreatic ganglia and nerves. A further difference becomes apparent during the antenatal period; while the 'interlobular small islets' persist in the pancreata of calves and adult cattle, the perilobular giant islets are subject to regression, characterised by involution of the parenchyma, extensive haemorrhage, leukocyte infiltration (myeloid and T-cells) and progressive fibrotic replacement. In conclusion, epithelial precursor cells of the ductolo-acinar tree may give rise to populations of pancreatic islets with different histomorphology, cellular composition and fates. This should be taken into account when using these cells for the generation of pancreatic islets for transplantation therapy.

Expression of KIT in the ovary, and the role of somatic precursor cells.

KIT is a type III receptor protein tyrosine kinase, and KITL its cognate ligand. KIT can mediate its effects via several intracellular signalling pathways, or by formation of a cell-cell anchor with its ligand. Through these mechanisms, KIT controls fundamental cellular processes, including migration, proliferation, differentiation and survival. These cellular processes are modulated by soluble KIT, a cleavage product of KIT, generated at the cell membrane. A cell-retained KIT cleavage fragment also arises from this cleavage event. This cleavage fragment must be distinguished from truncated KIT (trKIT), which originates through cryptic promoter usage. The expression of trKIT is highly restricted to postmeiotic germ cells in the testis. In contrast, KIT, together with its cleavage products, is present in somatic cells and germ cells in the gonads of both sexes. A functional KITL/KIT system is mandatory for normal population of the gonads by germ cells. Signalling via the KITL/KIT system promotes the growth, maturation, and survival of germ cells within the gonads, and prevents meiotic entry and progression. In addition to its importance in germ cell biology, the KITL/KIT system is crucial for gonadal stromal differentiation. During foetal life, KIT is expressed by testicular stromal precursor cells, which develop into Leydig cells. In the ovary, stromal cell KIT expression accompanies theca layer development around advanced follicles. After ovulation, KIT-immunopositive cells translocate from the theca layer to the luteal ganulosa where they contribute to a delicate cellular network that extends between the fully luteinised large luteal cells. In the outer regions of the developing corpus luteum, a highly conspicuous subpopulation of KIT/CD14-double-immunopositive cells can be observed. KIT/CD14-double-immunopositive cells are also seen in the haematopoietic-like colonies of long-term granulosa cultures established from late antral follicles. These cultures demonstrate expression of pluripotency marker genes such as octamer binding transcription factor-3/4 and sex determining region Y-box 2. The KIT/CD14-double-immunopositive cells can be purified and enriched by KIT-immunopositive magnetic cell sorting. Subsequent exposure of the KIT-expressing cells to the hanging drop culture method, combined with haematopoietic differentiation medium, provides the signals necessary for their differentiation into endothelial and steroidogenic cells. This suggests that monocyte-derived multipotent cells are involved in ovarian tissue remodelling. In summary, multicelluar KITL/KIT signalling organizes the stroma in the ovary and testis; monocyte-derived multipotent cells may be involved.

The CD34 surface antigen is restricted to glucagon-expressing cells in the early developing bovine pancreas.

Controversy remains regarding the origin of the pancreatic endocrine cells. It is generally accepted that the majority of insulin-secreting cells derive from the endodermal epithelium of the gastrointestinal tract. The aim of this study was to determine the contribution made by a particular cluster of differentiation (CD)-positive cells to the development of the bovine endocrine pancreas. In bovine embryos and foetuses with crown to rump lengths (CRL) ranging from 1 to 47 cm, cells staining positively for CD34 and/or CD133 were always more numerous in the left lobe and body of pancreas than in the right lobe. In the early stages of pancreatic development (CRL <5 cm), CD34 and/or CD133-reactive cells were concentrated within the epithelial cell cords that form the primitive pancreas. In later developmental stages (CRL >5 cm), individual or groups of CD34 and/or CD133-reactive cells were present in newly formed acini, which bulged out from the duct system that had arisen from the cords. Some of the positively stained cells accumulated in focal areas associated with hyperplastic intra-acinar cells. These "acino-insula-like complexes" appeared to enlarge with age and develop into intralobular Islets of Langerhans. Most of the described CD34 and/or CD133-reactive cells displayed co-localisation with glucagon. A negligible number of these cells showed co-localisation with insulin. Glucagon-stained cells were distinct from insulin-stained cells and were more abundant in embryonic and early foetal pancreata. Our data demonstrate that CD34 and/or CD133-reactive cells contribute to the pancreatic alpha cell population during early foetal development in cattle.

