Structural basis for the C4d.1/C4d.2 serologic allotypes of murine complement component C4

The C4d.1 antigenic specificity was first defined serologically in 1959 as an H-2-associated cellular alloantigen first designated "G," later H-2.7. It was subsequently shown to be an allotype of component C4 of the C system, with the antigenic determinant carried on the C4d proteolytic fragment of the alpha-chain, thus the designation C4d.1. Alloantisera defining an antithetical Ag, C4d.2, were also prepared. Previous studies in our laboratory showed that the structural difference between the two specificities resides in a single tryptic peptide of C4d. As an efficient approach to definition of the amino acid difference(s) involved, genomic clones covering the C4d regions from two H-2 haplotypes of the C4d.1 type have been prepared and sequenced, and compared with two sequences already available for C4d.2-type molecules. The results indicate that the rather striking serologic difference between C4d.1 and C4d.2 is attributable to the single amino acid substitution of arginine in C4d.2 for glutamine in C4d.1. The substituted residue is in a highly hydrophilic region of the C4 molecule, at a position homologous to one that contributes to the Chido/Rodgers serologic difference of human C4 molecules. This substitution also determines a new Pst I site in C4d.1 strains. A HindIII restriction fragment length polymorphism between C4d.1 and C4d.2 has also been observed.     

A single arginine to tryptophan interchange at beta-chain residue 458 of human complement component C4 accounts for the defect in classical pathway C5 convertase activity of allotype C4A6. Implications for the location of a C5 binding site in C4.

In general, C4A allotypes of human C4 show one-fourth to one-third the hemolytic activity of C4B allotypes. An exception to this rule is C4A6 which is almost totally deficient in hemolytic activity. Previous studies have localized the defect in C4A6 to the C5 convertase stage. Of the two critical events required for C5 cleavage, namely formation of a covalent adduct between C3b and the C4b subunit of the C3 convertase (C4b2a), and binding of C5 to this C4b-C3b complex, it is a defect in the latter step that accounts for the aberrant activity of C4A6. DNA sequencing studies described in a companion paper have suggested that the sole C4A6-specific difference was a Trp for Arg replacement at beta-chain residue 458. To directly ascertain whether this single substitution was responsible for the hemolytic defect in C4A6, we have used site-directed mutagenesis to introduce this change into both C4A and C4B cDNA expression plasmids. We found that the R to W replacement totally abrogated hemolytic activity. However, irrespective of the amino acid at residue 458, the mutant proteins behaved like their wild-type counterparts with respect to covalent binding to C1-bearing targets, i.e., the C4B recombinants displayed higher binding to sheep and human red cells than did the C4A counterparts. Furthermore, the mutants were able to form covalent C4b-C3b adducts. There was, however, substantially less C5 cleavage produced by cell-bound C4boxy23b complexes made with R458W mutant C4B than with wild-type C4B. These results are consistent with the sole defect in the mutants being at the C5 binding stage and strongly suggest that Arg 458 of the C4 beta-chain contributes to the C5 binding site of the molecule.     

The coding sequence of the hemolytically inactive C4A6 allotype of human complement component C4 reveals that a single arginine to tryptophan substitution at beta-chain residue 458 is the likely cause of the defect.

The C4A6 allotype of the human complement component C4 is known to be defective in C5 binding within the C5 convertase. To characterize the position and nature of the molecular defect in the C4A6 allotype we have isolated the C4A6 gene from a cosmid genomic DNA library. Direct sequencing of a 4.4-kb region of the gene covering exons 17 to 31 and encoding the C4d fragment and most of the rest of the alpha chain of C4 revealed that the C4A6 allele encodes the A isotypic residues Pro Cys-Leu Asp at positions 1101, 1102, 1105, and 1106 and the same residues as the C4A3 alpha gene at the polymorphic positions 1054 (Asp), 1157 (Asn), 1182 (Thr), 1188 (Val), 1191 (Leu) and 1267 (Ala). In addition the C4A6 allele was shown to encode a Pro at the previously characterized polymorphic position 707 in the C4a peptide where the C4A3 alpha allele encodes a Leu. The remaining 26 exons of the C4A6 gene were analyzed by detecting nucleotide mismatches in C4A6/C4A3 and C4A6/C4B1 DNA heteroduplexes using the chemical cleavage of mismatch technique. The regions around detected mismatches were sequenced. In total seven nucleotide differences were defined on comparison of the C4A6 and other C4 sequences, of which three were present in exons. Two of these resulted in amino acid changes. One of the amino acid differences is a known polymorphism in C4, a Tyr/Ser substitution at position 328 in the beta-chain. The second amino acid difference caused by a C to T transition in the first base of the codon for amino acid residue 458 was the only one shown to be specific to the C4A6 allotype. The C4A6 allotype contains a Trp residue at this position in the beta-chain instead of the Arg residue found in all other C4A and C4B allotypes so far characterized. We propose that this Arg to Trp substitution at beta-chain residue 458 is responsible for the inability of C4A6 to bind C5 in the C5 convertase.     

