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)     

A proteoglycan related to the urinary trypsin inhibitor (UTI) links the two heavy chains of inter-alpha-trypsin inhibitor

cDNA studies have suggested that inter-alpha-trypsin inhibitor (ITI) is a complex of several different peptide chains; the sequence of the inhibitory part of ITI is in excellent agreement with that of the urinary trypsin inhibitor (UTI). The present report demonstrates that a compound immunologically related to UTI is released by digestion with porcine pancreatic elastase or human leucocyte elastase. Since UTI has been shown to be a proteoglycan, ITI has been treated by chondroitinase. In these conditions, ITI is dissociated and gives rise to two heavy chains (78 and 85 kDa) and one light chain (26 kDa) immunologically related to UTI and which in PAGE moves close to UTIc (produced by chondroitinase treatment of UTI). We suggest that ITI is a non-covalent complex comprising two heavy chains and one light chain immunologically related to UTI and which is also a proteoglycan.     

Accumulation of immunoglobulin messenger ribonucleic acid in immunized mouse spleen.

We have measured the concentration of mRNAs coding for immunoglobulins, k and lambda type light chains and gamma 1 type heavy chain, in mouse spleen cells activated by bacterial lipopolysaccharide or sheep red blood cells. These mRNAs were quantitated by hybridization to radioactive DNA complementary to highly purified immunoglobulin mRNAs from mouse myelomas. In the lipopolysaccharide-stimulated spleen cells, only light chain mRNA accumulated, whereas gamma 1 type heavy chain mRNA remained unvaried. The light chain mRNA concentration also increased in purified bone-marrow-derived lymphocytes. The lipopolysaccharide-induced light chain mRNA was similar to light chain mRNAs purified from myelomas. The accumulation and disappearance of light chain mRNA in bone-marrow-derived lymphocytes coincide with the kinetics of synthesis of immunoglobulin M which is the major species induced by lipopolysaccharide. In sheep red blood cell stimulated spleen, the specific accumulation of k type light chain and gamma 1 type heavy chain mRNAs parallels immunoglobulin G synthesis. These results seem to indicate that the increment of immunoglobulin mRNA concentration in bone-marrow-derived lymphocytes is important for induction of immunoglobulin synthesis.     

Messenger RNA for immunoglobulin light and heavy chains in MOPC-315 plasmacytoma and variants

Mouse plasmacytoma MOPC-315 produces light and heavy immunoglobulin chains. The variants, MOPC-315 NP-1 and MOPC-315 NR, synthesize only heavy or light chains, respectively. To eludicate the inability of MOPC-315 variants to produce intact light or heavy chains, complementary DNAs (cDNAs) to the mRNAs were prepared. From the kinetics of DNA-RNA hybridization, the RNA of the MOPC-315 NP-1 variant was shown to contain few or no sequences homologous with MOPC-315 light chain mRNA. Thus, the inability of this variant to produce light chain results from the absence of light chain mRNA. In contrast, the polyadenylated mRNA fraction of the MOPC-315 NR variant, which does not synthesize heavy chain, contains about two-thirds of the sequences present in heavy chain mRNA. Thus, this variant contains a fragment of heavy chain mRNA.     

Cloning of cDNAs coding for the heavy chain region and connecting region of human factor V, a blood coagulation factor with four types of internal repeats

Human factor V is a high molecular weight plasma glycoprotein that participates as a cofactor in the conversion of prothrombin to thrombin by factor Xa. Prior to its participation in the coagulation cascade, factor V is converted to factor Va by thrombin generating a heavy chain and a light chain, and these two chains are held together by calcium ions. A connecting region originally located between the heavy and light chains is liberated during the activation reaction. In a previous study, a cDNA of 2970 nucleotides that codes for the carboxyl-terminal 938 amino acids of factor V was isolated and characterized from a Hep G2 cDNA library [Kane, W. H., & Davie, E. W. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 6800-6804]. This cDNA has been used to obtain additional clones from Hep G2 and human liver cDNA libraries. Furthermore, a Hep G2 cDNA library prepared with an oligonucleotide from the 5' end of these cDNAs was screened to obtain overlapping cDNA clones that code for the amino-terminal region of the molecule. The composite sequence of these clones spans 6911 nucleotides and is consistent with the size of the factor V message present in Hep G2 cells (approximately 7 kilobases). The cDNA codes for a leader sequence of 28 amino acids and a mature protein of 2196 amino acids. The amino acid sequence predicted from the cDNA was in complete agreement with 139 amino acid residues that were identified by Edman degradation of cyanogen bromide peptides isolated from the heavy chain region and connecting region of plasma factor V.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human plasma inter-alpha-trypsin inhibitor is encoded by four genes on three chromosomes

Human inter-alpha-trypsin inhibitor is a plasma protein of Mr 180,000 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 92,000), H2 (Mr 98,000) and H3 (Mr 107,000). 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-alpha-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-alpha-trypsin inhibitor are encoded by at least four functional genes.     

