Physical mapping of four serpin genes: alpha 1-antitrypsin, alpha 1-antichymotrypsin, corticosteroid-binding globulin, and protein C inhibitor, within a 280-kb region on chromosome I4q32.1.

Alpha 1-antitrypsin (alpha 1AT; protease inhibitor [PI] locus), alpha 1-antichymotrypsin (alpha 1ACT; AACT locus), corticosteroid-binding globulin (CBG; CBG locus), and protein C inhibitor (PCI; PCI locus) are members of the serine protease inhibitor (serpin) superfamily. A noncoding PI-like (PIL) gene has been located 12 kb 3' of the PI gene. The PI, PIL, and AACT loci have been localized to 14q32.1, the CBG locus has been localized to 14q31-14q32.1, and PCI has been mapped to chromosome 14. Genetic linkage analysis suggests tight linkage between PI and AACT. We have used pulsed-field gel electrophoresis to generate a physical map linking these five serpin genes. The order of the genetic loci is AACT/PCI-PI-PIL-CBG, with a maximum distance of about 220 kb between the AACT/PCI and PI genes. These genes form a PI cluster at 14q32.1, similar to that of the homologous genes on murine chromosome l2. The close proximity of these genes has implications for disease-association studies.     

Physical and genetic mapping of the serpin gene cluster at 14q32.1: allelic association and a unique haplotype associated with alpha 1-antitrypsin deficiency.

The alpha 1-antitrypsin (PI) gene is part of a cluster of structurally related serine protease inhibitor genes localized at chromosome 14q32.1, a cluster that includes the alpha 1-antichymotrypsin (AACT), protein C inhibitor (PCI), and corticosteroid-binding globulin (CBG) genes and the alpha 1-antitrypsin-like pseudogene (PIL). The order of the genes is refined here by genetic mapping using simple tandem repeat polymorphisms (STRPs) and by physical mapping in YACs. The order of the genes is (centromere)-CBG-PIL-PI-PCI-AACT-(telomere). Analysis of DNA haplotypes comprising STRP and RFLP markers in the serpin genes reveals considerable allelic association throughout the cluster. Furthermore, the common alpha 1-antitrypsin deficiency allele, PI*Z, has a unique DNA haplotype at the CBG, PIL, and PI loci, which extends over 60 kb in 97% of cases and in 44% of cases includes the PCI and AACT loci. This unique haplotype will be of use in examining a number of other diseases, particularly those with an inflammatory component, thought to be associated with alpha 1-antitrypsin deficiency or partial deficiency.     

A 370-kb Cosmid Contig of the Serpin Gene Cluster on Human Chromosome 14q32.1: Molecular Linkage of the Genes Encoding α1-Antichymotrypsin, Protein C Inhibitor, Kallistatin, α1-Antitrypsin, and Corticosteroid-Binding Globulin

The human genes encoding α1-antitrypsin (α1AT, gene symbol PI), corticosteroid-binding globulin (CBG), α1-antichymotrypsin (AACT), and protein C inhibitor (PCI) are related by descent, and they all map to human chromosome 14q32.1. This serine protease inhibitor (serpin) gene cluster also contains an antitrypsin-related sequence (ATR, gene symbol PIL), but the precise molecular organization of this region has not been defined. In this report we describe the generation and characterization of an 370-kb cosmid contig that includes all five serpin genes. Moreover, a newly described serpin, kallistatin (KAL, gene symbol PI4), was also mapped within the region. Gene order within this interval is cen–CBG–ATR–α1AT–KAL–PCI–AACT–tel. The genes occupy 320 kb of genomic DNA, and they are organized into two discrete subclusters of three genes each that are separated by 170 kb. The distal subcluster includes KAL, PCI, and AACT; it occupies 63 kb of DNA, and all three genes are transcribed in a proximal-to-distal orientation. Within the subcluster, there is 12 kb of intergenic DNA between KAL and PCI and 19 kb between PCI and AACT. The proximal subcluster includes α1AT, ATR, and CBG; it occupies 90 kb of genomic DNA, with 12 kb of DNA between α1AT and ATR and 40 kb between ATR and CBG. These genes are all transcribed in a distal-to-proximal orientation. This represents the first detailed physical map of the serpin gene cluster on 14q32.1.     

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.     

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.      

