BRM (SNF2alpha) expression is concomitant to the onset of vasculogenesis in early mouse postimplantation development.

In mammals, the SWI/SNF complex is involved in chromatin remodelling in a wide range of cellular events for which regulatory factors require access to DNA. In the present study, we analyzed in early postimplantation mouse embryos the expression pattern of BRM (SNF2alpha) and BRG1 (SNF2beta), which are both ATPase subunits of this complex. Contrarily to the previous studies conducted in adult mice, showing the ubiquitous and overlapping expressions of BRM and BRG1, we show that BRM expression is restricted to mesodermal tissues involved in early vasculogenesis and heart morphogenesis.

Somatic linker histone H1 is present throughout mouse embryogenesis and is not replaced by variant H1 degrees.

A striking feature of early embryogenesis in a number of organisms is the use of embryonic linker histones or high mobility group proteins in place of somatic histone H1. The transition in chromatin composition towards somatic H1 appears to be correlated with a major increase in transcription at the activation of the zygotic genome. Previous studies have supported the idea that the mouse embryo essentially follows this pattern, with the significant difference that the substitute linker histone might be the differentiation variant H1 degrees, rather than an embryonic variant.

[Cloning: present and perspectives].

Human embryonic cells obtained through somatic cloning would allow selfgrafting for therapeutical purposes. Data available from animal research indicate that this issue should be considered with great care.

Differential preimplantation regulation of two mouse homologues of the yeast SWI2 protein.

Epigenetic regulation of gene expression through modification of chromatin organization is an important mechanism in the development of eucaryotic organisms. We investigated the developmentally regulated expression of the mouse mBRG1 and mbrm genes, which are homologous to the yeast SWI2 gene. Both proteins are involved in chromatin remodeling as components of the mammalian SWI/SNF complex.

Mouse embryos do not wait for the MBT: chromatin and RNA polymerase remodeling in genome activation at the onset of development.

In Xenopus and Drosophila embryos, activation of the zygotic genome occurs after a series of rapid nuclear divisions in which DNA replication occupies most of the cell cycle. In these organisms, it has been proposed that zygotic transcription does not begin until a threshold nucleocytoplasmic ratio has been obtained in which repressive factors are titrated out and interphase becomes long enough to allow synthesis of transcripts. In mammalian embryos, however, a model of threshold nucleocytoplasmic ratios does not seem to apply, as beginning with the 1-cell stage, there are regulated cell cycles with the expression of zygotic transcripts during the cleavage period.

Progressive maturation of chromatin structure regulates HSP70.1 gene expression in the preimplantation mouse embryo.

In the widely studied model organisms, Drosophila and Xenopus, early embryogenesis involves an extended series of nuclear divisions prior to activation of the zygotic genome. The mammalian embryo differs in that the early cleavage phase is already characterized by regulated cell cycles with specific zygotic gene expression. In the mouse, where major activation of the zygotic genome occurs at the 2-cell stage, the HSP70.

Capture of a cellular transcriptional unit by a retrovirus: mode of provirus activation in embryonal carcinoma cells.

The expression of murine leukemia provirus in embryonal carcinoma (EC) cells is blocked by a mechanism still incompletely understood. The blockage is not overcome by deleting a large portion of the enhancer region (in U3) in recombinant retroviruses (M-MuLVneo delta Enh). This confirms the presence of negative elements outside the viral 82-bp repeats.

Differential regulation of the N-myc gene in transfected cells and transgenic mice.

The N-myc gene is expressed specifically in the early developmental stages of numerous cell lineages. To assay for sequences that could potentially regulate N-myc expression, we transfected constructs that contained murine N-myc genomic sequences linked to a reporter gene and genomic clones that contained the complete human or murine N-myc genes into cell lines that either express or do not express the endogenous N-myc gene. Following either transient or stable transfection, the introduced N-myc sequences were expressed regardless of the expression status of the endogenous gene.

Structure of four amplified DNA novel joints.

The structures of four novel joints present in the amplified DNA of a Syrian hamster cell line highly resistant to N-(phosphonacetyl)-L-aspartate were analyzed. Novel joints J1, J2, and J4 were formed by recombination between two regions of wild-type DNA, whereas joint J3 is the end point of an inverted duplication. A fraction of the J3 copies displays a cruciform structure in the purified genomic DNA.

Structure and expression of the murine L-myc gene.

We have isolated a 12 kb clone from the murine genome which we show by DNA transfection studies to contain an entire functional L-myc gene and the transcriptional promoter sequences necessary for its expression. We have also isolated a 3.1 kb cDNA sequence from a murine brain cDNA library which corresponds to most of the L-myc mRNA.

Myc family of cellular oncogenes.

The myc family of cellular oncogenes contains three well-defined members: c-myc, N-myc and L-myc. Additional structural and functional evidence now suggests that other myc-family oncogenes exist. The overall structure and organization of the c-, N-, and L-myc genes and transcripts are very similar.

New RNA species is produced by alternate polyadenylation following rearrangement associated with CAD gene amplification.

Mammalian cells selected to resist N-(phosphonacetyl)-L-aspartate (PALA) contain amplified copies of the CAD gene. While a single 7.9-kb mRNA species is detected in PALA-sensitive and most PALA-resistant cell lines, two RNA species (7.

Structure and expression of the murine N-myc gene.

We have demonstrated that the entire murine N-myc gene and the sequences necessary for its expression in human neuroblastoma cells are contained within a 7.4-kilobase murine genomic clone. The complete nucleotide sequence of this gene reveals a number of striking similarities and differences when compared to the related c-myc gene including the following: (i) each gene contains three exons of which the first encodes a long 5'-untranslated leader sequence; (ii) the coding regions of the N- and c-myc genes share regions of substantial nucleic acid homology, the putative N-myc protein shares substantial homology with the c-myc protein; (iii) as with c-myc, extensive nucleotide sequence homology exists between the untranslated regions of the human and murine N-myc gene transcripts; however, the N-myc and c-myc untranslated regions are totally divergent; (iv) the N-myc transcriptional promoter differs from that of c-myc and is more related to the promoter of the simian virus 40.

Human N-myc is closely related in organization and nucleotide sequence to c-myc.

N-myc, a cellular gene related to the c-myc proto-oncogene, was originally identified on the basis of its very frequent amplification and overexpression in a restricted set of tumours, most notably human neuroblastomas. That N-myc may have a causal role in the genesis of these tumours is suggested by the observation that in the rat embryo fibroblast co-transformation assay it has a transforming potential similar to that of c-myc. The apparent structural and functional homology of N-myc and c-myc suggests that they may be members of the same protooncogene family.