Variation in the relative synthesis of immunoglobulin G and non-immunoglobulin G proteins in cultured MPC-11 cells with changes in the overall rate of polypeptide chain initiation and elongation

The synthesis of individual proteins in the mouse plasmacytoma cell MPC-11 is differentially inhibited when the rate of polypeptide chain initiation is reduced by exposure of cells to hypertonic medium. The synthesis of immunoglobulin G light and heavy chain polypeptides is 3.5 to 4-fold and 1.5 to 2-fold more resistant, respectively, than the synthesis of non-immunoglobulin G proteins when total protein synthesis is reduced by ~90%. In contrast, when polypeptide chain elongation is inhibited, the synthesis of the light and heavy chains is not more resistant than the synthesis of non-immunoglobulin G proteins.The results with MPC-11 cells suggests that: (1) under standard growth conditions the relative synthesis of individual proteins is determined mainly, but not exclusively, by the relative amounts of the individual messenger RNA species present in the cell; (2) under conditions where the overall rate of polypeptide chain initiation is reduced the relative synthesis of individual proteins becomes more dependent upon the intrinsic ability of their corresponding mRNAs to form functional mRNA-ribosome initiation complexes.     

Heavy-chain mutants derived from gamma 2b mouse myeloma: characterization of heavy-chain messenger ribonucleic acid, proteins, and secretion in delection mutants and messenger ribonucleic acid in gamma2a mutant progeny

Mouse myeloma mutants isolated from cell line 45.6 (gamma 2b) producing structurally altered immunoglobulin heavy (H) chains have been characterized. The mutant 10-1 synthesizes an H chain of 47 000 daltons containing a CH1 deletion; two mutants, G251 and I17, derived from 10-1 synthesize H chains of 40 000 and 35 000 daltons, respectively. The messenger ribonucleic acids (mRNAs) in these mutants have been shown to be smaller in molecular weight than mRNAs produced in 45.6 cells and lack a portion, but not all, of the CH1 domain. The H chains of G251 and I17 no longer express IgG subclass-specific determinants, are not secreted, and are structurally altered in the carboxyl-terminal portion of the molecule. In vitro the mRNAs of the mutants code for the synthesis of a polypeptide precursor characteristic of secreted proteins; the shortened proteins are apparently glycosylated intracellularly. Somatic cell hybrids between a structurally altered nonsecretor and a drug-marked wild-type myeloma cell secret only the wild-type protein. Reversion to secretion for G251 or I17 is accompanied by a change in the amino acid composition of the H chain such that gamma 2a subclass-specific determinants are expressed. Therefore, the primary structure of the H chain is an important factor in determining secretion. The gamma 2a-secreted chains from G251 and I17 fall into two classes: (1) those synthesizing proteins of approximately 47 000 daltons producing H-chain mRNAs of approximately 1.66 kilobases that are deleted for a portion, but not all, of CH1; (2) those synthesizing gamma2a proteins of approximately 55 000 daltons that are encoded in mRNAs of apparently wild-type size and that have regained CH1 sequences. The molecular explanations for the production of these alterations is discussed.     

Fast myosin light chain expression in chicken muscles studied by in situ hybridization.

