Length Polymorphisms in Human Proline-Rich Protein Genes Generated by Intragenic Unequal Crossing over

Southern blot hybridization analysis of genomic DNAs from 44 unrelated individuals revealed extensive insertion/deletion polymorphisms within the BstNI-type loci (PRB1, PRB2, PRB3 and PRB4) of the human proline-rich protein (PRP) multigene family. Ten length variants were cloned, including alleles at each of the four PRB loci, and in every case the region of length difference was localized to the tandemly repetitious third exon. DNA sequences covering the region of length variation were determined for seven of the alleles. The data indicate (1) that the PRB loci can be divided into two subtypes, PRB1 plus PRB2, and PRB3 plus PRB4, and (2) that the length differences result from different numbers of tandem repeats in the third exons. Variant chromosomes were also identified with different numbers of PRP loci resulting from homologous but unequal exchange between the PRB1 and PRB2 loci. The overall data are compatible with the observed length variants having been generated via homologous but unequal intragenic exchange. The results also indicate that these crossover events are sensitive to the amount of homology shared between the interacting DNA strands. Allelic length variants have arisen independently at least 20 times at the PRB loci, but only one has been detected at a PRH locus. Comparison of the detailed structures of the repetitious regions in PRB and PRH loci shows that the repeats in PRB genes are very similar to each other in sequence and in length. The PRH genes contain fewer repeats, which differ considerably in their individual lengths. These differences suggest that the larger number of length variants in PRB genes is related to their greater ease of homologous but unequal pairing compared to PRH genes.     

Organization and conservation of the GART/SON/DONSON locus in mouse and human genomes

The SON gene, which maps to human chromosome 21q22.1-q22.2, encodes a novel regulatory protein. Here we describe the organization of the Son locus in the mouse genome. The mouse Son gene spans a region of approximately 35 kb. The coding region is more than 8 kb in length and has been completely sequenced. The gene is organized into 11 coding exons and 1 noncoding 3'UTR exon, with over 70% of the coding region residing in one 5.7-kb exon. The gene contains at least one alternative exon, N/C exon 1, which can be used, by splicing, to generate a truncated form of the SON protein. Further investigation of the mouse Son locus has identified the genes directly flanking Son. The glycinamide ribonucleotide formyltransferase gene, Gart, is encoded 5' of Son in a head-to-head arrangement, with the start of both genes lying within 899 bp. Sequence comparison with the expressed sequence tagged database identified a novel gene within 65 bp of the 3' end of Son, which we have named Donson. In this unusually compact gene cluster, we have found overlap in the pattern of expression between Gart, Son, and Donson. However, at least two of these genes have very different functions. While GART is involved in purine biosynthesis, we find that SON shows the characteristics of "SR- type" proteins, which are involved in mRNA processing and gene expression.     

Partial structure of the human H-protein gene

In a span of approximately 13 kb, two genomic fragments showing an obvious overlap encoded the 1,192 base pair (bp) cDNA sequence for human H-protein. Because of the close similarity in the genomic organization comprised of five exons to that for the chicken H-protein gene, this region was assigned to the true H-protein gene in human. Primer extension analysis suggested and S1 protection analysis confirmed that at least one additional exon for the 74 bases-long 5' untranslated region in H-protein mRNA exists as the presumable first exon. None of the 5.0- and 5.5-kb SacI and the 5.2-kb EcoRI fragments which were undetectable in the genomes of patients with nonketotic hyperglycinemia was included in the true H-protein gene.     

