Organization and polymorphism of rabbit immunoglobulin heavy chain genes

Germline genes encoding C mu, C gamma, C alpha, and C epsilon heavy chains of rabbit immunoglobulins have been isolated from recombinant phage and cosmid libraries. The JH, C mu, C gamma, and C epsilon are found in a 5'-JH-C mu-C gamma-C epsilon-3' orientation on a 90kb stretch of DNA. Four C alpha genes have been cloned and presumably reside 3' to the other CH genes. Southern blot analysis of rabbit sperm DNA indicates that the rabbit genome contains a single C gamma gene, one C mu gene, and as many as 10 C alpha genes. Restriction site polymorphism is found for C mu, C gamma, and C alpha genes of rabbits of various heavy chain haplotypes. The organization of the rabbit CH genes differs from that of mouse and human CH genes in that the rabbit has multiple C alpha genes, whereas mouse and human have one or two C alpha genes, respectively. In addition, mouse and human have four C gamma genes, whereas rabbit has only one C gamma gene. The presence of a single C gamma gene indicates that at least in the rabbits examined, no germline gene encoding latent or unexpected, C gamma allotypes is present. The genetic control of the expression of latent C gamma allotypes is discussed.     

Homology between the Lpm system of allotypes in the American mink and the Gp system of allotypes in the domestic pig]

The 5 alpha-macroglobulin allotypes alpha M1, alpha M2, alpha M3, alpha M4 and alpha M5 were identified in pig. The alpha M1 allotype was reported as a marker of pig alpha-macroglobulin, the latter being homologous to alpha 2-macroglobulins in human and in mink. The allotypes alpha M2-alpha M5 were specified as markers of the second isotypical variant of pig alpha-macroglobulins, which was homologous to mink Lpm macroglobulin (alpha 1M). As seen from data obtained by International Comparative Test ISABR 87-88, alpha M1 is a new allotype, while allotypes alpha M2--alpha M5 correspond to four allotypes in the Gp system (Janik et al.). Based on these data, a conclusion was made on the homology between the Lpm system in american mink and the Gp system in pig. Since the allotypes studied are the part of alpha-macroglobulins, a locus controlling them was designated the AM locus. We also find it more advantageous to apply the same name to the homologous locus in mink, instead of the Lpm used earlier. Genetic control of 5 allotypes was studied and the structure of the AM locus in pig analysed in detail. Comparative study of organization of the above locus and the homologous locus in mink was carried out.     

Evolution of genes for allelic and isotypic forms of immunoglobulin kappa chains and of the genes for T-cell receptor beta chains in rabbits

New insights into the evolution of the families of genes encoding immunoglobulins and T-cell receptors of rabbits (Oryctolagus cuniculus) have come from molecular genetic studies. In contrast to human and mouse, rabbits were shown to have two genes for the constant region of immunoglobulin light chains (C kappa 1 and C kappa 2 isotypes) and complex allelic variants of K1 (allotypes). Although K1 allotype protein sequences differed at up to 41% of the amino acid positions, 3' untranslated, 5', and 3' flanking regions were conserved, and in the coding regions 78-80% of the codons with differences had replacement changes. Proportions of silent changes and changes in noncoding regions were comparable. Thus, in spite of their markedly different protein sequences, the K1b4, b5, and b9 allotypes appeared to be products of allelic genes. Molecular genetic analyses suggested that they may have undergone rapid divergence after an ancestral K2-like gene duplicated. Some rabbits were found to have two similar T-cell receptor C beta genes as do humans and many strains of mice, but others appeared to have three different C beta. In addition, we found allotypic forms of C beta. Some of the C beta allotypic differences occurred at positions where analogous C kappa allotypic differences were found. We also found V beta in mouse and human that were more similar to rabbit V beta than closely linked rabbit genes were to each other. This contrasts with rabbit immunoglobulin VH gene sequences that reflect concerted evolution. The data suggested that T-cell receptor V beta genes duplicated prior to mammalian radiation.     

