Recombination of two homologous MHC class III genes of the mouse (C4 and Slp) that accounts for the loss of testosterone dependence of sex-limited protein expression

In most mouse strains, expression of a gene encoding sex-limited protein (Slp), an isotype of the fourth component of complement (C4), is induced by testosterone, or the gene is not expressed at all; however, in some wild-derived strains carrying H-2w7, H-2w16, or H-2w19 haplotype, Slp is expressed constitutively in the same way as C4. To examine the structural basis for the testosterone-independent expression of Slp, 41 overlapping clones together encoding the S region were isolated from C3H.W7 mouse (H-2w7) cosmid library. Five C4-related genes each spanning approximately 16 kb were identified among the cluster of cosmid clones and were isolated for structural study. One of the genes (C4w7) hybridized with the C4-specific oligonucleotide probe but not with the Slp-specific oligonucleotide probe, whereas the other genes (Slpw7a, Slpw7b, Slpw7c, and Slpw7d) hybridized only with the Slp-specific probe. Restriction mapping of these genes and sequencing of the selected regions of 5'-flanking regions of the genes were performed, and the results were compared with the data obtained with the C4 and Slp genes of FM (H-2d) and B10.BR (H-2k). These studies showed that three of the C4-related genes of C3H.W7 (Slpw7b, Slpw7c, and Slpw7d) are C4-Slp recombinant genes comprising a 5'-region derived from C4 gene and a 3'-region derived from Slp gene. It is suggested that 5'-flanking region derived from C4 in these C4-Slp recombinant genes accounts for testosterone-independent expression of Slp in C3H.W7 mouse.     

Murine sex-limited protein: complete cDNA sequence and comparison with murine fourth complement component

Murine sex-limited protein (Slp) is a structural homologue of the murine fourth complement component (C4) that lacks C4 activity and has no known function. The genes for C4 and Slp lie closely linked in the S region of the murine major histocompatibility complex. We have sequenced a cDNA clone that spans the entire protein-coding region of Slp from the mouse strain B10.WR. The sequence contains a 1735 amino acid-long open reading frame encoding a putative prepro-Slp flanked by 51 and 103 untranslated nucleotides at the 5' and 3' ends respectively; it shows 96% nucleotide and 94% amino acid identity with our previously reported complete sequence of murine C4 from the same mouse strain. The present complete Slp sequence differs slightly from our previously reported partial sequence from the same mouse strain; this suggests that at least two distinct Slp genes are transcribed in B10.WR mice. We suggest, by analogy with procaryotic DNA-binding proteins, that a three amino acid deletion in Slp, close to the Cls cleavage site, makes that site resistant to proteolysis; this renders Slp inactive. We also speculate on the possibility that Slp might be a gene in evolutionary transition; one that is midway in the evolution of a completely silent pseudogene or a new gene with a novel function.     

Constitutive expression of Slp genes in mouse strain B10.WR directed by C4 regulatory sequences

The murine fourth component of complement (C4) and sex-limited protein (Slp) are two closely related serum proteins that exhibit very disparate patterns of gene expression: all mice constitutively express C4, whereas only adult male mice from a limited number of standard inbred strains express Slp. Several exceptional strains exhibit constitutive (C4-like) Slp expression, a phenotype that correlates with multiple copies of the Slp gene. To determine the molecular basis for constitutive Slp expression we have isolated genomic clones and compared the sequences of 1.5 kb of 5' flanking DNA from 1 C4 gene and three different Slp genes from the Slp-constitutive strain B10.WR. These sequence comparisons demonstrate C4-like regulatory sequences adjacent to two of the Slp genes. By analysis of cDNA clones isolated from a B10.WR liver library we demonstrate that the constitutive Slp phenotype is due primarily to expression of one of these C4/Slp hybrid genes. It appears likely that Slp gene duplication in strain B10.WR came about via homologous unequal crossover events between C4 and Slp genes; this would accommodate both the gene sequence data and the pattern of C4-like Slp expression in mouse strain B10.WR.     

Mice constitutive for sex-limited protein (SLP) expression contain multiple Slp gene sequences

The murine fourth component of complement (C4) and sex-limited protein (Slp) are two closely related serum proteins whose structural genes map to the S region of H-2. Serum C4 levels vary as much as 20-fold between C4 high (C4H) and C4 low (C4L) strains, and Slp expression can be null (SlpO), limited to male mice of a subset of C4H strains (Slp+), or "constitutive" (SlpC), in which female as well as male mice express Slp. In this study, we compare, by genomic Southern blot analysis, the C4 and Slp genes from eight congenic inbred mouse strains representative of three distinct phenotypes: C4H, Slp+ (two strains), C4H, SlpO (two strains), C4H, SlpC (three strains), and C4L, SlpO (one strain). By using cDNA probes that recognize both C4 and Slp genes, and are derived from the extreme 5' and 3' ends of the mRNA as well as internal coding sequences, we find no evidence to suggest that strain-specific variations in the expression of C4 and Slp are due to gross deletions of major portions of the structural genes. In most cases, two distinct C4/Slp genes are detected; hybridization with C4- and Slp-specific probes indicate that one of these is C4 and the other is Slp. The three SlpC strains are exceptional: they carry at least four C4/Slp genes; one of these hybridizes to the C4-specific probe whereas the remaining genes hybridize to the Slp-specific probe. Hence, multiple duplication of a gene containing Slp sequences has occurred in certain strains of mice, and this is accompanied by constitutive expression of the Slp protein.     

