Biosynthesis of bikunin (urinary trypsin inhibitor) in rat hepatocytes.

One of the major sulfated proteins secreted by rat hepatocytes contains a low-sulfated chondroitin sulfate chain and its apparent molecular mass upon sodium dodecyl sulfate/polyacrylamide gel electrophoresis shifts from 40 to 28 kDa upon chondroitinase ABC treatment (E. M. Sj?berg and E. Fries, 1990, Biochem. J. 272, 113-118). These properties suggest that this protein is the rat homologue of the major trypsin inhibitor of human urine which was recently named bikunin. In serum, bikunin occurs mainly as a subunit of the pre-alpha-inhibitor and the inter-alpha-inhibitor; in these proteins it is covalently linked to the other polypeptides through its chondroitin sulfate chain. Bikunin has been shown to be synthesized by liver cells as a 42-kDa precursor, in which it is linked to alpha 1-microglobulin by two basic amino acids. We have isolated bikunin from rat urine and prepared antibodies against it. In rat hepatocytes pulse-labeled with [35S]methionine, these antibodies precipitated a labeled protein of 42 kDa. Upon chase, three different labeled proteins were recognized by the antibodies in the medium: one protein of 40 kDa (free bikunin), one of 125 kDa (presumably pre-alpha-inhibitor), and one greater than 240 kDa (possibly a protein related to the inter-alpha-inhibitor). Pulse-chase experiments with [35S]sulfate showed that these proteins occurred intracellularly as precursors containing alpha 1-microglobulin. These results demonstrate that the completion of the chondroitin sulfate chain and its coupling to other polypeptide chains occur before the cleavage of the alpha 1-microglobulin/bikunin precursor.     

The 41-amino-acid C-terminal region of the hepatitis E virus ORF3 protein interacts with bikunin, a kunitz-type serine protease inhibitor

Hepatitis E virus (HEV), a human plus-stranded RNA virus, contains three open reading frames (ORF). Of these, ORF1 encodes the viral nonstructural polyprotein, ORF2 encodes the major capsid protein, and ORF3 codes for a phosphoprotein of undefined function. Recently, using the yeast two-hybrid system to screen a human cDNA liver library, we have isolated and characterized AMBP (alpha1-microglobulin/bikunin precursor), which specifically interacts with the ORF3 protein of HEV. The ORF3 protein expedites the processing and secretion of alpha1-microglobulin. When checked individually for interaction, the second processed protein from AMBP, bikunin, strongly interacted with the full-length ORF3 protein. This protein-protein interaction has been validated by immunoprecipitation in both COS-1 and Huh7 cells and by His6 pull-down assays. In dual-labeling immunofluorescent staining, followed by fluorescence microscopy of transfected human liver cells, ORF3 colocalized with endogenously expressed bikunin. Finally, a 41-amino-acid C-terminal region of ORF3 has been found to be responsible for interacting with bikunin. The importance of this virus-host protein-protein interaction, with reference to the viral life cycle, has been discussed.     

Expression of the AMBP gene transcript and its two protein products,alpha(1)-microglobulin and bikunin,in mouse embryogenesis

The expression pattern of the alpha(1)-microglobulin/bikunin precursor (AMBP) gene, and its two protein products were studied in mouse embryos of 8.5-15.5 days of embryonic development by in situ hybridization and immunohistochemistry. AMBP mRNA is strongly transcribed in liver parenchyma, pancreas, and intestine epithelium. Sites of weaker expression are the vessels of the umbilical cord, the developing vertebral bodies, and kidney. The alpha(1)-microglobulin and bikunin proteins are accordingly present in developing hepatocytes, pancreas, kidney, and gut. However, additional sites of protein distribution were found that do not correlate to mRNA localization: alpha(1)-microglobulin was found in myocytes and bikunin in cardiac muscle, nervous system microvasculature, and connective tissue. Both proteins were found in brain mesenchyme and meninges. Thus, a restricted expression of the AMBP mRNA in a few organs contrasts to a widespread and unique distribution of each of the two proteins.     