Partial amino acid sequence of a rabbit immunoglobulin light chain of allotype b5

The amino acid sequence of a rabbit immunoglobulin light chain of allotype b5 has been nearly completed. A comparison of its structure with that of light chains of allotypes b4, b6, and b9 confirms that the constant regions of these various kappa chains differ by 20-35%. The substitutions are clustered in parts of the second half of the chain, and the b5 form bears more resemblance to the b6 chain than to any other, in good agreement with previous serological data. The analysis of the variable region reveals the existence of certain allotype-associated residues which have also been reported in other b5 chains, but not in proteins of the other allotypes. An examination of the rabbit light chain sequences between positions 96 and 107 suggests that this portion of the chain may be encoded separately by a joining "J" DNA segment, as has been described previously for murine and human immunoglobulins. In the rabbit, however, these J kappa regions appear to differ from one allotype to another. Together with the extensive variations of the constant regions, these data suggest that the rabbit kappa gene organization more closely resembles the murine gamma system (four different C gamma genes each flanked by its J segment) than the murine kappa system (a single C kappa gene).     

Assignment of orthologous relationships among mammalian alpha-globin genes by examining flanking regions reveals a rapid rate of evolution

In order to study the relationships among mammalian alpha-globin genes, we have determined the sequence of the 3' flanking region of the human alpha 1 globin gene and have made pairwise comparisons between sequenced alpha-globin genes. The flanking regions were examined in detail because sequence matches in these regions could be interpreted with the least complication from the gene duplications and conversions that have occurred frequently in mammalian alpha-like globin gene clusters. We found good matches between the flanking regions of human alpha 1 and rabbit alpha 1, human psi alpha 1 and goat I alpha, human alpha 2 and goat II alpha, and horse alpha 1 and goat II alpha. These matches were used to align the alpha-globin genes in gene clusters from different mammals. This alignment shows that genes at equivalent positions in the gene clusters of different mammals can be functional or nonfunctional, depending on whether they corrected against a functional alpha-globin gene in recent evolutionary history. The number of alpha-globin genes (including pseudogenes) appears to differ among species, although highly divergent pseudogenes may not have been detected in all species examined. Although matching sequences could be found in interspecies comparisons of the flanking regions of alpha- globin genes, these matches are not as extensive as those found in the flanking regions of mammalian beta-like globin genes. This observation suggests that the noncoding sequences in the mammalian alpha-globin gene clusters are evolving at a faster rate than those in the beta-like globin gene clusters. The proposed faster rate of evolution fits with the poor conservation of the genetic linkage map around alpha-globin gene clusters when compared to that of the beta-like globin gene clusters. Analysis of the 3' flanking regions of alpha-globin genes has revealed a conserved sequence approximately 100-150 bp 3' to the polyadenylation site; this sequence may be involved in the expression or regulation of alpha-globin genes.      

Gene conversion in human immunoglobulin gamma locus shown by unusual location of IgG allotypes

The constant region of the gamma 1, gamma 2 and gamma 3 heavy chains of the human IgG1, IgG2 and IgG3 immunoglobulins carries antigenic determinants or G1m, G2m and G3m allotypes, which are genetic markers of these subclasses. The exceptional presence on gamma 1 and gamma 2 chains of Gm allotypes usually located on the CH3 domain of gamma 3 shows an unexpected clustering of base changes and subsequent identity of short DNA sequences in the CH3 exon of the non-allelic gamma 1, gamma 2 and gamma 3 genes. Such clusters of substitutions are not easily explained on the classical basis of point mutations. A gene conversion, which substituted a segment of the gamma 1 or gamma 2 gene with the homologous region of the non-allelic gamma 3 gene, is more likely. Other examples of possible conversion involving the gamma genes are described. The conservation or the restoration of short sequences produced by the conversion events might be related to the biological properties of the constant region of the heavy chains.     

Genomic organization of adrenergic and serotonin receptors in the mouse: linkage mapping of sequence-related genes provides a method for examining mammalian chromosome evolution.

