Biological effects of FoxJ2 over-expression.

As reported previously, we have extensively studied FoxJ2, a member of the Fork Head transcription factors family. While the biochemical and functional structures of this transcription factor are well understood, its biological function remains unknown. Here, we present data that address this point using transgenic mouse technology.

EVG, the remnants of a primordial bilaterian's synteny of functionally unrelated genes.

Extant genomes are the result of repeated duplications and subsequent divergence of primordial genes that assembled the genomes of the first living beings. Increased information on genome maps of different species is revealing conserved syntenies among different vertebrate taxa, which allow to trace back the history of current chromosomes. However, inferring neighboring relationships between genes of more primitive genomes has proven to be very difficult.

Functional domains of FOXJ2.

FOXJ2 is a fork head transcriptional activator, the expression of which starts very early in embryonic development and it is distributed widely in the adult. Here, we describe the characterization of domains that are important for its function. FOXJ2 is localized constitutively at the nucleus of the cell.

DmFoxF, a novel Drosophila fork head factor expressed in visceral mesoderm.

DmFoxF is a novel Drosophila fork head domain factor, which is expressed in the visceral mesoderm of the embryo. Our data suggest that DmFoxF is the fly orthologue of the vertebrates FOXF1 and FOXF2 transcription factors. DmFoxF shares homology with FOXF1 and FOXF2 in its fork head domain, and it is able to specifically bind DNA sequences recognized by these vertebrate fork head factors.

Fhx (Foxj2) expression is activated during spermatogenesis and very early in embryonic development.

FHX (FOXJ2) is a recently characterized human fork head transcriptional activator that binds DNA with a dual sequence specificity. We have cloned the cDNA for the mouse orthologue Foxj2 and characterized its expression in the gonads and along the early pre-implantation development of the mouse. In the testis, Foxj2 is expressed from pachytene spermatocytes to round spermatids, but not in spermatogonia.

FHX.L and FHX.S, two isoforms of the human fork-head factor FHX (FOXJ2) with differential activity.

Many biological phenomena are dependent on mechanisms that fine-tune the expression levels of particular genes. This can be achieved by altering the relative activity of a single transcription factor, by post-translational modifications or by interaction with regulatory molecules. An alternative mechanism is based on competition between two or more differently active isoforms of the same transcription factor.

Collagen alpha1(I) gene contains an element responsive to tumor necrosis factor-alpha located in the 5' untranslated region of its first exon.

The aims of the present study were to identify the cis-acting element through which tumor necrosis factor-alpha (TNFalpha) inhibits collagen alpha1(I) gene transcription and the trans-acting factors involved in this effect in cultured hepatic stellate cells. Deletion analysis of the collagen alpha1(I) promoter demonstrated that TNFalpha inhibited gene expression through an element located between -59 and + 116 bp relative to the transcription start site. DNase I protection assays revealed a footprint between +68 and +86 bp of the collagen first exon, the intensity of which decreased when the DNA probe was incubated with nuclear protein from TNFalpha-treated hepatic stellate cells.

FHX, a novel fork head factor with a dual DNA binding specificity.

The HNF3/fork head family includes a large number of transcription factors that share a structurally related DNA binding domain. Fork head factors have been shown to play important roles both during development and in the adult. We now describe the cloning of a novel mammalian fork head factor that we have named FHX (fork head homologous X (FHX), which is expressed in many adult tissues.

Transcriptional induction of endothelial nitric oxide gene by cyclosporine A. A role for activator protein-1.

We have previously shown that the immunosuppressant cyclosporine A (CsA) increases the activity, the protein level, and the steady-state levels of the mRNA of the endothelial nitric-oxide synthase (eNOS) gene in bovine aortic endothelial cells (BAEC). We have now investigated the mechanisms responsible for these effects. Preincubation with an inhibitor of RNA polymerase II abolished CsA-induced eNOS up-regulation.

A set of polyclonal and monoclonal antibodies reveals major differences in post-translational modification of the rat HNF1 and vHNF1 homeoproteins.

The related homeodomain-containing transcription factors HNF1 (HNF1 alpha) and vHNF1 (HNF1 beta) recognise common target DNA sequences in the regulatory regions of many genes and are expressed in several parenchymal cell types, predominantly in liver, kidney, intestine and pancreas. HNF1-null mutant mice, with a wild-type vHNF1 gene, develop normally, but die within a few weeks of birth with severe liver and kidney failure. Humans with a mutation in the HNF1 alpha gene develop non-insulin dependent diabetes on maturity (MODY 3).

Expression of the human gene coding for the alpha-chain of C4b-binding protein, C4BPA, is controlled by an HNF1-dependent hepatic-specific promoter.

C4b-binding protein (C4BP) is an abundant oligomeric plasma glycoprotein which controls the activation of the complement cascade through the classical pathway. In humans, the majority form of C4BP is composed of seven alpha-chains and one beta-chain, covalently linked by their C-termini. C4BP is mainly expressed in the liver.

The gene coding for the beta-chain of C4b-binding protein (C4BPB) has become a pseudogene in the mouse.

C4BP beta is one of the two polypeptides that in humans compose the plasma glycoprotein C4b-binding protein (C4BP). C4BP beta binds the anticoagulant vitamin K-dependent protein S. Two, nonmutually exclusive, roles have been proposed for the C4BP-protein S interaction.

The transactivation potential of variant hepatocyte nuclear factor 1 is modified by alternative splicing.