Structural basis of the polymorphism of human complement components C4A and C4B: gene size, reactivity and antigenicity.

The human complement components C4A and C4B are highly homologous proteins, but they show markedly different, class-specific, chemical reactivities. They also differ serologically in that C4A generally expresses the Rodgers (Rg) blood group antigens while C4B generally expresses the Chido (Ch) blood group antigens. C4A 1 and C4B 5 are exceptional variants which possess their class-specific chemical reactivities, but express essentially the reversed antigenicities. The genes encoding the typical Rg-positive C4A 3a and Ch-positive C4B 3 allotypes and the interesting variants C4A 1 and C4B 5 have been cloned. Characterization of the cloned DNA has revealed that the genes encoding the A 3a, A 1 and B 3 allotypes are 22 kb long, but that encoding B 5 is only 16 kb long. Comparison of derived amino acid sequences of the polymorphic C4d fragment has shown that C4A and C4B can be defined by only four isotypic amino acid differences at position 1101-1106. Over this region C4A has the sequence PCPVLD while C4B has the sequence LSPVIH, and this presumably is the cause of their different chemical reactivities. Moreover, the probable locations of the two Rg and the six Ch antigenic determinants have been deduced. Our structural data on the C4A and C4B polymorphism pattern suggests a gene conversion-like mechanism is operating in mixing the generally discrete serological phenotypes between C4A and C4B.     

The low C5 convertase activity of the C4A6 allotype of human complement component C4.

We have compared the C5-convertase-forming ability of different C4 allotypes, including the C4A6 allotype, which has low haemolytic activity and which has previously been shown to be defective in C5-convertase formation. Recent studies suggest that C4 plays two roles in the formation of the C5 convertase from the C3 convertase. Firstly, C4b acts as the binding site for C3 which, upon cleavage by C2, forms a covalent linkage with the C4b. Secondly, C4b with covalently attached C3b serves to form a high-affinity binding site for C5. Purified allotypes C4A3, C4B1 and C4A6 were used to compare these two activities of C4. Covalently linked C4b-C3b complexes were formed on sheep erythrocytes with similar efficiency by using C4A3 and C4B1, indicating that the two isotypes behave similarly as acceptors for covalent attachment of C3b. C4A6 showed normal efficiency in this function. However, cells bearing C4b-C3b complexes made from C4A6 contained only a small number of high-affinity binding sites for C5. Therefore a lack of binding of C5 to the C4b C3b complexes is the reason for the inefficient formation of C5 convertase by C4A6. The small number of high-affinity binding sites created, when C4A6 was used, were tested for inhibition by anti-C3 and anti-C4. Anti-C4 did not inhibit C5 binding, whereas anti-C3 did. This suggests that the sites created when C4A6 is used to make C3 convertase may be C3b-C3b dimers, and hence the low haemolytic activity of C4A6 results from the creation of low numbers of alternative-pathway C5-convertase sites.     

C4B3 allotype with a novel Ch phenotype

The fourth component of complement (C4) has two classes of protein, C4A and C4B, both of which have many allelic forms. The serological determinants Rodgers (Rg1, Rg2) and Chido (Ch1, Ch2, Ch3) are generally associated with C4A and C4B, respectively. The C4B3 allotype has been detected in a single Canadian family that expresses a novel Ch phenotype, Ch:–1, 2, –3. There was no information for the Rg determinants, as the C4A ^* 2B ^* 3 haplotype would normally express Rg on the C4A protein. Other C4B3 allotypes in informative families have different Ch phenotypes, and the relationships of these within extended major histocompatibility complex haplotypes are discussed in this paper.     