We have studied the fiber type-specific expression of the fast myosin light chain isoforms LC 1f, LC 2f, and LC 3f in adult chicken muscles using in situ hybridization and two-dimensional gel electrophoresis. Type II (fast) fibers contain all three fast myosin light chain mRNAs; Types I and III (slow) fibers lack them. The myosin light chain patterns of two-dimensional gels from microdissected single fibers match their mRNA signals in the in situ hybridizations. The results confirm and extend previous studies on the fiber type-specific distribution of myosin light chains in chicken muscles which used specific antibodies. The quantitative ratios between protein and mRNA content were not the same for all three fast myosin light chains, however. In bulk muscle samples, as well as in single fibers, there was proportionally less LC 3f accumulated for a given mRNA concentration than LC 1f or LC 2f. Moreover, the ratio between LC 3f mRNA and protein was different in samples from muscles, indicating that LC 3f is regulated somewhat differently than LC 1f and LC 2f. In contrast to other in situ hybridization studies on the fiber type-specific localization of muscle protein mRNAs, which reported the RNAs to be located preferentially at the periphery of the fibers, we found all three fast myosin light chain mRNAs quite evenly distributed within the fiber's cross-sections, and also in the few rare fibers which showed hybridization signals several-fold higher than their surrounding counterparts. This could indicate principal differences in the intracellular localization among the mRNAs coding for various myofibrillar protein families.     

Glycosylation causes an apparent block in translation of immunoglobulin heavy chain

Analysis of nascent heavy chains isolated from MPC11 (gamma 2b heavy chains) and MOPC 21 (gamma 1 heavy chains) mouse myeloma cells demonstrates an accumulation of nascent heavy chains which are slightly smaller in mass (approximately 35,000 daltons) than nascent heavy chains which have just been glycosylated (approximately 38,000 daltons). The accumulation of 35,000-dalton nascent heavy chain appears to be a consequence of the glycosylation process since tunicamycin, an inhibitor of glycosylation, abolishes the apparent translational block manifested by the accumulation of 35,000-dalton nascent chains. Tunicamycin also causes a 15 to 25% increase n the relative rate of synthesis of heavy chain compared to the corresponding rate of synthesis of the nonglycosylated light chain synthesized by the same cell. These results suggest that the translation block, caused by the glycosylation process, of heavy chain synthesis contributes to the imbalance of heavy chain and light chain biosynthesis observed in malignant and normal lymphoid cells.     

Cloning, Chromosomal Localization, and Physical Linkage of the β and γ Subunits (SCNN1B and SCNN1G) of the Human Epithelial Amiloride-Sensitive Sodium Channel

Three subunits of the amiloride-sensitive Na⁺ channel, named α, β, and γ, have previously been cloned in rat colon. The human lung α chain (SCNN1A) has also been cloned and its gene localized on chromosome 12p13. We now report the molecular cloning of the human lung β (SCNN1B) and γ (SCNN1G) chains. In situ hybridization and pulsed-field electrophoresis experiments demonstrate that both genes are located within a common 400-kb fragment on chromosome 16p12-p13. Screening of the cDNA library reveals two forms of the β subunit that differ by the presence or absence of a 464-bp fragment in the 3′ region. A frameshift in the short form modifies the COOH terminal sequence of the corresponding protein. Since several similar frameshifts mutations have recently been reported in patients affected by a rare form of hypertension, the existence of COOH truncated forms of the β chain might be of physiological importance.     

肝癌细胞系（HepG2）感染HCV RNA的研究

为建立丙型肝炎病毒（HCV）体外感染和细胞培养系统,用定量的HCV RNA阳性血清感染人肝癌细胞系（HepG2细胞系）,应用地高辛标记HCV RNA探针原位杂交技术和RT－PCR方法对感染后的细胞和上清液听 HCV RNA进行了检测。在感染后的第一代至第七代的细胞中出现特异性杂交阳性信号,第一代、第二代和第六代检测出HCV RNA正链,并在感染后第一、二代检测出HCV RNA负链。显示HCV不仅能在体外感染HepG2细胞系,而且在基因的复制,证明HepG2细胞能作为HCV的体外细胞培育系。     

