Identification of a new EGF-repeat-containing gene from human Xp22: a candidate for developmental disorders

Epidermal growth factor (EGF) repeat-containing proteins constitute an expanding family of proteins involved in several cellular activities such as blood coagulation, fibrinolysis, cell adhesion, and neural and vertebrate development. By using a bioinformatic approach, we have identified a new member of this family named MAEG (MAM- and EGF-containing gene; HGMW-approved gene symbol and gene name). Sequence analysis indicates that MAEG encodes a secreted protein characterized by the presence of five EGF repeats, three of which display a Ca(2+)-binding consensus sequence. In addition, a MAM domain is also present at the C-terminus of the predicted protein product. The human and murine full-length cDNAs were identified and mapped to human Xp22 and to the mouse syntenic region. Northern analysis indicates that MAEG is expressed early during development. Taken together, these data render MAEG a candidate for human and murine developmental disorders.     

mRNA expression of the murine glycoprotein (transmembrane) nmb (Gpnmb) gene is linked to the developing retinal pigment epithelium and iris

The murine homologue of the human glycoprotein (transmembrane) NMB (GPNMB) gene was identified by subtractive cloning from in vitro cultured murine primary osteoblast cells and subsequent RACE-PCR. GPNMB is a highly glycosylated type I transmembrane protein that shares significant sequence homology to several melanosomal proteins. Increasing expression of Gpnmb mRNA was observed during differentiation of murine primary osteoblast cell cultures. To address the potential functions of GPNMB we analysed its mRNA-expression during murine embryonic development. In early development Gpnmb mRNA is detected at high levels in the outer layer of the retina. Later in development expression gets restricted to the retinal pigment epithelium and iris. At the cytoplasmic domain of GPNMB, a conserved di-leucin-based endosomal/melanosomal-sorting signal (ExxPLL) was located, present as well in several known melanosomal proteins. To analyse the subcellular localization we used EGFP-tagged GPNMB transfected in COS7 and HEK293 cells. In both non-pigmented cell lines, the EGFP-GPNMB fusion protein was localized to vesicular, endosomal like structures. Sequence homology to known melanosomal proteins, mRNA expression and subcellular localization are suggestive for GPNMB as an intracellular, endosomal/melanosomal compartment specific protein important for melanin biosynthesis and the development of the retinal pigment epithelium and iris. As the gene coding for human GPNMB was localized to chromosome 7p15, a locus involved in the human inherited disease cystoid macular edema, also known as dominant cystoid macular dystrophy (OMIM 153880) we highly suggest that GPNMB is a candidate gene for this human inherited disease.     

Involvement of EAT/mcl-1, an anti-apoptotic bcl-2-related gene, in murine embryogenesis and human development

Apoptosis plays an important regulatory role in mammalian embryogenesis and development. EAT/mcl-1 (EAT), an anti-apoptotic bcl-2-related gene, was isolated during the early differentiation of a human embryonal carcinoma cell line, an event which serves as a model of early embryogenesis. EAT is involved in apoptotic regulation and is believed to also function as an immediate-early gene. Thus it was hypothesized that EAT would be expressed during early embryogenesis and would be involved in the regulation of apoptosis during this critical period. To clarify this early expression, two antibodies to EAT were generated by use of immunizing oligopeptide (aa 37-55) and recombinant protein (aa 31-229) for use in immunohistochemistry and immunoblotting, respectively. With these antibodies, we then determined EAT expression during murine embryogenesis and in human development, using human fetal tissue of 6 to 23 gestational weeks. During murine embryogenesis, the EAT protein was found to be rapidly induced after fertilization, to peak at the 2-cell stage, to remain constant until the 8-cell stage, and then to decrease to below unfertilized egg levels in blastocysts. EAT expression patterns in early human development were found to essentially overlap those observed in adult tissues which suggest that EAT expression continues until adulthood in terminally differentiated tissues. Among tissues distinct to fetal development, EAT was detected in the mesonephric (Wolffian) duct and paramesonephric (Müllerian) duct. It is also noteworthy that prominent EAT immunoreactivity was also observed in large primary oocytes in 21-week fetal ovary, but was not detected in primordial germ cells in 23-week fetal testis. In summary, EAT expression was detected in hematopoietic, epithelial, neural, endocrine, and urogenital cells; this provides evidence that EAT, as an anti-apoptotic molecule, possibly functions to regulate apoptosis during development in these systems.     

Rate of replication of the murine immunoglobulin heavy-chain locus: evidence that the region is part of a single replicon.