Secretion of a lambda 2 immunoglobulin chain is prevented by a single amino acid substitution in its variable region

We have studied two derivatives of the IgA (lambda 2) secreting myeloma cell line MOPC315:MOPC315.26, which produces and secretes a lambda 2 light chain, and MOPC315.37, which produces but does not secrete the lambda 2 chain. It has been reported that the only alteration in the MOPC315-37 lambda 2 chain is located in the variable region (Mosmann and Williamson, (1980) Cell 20, 283-292). In order to determine the nature of this alteration, we cloned the fragment of the chromosome containing the rearranged lambda 2 gene from both the nonsecreting variant MOPC315-37 and the normal lambda 2-secreting parent MOPC315-26 and determined their nucleotide sequence. We found that the nucleotide sequences coding for the leader peptide and for the constant region of the lambda 2 chain were identical in the secretor and nonsecretor. The sequences of the variable region differed at a single base pair corresponding to the first nucleotide in the codon for amino acid number 15. MOPC315-26 has a G in this position creating the codon GGT which codes for glycine, and MOPC315-37 has a C in this position creating the codon CGT which codes for arginine. Thus, we have demonstrated that a single amino acid substitution of a neutral amino acid, glycine, for a positively charged amino acid, arginine, results in the failure of a protein to be secreted.     

The origin of the very variable haemolytic activities of the common human complement component C4 allotypes including C4-A6.

The human complement component C4 occurs in many different forms which show big differences in their haemolytic activities. This phenomenon seems likely to be of considerable importance both physiologically and pathologically. C4 is coded by duplicated genes between HLA-D and HLA-B loci in the major histocompatibility complex in man. Several fold differences in haemolytic activity between products of the two loci C4-A and C4-B have been correlated with changes of six amino acid residues in this large protein of 1722 residues and with differences of several fold in the covalent binding of C4 to antibody-antigen aggregates. Some allotypes of one locus also differ markedly, notably C4-A6 which has 1/10th the haemolytic activity of other C4-A allotypes. A monoclonal antibody affinity column has been prepared which is able to separate C4-A from C4-B proteins and, using serum from an individual expressing only the C4-A6 allele at the C4-A locus, C4-A6 protein has been prepared. Investigation has shown C4-A6 to have the same reactivity as other C4-A allotypes except in the formation of the complex protease, C5 convertase. This protease is formed from C4, C2 and C3 and if C4-A6 is used it has approximately 1/5th the catalytic activity compared with other C4-A allotype. Allelic differences in sequence identified in C4 proteins so far are few and it is probable that the big difference in catalytic activity of C5 convertase is caused by very small changes in structure.     

Preparation of an alloantiserum to murine C3 and demonstration of multiple alleles.

An antiserum was produced in C3H/He mice that can recognize the antigenic variations of murine C3. The alloantiserum is directed to the gene product of one of the alleles (C3-1a allele) of the C3-1 locus that controls genetic variations of murine C3 and is linked to H-2. The antiserum formed a single precipitin line in the Ouchterlony test with sera obtained from mice that carry the C3-1a/a or C3-1a/b genotype, but it did not react with sera from mice that do not have C3 coded for by the C3-1a allele. By the use of the alloantiserum, we detected a new C3 allotype (C3-1 CC) in SWR/J mice. The C3-1 CC is distinct from the other two allotypes on the basis of antigenicity and isoelectric point (pI). Therefore, at least three alleles have been identified for the C3-1 locus.     

Response of a wild type and a non-nitrogen-fixing mutant of Anabaena doliolum towards different amino acids

The effects of various amino acids on growth and heterocyst differentiation have been studied on wild type and a heterocystous, non-nitrogen-fixing (het+ nif-) mutant of Anabaena doliolum. Glutamine, arginine and asparagine showed maximum stimulation of growth. Serine, proline and alanine elicited slight stimulation of growth of wild type but failed to show any stimulatory effect on mutant strain. Valine, glutamic acid, iso-leucine and leucine at a concentration of as low as 0.1 mM were inhibitory to growth of parent type. Methionine, aspartic acid, threonine, cysteine, and tryptophan did not affect growth at concentrations lower than 0.5 mM. But at 1 mM, these amino acids were inhibitory. In addition to the stimulatory effects of glutamine, arginine and asparagine, the heterocyst frequency was also repressed by these amino acids. Glutamine and arginine at 2 mM completely repressed heterocyst differentiation in the mutant strain; however, other amino acids failed to repress the differentiation of heterocysts. Our results suggest that glutamine and arginine are utilized as nitrogen sources. This is strongly supported from the data of growth and heterocyst differentiation of mutant strain, where at least with glutamine there is good growth without heterocyst formation. Studies with glutamine and arginine on other N2-fixing blue-green algae may reveal the regulation of the heterocyst-nitrogenase sub-system.     

