Complete structure of the chicken alpha 2(VI) collagen gene

Type VI collagen is a hybrid molecule consisting of a short triple helix flanked by two large globular domains. These globular domains are composed of several homologous repeats which show a striking similarity to the collagen-binding motifs found in von Willebrand factor. The alpha 2(VI) subunit contains three of these homologous repeats termed D1, D2 and D3. We have isolated and characterized the entire gene for chicken alpha 2(VI) collagen. This gene, which is present as a single copy in the chicken genome, is 26 kbp long and comprises 28 exons. All exons can be classified in three groups. (a) The triple-helical domain is encoded by 19 short exons (27-90 bp) separated by introns of phase class 0. These exons are multiples of 9 bp and encode an integral number of collagenous Gly-Xaa-Yaa triplets. (b) The homologous repeats D1-D3 are encoded by one or two very long exons each (153-1578 bp). These exons are separated by introns of phase class 1. (c) The homologous repeats and the collagen sequence are linked to each other by three short adapter segments which are each encoded by a single exon (21-46 bp). The modular nature of the polypeptide is thus clearly reflected by the mosaic structure of its gene. The size of the exons and the phase class of the introns suggest that the alpha 2(VI) gene evolved by duplication and shuffling of two different primordial exons, one of 9 bp encoding a collagen Gly-Xaa-Yaa triplet and one of 600 bp encoding the precursor of the homologous repeats.     

Structure of the murine complement factor H gene

Factor H is a regulatory protein of the alternative pathway of complement activation comprised of 20 tandem repeating units of 60 amino acids each. A factor H cDNA clone was used to identify 17 genomic clones from a cosmid library. Four clones were selected for analysis of intron/exon junctions and 5' and 3' regions of the gene and for mapping of the exons. The factor H gene was found to be comprised of 22 exons. Each repeating unit is encoded by one exon, except the second repeat, which is coded by two exons; the leader sequence is encoded by a separate exon. The exons range in size from 77 to 210 base pairs (bp) and average 178 bp. They span a region of approximately 100 kilobases (kb) on chromosome 1. The leader sequence exon is 26 kb upstream of the first repeat exon, representing the largest intron. The other introns range in size from 86 bp to 12.9 kb, and the average intron size is 4.7 kb. Analysis of the genomic organization of the factor H gene has provided insight into the protein structure and will enable the construction of deletion mutants for functional studies.     

Structure and chromosome assignment of the murine p36 (calpactin I heavy chain) gene

p36 is a major substrate of both viral and growth factor receptor associated protein kinases. This protein has recently been named calpactin I heavy chain since it is the large subunit of a Ca2(+)-dependent phospholipid and actin binding heterotetramer. The primary structure of p36 has been determined from analysis of cloned cDNA. The protein contains 338 amino acids, has an approximate molecular weight of 39,000, and is comprised of several distinct domains, including four 75 amino acid repeats. From two overlapping cosmid clones isolated from different mouse genomic liver libraries, the complete intron/exon structure of the p36 gene was determined and the 5' and 3' noncoding regions of the gene were analyzed. The coding and 3' untranslated region of the p36 gene contains 12 exons which range in size from 48 to 322 base pairs (bp) with an average size of 107 bp. The repeat structures found at the protein level are not delineated by single exons, but the N-terminal p11-binding domain is encoded by a single exon. Structural mapping of the gene demonstrated that the lengths of the first two introns in the coding region are together approximately 6 kilobases (kb), while the other introns range in size from 600 to 3600 bp with an average size of 1650 bp. The p36 gene is at least 22 kb in length and has a coding sequence of approximately 1 kb, representing only 4.5% of the gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization of human cDNA clones encoding the alpha and the alpha' subunits of casein kinase II

