Precocious differentiation of chick embryo pancreas in vitro: Roles of prednisolone,insulin and L-thyroxine

The hormonal requirements for functional differentiation of chick embryo pancreas were investigated by using organ cultures in chemically defined medium. The hormones tested were prednisolone, insulin and thyroxine, and the parameters examined were α-amylase (EC 3.2.1.1) and chymotrypsinogen (EC 3.4.4.5) activities, and the ultrastructure of the tissues. Addition of prednisolone alone to explants from 14-day-old chicken embryo pancreas for 3 days increased the activities of amylase and chymotrypsinogen in the tissues by 3.4- and 6.6-fold, respectively, those of tissues before cultivation. Neither thyroxine or insulin alone, nor both hormones together affected pancreatic exocrine differentiation. Thyroxine enhanced the effect of prednisolone on both enzymes, but insulin did not. When the explants were cultured in the medium containing all three hormones, maximum enzyme activities were observed; amylase or chymotrypsinogen activity being 7- or 18-fold, respectively, that of tissues before cultivation. But these three hormones were not simultaneously necessary. Morphological differentiation was also observed in explants cultivated in medium containing these three hormones. These results suggest that glucocorticoids are essential for normal differentiation of chick pancreas during the late fetal period, possibly with insulin and thyroxine, and also support the idea that pancreatic enzymes are controlled separately.     

Mammalian follicular development and atresia: role of apoptosis

The regulation of follicular development and atresia is a complex process and involves interactions between endocrine factors (gonadotropins) and intraovarian regulators (sex steroids, growth factors and cytokines) in the control of follicular cell fate (i.e. proliferation, differentiation and programmed cell death). Granulosa and theca cells are key players in this fascinating process. As atresia is the fate of most follicles, understanding of how these physiological regulators participate in determining the destiny of the follicle (to degenerate or to ovulate) at cellular and subcellular levels is fundamental. This short review summarizes the role of intraovarian modulators of programmed cell death in the induction of atresia during follicular development.     

Precocious differentiation of chick embryo pancreas in vitro. Roles of prednisolone, insulin and L-thyroxine.

The hormonal requirement for functional differentiation of chick embryo pancreas were investigated by using organ cultures in chemically defined medium. The hormones tested were prednisolone, insulin and thyroxine, and the parameters examined were alpha-amylase (EC 3.2.1.1) and chymotrypsinogen (EC 3.4.4.5) activities, and the ultrastructure of the tissues. Addition of prednisolone alone to explants from 14-day-old chicken embryo pancreas for 3 days increased the activities of amylase and chymotrypsinogen in the tissues by 3.4- and 6.6-fold, respectively, those of tissues before cultivation. Neither thyroxine or insulin alone, nor both hormones together affected pancreatic exocrine differentiation. Thyroxine enhanced the effect of prednisolone on both enzymes, but insulin did not. When the explants were cultured in the medium containing all three hormones, maximum enzyme activities were observed; amylase or chymotrypsinogen activity being 7- or 18-fold, respectively, that of tissues before cultivation. But these three hormones were not simultaneously necessary. Morphological differentiation was also observed in explants cultuvated in medium containing these three hormones. These results suggest that glucocorticoids are essential for normal differentiation of chick pancreas during the late fetal period, possibly with insulin and thyroxine, and also support the idea that pancreatic enzymes are controlled separately.     

Mammalian epigenomics: reprogramming the genome for development and therapy

Epigenetic modifications of DNA and chromatin are important for genome function during development and in adults. DNA and chromatin modifications have central importance for genomic imprinting and other aspects of epigenetic control of gene expression. In somatic lineages, modifications are generally stably maintained and are characteristic of different specialized tissues. The mammalian genome undergoes major reprogramming of modification patterns in germ cells and in the early embryo. Some of the factors that are involved both in maintenance and in reprogramming, such as methyltransferases, are being identified. Epigenetic reprogramming is deficient in animal cloning, which is a major explanation for the inefficiency of the cloning procedure. Deficiencies in reprogramming are likely to underlie the occurrence of epimutations and of epigenetic inheritance. Environmental factors can alter epigenetic modifications and may thus have long-lasting effects on phenotype. Epigenomics methods are being developed to catalogue genome modifications under normal and pathological conditions. Epigenetic engineering is likely to play an important role in medicine in the future.     