The ORF3 protein of hepatitis E virus interacts with liver-specific alpha1-microglobulin and its precursor alpha1-microglobulin/bikunin precursor (AMBP) and expedites their export from the hepatocyte

Hepatitis E virus (HEV), a plus-stranded RNA virus contains three open reading frames. Of these, ORF1 encodes the viral nonstructural polyprotein; ORF2 encodes the major capsid protein and ORF3 codes for a phosphoprotein of undefined function. Using the yeast two-hybrid system to screen a human cDNA liver library we have isolated, an N-terminal deleted protein, alpha(1) -microglobulin/bikunin precursor (AMBP) that specifically interacts with the ORF3 protein of HEV. Independently cloned, full-length AMBP was obtained and tested positive for interaction with ORF3 using a variety of in vivo and in vitro techniques. AMBP, a liver-specific precursor protein codes for two different unrelated proteins alpha(1)-microglobulin (alpha(1)m) and bikunin. alpha(1) m individually interacted with ORF3. The above findings were validated by COS-1 cell immunoprecipitation, His(6) pull-down experiments, and co-localization experiments followed by fluorescence resonance energy transfer analysis. Human liver cells showing co-localization of ORF3 with endogenously expressing alpha(1) m showed a distinct disappearance of the protein from the Golgi compartment, suggesting that ORF3 enhances the secretion of alpha(1)m out of the hepatocyte. Using drugs to block the secretory pathway, we showed that alpha m was not degraded in the presence of ORF3. Finally, (1)pulse labeling of alpha(1)m showed that its secretion was expedited out of the liver cell at faster rates in the presence of the ORF3 protein. Hence, ORF3 has a direct biological role in enhancing alpha(1)m export from the hepatocyte.     

Expression of a functional proteinase inhibitor capable of accepting xylose: bikunin

Bikunin is a Kunitz-type proteinase inhibitor, which is cross-linked to heavy chains via a chondroitin sulfate chain, forming inter-alpha-inhibitor and related molecules. Rat bikunin was produced by baculovirus-infected insect cells. The protein could be purified with a total yield of 20 mg/liter medium. Unlike naturally occuring bikunin the recombinant protein had no galactosaminoglycan chain. Endoglycosidase digestion also suggested that the recombinant form lacked N-linked oligosaccharides. Bikunin is translated as a part of a precursor, alpha1-microglobulin/bikunin, but the functional significance of the cotranslation is unknown. Our results indicate that the proteinase inhibitory function of bikunin is not regulated by the alpha1-microglobulin-part of the alpha1-microglobulin/bikunin precursor since recombinant bikunin had the same trypsin inhibitory activity as the recombinant precursor. Both free bikunin and the precursor were also functional as a substrate in an in vitro xylosylation system. This demonstrates that the alpha1-microglobulin-part is not necessary for the first step of galactosaminoglycan assembly.     

Immunohistochemical distribution of inter-alpha-trypsin inhibitor chains in normal and malignant human lung tissue.

The inter-alpha-trypsin inhibitor (ITI) family is a group of plasma proteins built up from heavy (HC1, HC2, HC3) and light (bikunin) chains synthesized in the liver. In this study we determined the distribution of ITI constitutive chains in normal and cancerous lung tissues using polyclonal antibodies. In normal lung tissue, H2, H3, and bikunin chains were found in polymorphonuclear cells, whereas H1 and bikunin proteins were found in mast cells. Bikunin was further observed in bronchoepithelial mucous cells. In lung carcinoma, similar findings were obtained on infiltrating polymorphonuclear and mast cells surrounding the tumor islets. Highly differentiated cancerous cells displayed strong intracytoplasmic staining with H1 and bikunin antiserum in both adenocarcinoma and squamous cell carcinoma. Moreover, weak but frequent H2 expression was observed in adenocarcinoma cells, whereas no H3-related protein could be detected in cancer cells. Local lung ITI expression was confirmed by RT-PCR. Although the respective role of inflammatory and tumor cells in ITI chain synthesis cannot be presently clarified, these results show that heavy chains as well as bikunin are involved in malignant transformation of lung tissue.(J Histochem Cytochem 47:1625-1632, 1999)     

Biosynthesis of inter-alpha-trypsin inhibitor and alpha 1-microglobulin in a human hepatoma cell line.