Casein kinase II is a widely distributed protein serine/threonine kinase. The holoenzyme appears to be a tetramer, containing two alpha or alpha' subunits (or one of each) and two beta subunits. Complementary DNA clones encoding the subunits of casein kinase II were isolated from a human T-cell lambda gt10 library using cDNA clones isolated from Drosophila melanogaster [Saxena et al. (1987) Mol. Cell. Biol. 7, 3409-3417]. One of the human cDNA clones (hT4.1) was 2.2 kb long, including a coding region of 1176 bp preceded by 156 bp (5' untranslated region) and followed by 871 bp (3' untranslated region). The hT4.1 clone was nearly identical in size and sequence with a cDNA clone from HepG2 human hepatoma cultured cells [Meisner et al. (1989) Biochemistry 28, 4072-4076]. Another of the human T-cell cDNA clones (hT9.1) was 1.8 kb long, containing a coding region of 1053 bp preceded by 171 bp (5' untranslated region) and followed by 550 bp (3' untranslated region). Amino acid sequences deduced from these two cDNA clones were about 85% identical. Most of the difference between the two encoded polypeptides was in the carboxy-terminal region, but heterogeneity was distributed throughout the molecules. Partial amino acid sequence was determined in a mixture of alpha and alpha' subunits from bovine lung casein kinase II. The bovine sequences aligned with the 2 human cDNA-encoded polypeptides with only 2 discrepancies out of 535 amino acid positions. This confirmed that the two human T-cell cDNA clones encoded the alpha and alpha' subunits of casein kinase II. Microsequence data determined from separated preparations of bovine casein kinase II alpha subunit and alpha' subunit [Litchfield et al. (1990) J. Biol. Chem. 265, 7638-7644] confirmed that hT4.1 encoded the alpha subunit and hT9.1 encoded the alpha' subunit. These studies show that there are two distinct catalytic subunits for casein kinase II (alpha and alpha') and that the sequence of these subunits is largely conserved between the bovine and the human.     

Structural organization of the mouse lactoferrin gene.

The complete structure of the mouse lactoferrin gene is presented. Mouse lactoferrin (mLF) is encoded by a single copy gene of approximately 30 kilobases (kb) in size. The gene is organized into 17 exons separated by 16 introns. The exons range in size from 48 base pairs (bp) to 190 bp whereas the introns range from 0.2 kb to 4.3 kb. Structural analysis of the mouse lactoferrin gene reveals that this gene shares a similar intron-exon distribution pattern with both human transferrin and chicken ovotransferrin.     

Characterization of the subunits of beta-conglycinin

Four subunits of beta-conglycinin were purified from soybean cultivar CX 635-1-1-1, and were designated alpha, alpha', beta, and beta' in accordance with nomenclature proposed by Thanh and Shibasaki [(1977) Biochim. Biophys. Acta 490, 370-384]. Of these subunits, beta' has not previously been reported or characterized. Consistent with the low levels of methionine in these proteins, cyanogen bromide cleavage of alpha', alpha, and beta' subunits produced only a few fragments. The beta subunit contains no methionine and was not cleaved by cyanogen bromide. The NH2-terminal amino acid sequences of the alpha and alpha' subunits are homologous, and each has valine at its amino terminus. The beta subunit has a very different NH2-terminal sequence from those of the alpha and alpha' subunits, and has leucine at its amino terminus. The NH2-terminal sequence of the beta' subunit could not be determined, as it appeared to be blocked to Edman degradation. Although alpha and alpha' subunits have similar NH2-terminal sequences, they differ in the number of methionine residues and so yielded different numbers of cyanogen bromide fragments. Two cyanogen bromide fragments (CB-1 and CB-2) were purified from the alpha subunit. CB-1 originated from the NH2-terminal end of the subunit. The amino acid sequence of CB-2 was identical to that predicted from the nucleotide sequence of cDNA clone pB36. The insert in pB36 encoded 216 amino acids from the COOH-terminal end of the alpha subunit and contained a 138-bp trailer sequence which was followed by a poly-(A) tail. Maps showing the relative positions of methionine residues and carbohydrate moieties in the alpha and alpha' subunits were drawn, based on primary sequence data, and the size and carbohydrate content of the CNBr fragments derived from the subunits.     

Phylogeny of C4b-C3b cleaving activity: similar fragmentation patterns of human C4b and C3b produced by lower animals

Functional and structural studies of the activated proteins of the complement system C4b and C3b have led to the identification of cleavage products resulting from the effect of the regulatory proteins, factor I, H, and C4b binding protein (bp). In this paper we report the results of studies that investigated the capacity of plasma or serum from a wide range of phylogenetic species to yield similar cleavage products. Sera and plasma from mammals, reptiles, amphibia, and fishes are capable of cleaving fluid phase human C4b and C3b, generating apparently the same fragments as observed using normal human serum: alpha 2, alpha 3, alpha 4 from the alpha' chain of C4b: and alpha-68, alpha-46, alpha-43, and alpha-30 from the alpha' chain of C3b. When C3b bound to a cell membrane is used C3c and C3dg are generated. The generation of these fragments from C3bi is a dose-dependent reaction. There is no correlation between the evolution of the species and the quantitative capability to degrade the substrates. Birds possess only a limited capability to degrade the alpha' chain of C4b and have no cleaving activity for C3b, whereas sera from more primitive vertebrate species (chondrichthyes and agnatha) fail to participate in the reaction. Contrary to other species, the proteins in fish serum or plasma responsible for the degradation of C4b and C3b show a unique requirement for Ca2+ ions. Magnesium and barium are less effective, and in their presence a 65,000 dalton intermediate product is observed. These results demonstrate that protein(s) displaying proteolytic activity for products of complement activation, probably related to I, H, and C4bp, are present in plasma of species whose evolution have preceded humans by 300 million years. Moreover, the recognition of human substrates and the generation of fragments identical to those produced by human serum suggests that human C4b and C3b share structural characteristics with their evolutionary ancestors in the serum or plasma of the species studied.     

