Two nonallelic tRNAiMet genes are located in the p23 leads to q12 region of human chromosome 6

Structural analysis of a bovine arginine tRNA(CCG) gene

A bovine genomic clone containing a 17.4-kb DNA fragment was isolated and found to contain a solitary arginine tRNA gene with an anticodon of CCG that has a 100% identity to its cognate tRNA. This arginine tRNA gene, symbolized as TRR4, has a characteristic internal split promoter and a typical termination site for RNA polymerase III. The tRNA gene was transcribed in vitro by RNA polymerase III using a HeLa cell-free extract to yield a mature-sized tRNA product. The gene was mapped to bovine chromosome 19 using a panel of bovine-rodent somatic cell hybrid DNAs.

An intron-containing tRNAArg gene within a large cluster of human tRNA genes

The insert within lambda Ht363, a recombinant selected from a bank of human genomic DNA cloned in lambda Ch4A, is described. Southern blot hybridization with a mixed tRNA[32P]pCp probe revealed the presence of four tRNA genes, which were shown to represent further copies of genes previously identified as a solitary tRNAGly gene and as a three gene cluster on two different recombinants. In vitro transcription of a fragment containing the three gene cluster revealed the presence of a further pol III gene, which was shown to be that for a tRNAArgTCT. This gene contains a 15 bp intron, the presence of which presumably prevented its detection on Southern blots by tRNA hybridisation. The gene is present in the previously reported cluster and occurs in higher copy number (> 7) in other arrangements in the genome. Most of the copies of the gene have related intron sequences.

The first human genes for tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU) and more tRNA(Val) pseudogenes: expression and pre-tRNA maturation in HeLa cell-free extracts

A functional tRNA(Val) gene, which codes for the major tRNA(ValIAC) isoacceptor species, and three new tRNA(Val) pseudogenes have been isolated from human genomic DNA. Two tRNA(Val) pseudogenes and a tRNA(Val) variant gene were found to be associated with tRNA genes encoding tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU), respectively, on distinct DNA fragments. All tRNA genes, including the pseudogenes, are actively transcribed in HeLa nuclear extract. Pre-tRNAs of tRNA(Val), tRNA(Arg), tRNA(Thr), and tRNA(Gly) genes are correctly processed to mature-sized tRNAs, whereas the three tRNA(Val) pseudogenes yield stable pre-tRNAs in vitro. These findings reveal that, together with the three known pseudogenes, half of the members of the human tRNA(Val) gene family are pseudogenes, all of which are active in homologous nuclear extracts in vitro and presumably also in vivo.

Chromosomal assignment of a large tRNA gene cluster (tRNA(Leu), tRNA(Gln), tRNA(Lys), tRNA(Arg), tRNA(Gly)) to 17p13.1

A cluster of tRNA genes (tRNA(UAGLeu), tRNA(CUGGln), tRNA(UUULys), tRNA(UCUArg)) and an adjacent tRNA(GCCGly) have been assigned to human chromosome 17p12-p13.1 by in situ hybridization using a 4.2 kb human DNA fragment for tRNA(Leu), tRNA(Gln), tRNA(Lys), tRNA(Arg), and, for tRNA(Gly), 1.3 kb and 0.58 kb human DNA fragments containing these genes as probes. This localization was confirmed and refined to 17p13.100-p13.105 using a somatic cell hybrid mapping panel. Preliminary experiments with the biotinylated tRNA Leu, Gln, Lys, Arg probe and metaphase spreads from other great apes suggest the presence of a hybridization site on the long arm of gorilla (Gorilla gorilla) chromosome 19 and the short arm of orangutan (Pongo pygmaeus) chromosome 19 providing further support for homology between HSA17, GGO19 and PPY19.

Regional assignment of 41 human DNA fragments on chromosome 7 by means of a somatic cell hybrid panel

To detect new restriction fragment length polymorphisms that would cover human chromosome 7 with a network of genetic landmarks, a chromosome 7-specific phage gene library was screened for human single-copy fragments. With use of a somatic cell hybrid panel containing defined regions of human chromosome 7, 41 cloned human single-copy sequences were assigned to five regions of this chromosome. Of special importance are the cell hybrid clones GM1059Rag5 and 7851Rag10-1, derived from human cells with interstitial deletions spanning the bands 7q22-q32, within which the cystic fibrosis gene is located. Twelve new probes are described in 7q22-q32, five of which detect a total of six RFLPs.