Proteomic characterization of inter-alpha inhibitor proteins from human plasma

Inter-alpha inhibitor proteins (IaIp) are a family of structurally related serine protease inhibitors found in relatively high concentrations in human plasma. Recent studies have implicated a role for IaIp in sepsis, and have demonstrated their potential as biomarkers in sepsis and cancer. For characterization of isolated IaI proteins and contaminating proteins during the last steps of the purification process, SELDI-TOF MS and HPLC-ESI-MS/MS were used. After separation by SDS-PAGE or 2-DE, polypeptide bands of 80, 125 and 250 kDa were excised from gels and digested by trypsin. The tryptic peptides were analyzed by both MS methods. The main contamination during the purification process, a band of 80 kDa, contains mainly IaIp heavy chain (HC) H3. HC H1 and H2 were also found in this band. In addition, some vitamin K-dependent clotting factors and inhibitors and other plasma proteins were identified. The 125-kDa band, representing the pre-alpha inhibitor, was found to contain both bikunin and HC H3. The presence of other HC H1, H2 and the recently described HC H4 was also detected by SELDI-TOF MS. The presence of HC H1, H2, and H3 in the 125-kDa band was confirmed by ESI-MS/MS, but not the presence of the H4. Three polypeptides, H1 and H2 together with bikunin, were identified in the 250-kDa band, representing the ITI, by both MS techniques. Once again, the presence of H4 was detected in this band only by SELDI-TOF MS, but the number of corresponding peptides was still not sufficient for final identification of this polypeptide. The importance of the application of proteomic methods for the proper evaluation of therapeutic drugs based on human plasma is discussed.     

Assembly and secretion of fibrinogen. Degradation of individual chains.

Hep G2 cells produce surplus A alpha and gamma fibrinogen chains. These excess chains, which are not secreted, exist primarily as free gamma chains and as an A alpha-gamma complex. We have determined the intracellular location and the degradative fate of these polypeptides by treatment with endoglycosidase-H and by inhibiting lysosomal enzyme activity, using NH4Cl, chloroquine, and leupeptin. Free gamma chain and the gamma component of A alpha-gamma are both cleaved by endoglycosidase-H, indicating that the gamma chains accumulate in a pre-Golgi compartment. Lysosomal enzyme inhibitors did not affect the disappearance of free gamma chains but inhibited A alpha-gamma by 50%, suggesting that A alpha-gamma is degraded in lysosomes. The degradative fate of individual chains was determined in transfected COS cells which express but do not secrete single chains. Leupeptin did not affect B beta chain degradation, had very little affect on gamma chain, but markedly inhibited A alpha chain degradation. Antibody to immunoglobulin heavy chain-binding protein (GRP 78) co-immunoprecipitated B beta but not A alpha or gamma chains. Preferential binding of heavy chain-binding protein to B beta was also noted in Hep G2 cells and in chicken hepatocytes. Taken together these studies indicate that B beta and gamma chains are degraded in the endoplasmic reticulum, but only B beta is bound to BiP. By contrast A alpha chains and the A alpha-gamma complex undergo lysosomal degradation.     

The molecular organization of the protein HC-IgA complex (HC-IgA)

Complexes of protein HC and monoclonal IgA1 or IgA2 or polyclonal IgA were isolated from human blood plasma. Dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting showed that all complexes contain three types of chains: two light immunoglobulin chains, one regular IgA alpha-chain, and one chain with Mr = 90,000 carrying both alpha-chain and protein HC epitopes. The complexes were split into Fab alpha and Fc alpha fragments by bacterial IgA proteases. The protein HC epitopes were linked to the Fc fragments. Complexes of protein HC and an alpha-chain devoid of the variable region and the first heavy chain constant domain could also be demonstrated to be present in the blood plasma of a patient with alpha-heavy chain disease. Pepsin digestion of HC-IgA released a fragment containing all the protein HC epitopes and the C-terminal nonapeptide of the IgA alpha-chain. The light immunoglobulin chains, the regular alpha-chain, and the 90,000-Da chain from monoclonal HC-IgA1 were isolated by preparative dodecyl sulfate-polyacrylamide gel electrophoresis and by repeated gel filtration in dodecyl sulfate-containing buffer. The N-terminal amino acid sequence of the alpha-chain was identical with that of a regular human heavy immunoglobulin chain of subgroup III. Subtractive degradations of the 90,000-Da chain displayed 2 amino acid residues in each position in a pattern suggesting simultaneous degradations of a chain identical with the regular alpha-chain of HC-IgA and of uncomplexed, low molecular weight, protein HC. All the results are compatible with a model for HC-IgA in which a single low molecular weight protein HC polypeptide chain is covalently linked, side by side, to the C-terminal nonapeptide of one of the two alpha-chains of a regular monomeric IgA unit.     