Identification of the C3b receptor-binding domain in third component of complement

We report here that complement receptor type one (CR1) binds to a region of C3b that is contained within the NH2 terminus of the alpha' chain. In an enzyme-linked immunosorbent assay, CR1 bound to C3b, iC3b, and C3c but not to C3d, and this binding was inhibited by soluble C3b and C3c. Further attempts to generate a small C3 fragment capable of binding CR1 were unsuccessful. However, elastase degradation of C3 generated four species of C3c (C3c I-IV), two of which bound CR1. NH2-terminal sequence analysis and sodium dodecyl sulfate-gel electrophoresis of the C3cs indicated that the beta chains and the 40,000-dalton COOH-terminal alpha' chain fragments were identical; the NH2-terminal alpha' chain fragments of C3c I-IV varied from 21,000 to 27,000 daltons and accounted for the differential binding to CR1. C3c-I and II, which do not bind CR1, were missing 8 and 9 residues from the NH2 terminus of the alpha' chain when compared with the intact alpha' chain of C3b. C3c-III and IV, which bind CR1, had NH2 termini identical to the intact NH2-terminal alpha' chain of C3b. Using iodinated concanavalin A and endoglycosidase H, we showed that the NH2-terminal alpha' chains of C3c-I and III were glycosylated, while C3c-II and IV were not. Therefore, these data indicated that the amino terminus of the NH2-terminal alpha' chain fragment of C3c was responsible for binding CR1 while the COOH terminus of this fragment was not involved since the presence or absence of this region in C3c did not affect CR1 binding to C3c. Subsequently, two peptides were synthesized from the NH2-terminal alpha' chain fragment of C3c: X42, 42 residues in length from the NH2 terminus and C30, 30 residues in length from the COOH terminus. X42 inhibited binding of CR1 to C3b, and this effect was also observed with antipeptide antibodies against the X42 peptide. The C30 and other C3-derived peptides and antipeptide antibodies had no effect on the binding of CR1 to C3b.     

Complementary DNA and derived amino acid sequence of the beta subunit of human complement protein C8: identification of a close structural and ancestral relationship to the alpha subunit and C9

A cDNA clone encoding the beta subunit (Mr 64,000) of the eighth component of complement (C8) has been isolated from a human liver cDNA library. This clone has a cDNA insert of 1.95 kilobases (kb) and contains the entire beta sequence [1608 base pairs (bp)]. Analysis of total cellular RNA isolated from the hepatoma cell line HepG2 revealed the mRNA for beta to be approximately 2.5 kb. This is similar to the message size for the alpha subunit of C8 and confirms the existence of different mRNAs for alpha and beta. This finding supports genetic evidence that alpha and beta are encoded at different loci. Analysis of the derived amino acid sequence revealed several membrane surface seeking segments that may facilitate beta interaction with target membranes during complement-mediated cytolysis. Determination of the carbohydrate composition indicated 1 or 2 asparagine-linked but no O-linked oligosaccharide chains. Comparison of the beta sequence to that reported for alpha in the preceding paper [Rao, A. G., Howard, O. M. Z., Ng, S. C., Whitehead, A. S., Colten, H. R. & Sodetz, J. M. (1987) Biochemistry (preceding paper in this issue)] and to that of human C9 revealed a striking homology between all three proteins. For beta and alpha, the overall homology is 33% on the basis of identity and 53% when conserved substitutions are allowed. For beta and C9, the values are 26% and 47%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Class II genes of the human major histocompatibility complex. Comparisons of the DQ and DX alpha and beta genes

The human major histocompatibility complex, HLA, contains the genes of several class II molecules. We present here the molecular maps of the DQ and DX subregions and analyze the sequences of the polymorphic DQ alpha and DQ beta genes as well as the DX alpha and DX beta genes. The DQ alpha and DQ beta genes are oriented in opposite directions, approximately 12 kilobases apart. The DX alpha and DX beta genes are similarly oriented about 8 kilobases. The exon-intron organizations of the DQ alpha and DX alpha genes are analogous to those of other class II alpha genes. Comparison of the DQ alpha gene sequence to three DQ alpha cDNA clones shows that amino acid replacements are predominantly located between residues 45 and 80 in the amino-terminal domain. Analysis of the frequency of silent and replacement substitutions indicates that there is little selection against replacements in DQ alpha first domains. The exons encoding the second domains of DQ alpha and DX alpha are virtually identical, suggesting that a gene conversion event has occurred between these genes. The DX beta gene is very similar to the DQ beta gene but differs in the cytoplasmic portion. The DX beta gene contains a separate exon of 24 nucleotides encoding the core of the cytoplasmic tail. This exon is not expressed in the DQ beta genes due to a nonfunctional splice junction. Comparison of the number of nucleotide substitutions in the DQ beta first and second domain exons suggests that little or no phenotypic selection acts on the first domain whereas the second domain is under strong selection.     

