Inter-alpha-inhibitor (IalphaI) and related molecules, collectively referred to as the IalphaI family, are a group of plasma protease inhibitors. They display attractive features such as precursor polypeptides that give rise to mature chains with quite distinct fates and functions, and inter-chain glycosaminoglycan bonds within the various molecules. The discovery of an ever growing number of such molecules has raised pertinent questions about their pathophysiological functions. The knowledge of this family has long been structure-oriented, whereas the structure/function and structure/regulation relationships of the family members and their genes have been largely ignored. These relationships are now being elucidated in events such as gene transcription, precursor processing, changes in plasma protein levels in health and disease and binding capacities that involve hyaluronan as well as other plasma proteins as ligands. This review presents some recent progress made in these fields that paves the way for an understanding of the functions of IalphaI family members in vivo. Finally, given the wealth of heterogeneous, complicated and sometimes contradictory nomenclatures and acronyms currently in use for this family, a new, uniform, nomenclature is proposed for IalphaI family genes, precursor polypeptides and assembled proteins.
As indicators of responsiveness to a tumour necrosis factor (TNF)α blocking agent (infliximab) are lacking in rheumatoid arthritis, we have used gene profiling in peripheral blood mononuclear cells to predict a good versus poor response to infliximab. Thirty three patients with very active disease (Disease Activity Score 28 >5.1) that resisted weekly methotrexate therapy were given infliximab at baseline, weeks 2 and 6, and every 8th week thereafter. The patients were categorized as responders if a change of Disease Activity Score 28 = 1.2 was obtained at 3 months. Mononuclear cell RNAs were collected at baseline and at three months from responders and nonresponders. The baseline RNAs were hybridised to a microarray of 10,000 non-redundant human cDNAs. In 6 responders and 7 non-responders, 41 mRNAs identified by microarray analysis were expressed as a function of the response to treatment and an unsupervised hierarchical clustering perfectly separated these responders from non-responders. The informativeness of 20 of these 41 transcripts, as measured by qRT-PCR, was reassessed in 20 other patients. The combined levels of these 20 transcripts properly classified 16 out of 20 patients in a leaveone-out procedure, with a sensitivity of 90% and a specificity of 70%, whereas a set of only 8 transcripts properly classified 18/ 20 patients. Trends for changes in various transcript levels at three months tightly correlated with treatment responsiveness and a down-regulation of specific transcript levels was observed in non-responders only. Our gene profiling obtained by a noninvasive procedure should now be used to predict the likely responders to an infliximab/methotrexate combination.
During an acute, systemic inflammation, the liver is triggered by blood-borne pro-inflammatory cytokines such as Tumor Necrosis Factor alpha, Interleukin-1beta and Interleukin-6. The end result is an up- or down-regulated synthesis and/or activation of liver-enriched transcription factors that in turn regulate many target genes coding for resident or secreted acute phase proteins. In this review, various classifications of these acute phase proteins are presented. Major inflammation-driven changes in the synthesis and/or activity of the hepatic transcription factors are illustrated. Some of their up- or down-regulated target genes are used as paradigms of the various transcriptional mechanisms that take place on gene promoters during an acute, systemic inflammation. Finally, further specific features of inflammation-associated gene transcription in liver from acute phase onset to resolution are provided.