1. Biosynthesis of alpha 1-microglobulin and inter-alpha-trypsin inhibitor was investigated in a human hepatoma cell line HepG-2. 2. alpha 1-Microglobulin was translated as a precursor common with the light chain of inter-alpha-trypsin inhibitor. 3. alpha 1-Microglobulin was synthesized and secreted into the growth medium within 30 min. 4. Processing of inter-alpha-trypsin-inhibitor-related proteins appeared slow and incomplete. The light chain was connected via a chondroitinsulphate to a heavy chain to form a 125,000-Mr protein and secreted within 1-4 hr.     

The alpha1-microglobulin/bikunin gene: characterization in mouse and evolution.

The 129Sv mouse gene coding for the alpha1-microglobulin/bikunin precursor has been isolated and characterized. The 11kb long gene contains ten exons, including six 5'-exons coding for alpha1-microglobulin and four 3'-exons encoding bikunin. Exon 7 also codes for the tribasic tetrapeptide RARR which connects the alpha1-microglobulin and bikunin parts. The sixth intron, which separates the alpha1-microglobulin and bikunin encoding parts, was compared in the human, mouse and a fish (plaice) gene. The size of this intron varies considerably, 6.5, 3.3 and 0.1kb in man, mouse and plaice, respectively. In all three genes, this intron contains A/T-rich regions, and retroposon elements are found in the first two genes. This indicates that this sixth intron is an unstable region and a hotspot for recombinational events, supporting the concept that the alpha1-microglobulin and bikunin parts of this gene are assembled from two ancestral genes. Finally, the nonsynonymous nucleotide substitution rate of the gene was determined by comparing coding sequences from ten vertebrate species. The results indicate that the alpha1-microglobulin part of the gene has evolved faster than the bikunin part.     

In vivo metabolism of inter-alpha-trypsin inhibitor and its proteinase complexes: evidence for proteinase transfer to alpha 2-macroglobulin and alpha 1-proteinase inhibitor

Inter-alpha-trypsin inhibitor was purified by a modification of published procedures which involved fewer steps and resulted in higher yields. The preparation was used to study the clearance of the inhibitor and its complex with trypsin from the plasma of mice and to examine degradation of the inhibitor in vivo. Unlike other plasma proteinase inhibitor-proteinase complexes, inter-alpha-trypsin inhibitor reacted with trypsin did not clear faster than the unreacted inhibitor. Studies using 125I-trypsin provided evidence for the dissociation of complexes of proteinase and inter-alpha-trypsin inhibitor in vivo, followed by rapid removal of proteinase by other plasma proteinase inhibitors, particularly alpha 2-macroglobulin and alpha 1-proteinase inhibitor. Studies in vitro also demonstrated the transfer of trypsin from inter-alpha-trypsin inhibitor to alpha 2-macroglobulin and alpha 1-proteinase inhibitor but at a much slower rate. The clearance of unreacted 125I-inter-alpha-trypsin inhibitor was characterized by a half-life ranging from 30 min to more than 1 h. Murine and human inhibitors exhibited identical behavior. Multiphasic clearance of the inhibitor was not due to degradation, aggregation, or carbohydrate heterogeneity, as shown by competition studies with asialoorosomucoid and macroalbumin, but was probably a result of extravascular distribution or endothelial binding. 125I-inter-alpha-trypsin inhibitor cleared primarily in the liver. Analysis of liver and kidney tissue by gel filtration chromatography and sodium dodecyl sulfate gel electrophoresis showed internalization and limited degradation of 125I-inter-alpha-trypsin inhibitor in these tissues. No evidence for the production of smaller proteinase inhibitors from 125I-inter-alpha-trypsin inhibitor injected intravenously or intraperitoneally was detected, even in casein-induced peritoneal inflammation. No species of molecular weight similar to that of urinary proteinase inhibitors, 19,000-70,000, appeared in plasma, liver, kidney, or urine following injection of inter-alpha-trypsin inhibitor.     