Cyclic x-ray responses in Mammalian cells in vitro

Various radiation responses in mammalian cells depend on the position of the cell within its generation cycle (that is, its age) at the time of irradiation. Studies have most often been made by irradiating synchronized populations of cells in vitro. Results in different cell lines are not easy to compare, but an attempt has been made here to point out similarities and differences with regard to cell killing and division delay. In general, survival data obtained so far show that, in cells with a short G(1), cells are most sensitive in mitosis and in G(2), less sensitive in G(1), and least sensitive during the latter part of the S period. In cells with a long G(1), in addition to the above, there is usually a resistant phase early in G(1) followed by a sensitive stage near its end. (The latter may be as sensitive as mitosis.) Exceptions to the above, especially in some L cell sublines, have been noted, and a possible explanation is given. In Chinese hamster cells, maximum survival after irradiation occurs during S, but it does not coincide with the time of the maximum rate of DNA synthesis or with the time of the maximum number of cells in DNA synthesis, and changes in survival also occur in cells inhibited from synthesizing DNA. Rather, survival depends on the position the cell has reached in the cycle at that time, which involves not only DNA synthesis but other processes as well. Survival is not completely correlated with DNA synthesis, since halting DNA synthesis just before or just after irradiation only slightly affects survival at its maximum. Division delay exhibits a pattern of response which is similar in most cell lines. Delay is considerable for cells irradiated in mitosis, is small for cells in G(1), increases to a maximum for cells during S, and declines for cells in G(2). L cells or human kidney cells may have a longer delay for cells irradiated in G(2) than for those irradiated in S. The results can be explained in terms of a two-component model of division delay. One component results from the prolongation of the S period due to the reduced rate of DNA synthesis, and the other, a block in G(2), is independent of DNA synthesis. The proportion of the two components may vary in different cell lines.     

Murine embryonic stem cell in vitro differentiation: applications to the study of vascular development

The present review summarizes knowledge accumulated during the last decade concerning in vitro endothelial differentiation from embryonic stem (ES) cells. There is now growing evidence that ES cells may provide a powerful model system to determine the cellular and molecular mechanisms of vascular development. ES cells differentiate into the endothelial lineage by successive maturation steps recapitulating in vivo events observed in the embryo. Further maturation of ES-derived embryoid bodies either in three dimensional gels or in confrontation cultures with tumor spheroids can also provide a model of physiological or tumoral angiogenesis. The data obtained from experimental in vitro differentiation of genetically modified mouse ES cells highlight the potential and the complementarity of this model system to in vivo gene knock out studies. We also consider and discuss some of the potential applications of ES cell technology in vascular biology for future directions in basic research and medicine, by manipulation of differentiation and the generation of cell populations for analysis and transplantation for therapeutic use.     

GDF11 modulates NGN3+ islet progenitor cell number and promotes beta-cell differentiation in pancreas development

Identification of endogenous signals that regulate expansion and maturation of organ-specific progenitor cells is a major goal in studies of organ development. Here we provide evidence that growth differentiation factor 11 (GDF11), a member of the TGF-beta ligand family, governs the number and maturation of islet progenitor cells in mouse pancreas development. Gdf11 is expressed in embryonic pancreatic epithelium during formation of islet progenitor cells that express neurogenin 3. Mice deficient for Gdf11 harbor increased numbers of NGN3+ cells, revealing that GDF11 negatively regulates production of islet progenitor cells. Despite a marked expansion of these NGN3+ islet progenitors, mice lacking Gdf11 have reduced beta-cell numbers and evidence of arrested beta-cell development, indicating that GDF11 is also required for beta-cell maturation. Similar precursor and islet cell phenotypes are observed in mice deficient for SMAD2, an intracellular signaling factor activated by TGF-beta signals. Our data suggest that Gdf11 and Smad2 regulate islet cell differentiation in parallel to the Notch pathway, which previously has been shown to control development of NGN3+ cells. Thus, our studies reveal mechanisms by which GDF11 regulates the production and maturation of islet progenitor cells in pancreas development.     