Progenitor cells harvested from bovine follicles become endothelial cells.

Hematopoietic-like colonies develop in post-confluent granulosa cell cultures derived from bovine antral follicles. Previously, we had shown that these colonies gave rise to macrophages. In the present study, we validated the presence of somatic KIT-positive (KIT(+)) progenitor cells in colony-containing granulosa cell cultures. The cultures expressed the progenitor cell markers Sox-2, Oct 3/4, KIT, and alkaline phosphatase in western blot analysis. The successful double immunofluorescence localization of KIT and CD14, CD45, CD133, or VEGF-R2 revealed a specific subpopulation of progenitor cells. Flow cytometry showed that cells doubly positive for KIT and CD14 or CD45 comprised less than 10% of the population. The KIT(+) cells were purified by magnetic selection and differentiated with the hanging drop technique using haematopoietic differentiation medium. Pure cultures of either granulosa cells or endothelial cells were obtained. The spindle-shaped and epithelioid phenotypes indicated endothelial cell heterogeneity of microvascular source. We conclude that progenitor cells are obtained from the follicle harvest, which differentiate into endothelial cells. The cells are relevant for findings to angiogenesis and luteinization of the corpus luteum.

Similar developmental patterns in immunolocalisation of stem cell factor and KIT in bovine meso- and metanephros.

The mesonephros is often regarded as a simplified version of the terminal renal organ, the metanephros. Both renal organs result from an epithelio-mesenchymal interaction between the Wolffian duct and the nephrogenic ridge. It appears that the epithelio-mesenchymal interaction makes use of similar signal cascades for both renal organs and that key events required for the development of the metanephros occur at earlier stages. In murine metanephroi, the stem cell factor (SCF)/-KIT-signal transduction pathway has recently been shown to regulate ureteric bud branching and epithelial cell differentiation. We immunohistochemically defined the time-sequence of KIT and SCF presence in both renal organs using bovine embryos/foetuses with crown rump length (CRL) of 1.7-24 cm. In the mesonephroi, epithelial cells with strong KIT staining were scattered in distal tubules, and SCF was expressed in the epithelial wall of corpuscles and proximal tubules. KIT positivity occurred in the metanephroi of embryos prior to SCF; KIT was predominantly localised at the ureteric bud tips in the nephrogenic zone. In foetuses of 13 cm and more CRL, the SCF/KIT profile of developmentally advanced nephrons mirrored the situation in the mesonephros. Epithelial cells with strong KIT staining were scattered in the cortical areas of distal tubules, while SCF was expressed in the epithelial wall of corpuscles and proximal tubules. Our morphological findings agree with a potential role of KIT at the ureteric bud tips and demonstrate a similar expression of KIT and SCF along the areas of developmentally advanced mesonephric and metanephric nephrons.

Receptors for NPY and PACAP differ in expression and activity during adipogenesis in the murine 3T3-L1 fibroblast cell line.

BACKGROUND AND PURPOSE: Neuropeptides are involved in the regulation of food intake in the central nervous system, but they might also act on peripheral fat tissue via neuropeptide receptors. EXPERIMENTAL APPROACH: We investigated the receptor expression and activity of pituitary adenylate cyclase-activating polypeptide (PACAP) and of neuropeptide Y at the mRNA and protein levels in the 3T3-L1 fibroblast line during differentiation into adipocytes. Intracellular calcium concentration was measured by calcium imaging. KEY RESULTS: The PACAP receptors PAC(1) and VPAC(2) as well as the neuropeptide Y(1) receptor were expressed at the mRNA level in fibroblasts, pre-adipocytes and adipocytes. The mRNA profile of the PAC(1) receptor isoforms showed the HOP sequence, whereas the HIP-isoform was present in subconfluent 3T3-L1 fibroblasts only. At the protein level, the mature 3T3-L1 adipocytes produced the PAC(1) and Y(1) receptors; only the PAC(1) receptor showed carbohydrate residues. Both neuropeptides induced an increase of intracellular calcium in mature adipocytes, which was absent in the precursor cells. These changes in calcium were mediated by Y(1) and PAC(1) receptors as demonstrated by the effects of specific receptor agonists and antagonists. CONCLUSIONS AND IMPLICATIONS: As the PAC(1)-HOP receptor variant seems to be responsible for PACAP-mediated calcium influx in many cell types, the HOP sequence might also mediate the increase in intracellular calcium in adipocytes. Because a high intracellular calcium level is associated with lipogenesis, peptidergic innervation of adipose tissue might be involved in stress-induced obesity.