We measured the temporal order of replication of EcoRI segments from the murine immunoglobulin heavy-chain constant region (IgCH) gene cluster, including the joining (J) and diversity (D) loci and encompassing approximately 300 kilobases. The relative concentrations of EcoRI segments in bromouracil-labeled DNA that replicated during selected intervals of the S phase in Friend virus-transformed murine erythroleukemia (MEL) cells were measured. From these results, we calculated the nuclear DNA content (C value; the haploid DNA content of a cell in the G1 phase of the cell cycle) at the time each segment replicated during the S phase. We observed that IgCH genes replicate in the following order: alpha, epsilon, gamma 2a, gamma 2b, gamma 1, gamma 3, delta, and mu, followed by the J and D segments. The C value at which each segment replicates increased as a linear function of its distance from C alpha. The average rate of DNA replication in the IgCH gene cluster was determined from these data to be 1.7 to 1.9 kilobases/min, similar to the rate measured for mammalian replicons by autoradiography and electron microscopy (for a review, see H. J. Edenberg and J. A. Huberman, Annu. Rev. Genet. 9:245-284, 1975, and R. G. Martin, Adv. Cancer Res. 34:1-55, 1981). Similar results were obtained with other murine non-B cell lines, including a fibroblast cell line (L60T) and a hepatoma cell line (Hepa 1.6). In contrast, we observed that IgCh segments in a B-cell plasmacytoma (MPC11) and two Abelson murine leukemia virus-transformed pre-B cell lines (22D6 and 300-19O) replicated as early as (300-19P) or earlier than (MPC11 and 22D6) C alpha in MEL cells. Unlike MEL cells, however, all of the IgCH segments in a given B cell line replicated at very similar times during the S phase, so that a temporal directionality in the replication of the IgCH gene cluster was not apparent from these data. These results provide evidence that in murine non-B cells the IgCH, J, and D loci are part of a single replicon.     

The murine Bin1 gene functions early in myogenesis and defines a new region of synteny between mouse chromosome 18 and human chromosome 2

We cloned and functionally characterized the murine Bin1 gene as a first step to investigate its physiological roles in differentiation, apoptosis, and tumorigenesis. The exon-intron organization of the >/=55-kb gene is similar to that of the human gene. Consistent with a role for Bin1 in apoptosis, the promoter included a functional consensus motif for activation by NF-kappaB, an important regulator of cell death. A muscle regulatory module defined in the human promoter that includes a consensus recognition site for myoD family proteins was not conserved in the mouse promoter. However, Bin1 is upregulated in embryonic development by E10.5 in myotomes, the progenitors of skeletal muscle, supporting a role in myogenesis and suggesting that the mouse and human genes may be controlled somewhat differently during development. In C2C12 myoblasts antisense Bin1 prevents induction of the cell cycle kinase inhibitor p21WAF1, suggesting that it acts at an early time during the muscle differentiation program. Interspecific mouse backcross mapping located the Bin1 locus between Mep1b and Apc on chromosome 18. Since the human gene was mapped previously to chromosome 2q14, the location of Bin1 defines a previously unrecognized region of synteny between human chromosome 2 and mouse chromosome 18.     

Drug-inducible gene recombination by the Dppa3-MER Cre MER transgene in the developmental cycle of the germ cell lineage in mice

Germ cells ensure the diversification and totipotency of genetic information via the elaborate genetic and epigenetic regulation of the genome architecture during their development. To understand the mechanism underlying the regulation of genome function in germ cells, it is of primary importance to develop systems in which gene function can be regulated at desired time points during their development. Here, we report the generation of transgenic strains that express Cre recombinase flanked by the ligand-binding domains of murine estrogen receptor (MER Cre MER [MCM]) under the control of the regulatory elements of the Dppa3 (also known as Stella or Pgc7) gene. On the administration of 4-hydroxytamoxifen (4-OHT), the Dppa3-MCM strains recombined the sequence flanked by the loxP elements (the floxed sequence) specifically in primordial germ cells as early as Embryonic Day (E) 7.0, and this recombination became robust after E9.5. Furthermore, these strains exhibited efficient and specific recombination of the floxed sequence during the growth of oocytes and in preimplantation embryos in the 4-OHT-dependent manner. Thus, these Dppa3-MCM strains offer valuable opportunities to explore gene function in both loss-of-function and gain-of-function experiments at a variety of time points during germ cell development.     