Five sequence-related genes encoding four adrenergic receptors and a serotonin receptor were localized to specific regions of four mouse chromosomes with respect to 11 other genetic markers. Linkage was established by the analysis of the haplotypes of 114 interspecific backcross mice. Adra2r (alpha 2-C10) and Adrb1r (beta 1) receptors mapped to the distal region of mouse chromosome 19. These genes were separated by 2.6 +/- 1.5 cM in a segment of mouse chromosome 19 that has a similar organization of these genes on the long arm of human chromosome 10. The Adra1r (alpha 1B), Adrb2r (beta 2), and Htra1 (5HT1A) genes mapped to proximal mouse chromosome 11, proximal mouse chromosome 18, and distal mouse chromosome 13, respectively. The organization of genes linked to these loci on regions of the three mouse chromosomes is consistent with the organization of homologous human genes on human chromosome 5. These findings further define the relationship of linkage groups conserved during the evolution of the mouse and human genomes. We have identified a region that may have been translocated during evolution and suggest that the human genomic organization of adrenergic receptors more closely resembles that of a putative primordial ancestor.     

Immunogenetic Polymorphism of Lipoproteins in Swine: Genetic, Immunological and Physiochemical Characterization of the Two Allotypes Lpr1 and Lpr2

Results of immunogenetic, immunochemical and physicochemical investigations on two serum allotypes of swine are reported. The allotypes, designated Lpr1 and Lpr2, have been identified by specific alloprecipitins in agar gel. Genetic studies indicate that the allotypes are specified by two codominant autosomal allelic genes, Lpr1 and Lpr2. All pigs 3 months of age or older were classified as belonging to one of three phenotypes, Lpr1, Lpr2 or Lpr1,2, each corresponding to one of three genotypes Lpr1/1, Lpr2/2 or Lpr1/2, respectively. The Lpr1 gene was absent or was found at low frequency in the breeds tested. The allotypes were found to occur in two physicochemical forms; in association with chylomicrons and very low density lipoproteins (VLDL) and, primarily, as a Lpr multimer free of the major lipoproteins showing very high density (VHD), d greater than 1.21 g/ml, and MW +/- 190,000. Gel-electrophoretic mobility for VHD-Lpr is different for each of the three Lpr genotypes residing in gamma-fast and beta-slow regions, but is identical for VLD-Lpr in which Lpr was found complexed with apo-B, migrating as VLDL in the alpha-2 slow (pre-beta) region. Serum levels of Lpr varied during the lifetime and between individuals and, especially, between sera of homozygous pigs being higher in Lpr1/1 than Lpr2/2. A linear relationship for Lpr1 and an atypical, inverse relationship for Lpr2 have been observed between the gene dosage, heterozygous vs. homozygous, and the Lpr serum level.     

Immunoglobulin allotypes (Gm,Am, and Km) in non-human primates

The immunoglobulin (Ig) allotypes (Gm, Am, and Km systems) are the genetic markers of the human IgG1, IgG2, IgG3(Gm), IgA2(Am), and kappa light chain(Km). The Gm system, with 18 allotypes shows the greatest degree of polymorphism and we define two Am and three Km allotypes. In this review, we report all the results observed in non-human primates belonging to Hominoidea, Cercopithecoidea, Ceboidea, Lorisoidea, Lemuroidea, and Tupaoidea superfamilies (72 species and subspecies). They concern published data and new unpublished ones. The distribution of the human allotypes and their localization are reported, as well as discordant results observed in some cases with anti-allotype reagents of the same specificity (human and animal origin). Some allotypes are restricted to man. Hominoidea have the greatest number of Gm allotypes and the richest polymorphism. Relatively few allotypes have been found in Cercopithecoidea and Prosimians; most Platyrrhinian species have no allotype. The epitopic polymorphism has been interpreted in terms of evolution of Ig allotypes from primate to man and of the phylogenetic relationships of non-human primate species.     