Genomic organization of the human asparagine transfer RNA genes: localization to the U1 RNA gene and class I pseudogene repeat units

Previously isolated human DNA clones containing asparagine transfer RNA (tRNAAsn) genes have been used to determine the genomic organization of this multigene family in man. One clone also contained a gene for U1 RNA, and so the organization of the two multigene families could be directly compared. The majority, and perhaps all, of the human tRNAAsn genes map to the same chromosome bands as do the U1 RNA true genes and class I pseudogenes located on the short and long arms, respectively, of chromosome 1. These two gene clusters were independently isolated using a somatic-cell hybrid minipanel, and use of repeat-unit DNA polymorphisms showed that one tRNA gene clone maps to the short-arm gene cluster and the other to the long-arm gene cluster. Electron microscopy of heteroduplexes between these two clones showed duplex formation along the proposed region of overlap between them, indicating that the short- and long-arm gene clusters are structurally related. I suggest that the split into two distinct loci was facilitated by a pericentric chromosome inversion. This would have had the effect of positioning the genes currently on the long arm adjacent to the centromeric heterochromatin, perhaps resulting in a "position effect" on transcription of these genes. Restriction fragments of different sizes were found that were common to a majority of repeat units, depending on the restriction enzyme being used. Pulsed-field electrophoresis revealed that fragments of molecular weight of 180 kb were common to each unit (or multiples of units). These fragments also contained U1 RNA gene sequences. I therefore propose that these two gene families are closely linked on repeat units (or multiples of units) of 180 kb in size, which are probably organized in tandem arrays.

Chromosomal assignment of a glutamic acid transfer RNA (tRNAGlu) gene to 1p36

A gene for tRNAGlu has been assigned to human chromosome 1p36 by in situ hybridisation using a [3H]-labelled or biotinylated 2.4-kb (human) DNA fragment containing a tRNAGlu gene as a probe. With the biotinylated DNA probe a secondary statistically significant site of hybridisation was observed at 1q21-22 which might represent a pseudogene or related sequence. In fibroblasts from gorilla (Gorilla gorilla) using biotin labelling, a single site of hybridisation occurred at 1qter which provides further support for homology of 1q in the higher apes and human 1p.

Mapping of human methylmalonyl CoA mutase (MUT) locus on chromosome 6

Methylmalonyl CoA mutase (MCM) catalyzes an essential step in the degradation of several branch-chain amino acids and odd-chain fatty acids. Deficiency of this apoenzyme causes the mut form of methylmalonic acidemia, an often fatal disorder of organic acid metabolism. An MCM cDNA has recently been obtained from human liver cDNA libraries. This clone has been used as a probe to determine the chromosomal location of the MCM gene and MUT locus. Southern blot analysis of DNA from human-hamster somatic-cell hybrid cell lines assigned the locus to region q12-p23 of chromosome 6. In situ hybridization further localized the locus to the region 6p12-21.2. A highly informative RFLP was identified at the MCM gene locus which will be useful for genetic diagnostic and linkage studies.

A human tRNA(iMet) gene produces multiple transcripts

A third nonallelic locus of the human methionyl-tRNA multigene family (tRNA(iMet-3) was isolated. This gene, unlike two other tRNA(iMet) loci, lacks a remarkable run of T and C residues which functions as a termination of transcription signal. Instead, three tandem termination signals, each containing no more than four thymidylate residues, function as relatively inefficient termination signals. As a result, polymerase readthrough generates at least three transcripts in vitro. The efficiency of apparent termination varies significantly at these sites. All resulting transcripts appear to be processed in vitro.

The molecular genetics of human chromosome 6

Chromosome 6 contains several clinically important markers as well as classical enzyme loci, proto-oncogenes, and a growing number of anonymous DNA restriction fragment length polymorphisms (RFLPs). It is also of unique interest because of the location of the major histocompatibility complex (MHC) on the short arm, at 6p21.3. The MHC is one of the most detailed areas of the human genetic map to date and many important diseases, some of a suspected autoimmune aetiology, are associated with it.

A human tRNA(iMet) gene produces multiple transcripts

A third nonallelic locus of the human methionyl-tRNA multigene family (tRNA(iMet-3) was isolated. This gene, unlike two other tRNA(iMet) loci, lacks a remarkable run of T and C residues which functions as a termination of transcription signal. Instead, three tandem termination signals, each containing no more than four thymidylate residues, function as relatively inefficient termination signals. As a result, polymerase readthrough generates at least three transcripts in vitro. The efficiency of apparent termination varies significantly at these sites. All resulting transcripts appear to be processed in vitro.

Assignment of the gene for carboxypeptidase A to human chromosome 7q22----qter and to mouse chromosome 6

A rat cDNA probe for preprocarboxypeptidase A was used to follow the segregation of the human gene for carboxypeptidase A (CPA) in 49 human X mouse somatic cell hybrids using Southern filter hybridization techniques. CPA was assigned to human chromosome 7q22----qter. Similarly, the probe was used to follow the segregation of the mouse gene for carboxypeptidase A (Cpa) in 19 mouse X Chinese hamster somatic cell hybrids. Cpa was assigned to mouse chromosome 6. The gene for carboxypeptidase A forms part of a syntenic group that is conserved in man and mouse.