The murine Slp gene. Additional evidence that sex-limited protein has no biologic function

Sex-limited protein (Slp) is a mouse serum protein of unknown function that has approximately 95% amino acid sequence identity with murine complement component C4 but is inactive in the complement pathway. The gene for Slp lies in the S region of the murine H-2 complex adjacent to the gene Cyp21 that encodes the Cytochrome P-450 enzyme steroid 21-hydroxylase. We report the sequence of a 26,307 bp long segment of the mouse genome that includes both the Slp and Cyp21 genes. The sequence reported was assembled from the sequences of three overlapping lambda phage genomic clones from mouse strain B10.WR, which carries four tandem pairs of Slp and Cyp21 genes. We also report the sequence of a fourth lambda clone, 12,539 bp in length, carrying parts of a distinct pair of Slp and Cyp21 genes from B10.WR mice. The Slp gene at 14.3 kb in length is about 1 kb shorter than the C4 gene; this difference is due primarily to absences of a simple repetitive sequence and a middle repetitive MT element in the corresponding introns 14 and 15, respectively. The gene sequence reveals an intron/exon organization identical to that of the murine C4 gene, and also that the 9 nucleotide deletion in exon 18, which appears to be directly responsible for the absence of complement activity, is unrelated to differences in intron sequences. Detailed comparisons of C4 and Slp gene sequences indicate that nucleotide substitutions in the Slp gene are occurring at approximately the same rate in both exons and introns. This implies that the murine Slp gene resembles a pseudogene and supports previously reported evidence that the Slp protein has no biologic function.     

Sequence comparison of alleles of the fourth component of complement (C4) and sex-limited protein (Slp).

cDNA clones specific for the fourth component of complement (C4) and its androgen-regulated isotype, sex-limited protein (Slp), have been isolated from two mouse haplotypes (H-2d and H-2w7) that show differential C4 activity and differential regulation of Slp. Clones were first isolated using a cDNA probe enriched by subtractive hybridization. Subsequent screening has resulted in cDNAs spanning the entire C4d mRNA, as well as much of C4w7, Slpw7 and a short region of Slpd. The cDNAs for C4 and Slp show extensive sequence homology, but can be distinguished using oligonucleotide probes synthesized to regions of greatest sequence divergence. Sequence differences between C4 and Slp indicate structurally important features of C4 that have been altered in Slp such that Slp is unable to participate in the complement pathway. Of the few nucleotide differences between C4d and C4w7, a single base change resulting in one less glycosylation site in the C4w7 alpha chain could account for its 4-fold reduced hemolytic efficiency. Sequence comparison of multiple alleles of C4 and Slp indicates that possible gene conversion events occurred in the H-2w7 strain that has multiple Slp genes.     

The complement component C4 of mammals.

Human complement component C4 is coded by tandem genes located in the HLA class III region. The products of the two genes, C4A and C4B, are different in their activity. This difference is due to a degree of 'substrate' specificity in the covalent binding reactions of the two isotypes. Mouse also has a duplicated locus, but only one gene produces active C4, while the other codes for the closely related sex-limited protein (Slp). In order to gain some insight into the evolutionary history of the duplicated C4 locus, we have purified C4 from a number of other mammalian species, and tested their binding specificities. Like man, chimpanzee and rhesus monkey appear to produce two C4 types with reactivities similar to C4A and C4B. Rat, guinea pig, whale, rabbit, dog and pig each expresses C4 with a single binding specificity, which is C4B-like. Sheep and cattle express two C4 types, one C4B-like, the other C4A-like, in their binding properties. These results suggest that more than one locus may be present in these species. If this is so, then the duplication of the C4 locus is either very ancient, having occurred before the divergence of the modern mammals, or there have been three separate duplication events in the lines leading to the primates, rodents and ungulates.     