Class II genes of the human major histocompatibility complex. Evolution of the DP region as deduced from nucleotide sequences of the four genes

The DP region of the human major histocompatibility complex contains two alpha genes and two beta genes. The DP alpha 1 and beta 1 genes encode the expressed DP histocompatibility antigen molecule, while the DP alpha 2 and beta 2 genes are inactive in the haplotypes examined. Here we present the sequence of the two DP beta genes and of the expressed DP alpha 1 gene. Nucleotide sequence comparisons reveal a considerably greater degree of similarity between the two beta genes than between the two alpha genes. We propose that a duplication giving rise to the DP alpha gene pair evolutionarily preceded the corresponding DP beta gene duplication. We also propose, based on the orientation of other class II gene pairs, that the original DP molecule was encoded by the DP beta 1 and DP alpha 2 genes. At some stage during the evolution of the DP region both of the two pseudogenes appear to have been expressed.     

Rapid evolution through gene duplication and subfunctionalization of the testes-specific alpha4 proteasome subunits in Drosophila

Gene duplication is an important mechanism for acquiring new genes and creating genetic novelty in organisms. Evidence suggests that duplicated genes are retained at a much higher rate than originally thought and that functional divergence of gene copies is a major factor promoting their retention in the genome. We find that two Drosophila testes-specific alpha4 proteasome subunit genes (alpha4-t1 and alpha4-t2) have a higher polymorphism within species and are significantly more diverged between species than the somatic alpha4 gene. Our data suggest that following gene duplication, the alpha4-t1 gene experienced relaxed selective constraints, whereas the alpha4-t2 gene experienced positive selection acting on several codons. We report significant heterogeneity in evolutionary rates among all three paralogs at homologous codons, indicating that functional divergence has coincided with genic divergence. Reproductive subfunctionalization may allow for a more rapid evolution of reproductive traits and a greater specialization of testes function. Our data add to the increasing evidence that duplicated genes experience lower selective constraints and in some cases positive selection following duplication. Newly duplicated genes that are freer from selective constraints may provide a mechanism for developing new interactions and a pathway for the evolution of new genes.     

Reverse genetic characterization of two paralogous acetoacetyl CoA thiolase genes in Arabidopsis reveals their importance in plant growth and development

Acetoacetyl CoA thiolase (AACT, EC 2.3.1.9) catalyzes the condensation of two acetyl CoA molecules to form acetoacetyl CoA. Two AACT-encoding genes, At5g47720 (AACT1) and At5g48230 (AACT2), were functionally identified in the Arabidopsis genome by direct enzymological assays and functional expression in yeast. Promoter::GUS fusion experiments indicated that AACT1 is primarily expressed in the vascular system and AACT2 is highly expressed in root tips, young leaves, top stems and anthers. Characterization of T-DNA insertion mutant alleles at each AACT locus established that AACT2 function is required for embryogenesis and for normal male gamete transmission. In contrast, plants lacking AACT1 function are completely viable and show no apparent growth phenotypes, indicating that AACT1 is functionally redundant with respect to AACT2 function. RNAi lines that express reduced levels of AACT2 show pleiotropic phenotypes, including reduced apical dominance, elongated life span and flowering duration, sterility, dwarfing, reduced seed yield and shorter root length. Microscopic analysis reveals that the reduced stature is caused by a reduction in cell size and fewer cells, and male sterility is caused by loss of the pollen coat and premature degeneration of the tapetal cells. Biochemical analyses established that the roots of AACT2 RNAi plants show quantitative and qualitative alterations in phytosterol profiles. These phenotypes and biochemical alterations are reversed when AACT2 RNAi plants are grown in the presence of mevalonate, which is consistent with the role of AACT2 in generating the bulk of the acetoacetyl CoA precursor required for the cytosol-localized, mevalonate-derived isoprenoid biosynthetic pathway.     

Independent recombination events between the duplicated human alpha globin genes; implications for their concerted evolution.

We have examined the molecular structure of the human alpha globin gene complex from individuals with a common form of alpha thalassaemia in which one of the duplicated pair of alpha genes (alpha alpha) has been deleted (-alpha 3-7). Restriction mapping and DNA sequence analysis of the mutants indicate that different -alpha 3.7 chromosomes are the result of at least three independent events. In each case the genetic crossover has occurred within a region of complete homology between the alpha 1 and alpha 2 genes. Since the -alpha chromosomes may reflect the processes of crossover fixation and gene conversion between the two genes, their structures may provide some insight into the mechanism by which the concerted evolution of the human alpha globin genes occurs.     