Nitrogen nutrition in the cyanobacterium Nostoc ANTH, a symbiotic isolate from Anthoceros: uptake and assimilation of inorganic-n and amino acids

Amino acid uptake and utilization of various nitrogen sources (amino acids, nitrite, nitrate and ammonia) were studied in Nostoc ANTH and i ts mu tant (Het(-)Nif(-)) isolate defective in heterocyst formation and N2-fixation. Both parent and its mutant grew at the expense of glutamine, asparagine and arginine as a source of fixed-nitrogen. Growth was better in glutamine-and asparagine-media as compared to that in arginine media. Glutamine and asparagine repressed heterocyst formation, N2-fixation and nitrate reduction in Nostoc ANTH, but arginine did so only partially. The poor growth in arginine-medium was not due to poor uptake rates, since the uptake rates were not significantly different from those for glutamine or asparagine. The glutamine synthetase activity remained unaffected during cultivation in media containing any one of the three amino acids tested. The uptake of amino acids was substrate-inducible, energy-dependent and required de novo protein synthesis. Nitrate and ammonium repressed ammonium uptake, but did not repress uptake of amino acids. In N2-medium (BG-11(0)), the uptake of ammonium and amino acids in the mutant was significantly higher than its parent strain. This was apparently due to nitrogen limitation since the mutant was unable to fix N2 and the growth medium lacked combined-N.     

Partial amino acid sequence in the N-terminal region of an anti-pneumococcal immunoglobulin heavy chain of allotype a2 (Short Communication)

The amino acid sequence of the N-terminal 48 residues of the heavy chain derived from a homogeneous rabbit antibody to type III pneumococci is described. This chain of allotype a(2) is compared with other rabbit heavy chains of allotypes a(1), a(2) and a(3). Within the N-terminal 25 positions, two chains which carry the same allotype a(2) possess identical amino acid sequences, but differ markedly from heavy chains of allotypes a(1) and a(3). Sequence variability is observed in residues 26-27 and 30-34, but not in residues 35-48.     

Genetic determinants of dengue type 4 virus neurovirulence for mice.

Mouse-adapted dengue type 4 virus (DEN4) strain H241 is highly neurovirulent for mice, whereas its non-mouse-adapted parent is rarely neurovirulent. The genetic basis for the neurovirulence of the mouse-adapted mutant was studied by comparing intratypic chimeric viruses that contained the three structural protein genes from the parental virus or the neurovirulent mutant in the background sequence of nonneurovirulent DEN4 strain 814669. The chimera that contained the three structural protein genes from mouse neurovirulent DEN4 strain H241 proved to be highly neurovirulent in mice, whereas the chimera that contained the corresponding genes from its non-mouse-adapted parent was not neurovirulent. This finding indicates that most of the genetic loci for the neurovirulence of the DEN4 mutant lie within the structural protein genes. A comparison of the amino acid sequences of the parent and its mouse neurovirulent mutant proteins revealed that there were only five amino acid differences in the structural protein region, and three of these were located in the envelope (E) glycoprotein. Analysis of chimeras which contained one or two of the variant amino acids of the mutant E sequence substituting for the corresponding sequence of the parental virus identified two of these amino acid changes as important determinants of mouse neurovirulence. First, the single substitution of Ile for Thr-155 which ablated one of the two conserved glycosylation sites in parental E yielded a virus that was almost as neurovirulent as the mouse-adapted mutant. Thus, the loss of an E glycosylation site appears to play a role in DEN4 neurovirulence. Second, the substitution of Leu for Phe-401 also yielded a neurovirulent virus, but it was less neurovirulent than the glycosylation mutant. These findings indicate that at least two of the genetic loci responsible for DEN4 mouse neurovirulence map within the structural protein genes.     