Mouse IgA allotypes have major differences in their hinge regions

Six IgA allotypes are serologically identifiable in inbred mice. The sequences of the PCR-amplified C alpha 1, C alpha 2 and C alpha 3 exons from the genomic DNA of mice of four previously unsequenced allotypes already have been compared with those of BALB/c and of a wild mouse, Mus pahari, in the literature. Sporadic differences, including several that may encode the known allotypic determinants, are found throughout the three exons, but major differences occur in the hinge. The hinge is longest in DBA/2 ( Igh-2(c)) mice, having an extra codon compared with that of BALB/c ( Igh-2(a)) and B10.A ( Igh-2(b)) mice. It is two codons shorter in CE ( Igh-2(f)) and four shorter in M. pahari, AKR and NZB (both Igh-2(d)) mice, but the position of the missing codons in the latter two strains is offset from that in M. pahari. The hinges in BALB/c ( Igh-2(a)) and DBA/2 ( Igh-2(c)) differ most from each other and from the other three allotypes, which are fairly closely related. Both BALB/c and DBA/2 have O-linked glycosylation sites, but they are in different positions in the hinge. Compared with BALB/c ( Igh-2(a)), B10.A( Igh-2(b)) has two extra Cys residues in the hinge, while DBA/2 ( Igh-2(c)), AKR/NZB ( Igh-2(d)) and CE ( Igh-2(f)) each have one. The differences in hinge length may have arisen by mismatching of highly repetitive portions of its sequence during meiotic recombination. Possible effects of the differences in hinge length and composition on the behavior of the mouse IgA allotypes are discussed.     

Concerted evolution of the primate immunoglobulin alpha-gene through gene conversion.

We determined four nucleotide sequences of the hominoid immunoglobulin alpha (C alpha) genes (chimpanzee C alpha 2, gorilla C alpha 2, and gibbon C alpha 1 and C alpha 2 genes), which made possible the examination of gene conversions in all hominoid C alpha genes. The following three methods were used to detect gene conversions: 1) phenetic tree construction; 2) detection of a DNA segment with extremely low variability between duplicated C alpha genes; and 3) a site by site search of shared nucleotide changes between duplicated C alpha genes. Results obtained from method 1 indicated a concerted evolution of the duplicated C alpha genes in the human, chimpanzee, gorilla, and gibbon lineages, while results obtained from method 2 suggested gene conversions in the human, gorilla, and gibbon C alpha genes. With method 3 we identified clusters of shared nucleotide changes between duplicated C alpha genes in human, chimpanzee, gorilla, and gibbon lineages, and in their hypothetical ancestors. In the present study converted regions were identified over the entire C alpha gene region excluding a few sites in the coding region which have escaped from gene conversion. This indicates that gene conversion is a general phenomenon in evolution, that can be clearly observed in non-functional regions.     

Specificity of amyloid precursor-like protein 2 interactions with MHC class I molecules

The ubiquitously expressed amyloid precursor-like protein 2 (APLP2) has been previously found to regulate cell surface expression of the major histocompatibility complex (MHC) class I molecule K(d) and bind strongly to K(d). In the study reported here, we demonstrated that APLP2 binds, in varied degrees, to several other mouse MHC class I allotypes and that the ability of APLP2 to affect cell surface expression of an MHC class I molecule is not limited to K(d). L(d), like K(d), was found associated with APLP2 in the Golgi, but K(d) was also associated with APLP2 within intracellular vesicular structures. We also investigated the effect of beta(2)m on APLP2/MHC interaction and found that human beta(2)m transfection increased the association of APLP2 with mouse MHC class I molecules, likely by affecting H2 class I heavy chain conformation. APLP2 was demonstrated to bind specifically to the conformation of L(d) having folded outer domains, consistent with our previous results with K(d) and indicating APLP2 interacts with the alpha1alpha2 region on each of these H2 class I molecules. Furthermore, we observed that binding to APLP2 involved the MHC alpha3/transmembrane/cytoplasmic region, suggesting that conserved as well as polymorphic regions of the H2 class I molecule may participate in interaction with APLP2. In summary, we demonstrated that APLP2's binding, co-localization pattern, and functional impact vary among H2 class I molecules and that APLP2/MHC association is influenced by multiple domains of the MHC class I heavy chain and by beta(2)m's effects on the conformation of the heavy chain.     

