Ty1 and delta elements occur adjacent to several tRNA genes in yeast

A comparative analysis of a number of yeast DNA-pBR322 recombinant plasmids carrying repetitive sequence elements has revealed that Ty1 or delta elements occur in the vicinity of several tRNA genes. Four examples have been characterized in detail: three glutamate tRNA genes and a serine tRNA gene. The tRNAGlu3 genes occupy different chromosomal locations; two of these genes are found adjacent to Ty1 elements, and the third is found adjacent to an independent delta element. A delta unit is also found adjacent to a tRNASer2 gene. Next to one of the tRNAGlu3 genes, the delta element is joined to a truncated sigma element. Junctions between different delta units were characterized by the sequence analysis of two DNA segments that carry no tRNA genes.     

Three mitochondrial tRNA genes from Arabidopsis thaliana: evidence for the conversion of a tRNAPhe gene into a tRNATyr gene.

Three tRNA genes have been isolated from a genomic library of Arabidopsis thaliana: a tRNASer (GCU), a tRNATyr (GUA) and a tRNAGlu (UUC) genes. These genes are located closely on the same DNA fragment. The tRNASer and the tRNAGlu genes have both 99% sequence similarity with their mitochondrial counterparts from higher plants indicating that these three tRNA genes are mitochondrial. The tRNATyr gene shows a particular high sequence similarity with the mitochondrial tRNAPhe pseudogene from maize, and both genes are flanked by a tRNASer gene in the upstream region. Extensive sequence comparisons of the Arabidopsis thaliana mitochondrial sequence containing the three tRNA genes and the corresponding region from maize and soybean mitochondria have shown evidence that the tRNA Tyr gene has been generated from a mitochondrial tRNAPhe gene. The conversion was accomplished by three genetic events: a 4 base-pair deletion, a mutation and a recombination, which led to the transformation of the acceptor stem and the anticodon.     

The human desmin and vimentin genes are located on different chromosomes

We have used somatic cell hybrids of Chinese hamster X man and mouse X man to localize the genes (des and vim) encoding the intermediate filaments desmin and vimentin in the human genome. Southern blots of DNA prepared from each cell line were screened with hamster cDNA probes specific for des and vim genes, respectively. The single-copy human des gene is located on chromosome 2, and the single-copy human vim gene is assigned to chromosome 10. Partial restriction maps of the two human genomic loci are presented. A possible correlation of the des locus with several reported hereditary myopathies is discussed.     

Assignment of the functional gene for human adrenodoxin to chromosome 11q13----qter and of adrenodoxin pseudogenes to chromosome 20cen----q13.1.

Adrenodoxin is a small iron/sulfur protein serving as an electron-transport intermediate for all mitochondrial forms of cytochrome P450. Southern blots of normal genomic DNA cleaved with six restriction endonucleases probed with full-length human adrenodoxin cDNA revealed complex patterns indicating the presence of multiple adrenodoxin genes. Southern blots of DNA from a panel of mouse/human somatic cell hybrids identified cross-hybridizing adrenodoxin DNA in two loci, chromosome 11q13----qter and chromosome 20cen----q13.1. Examination of adrenodoxin clones from a genomic DNA library in phage lambda revealed some clones bearing gene fragments interrupted by introns and other clones bearing processed pseudogenes. By probing the mouse/human hybrids with unique intronic DNA and by correlating restriction maps of the phage clones with that of uncloned genomic DNA, we show that the authentic transcribed adrenodoxin gene lies on chromosome 11, while pseudogenes lie on chromosome 20.     