Nucleotide sequence of complementary DNA and derived amino acid sequence of murine complement protein C3

The nucleotide sequences coding for murine complement component C3 have been determined from a cloned genomic DNA fragment and several overlapping cloned complementary DNA fragments. The amino acid sequence of the protein was deduced. The mature beta and alpha subunits contain 642 and 993 amino acids respectively. Including a 24 amino acid signal peptide and four arginines in the beta-alpha transition region, which are probably not contained in the mature protein, the unglycosylated single chain precursor protein preproC3 would have a molecular mass of 186 484 Da and consist of 1663 amino acid residues. The C3 messenger RNA would be composed of a 56 +/- 2 nucleotide long 5' non-translated region, 4992 nucleotides of coding sequence, and a 3' non-translated region of 39 nucleotides, excluding the poly A tail. The beta chain contains only three cysteine residues, the alpha chain 24, ten of which are clustered in the carboxy terminal stretch of 175 amino acids. Two potential carbohydrate attachment sites are predicted for the alpha chain, none for the beta chain. From a comparison with human C3 cDNA sequence (of which over 80% has been determined) an extensive overall sequence homology was observed. Human and murine preproC3 would be of very similar length and share several noteworthy properties: the same order of the subunits in the precursor, the same basic residue multiplet in the beta-alpha transition region, and a glutamine residue in the thioester region. The equivalent position of the known factor I cleavage sites in human C3 alpha could be located in the murine C3 alpha chain and the size and sequence of the resulting peptide were deduced. A comparison of the amino acid sequences of murine C3 and human alpha 2-macroglobulin is given. Several areas of strong sequence homology are observed, and we conclude that the two genes must have evolved from a common ancestor.     

Structure and evolution of the human prosaposin chromosomal gene.

The gene for prosaposin was characterized by sequence analysis of chromosomal DNA to gain insight into the evolution of this locus that encodes four highly conserved sphingolipid activator proteins or saposins. The 13 exons ranged in size from 57 to 1200 bp, while the introns were from 91 to 3812 bp in length. The regions encoding saposins A, B, and D each had three exons, while that for saposin C had only two. This sequence included the regions that encode the carboxy terminus of the signal peptide, the four mature prosaposin proteins, and the 3' untranslated region. Primer extension studies indicated that over 99% of the coding sequence was contained in these 19,985 bp. Use of PCR and reverse PCR techniques indicated that the most 5' coding approximately 140 bp contained large introns and at least two small exons. Analyses of the intronic positions in the saposin regions indicated that this gene evolved from an ancestral gene by two duplication events and at least one gene rearrangement involving a double crossover after introns had been inserted into the gene.     

The exon organization of the triple-helical coding regions of the human alpha 1(VI) and alpha 2(VI) collagen genes is highly similar.

The alpha 1(VI) and alpha 2(VI) chains, two of the three constituent chains of type VI collagen, are highly similar in size and domain structure. They are encoded by single-copy genes residing in close proximity on human chromosome 21. To study the evolution of the type VI collagen genes, we have isolated and characterized genomic clones coding for the triple-helical domains of the human alpha 1(VI) and alpha 2(VI) chains, which consist of 336 and 335 amino acid residues, respectively. Nucleotide sequencing indicates that, in both genes, the exons are multiples of 9 bp in length (including 27, 36, 45, 54, 63, and 90 bp) except for those encoding for regions with triple-helical interruptions. In addition, the introns are positioned between complete codons. The most predominant exon size is 63 bp, instead of 54 bp as seen in the fibrillar collagen genes. Of particular interest is the finding that the exon structures of the alpha 1(VI) and alpha 2(VI) genes are almost identical. A significant deviation is that a segment of 30 amino acid residues is encoded by two exons of 54 and 36 bp in the alpha 1(VI) gene, but by a single exon of 90 bp in the alpha 2(VI) gene. The exon arrangement therefore provides further evidence that the two genes have evolved from tandem gene duplication. Furthermore, comparison with the previously reported gene structure of the chick alpha 2(VI) chain indicates that the exon structure for the triple-helical domain of the alpha 2(VI) collagen is strictly conserved between human and chicken.