Organization of rabbit immunoglobulin genes. I. Structure and multiplicity of germ-line VH genes

Two rabbit germ-line VH gene segments have been isolated from a recombinant phage DNA library. Nucleotide sequence analysis indicates that both of the genes share structural and regulatory features common to mouse and human VH genes, although one appears to be a pseudogene. Comparison of the protein sequences encoded by these genes to the protein sequences of rabbit immunoglobulin V regions indicates that both genes encode VH a-negative-like molecules. Quantitative genomic blot analysis with a VH probe capable of recognizing most, if not all, germ-line VH genes indicates that there are approximately 100 VH genes in the haploid genome of rabbits. The average spacing between the germ-line VH genes was determined to be approximately 6 kb. The molecular basis for the allelic inheritance of rabbit VH allotypes is discussed in view of the structural organization of germ-line VH genes.     

Human cardiac myosin heavy chain genes and their linkage in the genome.

Human myosin heavy chains are encoded by a multigene family consisting of at least 10 members. A gene-specific oligonucleotide has been used to isolate the human beta myosin heavy chain gene from a group of twelve nonoverlapping genomic clones. We have shown that this gene (which is expressed in both cardiac and skeletal muscle) is located 3.6kb upstream of the alpha cardiac myosin gene. We find that DNA sequences located upstream of rat and human alpha cardiac myosin heavy chain genes are very homologous over a 300bp region. Analogous regions of two other myosin genes expressed in different muscles (cardiac and skeletal) show no such homology to each other. While a human skeletal muscle myosin heavy chain gene cluster is located on chromosome 17, we show that the beta and alpha human cardiac myosin heavy chain genes are located on chromosome 14.     

Identification of rabbit genomic Ig-VH pseudogenes that could serve as donor sequences for latent allotype expression

Synthetic DNA oligomers specific for the VHa allotypes of rabbit Ig genes have been used to identify latent allotypic sequences in homozygous a1 and a2 rabbits. Two Ig VH pseudogenes containing latent a3 regions have been cloned from the genome of a homozygous a2 rabbit. Analysis of the regions associated with allotype expression indicates that these two pseudogenes contain VHa- sequences in framework region 1 (FR1) and VHa3 sequences in FR3. One gene has undergone an unusual rearrangement with a third VH gene, deleting their intervening sequences and recombining in FR3 with sequences 5' to the leader exon. Our results demonstrate the presence of latent VH sequences in the genomic DNA of normal rabbits and suggest that a mechanism such as gene conversion is responsible for expression of genetically-unexpected Ig VH genes.     

Highly variable regions of DNA flank the human alpha globin genes.

A series of restriction fragment length polymorphisms which are due to DNA rearrangements have been identified within two highly variable regions flanking the human alpha globin genes. The existence of such highly polymorphic areas provides a large number of individual genetic markers for the alpha globin gene cluster on chromosome 16. If, as seems likely, such regions occur frequently throughout the human genome they should be of considerable value in the antenatal diagnosis of genetic disease.     

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.     

Immunoglobulin (GM and KM) allotypes in the Sikh population of India

The populations of India are genetically diverse, both within and between geographic regions; immunoglobulin (GM) allotypes provide important information on genetic differences between populations, since the frequencies of combinations of allotypes (termed "haplotypes") vary dramatically among ethnic groups. As part of a project to assess genetic diversity among defined Indian populations, we have examined eight GM allotypes in a sample of 101 unrelated Sikhs who have migrated to Toronto, Canada: Glm(1, 2, 3, 17) and G3m (5, 15, 16, 21). Sikhs are a religious group that arose in the Punjab about 1500 A.D.; most of the original converts are believed to have been middle to upper-middle caste Hindus. Gm allotyping showed that six Gm haplotypes occurred at polymorphic frequencies (greater than 0.01) in Sikhs: Gm3;5, Gm1,17;21, Gm1,2,17;21, Gm1,17;5, Gm1,17;15,16, and Gm1,3;5. These haplotypes have all been previously reported in Indian populations. The frequencies of the first four haplotypes resembled the published frequencies for lower-caste Hindus of NW India more than upper-caste Hindus. However, the last two haplotypes have been found only in upper-caste Hindus. The frequency of one of these, Gm1,17;15,16 was higher in Sikhs (0.09) than has been reported in any Indian population with the exception of Parsis (who are descended from Iranians). We speculate that the high frequency of this haplotype may have been characteristic of some of the Hindu castes in the Punjab from which Sikhs are descended.