a1 protein alters the DNA binding specificity of alpha 2 repressor

The alpha 2 protein of S. cerevisiae, the product of the MAT alpha 2 gene, represses a set of cell-type-specific genes (the a-specific genes) by binding to an operator sequence upstream of each gene. We demonstrate that a second yeast regulatory protein, a1, the product of the MATa1 gene, can alter the binding specificity of alpha 2 so that it no longer recognizes the a-specific gene operator, but instead acquires the ability to recognize a different operator sequence found upstream of haploid-specific genes. Thus, under the influence of a1, alpha 2 can repress haploid-specific genes. An alpha cell expresses alpha 2 but not a1, so that alpha 2 turns off only the a-specific genes. An a/alpha cell makes both a1 and alpha 2, in a ratio that ensures that alpha 2 is distributed between two distinct binding modes: the alpha 2 binding mode and the a1-alpha 2 binding mode. Thus in an a/alpha cell, alpha 2 represses two distinct classes of genes.     

Nonrandom rearrangement of T cell receptor J alpha genes in bone marrow T cell differentiation cultures

TCR J alpha genes span a distance of approximately 65 kb on mouse chromosome 14. Due to the existence of 50 to 100 discrete J genes, a potential for great diversity exists within the V-J-C alpha gene products and within the ultimate repertoire of alpha beta TCR. We have prepared hybridomas from an in vitro system that supports T cell differentiation among bone marrow cells. We have examined the J alpha genes among these cells and categorized rearrangements according to their location within the J alpha locus. It was found that alpha rearrangements were always present among the hybridomas bearing beta gene rearrangements. When two bone marrow-derived alpha-bearing chromosomes could be demonstrated in these hybridomas, both were always rearranged and rearrangements on homologous chromosomes were shown to reside in similar regions of the J alpha locus. Most surprisingly, when hybridomas were categorized by the culture from which they derived, cells from the same culture (designated as a set) demonstrated a skewing of alpha rearrangements to restricted segments of J alpha genes. In one hybridoma, rearrangements on homologous chromosomes involved J alpha genes that were either identical or situated within a 1-kb segment of DNA. The skewing within sets could not be due to clonal identity between hybridomas as the beta and gamma rearrangements in all hybridomas were different. Results suggested that skewing of J alpha gene rearrangements occurred during the course of T cell development in vitro. Should the same situation occur in vivo, the number of distinct TCR J alpha sequences available for expression in early development may be far less than that predicted by gene number alone.     

Molecular map of the human HLA-SB (HLA-DP) region and sequence of an SB alpha (DP alpha) pseudogene.

The human major histocompatibility complex contains the genes for at least three different types of class II antigens, DR, DC and SB (DR, DQ and DP). They are all composed of an alpha and a beta chain. We have cloned a chromosomal region of 70 kb containing the SB (DP) gene family in overlapping cosmid clones. This segment contains two alpha genes and two beta genes, located in the order SB alpha 1, SB beta 1, SB alpha 2 and SB beta 2. The orientation of the alpha genes is reversed compared with that of the beta genes. This organisation suggests that the SB region has arisen by duplication of a chromosomal segment encompassing one alpha and one beta gene. Partial nucleotide sequences of the SB alpha 1 and SB beta 1 exons demonstrate that the genes correspond to SB alpha and beta cDNA clones. Consequently these genes are expressed. In contrast nucleotide sequence determination of the SB alpha 2 gene shows that it is a pseudogene.     

Gene conversions in the horse alpha-globin gene complex

The sequences of the linked alpha 2- and alpha 1-globin genes of the equine BI and BII haplotypes are greater than 99% identical within a 1.2-kb region extending from approximately 75 bp upstream of the putative cap site to a point approximately 150 bp 3' to the poly A addition signal. Differences between the alpha 2 and alpha 1 genes that are common to both haplotypes indicate that a major gene conversion occurred approximately 12 Myr ago and that this has been followed by shorter, more localized, conversions. Interhaplotype (allelic) comparisons at the alpha loci suggest that the BI and BII haplotypes have probably existed independently greater than or equal to 0.5 Myr and that the alpha 1 genes may have undergone a recent interchromosomal gene conversion.      

Mating-type control in Saccharomyces cerevisiae: isolation and characterization of mutants defective in repression by a1-alpha 2.