Developmental alterations in expression and subcellular localization of antizyme and antizyme inhibitor and their functional importance in the murine mammary gland

Ornithine decarboxylase (ODC), antizyme (AZ), and antizyme inhibitor (AIn) play a key role in regulation of intracellular polyamine levels by forming a regulatory circuit through their interactions. To gain insight into their functional importance in cell growth and differentiation, we systematically examined the changes of their expression, cellular polyamine contents, expression of genes related to polyamine metabolism, and β-casein gene expression during murine mammary gland development. The activity of ODC and AZ1 as well as putrescine level were low in the virgin and involuting stages, but they increased markedly during late pregnancy and early lactation when mammary cells proliferate extensively and begin to augment their differentiated function. The level of spermidine and expression of genes encoding spermidine synthase and AIn increased in a closely parallel manner with that of casein gene expression during pregnancy and lactation. On the other hand, the level of spermidine/spermine N ¹-acetyltransferase (SSAT) mRNA and AZ2 mRNA decreased during those periods. Immunohistochemical analysis showed the translocation of ODC and AIn between the nucleus and cytoplasm and the continuous presence of AZ in the nucleus during gland development. Reduction of AIn by RNA interference inhibited expression of β-casein gene stimulated by lactogenic hormones in HC11 cells. In contrast, reduction of AZ by AZsiRNA resulted in the small increase of β-casein gene expression. These results suggested that AIn plays an important role in the mammary gland development by changing its expression, subcellular localization, and functional interplay with AZ.     

Distinct roles for visceral endoderm during embryonic mouse development.

The murine visceral endoderm is an extraembryonic cell layer that appears prior to gastrulation and performs critical functions during embryogenesis. The traditional role ascribed to the visceral endoderm entails nutrient uptake and transport. Besides synthesizing a number of specialized proteins that facilitate uptake, digestion, and secretion of nutrients, the extraembryonic visceral endoderm coordinates blood cell differentiation and vessel formation in the adjoining mesoderm, thereby facilitating efficient exchange of nutrients and gases between the mother and embryo. Recent studies suggest that in addition to this nutrient exchange function the visceral endoderm overlying the egg cylinder stage embryo plays an active role in guiding early development. Cells in the anterior visceral endoderm function as an early organizer. Prior to formation of the primitive streak, these cells express specific gene products that specify the fate of underlying embryonic tissues. In this review we highlight recent investigations demonstrating this dual role for visceral endoderm as a provider of both nutrients and developmental cues for the early embryo.     

Interspecies somatic cell nuclear transfer is dependent on compatible mitochondrial DNA and reprogramming factors

Interspecies somatic cell nuclear transfer (iSCNT) involves the transfer of a nucleus or cell from one species into the cytoplasm of an enucleated oocyte from another. Once activated, reconstructed oocytes can be cultured in vitro to blastocyst, the final stage of preimplantation development. However, they often arrest during the early stages of preimplantation development; fail to reprogramme the somatic nucleus; and eliminate the accompanying donor cell's mitochondrial DNA (mtDNA) in favour of the recipient oocyte's genetically more divergent population. This last point has consequences for the production of ATP by the electron transfer chain, which is encoded by nuclear and mtDNA. Using a murine-porcine interspecies model, we investigated the importance of nuclear-cytoplasmic compatibility on successful development. Initially, we transferred murine fetal fibroblasts into enucleated porcine oocytes, which resulted in extremely low blastocyst rates (0.48%); and failure to replicate nuclear DNA and express Oct-4, the key marker of reprogramming. Using allele specific-PCR, we detected peak levels of murine mtDNA at 0.14±0.055% of total mtDNA at the 2-cell embryo stage and then at ever-decreasing levels to the blastocyst stage (<0.001%). Furthermore, these embryos had an overall mtDNA profile similar to porcine embryos. We then depleted porcine oocytes of their mtDNA using 10 μM 2',3'-dideoxycytidine and transferred murine somatic cells along with murine embryonic stem cell extract, which expressed key pluripotent genes associated with reprogramming and contained mitochondria, into these oocytes. Blastocyst rates increased significantly (3.38%) compared to embryos generated from non-supplemented oocytes (P<0.01). They also had significantly more murine mtDNA at the 2-cell stage than the non-supplemented embryos, which was maintained throughout early preimplantation development. At later stages, these embryos possessed 49.99±2.97% murine mtDNA. They also exhibited an mtDNA profile similar to murine preimplantation embryos. Overall, these data demonstrate that the addition of species compatible mtDNA and reprogramming factors improves developmental outcomes for iSCNT embryos.