Characterization of the gene for human plasminogen, a key proenzyme in the fibrinolytic system

The organization and structure of the gene coding for plasminogen has been determined by a combination of in vitro amplification of leukocyte DNA from normal individuals and isolation of unique clones from three different human genomic libraries. These clones were characterized by restriction mapping, Southern blotting, and DNA sequencing. The gene for human plasminogen spanned about 52.5 kilobases of DNA and consisted of 19 exons separated by 18 introns. DNA sequence analysis revealed that the five kringle structures in plasminogen were coded by two exons. The nucleotides in the introns at the intron-exon boundaries were GT-AG analogous to those found in other eukaryotic genes. Three polyadenylation sites for plasminogen mRNA were also identified. When the amino acid sequences deduced from the genomic DNA and cDNAs of plasminogen were compared with that of the plasma protein determined by amino acid sequence analysis, an apparent amino acid polymorphism was observed in several positions of the polypeptide chain. Nucleotide sequence analysis of the amplified genomic DNAs and genomic clones also revealed that the plasminogen gene was very closely related to several other proteins, including apolipoprotein(a). This protein may have evolved via duplication and exon shuffling of the plasminogen gene. The presence of another plasminogen-related gene(s) in the human genomic library was also observed.     

Discrimination among the human beta A, beta S, and beta C-globin genes using allele-specific oligonucleotide hybridization probes.

Synthetic nonadecanucleotides complementary to the human beta A-, beta S-, or beta C-globin sequences were used as hybridization probes to screen human genomic DNA samples for these genes. The oligonucleotides were 32P-labeled and used as probes to genotype restriction endonuclease digests of human genomic DNA. The data obtained show that hybridization with oligonucleotide probes, unlike restriction fragment length polymorphism (RFLP) analysis or direct restriction enzyme digestion, can be used to directly distinguish among the three alleles of beta-globin, beta A, beta S, and beta C, when present either in one (heterozygous) or two copies.     

A physical map of two clusters containing the genes for six proinflammatory receptors

The genes encoding for six receptors involved in the proinflammatory response lie on different chromosomes. Two receptors for N-formylpeptides (FPR1, FPR2), one homologue of these (FPRL2), and the receptor for complement fragment C5a (C5aR) are encoded by four genes mapped to human chromosome 19. The genes encoding two receptors for Interleukin-8 (IL8RA, IL8RB) have been located on human chromosome 2. In this report we describe the physical linkage between these genes in two different clusters. DNA fragments obtained by digestion with several restriction enzymes were separated by pulsed field gel electrophoresis. Nylon filters were hybridized with probes corresponding to the complete translated sequences of these genes. These probes were obtained from a human neutrophil cDNA-library. The four genes on chromosome 19 are contained in a 200 kilobase (kb) fragment. Both Interleukin-8 receptors are on a 150 kb fragment. The complete translated sequences for these genes were amplified from genomic DNA, indicating that they are contained in a single exon.The contributions of the first two authors to this research was equal     

Structure and organization of the human transglutaminase 1 gene.

Membrane-associated transglutaminases (TGase1) have recently been found to be common in mammalian cells, but it is not clear whether these derive from the same or different genes. In order to determine the complexity of this system, we have isolated and characterized the human gene (TGM1). The gene of 14,133 base pairs was found to contain 15 exons spliced by 14 introns. Interestingly, the positions of these introns have been conserved in comparison with the genes of two other transglutaminase-like activities described in the literature, but the TGM1 gene is by far the smallest characterized to date because its introns are relatively smaller. On the other hand, the TGase1 enzyme is the largest known transglutaminase (about 90 kDa), apparently because its gene acquired tracts that encode additional sequences on its amino and carboxyl termini that confer its unique properties. Southern blot analyses of total human genomic DNA cut with several restriction enzymes reveal only one band. Use of human-rodent cell hybrid panels and chromosomal in situ hybridization with biotin-labeled probes revealed that the human TGM1 gene maps to chromosome position 14q11.2-13. Such data suggest there is a single gene copy per haploid human genome. Comparisons of sequence identities and homologies indicate that the transglutaminase family of genes arose by duplications and subsequent divergent evolution from a common ancestor but later became scattered in the human genome. Although our present Southern blot and chromosomal localization studies revealed no restriction fragment length polymorphisms, comparisons of published sequences and our genomic clone indicate there are two sequence variants for TGase1 within the human population. The rare smaller variant contains a two-nucleotide deletion near the 5'-end, uses an alternate initiation codon, and differs from the common larger variant only in the first 15 amino acids. Furthermore, the DNA sequences of intron 14 possess several tracts of dinucleotide repeats that by polymerase chain reaction analysis show wide size polymorphism within the human population. Accordingly, this gene system constitutes a useful polymorphic marker for genetic linkage analyses.     