Spheroids of granulosa cells provide an in vitro model for programmed cell death coupled to steroidogenesis.

UNLABELLED: We describe the use of rotary cultures (72 rpm) as an excellent method for generating spheroids from dispersed bovine granulosa cells (GC). The GC spheroids were symmetrical (diameter between 100 and 200 microm), easily accessible, and could be obtained at high yields. On day one, the spheroids showed a two-layered outer zone of cells that stained lighter than the inner zone in semi-thin sections. Bromodeoxyuridine (BrdU) uptake was frequent and randomly distributed. By day two, a striking decrease in BrdU uptake was noted. Apoptotic bodies appeared up to day four, as did TUNEL and propidium iodide labelled dead cells. At that time, the inner zone contained cells with large-sized vacuoles and the core was amorphous. The large-sized vacuoles were identified at the ultrastructural level and represented autophagosomes and autophagolysosomes that were in different stages of development. Surprisingly, conspicuous signs of cell death were accompanied by an increase in spontaneous luteinization compared to conventional stationary cultures. We detected high levels of progesterone (immunoassay) accompanied by high levels of the proteins and enzymes relevant for steroidogenesis (StAR, P450scc, 3beta-HSD by immunoblot and immunohistochemistry, respectively). CONCLUSIONS: Concomitant to cell death, GC spheroids augment progesterone synthesis. The GC spheroids provide an ideal model for studying steroidogenesis coupled to programmed cell death at the level of the mitochondria.

KIT variants in bovine ovarian cells and corpus luteum.

We report the presence of KIT variants in granulosa and thecal cells of the follicle and endothelial and steroidogenic cells of the corpus luteum. Transcripts of both full-length splice variants, KIT and KITA, were ubiquitously detected in all cell types, in contrast to transcripts for truncated KIT. RT-PCR with exon-intron-specific primers suggested that KIT transcripts retained intron sequences. We used domain-specific KIT antibodies to identify truncated KIT proteins in cell conditioned media and lysates. These proteins represented soluble KIT and a so far disregarded intracellular KIT fragment, and were ubiquitously present. In contrast, glycosylated variants of full-length KIT were predominantly detected in thecal and endothelial cells. All KIT variants were encountered again in COS-7 cells transfected with a vector containing KITA. Phorbol 12-myristate-13-acetate treatment induced levels of truncated KITs, and this effect was repressed by the metalloproteinase inhibitor TAPI-1. Our findings show that ectodomain cleavage of full-length KIT generates an intracellular KIT. Our experiments suggest that replenishing full-length KIT differs among various ovarian cell types.

KIT receptor-positive cells in the bovine corpus luteum are primarily theca-derived small luteal cells.

The tyrosine kinase KIT receptor, the protooncogene CD117, plays a key role in growth and maturation of oocytes and follicles. Relevant data are sparse for the corpus luteum (CL). We first confirmed the presence of KIT mRNA and KIT protein in bovine CL homogenates. We then localized KIT-positive (KIT+) cells in CL sections by immunohistochemistry. At the CL stage of early development, the former theca transforming into capsule/septa showed a strong band-like KIT+ immunoresponse. In addition, CD45+ leukocytes in septa included subpopulations of CD45+/KIT+ and CD14+/KIT+ leukocytes as validated by double immunofluorescence localization. At the early secretory stage, KIT+ cells appeared within the septa/capsule region and in the periphery of the CL parenchyma, there forming a complex network. This was separate from the capillary bed as determined by double staining for CD117 and FVIII-related endothelial cell antigen (FVIIIr). The KIT+ network coincided with cells positive for cytochrome P450 17alpha-hydroxylase, a thecal cell-specific enzyme. The late secretory stage was defined by an advanced manifestation of the KIT+ network in the CL periphery. At the stage of regression, the KIT+ network was absent. The CL of pregnancy expressed high levels of KIT mRNA and KIT protein uniformly throughout pregnancy. The KIT+ immunolocalization revealed small fibroblast-like cells, luteal cells with granules, and clusters of large luteal cells with staining of the cell membrane. We conclude that a majority of KIT+ cells in the bovine CL are primarily theca-derived small luteal cells, and that a minority represent KIT+ leukocytes, in some cases KIT+ monocytes.