The in vitro interactions of rat pancreatic elastase and normal and inflammatory ray serum.

The partition of labelled rat pancreatic elastase (EC 3.4.21.11) between the different protease inhibitors of rat plasma was studied at different levels of saturation of the inhibitors of rat plasma was studied at different levels of saturation of the inhibitor capacity of plasma with the enzyme. The reaction mixtures were analysed by immunoelectrophoretic methods utilizing specific antisera against the different inhibitors and by gel filtration on Sephadex G-200. Rat serum was shown to contain four elastase binding proteins. alpha 1-antitrypsin, alpha 1-macroglobulin and alpha 2-acute phase protein and alpha 1-inhibitor 3 which exhibits immunologic cross-reaction with human inter-alpha-trypsin inhibitor and is of similar molecular weight. With minute amounts of labelled elastase the partition among the binding protein was alpha 1-macroglobulin 60%, alpha 1-antitrypsin 24% and alpha 1-I3 16%. The 60% value of alpha 1-M bound radioactivity in normal serum corresponds to the sum of alpha 1-M and alpha 2-AP labelling in inflammatory serum.     

Molecular cloning of porcine alpha 1-microglobulin/HI-30 reveals developmental and tissue-specific expression of two variant messenger ribonucleic acids.

A 1008 basepair (bp) cDNA clone encoding 335 amino acids followed by an inframe TGA translation termination codon and a 295-nucleotide 3' untranslated (UT) region has been isolated from a pig liver cDNA library. Based on the deduced amino acid and nucleotide sequence homology to a human cDNA (Kaumeyer, J.F., Polazzi, J.O. and Kotick, M.P. (1986) Nucleic Acids Res. 14, 7839-7850), the 5' amino terminus was found to code for alpha 1-microglobulin (alpha 1-M), a 183 amino acid protein belonging to the lipocalin protein superfamily (Pervaiz, S. and Brew, K. (1985) Science 228, 335-337). The 3' half encoded HI-30 which constitutes the Kunitz-type proteinase inhibitory (L-chain) domain of porcine inter-alpha-trypsin inhibitor (I alpha TI). In Northern blot hybridization, this cDNA identified two equally abundant mRNA species of approx. 1.3 kb and 1.6 kb in length. However, a 125 bp cDNA probe derived from the 3' UT region of the cDNA hybridized only to the 1.6 kb mRNA. The differences observed in the 3' UT region of these mRNAs suggest the utilization of alternative polyadenylation signals or presence of unprocessed nuclear RNA. Densitometric scanning of Northern blots indicated that alpha 1-M/HI-30 mRNA levels were higher (5-8-fold) in fetal and neonatal liver compared to that of primiparous pigs. In contrast, the RNA levels did not change significantly during pregnancy. Dot blot analysis of RNA indicated liver to be the major site of alpha 1-M/HI-30 mRNA expression with lower levels observed in the stomach. The results suggest that modulation of alpha 1-M/HI-30 gene expression could play a role during porcine growth. Increased I alpha TI L-chain mRNA levels may be particularly important in fetal and neonatal development when regulation of the inflammatory response and protection of macromolecules from proteolytic degradation is vital to survival and sustained growth.     

Isolation of plaice (Pleuronectes platessa) alpha1-microglobulin: conservation of structure and chromophore