Allotypes of the constant region of the rabbit T cell receptor beta-2 chain

Our laboratory previously reported that there was restriction fragment length polymorphism of TCR C beta genes in rabbits. EcoRI digests of DNA from different rabbits gave fragments of 9 and 6 kb (C beta a) or 14 and 6 kb (C beta b) that hybridized to a C beta cDNA probe. We also reported that the 9- and 14-kb types segregated as Mendelian traits and that there were allotypic differences in the first exon of the C beta 1 genes of C beta a and C beta b animals. Here we report the DNA sequence of the C beta 2 gene present in the 6-kb EcoRI fragment from a C beta b animal and compare the exon sequences with that of a cDNA from a C beta a animal. We find replacement changes in the first and third exons that probably represent allotypic forms of the rabbit C beta 2 gene. The genomic DNA 5' of exon 1 of both beta 1 and beta 2 contain alternating purine/pyrimidine repeat sequences. The genomic C beta 2 has an open reading frame of 69 amino acids in frame with exon 1 similar to a longer one previously found 5' of exon 1 of C beta 1. Further 5' of this region, rabbit C beta 1 and C beta 2 DNA sequences are only about 66% similar. Both the C beta 1 and C beta 2 sequences have two chi sequences; one in exon 1 with a perfect match and one in the intron downstream of exon 1 with one mismatch. Alternating purine/pyrimidine repeats and chi sequences found in rabbit C beta 1 and C beta 2 genes may have contributed to process(es) of gene duplication and/or conversion.     

Mitochondrial DNA sequence analysis of the cytochrome oxidase subunit II gene from Podospora anserina. A group IA intron with a putative alternative splice site

A 5 kb region of the 95 kb mitochondrial genome of Podospora anserina race s has been mapped and sequenced (1 kb = 10(3) base-pairs). This DNA region is continuous with the sequence for the ND4L and ND5 gene complex in the accompanying paper. We show that this sequence contains the gene for cytochrome oxidase subunit II (COII). This gene is 4 kb in length and is interrupted by a subgroup IB intron (1267 base-pairs (bp) in length) and a subgroup IA intron (1992 bp in length). This group IA intron has a long open reading frame (ORF; 472 amino acid residues) discontinuous with the upstream exon sequence. A putative alternative splice site is present, which brings the ORF into phase with the 5' exon sequence. The 5'- and 3'-flanking regions of the COII gene contain G + C-rich palindromic sequences that resemble similar sequences flanking many Neurospora crassa mitochondrial genes.     

Structure, organization, and regulation of a hamster proline-rich protein gene. A multigene family

Genomic DNA fragments bearing proline-rich protein (PRP) genes expressed specifically in hamster parotid glands have been isolated and characterized. Complete exonic sequences as well as intronic and a considerable portion of the flanking sequences are reported for a PRP gene, H29. H29 is interrupted by three intervening sequences, with consensus splice junctions, and it likely encodes the acidic hamster PRP Hp43a. Exceedingly high homology of the 5'-untranslated region and the sequence encoding the signal peptide is observed with other PRPs of all species studied. Significant homology was also detected among the repetitive sequences of the mature acidic PRPs from human, mouse, hamster, and rat. This conservation of the internal repeats of the PRPs suggested that proline-rich protein gene evolution involved intragenic duplication of internal repeats and gene duplication and conversion. Both hamster and mouse PRP genes (H29 and mouse proline-rich protein gene, respectively) share considerable sequence similarity in the 5'-flanking regions for about 100 base pairs upstream. The remainder of the upstream sequences were heterologous except for three oligonucleotide regions with 60-70% sequence conservation. These three regions are thought to be involved in the regulation of the tissue-specific PRP gene induction.     

Nucleotide sequence of the rat gamma-crystallin gene region and comparison with an orthologous human region

The sequences of a 51-kb region containing the cluster of five rat gamma-crystallin-coding genes (CRYG) and of a 7-kb region surrounding the sixth rat CRYG gene were determined. Approximately 78% of the total sequence represents intergenic DNA. We also sequenced 22 kb of DNA from the human CRYG gene cluster. All CRYG genes are associated with CpG-rich regions. The sequence similarity between the human and rat gene regions drops sharply (to 65%) in intronic and 3'-flanking regions but decreases only gradually in the 5'-flanking region. Highly conserved regions (greater than 80%) are found as far upstream as 1.5 kb. Overall intergenic distances are conserved. The human region contains much more repetitive DNA (24% vs. 10%) but less simple-sequence (sps) DNA (0.7% vs. 4%) than the rat region. Almost all repeats and spsDNA elements are located in the intergenic region. The location of repetitive and spsDNA differs between the orthologous regions and these elements were probably inserted after the evolutionary separation of rat and man. The Alu repeats in man and the B3 repeats in the rat are close copies of their respective consensus sequences and bordered by virtually perfect repeats. In contrast, the B1 and B2 repeats in the rat have diverged considerably from the consensus sequence and the surrounding direct repeats are usually imperfect. Thus the dispersion of the B1 and B2 repeats in the rat probably preceded that of the B3 repeats. Within the rat genomic region the spacing of Z-DNA elements is surprisingly regular, they are located about 12 kb apart. A search for putative matrix-associated regions suggests that the rat CRYG gene cluster is organized into two chromosomal domains.     