Human complement component C4. Structural studies on the fragments derived from C4b by cleavage with C3b inactivator.

1. One of the activation products of C4, C4b, was prepared, and the reactive thiol group on the alpha'-chain was radioactively labelled with iodo[2-14C]acetic acid. The alpha'-chain was isolated and the N-terminal amino acid sequence of the first 13 residues was determined. 2. C4b was cleaved by C3bINA in the presence of C4b-binding protein and C4d and C4c isolated. The radioactive label and therefore the reactive thiol group were located to C4d. 3. C4c was reduced and alkylated and the two alpha'-chain fragments of C4c were separated. 3. The molecular weights, amino acid analyses and carbohydrate content of the three alpha'-chain fragments were determined. C4d has a mol.wt. of 44500 and a carbohydrate content of 6%. The two alpha'-chain fragments of C4c have mol.wts. of 25000 (alpha 3) and 12000 (alpha 4) and carbohydrate contents of 10 and 22% respectively. 4. The N-terminal amino acid sequences of C4d, the alpha 3 and the alpha 4 fragments were determined for 18, 24 and 11 residues respectively and, by comparison with the N-terminal sequence of the C4b alpha'-chain, the 25000-mol.wt. fragment (alpha 3) was shown to be derived from the N-terminal part of the alpha'-chain. 5. C-Terminal analyses were done on the alpha'-chain and its three fragments. Arginine was found to be the C-terminal residue of C4d and of the alpha 3 fragment. The C-terminal residue of the alpha'-chain and of the alpha 4 fragment could not be identified. The order of the three fragments of the alpha'-chain is therefore: alpha 3(25000)--C4d(44500)--alpha 4(12000). The specificity of C3bINA is for an Arg--Xaa peptide bond.     

Arginine catabolism in the cyanobacterium Synechocystis sp. Strain PCC 6803 involves the urea cycle and arginase pathway

Cells of the unicellular cyanobacterium Synechocystis sp. strain PCC 6803 supplemented with micromolar concentrations of L-[(14)C]arginine took up, concentrated, and catabolized this amino acid. Metabolism of L-[(14)C]arginine generated a set of labeled amino acids that included argininosuccinate, citrulline, glutamate, glutamine, ornithine, and proline. Production of [(14)C]ornithine preceded that of [(14)C]citrulline, and the patterns of labeled amino acids were similar in cells incubated with L-[(14)C]ornithine, suggesting that the reaction of arginase, rendering ornithine and urea, is the main initial step in arginine catabolism. Ornithine followed two metabolic pathways: (i) conversion into citrulline, catalyzed by ornithine carbamoyltransferase, and then, with incorporation of aspartate, conversion into argininosuccinate, in a sort of urea cycle, and (ii) a sort of arginase pathway rendering glutamate (and glutamine) via Delta(1)pyrroline-5-carboxylate and proline. Consistently with the proposed metabolic scheme (i) an argF (ornithine carbamoyltransferase) insertional mutant was impaired in the production of [(14)C]citrulline from [(14)C]arginine; (ii) a proC (Delta(1)pyrroline-5-carboxylate reductase) insertional mutant was impaired in the production of [(14)C]proline, [(14)C]glutamate, and [(14)C]glutamine from [(14)C]arginine or [(14)C]ornithine; and (iii) a putA (proline oxidase) insertional mutant did not produce [(14)C]glutamate from L-[(14)C]arginine, L-[(14)C]ornithine, or L-[(14)C]proline. Mutation of two open reading frames (sll0228 and sll1077) putatively encoding proteins homologous to arginase indicated, however, that none of these proteins was responsible for the arginase activity detected in this cyanobacterium, and mutation of argD (N-acetylornithine aminotransferase) suggested that this transaminase is not important in the production of Delta(1)pyrroline-5-carboxylate from ornithine. The metabolic pathways proposed to explain [(14)C]arginine catabolism also provide a rationale for understanding how nitrogen is made available to the cell after mobilization of cyanophycin [multi-L-arginyl-poly(L-aspartic acid)], a reserve material unique to cyanobacteria.     