A cDNA coding for plaice (Pleuronectes platessa) alpha1-microglobulin (Leaver et al., 1994, Comp. Biochem. Physiol. 108B, 275-281) was expressed and purified from baculovirus-infected insect cells. Specific monoclonal antibodies were then prepared and used to isolate the protein from plaice liver and serum. Mature 28.5 kDa alpha1-microglobulin was found in both liver and serum. The protein consisted of an 184 amino acid peptide with a complex N-glycan in position Asn123, one intrachain disulfide bridge and a yellow-brown chromophore. Physicochemical characterization indicated a globular shape with a frictional ratio of 1.37, electrophoretic charge-heterogeneity and antiparallel beta-sheet structure. A smaller, incompletely glycosylated, yellow-brown alpha1-microglobulin as well as a 45 kDa precursor protein were also found in liver. The chromophore was found to be linked to alpha1-microglobulin intracellularly. Recombinant plaice alpha1-microglobulin isolated from insect cells had the same N-terminal sequence, globular shape and yellow-brown color as mature alpha1-microglobulin, but carried a smaller, fucosylated, non-sialylated N-glycan in the Asn123 position. The concentration of alpha1-microglobulin in plaice serum was 20 mg/l and it was found both as a 28.5 kDa component and as high molecular weight components. Thus, the size, shape, charge and color of plaice alpha1-microglobulin were similar to mammalian alpha1-microglobulin, indicating a high degree of structural conservation between fish and human alpha1-microglobulin. The monoclonal antibodies against plaice alpha1-microglobulin cross-reacted with human alpha1-microglobulin, emphasizing the structural similarity.     

Two out of the three kinds of subunits of inter-alpha-trypsin inhibitor are structurally related

Inter-alpha-trypsin inhibitor is a 240-kDa plasma-protein complex of three different types of glycoproteins. Their stoichiometric relation in the complex is not yet known. One subunit results from proteolytic processing of a precursor protein composed of alpha 1-microglobulin and a double-headed Kunitz-type proteinase inhibitor protein. From this, only the inhibitor protein becomes part of the inter-alpha-trypsin inhibitor complex. Another subunit whose function is not yet understood is structurally unrelated to the first one as well as to other proteins of various data collections. Now we have obtained a cDNA clone coding for 837 amino acid residues of a precursor protein of the third subunit. Its primary structure is 40% identical to that of the completely known second-subunit precursor. Peptide sequences obtained from isolated inter-alpha-trypsin inhibitor represent a distinct part of only about two thirds of the predicted polypeptide precursor, suggesting that its maturation is very similar to that of the second subunit. Therefore, we conclude that the deduced primary structure covers about 98% of the mature third subunit.     

Homologous chromosomal locations of the four genes for inter-alpha-inhibitor and pre-alpha-inhibitor family in human and mouse: assignment of the ancestral gene for the lipocalin superfamily.

The inter-alpha-inhibitor (I alpha I) and pre-alpha-inhibitor (P alpha I) family is composed of three plasma protease inhibitors, I alpha I, P alpha I, and bikunin, whose chains are encoded by a set of three evolutionarily related heavy (H) chain genes designated H1, H2, and H3 and a fourth gene, the so-called alpha 1-microglobulin/bikunin precursor (AMBP) gene. The latter codes for a precursor that splits into: (i) alpha 1-microglobulin, which belongs to the lipocalin superfamily; and (ii) bikunin, which is made up of two tandemly arranged protease inhibitor domains and belongs to the superfamily of Kunitz-type protease inhibitors. The bikunin chain is found in I alpha I and P alpha I molecules and it is also present as a free molecule in plasma. In human, the AMBP and H2 genes have been mapped to 9q32-q34 and 10p14-p15, respectively, while the H1 and H3 genes are tandemly located at 3p21.1-p21.2. In situ hybridization mappings indicate that the mouse AMBP gene (Intin-4) is located at 4C1----C4, and the H1 (Intin-1) and H3 (Intin-3) genes are colocated at 14A2----C1. In interspecific backcrosses (C57BL/6Pas x Mus spretus) a TaqI restriction variant in (and/or near) the H2 (Intin-2) gene identified a linkage of this gene with other polymorphic loci, which assigns Intin-2 to the centromeric area of chromosome 2. All such assignments are in conserved chromosomal regions between human and mouse. Therefore the genetic events that gave rise to the four I alpha I family genes took place prior to the divergence between human and mouse.(ABSTRACT TRUNCATED AT 250 WORDS)     