Expression of mRNA for cell adhesion molecules in the bovine corpus luteum during the estrous cycle and PGF2alpha-induced luteolysis.

Cell-to-cell interaction via cell contact-dependent pathway is essentially important for maintenance and regulation of corpus luteum (CL) integrity and its physiological actions. The objective of the present study was to evaluate the mRNA expression of the cell adhesion molecules (CAMs) that are constituent factors of gap junctions [connexin (Cx) 43] and adherence junctions (VE-, E-, N-cadherin) in two types of endothelial cells from the mid CL and in CL tissue during the estrous cycle and PGF(2alpha)-induced luteolysis in the cow. Specific mRNA expression for Cx43 and N-cadherin was detected in cytokeratin-positive (CK+) and cytokeratin-negative (CK-) luteal endothelial cells (EC) and fully luteinized granulosa cells (LGC). E-cadherin mRNA was expressed in CK+EC and LGC, but not in CK-EC. VE-cadherin mRNA was expressed in both CK+ and CK-EC. During the estrous cycle, Cx43 mRNA expression was significantly lower in the regressing CL. VE-cadherin expression also tended to increase in the mid CL and increased significantly in the regressing CL. E-cadherin mRNA expression was higher in the early and late CL than in the mid- and regressing CL. N-cadherin mRNA expression gradually increased from the early to late CL followed by a decrease in the regressing CL. During PGF(2alpha)-induced luteolysis, Cx43 mRNA expression appeared to increase, and VE-cadherin and E-cadherin mRNA significantly increased at 24 h. N-cadherin mRNA expression decreased 2 and 4 h after PGF(2alpha) administration. Collectively, expression of the mRNAs for CAMs was different in the two types of luteal endothelial cells and fully luteinized granulosa cells and changed independently in the CL during the estrous cycle and PGF(2alpha)-induced luteolysis in the cow. The results suggest that CAMs play physiological roles in cell-to-cell communication to regulate both gap and adherence junctions during CL development and regression in the cow.

The short prolactin receptor predominates in endothelial cells of micro- and macrovascular origin.

BACKGROUND: Controversial reports on prolactin receptors (PRL-R), the long and short form, on endothelial cells (EC) may be explained by the choice of EC derived from the micro- and macrovascular bed of either endocrine and non-endocrine organs. METHODS: We studied here PRL-R expression in organs [bovine corpus luteum (CL), umbilical vein, aorta] and in organ-derived EC cultures. RESULTS: In the intact CL, both PRL-R forms were present at mRNA and protein level throughout the oestrous cycle stages. The short form prevailed as protein. PRL-R-positive EC were noted by immunofluorescent staining in arterial blood vessels of CL septa, in the umbilical vein and the aorta. In EC cultures of micro- and macrovascular origin, transcripts of both PRL-R forms were shown; again the short-form protein prevailed. Blocking experiments with anti-prolactin (PRL) antibody led to a 60% decrease in cell growth. Treatment with PRL had no effect. CONCLUSION: PRL-R expression in micro- and macrovascular EC is associated with the predominant short form.

Stage-specific expression of the mitochondrial germ cell epitope PG2 during postnatal differentiation of rabbit germ cells.

Structural and biochemical differentiation of germ cell mitochondria is supposed to determine the fate and integrity of mitochondria in the early embryo. Immunofluorescent labeling of the primordial germ cell epitope 2 (PG2), which is associated with the outer mitochondrial membrane and is germ cell specific from the time of germ cell segregation during gastrulation, was used to elucidate biochemical characteristics of mitochondrial differentiation leading to a functional gamete. The PG2 epitope is found in both mitotic and meiotic male and female postnatal germ cells, but PG2 expression ceases transiently in initial stages of meiosis, i.e., in the female during early stages of follicle formation and in the male during prespermatogenesis and initial phases of spermatogenesis. Because the PG2 epitope is detectable in germ cells at the time when structurally immature mitochondria are present, we speculate that PG2 immunoreactivity closely mirrors the progress of mitochondrial differentiation during gametogenesis.