Structure and expression of the human cystatin C gene.

The structural organization of the gene for the human cysteine-proteinase inhibitor cystatin C was studied. Restriction-endonuclease digests of human genomic DNA hybridized with human cystatin C cDNA and genomic probes produced patterns consistent with a single cystatin C gene and, also, the presence of six closely related sequences in the human genome. A 30 kb restriction map covering the genomic region of the cystatin C gene was constructed. The positions of three polymorphic restriction sites, found at examination of digests of genomic DNA from 79 subjects, were localized in the flanking regions of the gene. The gene was cloned and the nucleotide sequence of a 7.3 kb genomic segment was determined, containing the three exons of the cystatin C structural gene as well as 1.0 kb of 5'-flanking and 2.0 kb of 3'-flanking sequences. Northern-blot experiments revealed that the cystatin C gene is expressed in every human tissue examined, including kidney, liver, pancreas, intestine, stomach, antrum, lung and placenta. The highest cystatin C expression was seen in seminal vesicles. The apparently non-tissue-specific expression of this cysteine-proteinase inhibitor gene is discussed with respect to the structure of its 5'-flanking region, which shares several features with those of housekeeping genes.     

Characterization of a rat tRNA gene cluster containing the genes for tRNAAsp, tRNAGly and tRNAGlu, and pseudogenes.

The putative genes for tRNAGAUAsp(C), tRNAGGAGly(G) and tRNAGAGGlu are in a cluster on the rat chromosome and are present exclusively in a 3.3 kb region cleaved with a restriction endonuclease EcoRI. The cluster reiterates about 10 times on the haploid DNA. Four lambda clones each containing an independent repeating unit were isolated from a rat gene library. The studies on the cloned DNA revealed that the length of the repeating unit including the 3.3 kb EcoRI fragment was at least 13.5 kb. Nucleotide sequence analysis of the 3.3 kb DNA in the isolated clones showed sequence variations among the repeating units and incomplete genes for tRNAGly and tRNAGlu within the clusters.     

Physical map of the Myxococcus xanthus chromosome.

The genome of Myxococcus xanthus, which is 9,454 kbp, is one of the largest bacterial genomes. The organization of the DNA and the distribution of genes encoding social and developmental behaviors were examined by using pulsed field gel electrophoresis. Intact genomic DNA was digested with AseI into 16 restriction fragments, which were separated by contour-clamped homogeneous electric field electrophoresis, purified, and radiolabeled. Each AseI fragment was hybridized to SpeI-digested DNA and to an M. xanthus genomic library contained in yeast artificial chromosomes. Some SpeI restriction fragments and yeast artificial chromosome clones contained AseI sites and hybridized with two different AseI restriction fragments, providing evidence for the juxtaposition of these AseI restriction fragments in the chromosome. The deduced AseI physical map is circular, suggesting that this bacterium contains a single, circular chromosome. Transposable elements shown by transduction to be in or near genes of interest were located on specific AseI restriction fragments by restriction analysis and Southern hybridization. Most AseI restriction fragments contained genes involved in social and developmental behaviors.     

Structure and restriction fragment length polymorphism of genes for human liver arylamine N-acetyltransferases.

Genomic DNA clones coding for polymorphic and monomorphic arylamine N-acetyltransferases (NAT) of human liver were isolated from a genomic DNA library, and their restriction maps and partial nucleotide sequences were determined. Messenger RNA for monomorphic NAT was coded in one exon, while mRNA for polymorphic NAT was coded in two exons; the 5'-noncoding region was located in one exon 8 kb upstream from another exon containing the coding and 3'-noncoding regions. Recently, we have shown that there are three types of polymorphic NAT gene; one of the genes corresponds to a high NAT activity, while the other two genes give rise to a low NAT activity. The restriction fragment length polymorphism (RFLP) was analyzed by Southern blot hybridization of genomic DNAs from homozygotes of the three polymorphic NAT genes using various fragments of the cloned NAT gene. RFLPs of polymorphic NAT gene were observed in coding and 3'-flanking region upon digestion with BamHI and KpnI.