A change in the balance between proliferation and apoptosis in the course of hepatocellular carcinoma (HCC) development and progression has been suspected. We wanted to identify related genes whose mRNA levels could provide markers of severity and prognosis after resection. The extent of cell apoptosis, proliferation, and differentiation was measured with a terminal deoxynucleotidyl transferase-mediated deoxyuridine 5-triphosphate-biotin nick-end labeling assay, and the Ki-67 index was determined in paired tumor and cirrhotic tissue samples from patients who had undergone HCC resection after diagnosis of hepatitis C-related or alcoholism-related cirrhosis. These patients included two groups with highly versus poorly differentiated tumor cells, and the latter was split into two subgroups of those with versus without early recurrence. The mRNA levels for various apoptosis-related or proliferation-related genes and those for the growth factor/receptor systems were measured by quantitative reverse transcriptase-polymerase chain reaction in paired tumor and cirrhotic liver samples from every patient, and some of the corresponding proteins were detected by immunohistochemistry. In all instances, protein expression was highly heterogeneous within groups and similar between groups. In contrast, some differences in mRNA level between tumor and cirrhotic tissues were quite informative. Low levels of hepatocyte growth factor and transforming growth factor alpha mRNAs were found concomitantly in highly differentiated tumors, whereas overexpression of mRNAs for the cognate receptors c-met and epidermal growth factor receptor were found in poorly differentiated tumors and primarily in patients with early tumor recurrence. These results argue for growth factor-dependent HCC development and provide novel and combined prognosis markers after HCC surgery.
A set of orthologous plasma proteins found in human, sheep, pig, cow and rodents, now collectively designated fetuin-A, constitutes the fetuin family. Fetuin-A has been identified as a major protein during fetal life and is also involved in important functions such as inhibition of the insulin receptor tyrosine kinase activity, protease inhibitory activities and development-associated regulation of calcium metabolism and osteogenesis. Furthermore, fetuin-A is a key partner in the recovery phase of an acute inflammatory response. We now describe a second protein of the fetuin family, called fetuin-B, which is found at least in human and rodents. On grounds of domain homology, overall conservation of cysteine residues and chromosomal assignments of the corresponding genes in these species, fetuin-B is unambiguously a paralogue of fetuin-A. Yet, fetuin-A and fetuin-B exhibit significant differences at the amino acid sequence level, notably including variations with respect to the archetypal fetuin-specific signature. Differences and similarities in terms of gene regulation were also observed. Indeed, studies performed during development in rat and mouse showed for the first time high expression of a member of the fetuin family in adulthood, as shown with the fetuin-B mRNA in rat. However, like its fetuin-A counterpart, the fetuin-B mRNA level is down-regulated during the acute phase of experimentally induced inflammation in rat.
Human inter‐α‐trypsin inhibitor is a plasma protein of Mr 180000 which has long been described as a single polypeptide chain. However, we have previously demonstrated that it is synthesized in liver by two different mRNA populations coding for heavy or light polypeptide chains [Bourguignon, J. et al. (1983) FEBS Lett. 162, 379–383] and cDNA clones for the heavy or light chains have recently been isolated and characterized [Bourguignon, J. et al. (1985) Biochem. Biophys. Res. Commun. 131, 1146–1153; Salier, J. P. et al. (1987) Proc. Natl Acad. Sci. USA 84, 8272–8276]. In the present study, we show that human poly(A)‐rich RNAs hybrid‐selected with various heavy‐chain‐encoding cDNA clones translate three different heavy chains, designated H1 (Mr 98000) and H3 (Mr 107000). We previously characterized two heavy‐chain cDNA clones. We now report that they correspond to H1 and H2 chains. We have also determined the sequence of an additional cDNA clone which codes for H3 chain. Its insert size is 1.79 kb with a single open reading frame and a poly(A) tail. The deduced amino acid sequence of the H3 chain is highly similar to those of the H1 (54%) and H2 (44%) chains. Northern analysis of human liver poly(A)‐rich RNAs with the three heavy‐chain cDNAs as probes clearly identified a single major mRNA population of 3.3 ± 0.1 kb. Chromosomal localization by in situ hybridization shows that inter‐α‐trypsin inhibitor genes are located on three different human chromosomes. The H1 and H3 genes are located in the p211–p212 region of chromosome 3, whereas the H2 gene resides in the p15 band of chromosome 10. The light‐chain gene is located in the q32–q33 region of chromosome 9. These results indicate that heavy and light chains of inter‐α‐trypsin inhibitor are encoded by at least four functional genes.
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