The alpha 2 protein, the product of the MAT alpha 2 cistron, represses various genes specific to the a mating type (alpha 2 repression), and when combined with the MATa1 gene product, it represses MAT alpha 1 and various haploid-specific genes (a1-alpha 2 repression). One target of a1-alpha 2 repression is RME1, which is a negative regulator of a/alpha-specific genes. We have isolated 13 recessive mutants whose a1-alpha 2 repression is defective but which retain alpha 2 repression in a genetic background of ho MATa HML alpha HMRa sir3 or ho MAT alpha HMRa HMRa sir3. These mutations can be divided into three different classes. One class contains a missense mutation, designated hml alpha 2-102, in the alpha 2 cistron of HML, and another class contains two mat alpha 2-202, in the MAT alpha locus. These three mutants each have an amino acid substitution of tyrosine or acid substitution of tyrosine or phenylalanine for cysteine at the 33rd codon from the translation initiation codon in the alpha 2 cistron of HML alpha or MAT alpha. The remaining 10 mutants make up the third class and form a single complementation group, having mutations designated aar1 (a1-alpha 2 repression), at a gene other than MAT, HML, HMR, RME1, or the four SIR genes. Although a diploid cell homozygous for the aarl and sir3 mutations and for the MATa, HML alpha, and HMRa alleles showed alpha mating type, it could sporulate and gave rise to asci containing four alpha mating-type spores. These facts indicate that the domain for alpha2 repression is separable from that for a1-alpha2 protein interaction or complex formation in the alpha2 protein and that an additional regulation gene, AAR1, is associated with the a1-alpha2 repression of the alpha1 cistron and haploid-specific genes.     

Latent a1 VH germline genes in an a2a2 rabbit. Evidence for gene conversion at both the germline and somatic levels

We have previously reported the sequences of putative latent a1 cDNA derived from an alpha 2 alpha 2 rabbit. Significant similarity to nominal a1 cDNA sequences was noted, but none of the latent sequences were completely a1-like. We have now probed a genomic library, produced from the same alpha 2 alpha 2 rabbit, for evidence of germline latent a1 VH genes. Four hundred ninety-four VH+ clones were screened with oligonucleotides specific for a1 diagnostic regions of framework region 1 (FR1) and FR3. Twenty-two percent of the VH+ clones hybridized with an a1FR3 oligonucleotide probe. Two a1 FR1 probes yielded weak signals with 6% to 13% of the VH+ clones. Twenty VH genes from clones positive for one or more of the a1-specific oligonucleotide probes were sequenced, revealing 14 unique germline VH genes. All but one of these genes were 85% to 92% identical to the VH1-a1 nominal gene prototype, with sequence identity extending into the leader intron. Most genes displayed extended regions of similarity to a1 in FR1, FR3, or both and expressed 13 to 17 of the 21 allotype-associated residues, consistent with the nominal a1 sequence. The a1-like sequences were variously interspersed with short non-a1 segments, suggestive of germline gene conversion. Although none of the germline a1-like VH genes we have isolated from the alpha 2 alpha 2 rabbits are identical to the known a1 genes or protein sequences from alpha 1 alpha 1 rabbits and 8 of 14 are pseudogenes, most could make significant contributions to the synthesis of a complete nominal a1 sequence by serving as a pool of sequence donors during somatic gene conversion.     

Block duplications of a zeta-zeta-alpha-theta gene set in the rabbit alpha-like globin gene cluster

In order to understand the coordinate regulation between the alpha-like and beta-like globins during the developmental switches in hemoglobin synthesis, we have studied the rabbit alpha-like globin gene family. A cluster of six linked genes arranged 5'-zeta 1-alpha 1-theta 1-zeta 2-zeta 3-theta 2-3' has been isolated as a set of overlapping clones from a library of rabbit genomic DNA. Blot-hybridization analysis of genomic DNA not only confirms this linkage arrangement but also reveals the presence of additional zeta and theta genes. We propose that this gene cluster was generated by a block duplication of a set of alpha-like genes; the proposed duplication unit is zeta-zeta-alpha-theta. Further duplications of a zeta-zeta-theta set are also proposed to have occurred. As expected for a duplicated locus, the rabbit alpha-like gene cluster contains long blocks of internal homology. The Z homology block is about 7.2 kilobase pairs long and contains the zeta genes; the T homology block is about 4.7 kilobase pairs long and contains a theta gene. Surprisingly, both Z and T homology blocks are flanked by a common junction sequence (J) which contains a region very similar to the 3'-untranslated sequence of an alpha-globin gene. Analysis of the J sequences suggests a recombination mechanism by which the alpha gene could have been deleted from the second set of genes in the cluster (zeta 2-zeta 3-theta 2). The relationships among the genes in characterized alpha-like gene clusters in mammals are summarized. The rabbit gene cluster differs from those of other mammals principally in the loss of a gene orthologous to the human psi alpha 1 and in the block duplication of the zeta-zeta-alpha-theta gene set.