alpha(1)-Microglobulin: a yellow-brown lipocalin

alpha(1)-Microglobulin, also called protein HC, is a lipocalin with immunosuppressive properties. The protein has been found in a number of vertebrate species including frogs and fish. This review summarizes the present knowledge of its structure, biosynthesis, tissue distribution and immunoregulatory properties. alpha(1)-Microglobulin has a yellow-brown color and is size and charge heterogeneous. This is caused by an array of small chromophore prosthetic groups, attached to amino acid residues at the entrance of the lipocalin pocket. A gene in the lipocalin cluster encodes alpha(1)-microglobulin together with a Kunitz-type proteinase inhibitor, bikunin. The gene is translated into the alpha(1)-microglobulin-bikunin precursor, which is subsequently cleaved and the two proteins secreted to the blood separately. alpha(1)-Microglobulin is found in blood and in connective tissue in most organs. It is most abundant at interfaces between the cells of the body and the environment, such as in lungs, intestine, kidneys and placenta. alpha(1)-Microglobulin inhibits immunological functions of white blood cells in vitro, and its distribution is consistent with an anti-inflammatory and protective role in vivo.     

Structural relationship between alpha 1-microglobulin from man, guinea-pig, rat and rabbit

Rabbit alpha 1-microglobulin was purified from the urine of sodium-chromate-treated animals by the use of gel chromatography on Sephadex G-100, affinity chromatography on concanavalin-A--Sepharose and ion-exchange chromatography on DEAE-Sephadex. Rabbit alpha 1-microglobulin had a molecular mass of 25.6 kDa on SDS/polyacrylamide gel electrophoresis. Alpha 1-microglobulin has previously been purified from the urine of humans, guinea-pigs and rats by similar methods, and the molecular masses of the four homologues were compared by SDS/polyacrylamide gel electrophoresis and gel chromatography in a denaturing medium. By these two methods the human homologue was 6 kDa and 3 kDa larger, respectively, than the other three proteins. Endoglycosidase F digestion of alpha 1-microglobulin, followed by SDS/polyacrylamide gel electrophoresis, revealed three protein bands in the human alpha 1-microglobulin sample, and only two bands in guinea-pig, rat and rabbit alpha 1-microglobulin, with a gap between each band of 2.6--2.9 kDa. The amino-terminal amino acid sequences of the four homologues were determined and between 72% and 81% homology was seen. The five amino-terminal amino acids present in the other species were missing in guinea-pig alpha 1-microglobulin. Our results indicate that human alpha 1-microglobulin is substituted with two N-linked oligosaccharides, while only one is attached to each of the other alpha 1-microglobulins, and that the extra glycosylamine-linked oligosaccharide in the human protein is attached to asparagine in position 17. Finally it is shown that all four homologues inhibit antigen stimulation of human lymphocytes, a finding which is consistent with our previous suggestion that the N-linked oligosaccharides carry the immunosuppressive activity of alpha 1-microglobulin.     

The cDNA structure and expression analysis of the genes for the cysteine proteinase inhibitor cystatin C and for beta 2-microglobulin in rat brain

Tissue patterns of gene expression were analyzed by measuring mRNA levels and incorporation of radioactive amino acids for cystatin C and beta 2-microglobulin, the two extracellular proteins in the brain with the highest ratio of concentration in cerebrospinal fluid over that in blood plasma. The primary structure of rat cystatin C mRNA from choroid plexus was determined by nucleotide sequencing of cloned cDNA and the tissue patterns of gene expression were analysed by RNA blot analysis and in situ hybridization. Cystatin C was found to be composed of 120 amino acids and to contain a potential site for N-linked glycosylation. The tissue with the highest cystatin C mRNA level was the choroid plexus of the brain. Cystatin C mRNA was also detected in lower levels in other areas of the brain, testis, epididymis, seminal vesicles, prostate, ovary, submandibular gland, and, in trace amounts, in liver. Choroid plexus pieces in culture secreted radioactive cystatin C when incubated with radioactive leucine. Rat beta 2-microglobulin cDNA was cloned and identified by nucleotide sequencing and comparison of the obtained sequence with that of mouse and human beta 2-microglobulin cDNA. Tissue levels of beta 2-microglobulin mRNA in the rat were measured by hybridization to rat beta 2-microglobulin cDNA. The highest levels of beta 2-microglobulin mRNA were observed in liver and choroid plexus. Other parts of the brain and testis contained lower levels of beta 2-microglobulin mRNA.