Structure and activity of C1r and C1s

During activation of the first component of the classical complement pathway the two zymogen subcomponents, C1r and C1s are converted to active proteolytic enzymes. Activated C1r cleaves C1s which then becomes the activator of C4 and C2. Amino acid sequence studies of the proteolytic chains of C1r and C1s, carried out in Oxford and Aberdeen respectively, have shown that they belong to the serine proteinase family. Modelling of these sequences to the three-dimensional coordinates of chymotrypsin (Birktoft & Blow 1972) reveals that both molecules have a conserved structural core, and that most of the differences lie in the external loops. Catalytically functional residues (Ile-16, His-57, Asp-102, Ser-195) are conserved, and residue 189 is aspartic acid, consistent with the known trypsin-like specificity of cleavage. Examination of the amino acid sequences of C4a, and comparison with those of the homologous molecules C3a and C5a, shows that there is a marked difference in the distribution of basic residues near the C-terminal arginine residue which is the site of action of C1s. When these amino acid sequences are modelled to the coordinates of C3a (Huber et al. 1980) and docked to the active site of C1s, the basic residues of C4a appear to interact with two glutamate residues peculiar to C1s, suggesting that this interaction may contribute to the ability of C1s to discriminate C4 from C3 and C5.     

Neurospora crassa mutant impaired in glutamine regulation.

The final products of the catabolism of arginine that can be utilized as nitrogen sources by Neurospora crassa are ammonium, glutamic acid, and glutamine. Of these compounds, only glutamine represses arginase and glutamine synthetase. We report here the isolation and characterization of a mutant of N. crassa whose arginase, glutamine synthetase, and amino acid accumulations are resistant to glutamine repression (glnI). This mutant has a greater capacity than the wild type (glns) to accumulate most of the arginine and some of the glutamine in osmotically sensitive compartments while growing exponentially. Nonetheless, the major part of the glutamine remains soluble and metabolically available for repression. We propose that the lower repression of glutamine synthetase by glutamine in this mutant could be a necessary condition for sustaining the higher flow of nitrogen for the accumulation of amino acids observed in ammonium excess and that, if glutamine is the nitrogen signal that regulates the arginine accumulation of the vesicle, the glnr mutant has also escaped this control. Finally, in the glnr mutant, some glutamine resynthesis is necessary for arginine biosynthesis and accumulation.     

Polymorphism of human complement component C4

An assessment has been made of the polymorphism of human complement component C4 by comparing derived amino acid sequences of cDNA and genomic DNA with limited amino acid sequences. In all, one complete and six partial sequences have been obtained from material from three individuals and include two C4A and two C4B alleles. Differences were found between the 4 alleles from 2 loci in only 15 of the 1722 amino acid residues, and 12 lie within one section of 230 residues, which in 1 allele also contains a 3-residue deletion. In three variable positions, an allelic difference in one C4 type was common to the other types. Three nucleotide differences were found in four introns. In spite of marked differences in their chemical reactivity, the many allelic forms appear to differ in less than 1% of their amino acid residue positions. This unusual pattern of polymorphism may be due to recent duplication of the C4 gene, or may have arisen by selection as a result of the biological role of C4, which interacts in the complement sequence with nine other proteins necessitating conservation of much of the surface structure.     

Metabolism of Proline, Glutamate, and Ornithine in Proline Mutant Root Tips of Zea mays (L.)

In excised pro_1-1 mutant and corresponding normal type roots of Zea mays L. the uptake and interconversion of [¹⁴C]proline, [¹⁴C]glutamic acid, [¹⁴C]glutamine, and [¹⁴C]ornithine and their utilization for protein synthesis was measured with the intention of finding an explanation for the proline requirement of the mutant. Uptake of these four amino acids, with the exception of proline, was the same in mutant and normal roots, but utilization differed. Higher than normal utilization rates for proline and glutamic acid were noted in mutant roots leading to increased CO₂ production, free amino acid interconversion, and protein synthesis. Proline was synthesized from either glutamic acid (or glutamine) or ornithine in both mutant and normal roots; it did not accumulate but rather was used for protein synthesis. Ornithine was not a good precursor for proline in either system, but was preferentially converted to arginine and glutamine, particularly in mutant roots. The pro_1-1 mutant was thus not deficient in its ability to make proline. Based on these findings, and on the fact that ornithine, arginine, glutamic acid and aspartic acid are elevated as free amino acids in mutant roots, it is suggested that in the pro_1-1 mutant proline catabolism prevails over proline synthesis.