The NuRD component Mbd3 is required for pluripotency of embryonic stem cells.

Cells of early mammalian embryos have the potential to develop into any adult cell type, and are thus said to be pluripotent. Pluripotency is lost during embryogenesis as cells commit to specific developmental pathways. Although restriction of developmental potential is often associated with repression of inappropriate genetic programmes, the role of epigenetic silencing during early lineage commitment remains undefined. Here, we used mouse embryonic stem cells to study the function of epigenetic silencing in pluripotent cells. Embryonic stem cells lacking Mbd3 - a component of the nucleosome remodelling and histone deacetylation (NuRD) complex - were viable but failed to completely silence genes that are expressed before implantation of the embryo. Mbd3-deficient embryonic stem cells could be maintained in the absence of leukaemia inhibitory factor (LIF) and could initiate differentiation in embryoid bodies or chimeric embryos, but failed to commit to developmental lineages. Our findings define a role for epigenetic silencing in the cell-fate commitment of pluripotent cells.

Growth and early postimplantation defects in mice deficient for the bromodomain-containing protein Brd4.

In a gene trap screen we recovered a mouse mutant line in which an insertion generated a null allele of the Brd4 gene. Brd4 belongs to the Fsh/Brd family, a group of structurally related proteins characterized by the association of two bromodomains and one extraterminal domain. Members of this family include Brd2/Ring3/Fsrg1 in mammals, fs(1)h in Drosophila, and Bdf1 in Saccharomyces cerevisiae. Brd4 heterozygotes display pre- and postnatal growth defects associated with a reduced proliferation rate. These mice also exhibit a variety of anatomical abnormalities: head malformations, absence of subcutaneous fat, cataracts, and abnormal liver cells. In primary cell cultures, heterozygous cells also display reduced proliferation rates and moderate sensitivity to methyl methanesulfonate. Embryos nullizygous for Brd4 die shortly after implantation and are compromised in their ability to maintain an inner cell mass in vitro, suggesting a role in fundamental cellular processes. Finally, sequence comparisons suggest that Brd4 is likely to correspond to the Brd-like element of the mediator of transcriptional regulation isolated by Y. W. Jiang, P. Veschambre, H. Erdjument-Bromage, P. Tempst, J. W. Conaway, R. C. Conaway, and R. D. Kornberg (Proc. Natl. Acad. Sci. USA 95:8538-8543, 1998) and the Brd4 mutant phenotype is discussed in light of this result. Together, our results provide the first genetic evidence for an in vivo role in mammals for a member of the Fsh/Brd family.

Role of heparan sulfate-2-O-sulfotransferase in the mouse.

Heparan sulfate (HS) is a long unbranched polysaccharide found covalently attached to various proteins at the cell surface and in the extracellular matrix. It plays a central role in embryonic development and cellular function by modulating the activities of an extensive range of growth factors and morphogens. HS 2-O-sulfotransferase (Hs2st) occupies a critical position in the succession of enzymes responsible for the biosynthesis of HS, catalysing the transfer of sulfate to the C2-position of selected hexuronic acid residues within the nascent HS chain. Previous studies have concluded that 2-O-sulfation of HS is essential for it to cooperate in many growth factor/receptor interactions. Surprisingly therefore, embryos lacking functional Hs2st survive until birth, but die perinatally, suffering complete failure to form kidneys. However, this rather late lethality belies a more intricate involvement of 2-O-sulfated HS during development. The purpose of this review is to summarise the requirements for 2-O-sulfated HS during mouse development, at the morphological and molecular level. The implications that altered HS structure may have on growth factor/receptor signalling in vivo will be discussed.

Specific modification of heparan sulphate is required for normal cerebral cortical development.

Proteoglycans are cell surface and extracellular matrix molecules to which long, unbranched glycosaminoglycan side chains are attached. Heparan sulphate, a type of glycosaminoglycan chain, has been proposed as a co-factor necessary for signalling by a range of growth factors. Here we provide evidence that loss of 2-O-sulphation in heparan sulphate leads to a significant reduction in cell proliferation in the developing cerebral cortex. The gene encoding heparan sulphate 2-sulphotransferase (Hs2st) is expressed in embryonic cortex and histological analysis of mice homozygous for a null mutation in Hs2st indicated a reduction in the thickness of the embryonic cerebral cortex. Using 5'-bromodeoxyuridine (BrdU) incorporation assays we found a reduction of approximately 40% in labelling indices of cortical precursor cells at E12. Comparison of the fates of cortical cells born on E13 and E15 in Hs2st(-/-) mutant and wildtype littermate embryos revealed no differences in the pattern of cell migration. Our findings suggest a critical role for 2-O-sulphation of heparan sulphate proteoglycan (HSPG) in regulating cell proliferation during development of the cerebral cortex, perhaps through the modulation of cellular responses to growth factor signalling.

In vivo and in vitro assays of thymic organogenesis.

We describe two complementary methods for the study of early thymus organogenesis in the mouse. The first is an in vitro technique for lineage analysis, where a chosen population of cells within the mouse embryo is labeled with a fluorescent cell tracker dye. The embryos are then transferred to whole embryo culture for a defined period, after which time the location of the labeled cells is determined with respect to the developing thymus. In the second method, an in vivo assay is used to determine the ability of a specific tissue type to form a structurally and functionally normal thymus. This method uses an ectopic grafting technique where the embryonic pharyngeal endoderm containing the prospective thymus tissue is carefully isolated and transplanted under the kidney capsule of an adult mouse. Together, these techniques have allowed the cell types that make a physical contribution to the formation of the thymic epithelium to be identified.

Heparan sulfate 2-O-sulfotransferase (Hs2st) and mouse development.

Heparan sulphate 2-O-sulphotransferase (Hs2st) acts at an intermediate stage in the pathway of biosynthesis of heparan sulphate (HS), catalysing the transfer of sulphate from 3'-phosphoadenosine-5'-phosphosulfate (PAPS) to the C2-position of selected hexuronic acid residues within the maturing HS chain. It is well established that 2-O-sulphation within HS, particularly of iduronate residues, is essential for HS to participate in a variety of high-affinity ligand-binding interactions. HS plays a central role in embryonic development and cellular function, modulating the activities of an extensive range of growth factors. Interestingly, in contrast to the early failure of embryos entirely lacking HS, Hs2st(-/-) mice survive until birth, but die perinatally due to a complete failure of kidney formation. The phenotype of Hs2st(-/-) mutant kidneys suggests that signalling between two tissues, ureteric bud and metanephric mesenchyme, is disrupted. We discuss candidate signalling molecules that may mediate this interaction. The HS generated by these mice lacks 2-O-sulphate groups but is extensively modified above wild type levels by O-sulphation at C-6 of glucosamine-N-sulfate (GlcNS) residues. We will discuss the potentially altered role of this atypical HS in growth factor signalling.

Functional evidence for a single endodermal origin for the thymic epithelium.

T cell development depends critically on several distinct thymic epithelial cell types that are organized into two main compartments: cortex and medulla. The prevailing hypothesis suggests that these derive from ectoderm and endoderm, respectively. Here we show that lineage analysis provides no evidence for an ectodermal contribution to the thymic rudiment. We further demonstrate, via ectopic transplantation, that isolated pharyngeal endoderm can generate a functional thymus containing organized cortical and medullary regions and that this capacity is not potentiated by the presence of pharyngeal ectoderm. These data establish that the cortical and medullary thymic epithelial compartments derive from a single germ layer, the endoderm, thus refuting the 'dual-origin' model of thymic epithelial ontogeny.