Two forms of the transcription factor vHNF1 (HNF1 beta or LFB3) have been previously described, derived by alternative splicing from a common premessenger RNA, and have been called vHNF1-A and vHNF1-B. vHNF1 proteins share a homologous homeo-related DNA-binding domain with the HNF1 protein, initially characterized as a liver-restricted transcription factor, and bind to a similar sequence motif. Here we demonstrate that vHNF1-A is a stronger transactivator than vHNF1-B when assayed in transient transfections using two different promoters.

C4BPAL1, a member of the human regulator of complement activation (RCA) gene cluster that resulted from the duplication of the gene coding for the alpha-chain of C4b-binding protein.

The regulator of complement activation (RCA) gene cluster evolved by multiple gene duplications to produce a family of genes coding for proteins that collectively control the activation of the complement system. We report here the characterization of C4BPAL1, a member of the human RCA gene cluster that arose from the duplication of the C4BPA gene after the separation of the rodent and primate lineages. C4BPAL1 maps 20 kb downstream of the C4BPA gene and is the same 5' to 3' orientation found for all RCA genes characterized thus far.

vHNF1 is expressed in epithelial cells of distinct embryonic origin during development and precedes HNF1 expression.

HNF1 (Hepatic Nuclear Factor 1) and vHNF1 are transcriptional regulators containing a highly divergent homeodomain. The first was initially found in liver nuclear extracts and is crucial for the transcription of albumin and many other hepatocyte specific genes, while the second was found in dedifferentiated hepatoma cells. Both recognize the same DNA binding site and can form homo and heterodimers in vitro and in vivo.

vHNF1 is a homeoprotein that activates transcription and forms heterodimers with HNF1.

vHNF1 and HNF1 are two nuclear proteins that bind to an essential element in the promoter proximal sequences of albumin and of many other liver-specific genes. HNF1 predominates in hepatocytes but is absent in dedifferentiated hepatoma cells. These cells contain vHNF1 but fail to express most of the liver traits.

Structure of the gene coding for the alpha polypeptide chain of the human complement component C4b-binding protein.

The human gene coding for the 70-kD polypeptide of the complement regulatory component C4b-binding protein (C4BP alpha) spans over 40 kb of DNA and is composed of twelve exons. Upon transcription in liver, or in Hep-G2 cells, this gene produces a single transcript of 2,262 nucleotides, excepting the poly A tail, that presents an unusually long 5' untranslated region (5' UTR) of 223 nucleotides. The C4BP alpha gene is organized as follows: the first exon codes for the first 198 nucleotides of the 5' UTR.

Human genes for the alpha and beta chains of complement C4b-binding protein are closely linked in a head-to-tail arrangement.

C4b-binding protein (C4BP) is an important component in the regulation of the complement system and also binds the anticoagulant vitamin K-dependent protein S. These activities are performed by distinct, although structurally related, polypeptides of 70 kDa (alpha chain) and 45 kDa (beta chain), respectively. In this report we have investigated the genetic relationships between these polypeptides.

Definition of IDDM-associated HLA DQ and DX RFLPs by segregation analysis of multiplex sibships.

Genetic variation of the DQ alpha and beta and of the DX alpha genes, detectable as RFLP in genomic DNA digests, has been suggested to improve the identification of individuals at high risk for insulin-dependent diabetes mellitus (IDDM). DNA from all members of 32 IDDM multiplex families was digested with six restriction endonucleases and the resulting fragments analyzed in Southern blots for hybridization with labeled cDNA probes for those genes. A computerized segregation analysis procedure was then used to assign fragments to haplotypes.

A physical map of the human regulator of complement activation gene cluster linking the complement genes CR1, CR2, DAF, and C4BP.

We report the organization of the human genes encoding the complement components C4-binding protein (C4BP), C3b/C4b receptor (CR1), decay accelerating factor (DAF), and C3dg receptor (CR2) within the regulator of complement activation (RCA) gene cluster. Using pulsed field gel electrophoresis analysis these genes have been physically linked and aligned as CR1-CR2-DAF-C4BP in an 800-kb DNA segment. The very tight linkage between the CR1 and the C4BP loci, contrasted with the relative long DNA distance between these genes, suggests the existence of mechanisms interfering with recombination within the RCA gene cluster.

Decay-accelerating factor. Genetic polymorphism and linkage to the RCA (regulator of complement activation) gene cluster in humans.

We have investigated the genetic relationships between the human decay-accelerating factor (DAF) and a group of complement components including the C3b/C4b receptor (CR1), C4-binding protein (C4bp), and factor H (H), to which DAF is structurally and functionally related. CR1, C4bp, and H were previously demonstrated to be encoded by a cluster of closely linked genes, which we have designated regulator of complement activation (RCA). Southern blot analysis of genomic DNA using a DAF cDNA probe unraveled the existence of restriction fragment length polymorphism (RFLP) for both Bam HI and Hind III restriction endonucleases.

Transcription and translation maps of African swine fever virus.

A transcription map of African swine fever (ASF) virus DNA was obtained by hybridization of 32P-labeled early and late RNAs synthesized in Vero cells infected with ASF virus to dot-blots containing cloned restriction fragments spanning the viral genome. Early RNAs synthesized in infected cells in the presence of protein or DNA synthesis inhibitors hybridized preferentially to four regions in the genome, with coordinates E1 (0-51.9 kbp), E3 (63.