Regeneration of Arabidopsis callus in vitro

This paper reports on an easy and reproducible method of regenerating Arabidopsis plants from callus culture. A combination of 6-benzylaminopurine (BAP) and -naphthalene acetic acid (NAA) in a Murashige and Skoog's (MS) based medium gives a high percentage of shoot formation in several genotypes.     

Regeneration of the exocrine pancreas is delayed in telomere-dysfunctional mice

Introduction

Telomere shortening is a cell-intrinsic mechanism that limits cell proliferation by induction of DNA damage responses resulting either in apoptosis or cellular senescence. Shortening of telomeres has been shown to occur during human aging and in chronic diseases that accelerate cell turnover, such as chronic hepatitis. Telomere shortening can limit organ homeostasis and regeneration in response to injury. Whether the same holds true for pancreas regeneration in response to injury is not known.

Methods

In the present study, pancreatic regeneration after acute cerulein-induced pancreatitis was studied in late generation telomerase knockout mice with short telomeres compared to telomerase wild-type mice with long telomeres.

Results

Late generation telomerase knockout mice exhibited impaired exocrine pancreatic regeneration after acute pancreatitis as seen by persistence of metaplastic acinar cells and markedly reduced proliferation. The expression levels of p53 and p21 were not significantly increased in regenerating pancreas of late generation telomerase knockout mice compared to wild-type mice.

Conclusion

Our results indicate that pancreatic regeneration is limited in the context of telomere dysfunction without evidence for p53 checkpoint activation.     

Exocrine pancreas development in zebrafish

Although many of the genes that regulate development of the endocrine pancreas have been identified, comparatively little is known about how the exocrine pancreas forms. Previous studies have shown that exocrine pancreas development may be modeled in zebrafish. However, the timing and mechanism of acinar and ductal differentiation and morphogenesis have not been described. Here, we characterize zebrafish exocrine pancreas development in wild type and mutant larvae using histological, immunohistochemical and ultrastructural analyses. These data allow us to identify two stages of zebrafish exocrine development. During the first stage, the exocrine anlage forms from rostral endodermal cells. During the second stage, proto-differentiated progenitor cells undergo terminal differentiation followed by acinar gland and duct morphogenesis. Immunohistochemical analyses support a model in which the intrapancreatic ductal system develops from progenitors that join to form a contiguous network rather than by branching morphogenesis of the pancreatic epithelium, as described for mammals. Contemporaneous appearance of acinar glands and ducts in developing larvae and their disruption in pancreatic mutants suggest that common molecular pathways may regulate gland and duct morphogenesis and differentiation of their constituent cells. By contrast, analyses of mind bomb mutants and jagged morpholino-injected larvae suggest that Notch signaling principally regulates ductal differentiation of bipotential exocrine progenitors.     

Myoblast differentiation in vitro: morphological differentiation of mononucleated myoblasts.

Phospholipase C from Clostridium perfringens has been shown previously to inhibit the fusion of cultured chick myoblasts without affecting recognition or cell cycle parameters. In this paper we report that the mononucleated myoblasts, in phospholipase C, synthesize thick and thin filaments and organize them into myofibrils, and that T-tubules and sarcoplasmic reticulum differentiate and join in morphologically typical junctions. The structurally differentiated myoblasts can then fuse with one another to form myotubes. We conclude that cell fusion is not necessary for muscle differentiation.