Chromosomal location of a major tRNA gene cluster of Xenopus laevis

In Xenopus laevis, genes encoding tRNAPhe, tRNATyr, tRNAMet1, tRNAAsn, tRNAAla, tRNALeu, and tRNALys are clustered within a 3.18-kb (kilobase) fragment of DNA. This fragment is tandemly repeated some 150 times in the haploid genome and its components are found outside the repeat only to a limited extent. The fragment hybridizes in situ to a single site very near the telomere on the long arm of one of the acrocentric chromosomes of the group comprising chromosomes 13-18. All the chromosomes of this group also hybridize with DNA coding for oocyte-specific 5S RNA. The tRNA gene cluster is slightly proximal to the cluster of 5S RNA genes.

Chromosomal assignments of human genes for serine proteases trypsin, chymotrypsin B, and elastase

The genes for the serine proteases trypsin, chymotrypsin B, and elastase were chromosomally assigned in man using cDNA probes that have been isolated from a rat pancreatic cDNA library. DNA from human X rodent somatic cell hybrids was cleaved with BamHI or EcoRI and analyzed by Southern filter hybridization methods for the segregation of the genes for trypsin-1 (TRY1), chymotrypsin B (CTRB), and elastase-1 (ELA1). TRY1 was assigned to human chromosome 7q22----qter, CTRB to chromosome 16, and ELA1 to chromosome 12. Although the three genes are members of the same gene family, they are dispersed over different chromosomes.

Chromosomal assignments of genes for trypsin, chymotrypsin B, and elastase in mouse

The mouse genes for the serine proteases trypsin (Try-1), chymotrypsin B (Ctrb), and elastase (Ela-1) were chromosomally assigned using Southern blot hybridization of mouse X Chinese hamster cell hybrid DNA. cDNA probes for the three genes were hybridized to cell hybrid DNA cleaved with BamHI or HindIII and the segregation of Try-1, Ctrb, and Ela-1 was correlated with the segregation of mouse chromosomes. Try-1 is located on chromosome 6, Ctrb is on chromosome 8, and Ela-1 is on chromosome 15. The three genes fall into three syntenic groups that are conserved in the mouse and human genomes.

A human autosomal phosphoglycerate kinase locus maps near the HLA cluster

The human cDNA probe pPGK824 , of Singer-Sam et al. [Singer-Sam, J., Simmer , R. L., Keith, D. H., Shively , L., Teplitz , M., Itakura , K., Gartler , S. M. & Riggs, A. D. (1983) Proc. Natl. Acad. Sci. USA 80, 802-806] was used to isolate a genomic clone lambda PGK-1 containing a portion of an autosomal locus for phosphoglycerate kinase (PGK). A unique sequence subclone (pGK-1) of lambda PGK-1 was then used to map this locus to the region p23-q12 of human autosome 6--i.e., to the interval that contains the major human histocompatibility locus (HLA). Since an autosomal gene coding for testis-specific PGK in the mouse has been shown to be closely linked to the H2 locus and to the T/t-complex locus [ Eicher , E. M., Cherry, M. & Flaherty , L. (1978) Mol. Gen. Genet. 158, 225-228], it is suggested that the lambda PGK-1 recombinant clone contains part of the human gene for the testis-specific isozyme of PGK. In addition, the subcloned pGK-1 detects an EcoRI restriction fragment length variant and may therefore prove useful for further genetical analysis of the HLA region and specifically for testing the hypothesis that spina bifida and anencephaly may be the human equivalent of the murine defects due to the T/t-complex locus. Our findings support the generally held hypothesis that a large number of structural loci clustered around the histocompatibility genes have been conserved in a close linkage association throughout a large evolutionary interval.

DNA restriction fragment length polymorphisms and heterozygosity in the human genome

A list is presented of published reports of DNA polymorphisms found in the human genome by restriction enzyme analysis. While the list indicates the large number of restriction fragment length polymorphisms (RFLPs) detected to date, the information collated is insufficient to permit an estimate of heterozygosity for the genome as a whole. Data from our laboratory are therefore also presented on RFLPs detected using a random sample of cloned DNA segments. Such an analysis has permitted a first unbiassed estimate of heterozygosity for the human genome. Since this figure is an order of magnitude higher than previous estimates derived from protein data, the majority of polymorphic variation present in the human genome must, by implication, occur in noncoding sequences. In addition it was confirmed that enzymes containing the dinucleotide CpG in their recognition sequences detect more polymorphic variation than those that do not contain a CpG. Also presented are the clinical applications of DNA polymorphisms in the diagnosis of human genetic disease.