Human inter-alpha-trypsin inhibitor heavy chain H3 gene. Genomic organization, promoter analysis, and gene linkage.

To understand more about the human inter-alpha-trypsin inhibitor heavy chain H3 (ITIH3) expression and the relationship between this gene and the family of other ITI heavy chain genes, an analysis of the structure of the ITIH3 gene and its promoter region was performed. This gene is a single copy gene, 14 kilobase pair in length and consists of 22 exons. ITIH3 shares highly conserved exon size and intron-exon borders with other ITI heavy chain genes. We determined that the human ITIH1, ITIH3, and ITIH4 genes are closely linked within a 45-kilobase pair. They are arranged in the order of H1-H3-H4, with the ITIH4 gene transcribed in the opposite direction. A model for the evolution of the ITI heavy chain gene family is presented that involves multiple rounds of gene duplication plus inversion events. The minimum promoter region (-135 to +75) is identified in HepG2 cells. The transient transfection study in various cell lines indicates that the activity of the ITIH3 promoter is not liver-specific. DNase I footprinting, mobility shift assays, and cotransfection experiments reveal a functional CCAAT/enhancer-binding protein site (C/EBP, -1344 to -1305) which interacts with C/EBPalpha and C/EBPbeta factors. The latter factors control the transcription of the ITIH3 gene positively.

Metalloelastase expression in a mouse macrophage cell line--regulation by 4beta-phorbol 12-myristate 13-acetate, lipopolysaccharide and dexamethasone.

The regulation of the expression of mouse macrophage elastase (MME) was investigated using the murine tumor cell line P388D1. The effects of three factors were studied: a phorbol ester (4beta-phorbol 12-myristate 13-acetate, PMA), an endotoxin (lipopolysaccharide, LPS) and a corticosteroid (dexamethasone). Both in situ hybridization and northern blot analysis showed that P388D1 cells constitutively express the MME gene. Quantification of the MME mRNA by northern blot analysis showed that only PMA and dexamethasone significantly regulate MME gene expression in a time-dependent and dose-dependent manner. After PMA treatment, the MME mRNA level was maximal between 4 h and 9 h (medium-term response), and the mean amplitude of the response to a concentration of 100 nM was 2.5-fold (P<0.01). LPS did not induce any significant change in MME mRNA level even when 1% serum was added to the cultures. Following dexamethasone treatment, the MME mRNA level was minimal between 21 h and 33 h (long-term response), and the mean amplitude of the response to a concentration of 100 nM was 0.49-fold (P < 0.05). Using actinomycin D, it appeared that the inhibition of RNA synthesis reduces the ulterior stimulating effect of PMA from 184% to 121%, and that MME mRNA has a half-life longer than 8 h, which is not diminished by dexamethasone. These results strongly suggest that the two factors modify MME mRNA level by stimulating (PMA) or inhibiting (dexamethasone) the transcription of the gene, rather than by modifying the transcript stability. Analysis of the cell-conditioned media by elastin zymography showed the MME as a lysis band in the 22-kDa region, the intensity of which varied with the treatments. The MME secretion is stimulated by PMA, inhibited by dexamethasone and does not show any variation after LPS treatment.

The human inter-alpha-trypsin inhibitor genes respond differently to interleukin-6 in HepG2 cells.

The effects of interleukin 6 (IL-6), the major inducer of the acute-phase reaction, on the expression of inter-alpha-trypsin inhibitor (ITI) genes were examined using human HepG2 hepatoma cells. The three ITI heavy-chain genes H1, H2 and H3 were transcriptionally regulated by IL-6 in a dose- and time-dependent manner. The treatment of HepG2 cells with IL-6 resulted in an increase of H1 and H3 mRNA levels and a decrease of H2 and L mRNA levels. Actinomycin D blocked the action of IL-6, suggesting that IL-6 regulated the H1, H2, H3 gene expression. Moreover, the kinetics of the ITI mRNA degradation in untreated and IL-6-treated cells confirmed these data. The nuclear run-on assay supports the regulatory effect of IL-6 at the transcription level of the L and H2 genes. Primer extension experiments showed that the effect of IL-6 on L, H2 and H3 mRNA synthesis was not related to the transcription starting point. Although H1, H2, H3 and L gene products are supposedly present in similar amounts in the ITI and pre-alpha-trypsin inhibitor molecules, the present work shows that these genes are regulated in a different manner, at least under the influence of IL-6.

Tandem orientation of the inter-alpha-trypsin inhibitor heavy chain H1 and H3 genes.

The inter-alpha-trypsin inhibitor H1 (ITIH1) and inter-alpha-trypsin inhibitor H3 (ITIH3) genes have both previously been mapped to chromosomes 3 and 14 in the human and mouse, respectively. We now present evidence that these genes are physically linked. By using cDNA probes, a recombinant DNA phage has been isolated from a bacteriophage DNA library, which contains sequences flanking the 5' end of the ITIH3 gene and the 3' end of the ITIH1 gene. Restriction endonuclease mapping, PCR analysis and DNA sequence determination of the recombinant phage and comparison to genomic DNA revealed that the genes are in tandem, 2721 base pairs apart, with the ITIH1 gene to the 5' side of the ITIH3 gene. Their respective transcriptional units are thus on the same strand of DNA and most probably arose in evolution as the consequence of a duplication of a common ancestral gene.

Human inter-alpha-trypsin inhibitor: full-length cDNA sequence of the heavy chain H1.

Inter-alpha-trypsin inhibitor (ITI), called inter-alpha-inhibitor, is a 220 kDa serine proteinase inhibitor found in human serum. It is composed of at least three distinct polypeptide chains. These chains, named H1, H2 and L, are an independently synthesized and proteolytically processed precursor protein. Only the complete structure of H2 and L has been established so far. We used a PCR-based cloning approach and a cDNA screening library to isolate the full-length cDNA H1. The amino acid sequences of the two heavy chains deduced from the cDNA are highly similar (40% identity). Nevertheless, the structure of the signal peptide and propeptide in the N-terminal region is different in these two chains. A complex posttranslational cleavage at both ends of H1 and H2 may be proposed prior to assembly of the ITI chains.