Tyrosinase and tyrosinase related protein 1 alleles specify domestic cat coat color phenotypes of the albino and brown loci

The genes encoding enzymes of the tyrosinase family are strong candidates for coat color variation in mammals. To investigate their influence in domestic cat coat color, we determined the complete nucleotide coding sequence of the domestic cat genes tyrosinase (TYR)--a plausible candidate gene for the albino (C) locus, and tyrosinase related protein 1 (TYRP1)--a candidate gene for the brown (B) locus. Sequence variants between individuals exhibiting variation in pigmentation were submitted to association studies. In TYR, two nonsynonymous substitutions encoding TYR-G301R and TYR-G227W were associated with the siamese and burmese phenotypes of the albino locus, respectively. TYRP1 was mapped on chromosome D4 within 5 cM of a highly polymorphic microsatellite, previously found to be fixed in a cat breed selected for the chocolate (b) allele of the B locus, which reinforced TYRP1 as a candidate gene for the B locus in the domestic cat. Two DNA polymorphisms, one leading to a TYRP1-A3G substitution in the signal peptide and another to an in-frame insertion TYRP1-421ins17/18 caused by a donor splice site mutation in intron 6, were associated with the chocolate (b) allele. A premature UAG stop codon at position 100 of TYRP1 was associated with a second allele of the B locus, cinnamon (b(l)). The results provide very strong evidence that the specific nucleotide variants of feline TYR (chromosome D1) are causative of the siamese (c(s)) and burmese (c(b)) alleles of the albino locus, as well as nucleotide variants of TYRP1 (chromosome D4) as specifying the chocolate (b) and cinnamon (b(l)) alleles of the B locus.     

Genomic organization of the S locus: Identification and characterization of genes in SLG/SRK region of S(9) haplotype of Brassica campestris (syn. rapa).

In Brassica, two self-incompatibility genes, encoding SLG (S locus glycoprotein) and SRK (S-receptor kinase), are located at the S locus and expressed in the stigma. Recent molecular analysis has revealed that the S locus is highly polymorphic and contains several genes, i.e., SLG, SRK, the as-yet-unidentified pollen S gene(s), and other linked genes. In the present study, we searched for expressed sequences in a 76-kb SLG/SRK region of the S(9) haplotype of Brassica campestris (syn. rapa) and identified 10 genes in addition to the four previously identified (SLG(9), SRK(9), SAE1, and SLL2) in this haplotype. This gene density (1 gene/5.4 kb) suggests that the S locus is embedded in a gene-rich region of the genome. The average G + C content in this region is 32.6%. An En/Spm-type transposon-like element was found downstream of SLG(9). Among the genes we identified that had not previously been found to be linked to the S locus were genes encoding a small cysteine-rich protein, a J-domain protein, and an antisilencing protein (ASF1) homologue. The small cysteine-rich protein was similar to a pollen coat protein, named PCP-A1, which had previously been shown to bind SLG.     

Effects of a temperature sensitivity mutation in the J1R protein component of a complex required for vaccinia virus assembly

Vaccinia virus J1R protein is required for virion morphogenesis (W. L. Chiu and W. Chang, J. Virol. 76:9575-9587, 2002). In this work, we further characterized the J1R protein of wild-type vaccinia virus and compared it with the protein encoded by the temperature-sensitive mutant virus Cts45. The mutant Cts45 was found to contain a Pro-to-Ser substitution at residue 132 of the J1R open reading frame, which is responsible for a loss-of-function phenotype. The half-life of the J1R-P132S mutant protein was comparable at both 31 and 39 degrees C, indicating that the P132S mutation did not affect the stability of the J1R protein. We also showed that the J1R protein interacts with itself in the virus-infected cells. The N-terminal region of the J1R protein, amino acids (aa) 1 to 77, interacted with the C-terminal region, aa 84 to 153, and the P132 mutation did not abolish this interaction, as determined by two-hybrid analysis. Furthermore, we demonstrated that J1R protein is part of a viral complex containing the A30L, G7L, and F10L proteins in virus-infected cells. In immunofluorescence analyses, wild-type J1R protein colocalized with the A30L, G7L, and F10L proteins in virus-infected cells but the loss-of-function P132 mutant did not. Furthermore, without a functional J1R protein, rapid degradation of A30L and the 15-kDa forms of the G7L and F10L proteins was observed in cells infected with Cts45 at 39 degrees C. This study thus demonstrated the importance of the J1R protein in the formation of a viral assembly complex required for morphogenesis.     

Murine sex-limited protein (Slp) antigenic sites in human complement component C4

Human complement component C4 is encoded by two HLA-linked loci, A and B. In the mouse, the H-2 region contains structural genes for two serum proteins that react with antibodies to human C4, but one of these proteins (Slp) has no C4 hemolytic activity. Because the product of C4-A locus in man has low hemolytic activity, a previous report suggests it may be the homologue of murine Slp. We show here that Slp antigenic determinants are found in human C4. However, they are expressed in the products of both loci A and B, that is, C4A and C4B, since both proteins were specifically immunoprecipitated by the IgG fraction of alloantisera to mouse Slp. Therefore, Slp-associated structural features are preserved in evolution, although they do not seem to be relevant to the hemolytic properties of C4.