Separation of four class II molecules from DR2 and DRw6 homozygous B lymphoid cell lines

Four human class 11 molecules, one FA, one DC1, and two DR-like molecules, were isolated from DR2 and DRw6 homozygous cell lines by means of a variety of monoclonal antibodies and were compared with each other by two-dimensional (2-D) gel electrophoresis. Anti-DR2 or anti-DR3 + 5 + w6 sera immunoprecipitated two distinct light chains (L1 and L2) and one heavy chain (H1) from a DR2 or DRw6 homozygous cell line, respectively. One or both of these two class II molecules were also immunoprecipitated by DR-specific monoclonal antibodies and were considered to constitute a DR family of molecules. Three DC1-specific monoclonal antibodies, SDR4.1, Tu22, and PLM5, immunoprecipitated a set of heavy (H2) and light (L3) chains distinct from those of two DR-like molecules. The heavy chains of the DC1 antigens from DR2 and DRw6 cell lines were indistinguishable, whereas the light chains were structurally distinct from each other. A fourth molecule, FA, was identified by a novel monoclonal antibody and was also detected by two additional antibodies, Tu39 and SG171, that blocked the SB-specific T-cell proliferative response. The FA light chain (L4) was distinct from those of the former three antigens on both cell lines, whereas the FA heavy chain was indistinguishable from the DC1 heavy chain (H2) in this 2-D gel analysis. Thus, four light chains and two heavy chains were isolated from both DR2 and DRw6 homozygous cell lines. A possible gene-antigen organization of the DC-like antigens was also discussed.     

Analysis of myosin light and heavy chain types in single human skeletal muscle fibers

In this study, myosin types in human skeletal muscle fibers were investigated with electrophoretic techniques. Single fibers were dissected out of lyophilized surgical biopsies and typed by staining for myofibrillar ATPase after preincubation in acid or alkaline buffers. After 14C-labelling of the fiber proteins in vitro by reductive methylation, the myosin light chain pattern was analysed on two-dimensional gels and the myosin heavy chains were investigated by one-dimensional peptide mapping. Surprisingly, human type I fibers, which contained only the slow heavy chain, were found to contain variable amounts of fast myosin light chains in addition to the two slow light chains LC1s and LC2s. The majority of the type I fibers in normal human muscle showed the pattern LC1s, LC2s and LC1f. Further evidence for the existence in human muscle of a hybrid myosin composed of a slow heavy chain with fast and slow light chains comes from the analysis of purified human myosin in the native state by pyrophosphate gel electrophoresis. With this method, a single band corresponding to slow myosin was obtained; this slow myosin had the light chain composition LC1s, LC2s and LC1f. Type IIA and IIB fibers, on the other hand, revealed identical light chain patterns consisting of only the fast light chains LC1f, LC2f and LC3f but were found to have different myosin havy chains. On the basis of the results presented, we suggest that the histochemical ATPase normally used for fibre typing is determined by the myosin heavy chain type (and not by the light chains). Thus, in normal human muscle a number of 'hybrid' myosins were found to occur, namely two extreme forms of fast myosins which have the same light chains but different heavy chains (IIA and IIB) and a continuum of slow forms consisting of the same heavy chain and slow light chains with a variable fast light chain composition. This is consistent with the different physiological roles these fibers are thought to have in muscle contraction.     

Factor X activator from Vipera lebetina venom is synthesized from different genes

Vipera lebetina venom contains specific coagulant Factor X activator (VLFXA) that cleaves the Arg52-Ile53 bond in the heavy chain of human factor X. VLFXA is a glycoprotein that is composed of a heavy chain (HC) and two light chains (LC) linked by disulfide bonds. The complete amino acid sequences of the three chains of the factor X activator from V. lebetina snake venom are deduced from the nucleotide sequences of cDNAs encoding these chains. The full-length cDNA (2347 bp) sequence of the HC encodes an open reading frame (ORF) of 612 amino acids that includes signal peptide, propeptide and mature metalloproteinase with disintegrin-like and cysteine-rich domains. The light chain LC1 contains 123 and LC2 135 amino acid residues. Both light chains belong to the class of C-type lectin-like proteins. The N-termini of VLFXA chains and inner sequences of peptide fragments detected by liquid chromatography-electrospray ionization tandem mass spectrometry (LC MS/MS) from protein sequence are 100% identical to the sequences deduced from the cDNA. The molecular masses of tryptic fragments of VLFXA chains analyzed by matrix-assisted laser desorption ionization time of flight mass spectrometry (MALDI-TOF MS) also confirm the protein sequences deduced from the cDNAs. These are the first cloned factor X activator heavy and light chains. We demonstrate that the heavy and light chains are synthesized from different genes.