Structural organization and complete sequence of the human alpha-N-acetylgalactosaminidase gene: homology with the alpha-galactosidase A gene provides evidence for evolution from a common ancestral gene.

Human alpha-N-acetylgalactosaminidase (alpha-GalNAc; EC 3.2.1.49), the lysosomal glycohydrolase that cleaves alpha-N-acetylgalactosaminyl moieties in glycoconjugates, is encoded by a gene localized to chromosome 22q13----qter. The deficient activity of this enzyme results in Schindler disease, an autosomal recessive disorder characterized by the increased urinary excretion of glycopeptides and oligosaccharides containing alpha-N-acetylgalactosaminyl moieties. Recently, the 3.6-kb full-length alpha-GalNAc cDNA sequence was isolated and found to have remarkable nucleotide and predicted amino acid homology (55.8 and 46.9%, respectively) with the human alpha-galactosidase A (alpha-Gal A) cDNA. To investigate the possible evolutionary relatedness of the two glycosidases, the alpha-GalNAc chromosomal gene was isolated and characterized. Screening of a human genomic DNA cosmid library resulted in the identification of a clone, gAGB-1, with an approximately 35-kb insert that contained the entire alpha-GalNAc gene. A single approximately 15-kb EcoRI fragment of gAGB-1, which contained the complete 3.6-kb cDNA sequence, was digested and the subcloned fragments were sequenced in both orientations. The 13,709-bp alpha-GalNAc gene had nine exons ranging from 95 to 2028 bp and intronic sequences of 304 to 2684 bp. All exon/intron junctions conformed to the GT/AG consensus rule. Analysis of 1.4 kb of 5' flanking sequence revealed three Sp1 and two CAAT-like promoter elements. This region was GC-rich (56%), but no HTF island was identified. The gene contained six Alu-repetitive elements, all in the reverse orientation. Comparison of the structural organization of the alpha-GalNAc and the alpha-Gal A genes revealed that all six alpha-Gal A introns were identically positioned in the homologous alpha-GalNAc exonic sequence. Two additional introns, 1 and 8, were identfied in the alpha-GalNAc gene. The predicted amino acid sequences of alpha-GalNAc exons 2 through 7 and those of corresponding alpha-Gal A exons 1 through 6 were 46.2 to 62.7% identical. In contrast, there was little, if any, similarity between the deduced amino acid sequences of alpha-Gal A exon 7 and alpha-GalNAc exons 8 and 9. The remarkable amino acid identity and the identical exonic interruption by six introns of the alpha-GalNAc and alpha-Gal A genes suggest that this region in both genes is evolutionarily related and arose through duplication and divergence from a common ancestral gene.     

Junctions between genes in the haptoglobin gene cluster of primates.

To investigate the nature of the recombination that generated the haptoglobin three-gene cluster in Old World primates, we sequenced the region between the second gene (HPR) and the third gene (HPP) in chimpanzees (15 kb), as well as the region 3' to the cluster in humans (14 kb). Comparison to the previously sequenced human haptoglobin (HP) and HPR genes showed that the junction point between HP and HPR in humans (junction 1) was not identical to the junction point between the HPR and HPP genes of the chimpanzee (junction 2). An Alu sequence was found at each junction, but both Alu sequences lacked short direct repeats of the flanking genomic DNA. The lack of direct repeats implies that both junction Alu sequences are the products of recombination between different Alu elements. In addition, other insertion and deletion events are clustered in the regions near the junction Alu sequences. The observation that Alu sequences define the junctions between genes in the haptoglobin gene cluster emphasizes the importance of Alu sequences in the evolution of multigene families.