Toward a cDNA map of the human genome

Advances in the Human Genome Project are shaping the strategies for identifying the 50,000-100,000 human genes. High-resolution genetic maps of the human genome combined with sequencing herald an era of rapid regional definition of disease genes. However, only once their chromosome band location is known will the systematic partial sequencing of thousands of random cDNA clones provide the reagents for teh rapid assessment of the genes responsible for the inherited disorders. We now present an approach to the rapid determination of map position and therefore to the creation of a transcribed map of the human genome. Sensitive fluorescence in situ hybridization has been combined with high-resolution chromosome banding and random cDNA sequencing to map 41 cDNAs with an average insert size of <2 kb to single human chromosome bands. The result provide 15 new genes, with database and functional information, as candidates for human disease. These include the large extracellular signal-related kinase (HUMERK), the ERK activator kinase (PRKMK1), a new member of the RAS oncogene family, protein phosphatase 2 regulatory subunit B alpha isoform (PPP2R2A), and a novel human gene with very high homology to a plant membrane transport family. Further, an analysis of expressed genes associated with pseudogenes showed that by using these techniques, it is possible to detect accurately the transcribed locus within a multigene or processed pseudogene family in most cases. These findings suggest that direct cDNA mapping using fluorescence in situ hybridization provides an accurate and rapid approach to the definition of a transcribed map of the human genome. This low-cost, high-resolution (2-5 Mb) mapping greatly enhances the speed with which these genes can be subsequently assigned to contigs. This assignment provides a necessary first step in understanding the relationship of the genes to both acquired and inherited human diseases.     

Substitution of the human beta-spectrin promoter for the human agamma-globin promoter prevents silencing of a linked human beta-globin gene in transgenic mice

During development, changes occur in both the sites of erythropoiesis and the globin genes expressed at each developmental stage. Previous work has shown that high-level expression of human beta-like globin genes in transgenic mice requires the presence of the locus control region (LCR). Models of hemoglobin switching propose that the LCR and/or stage-specific elements interact with globin gene sequences to activate specific genes in erythroid cells. To test these models, we generated transgenic mice which contain the human Agamma-globin gene linked to a 576-bp fragment containing the human beta-spectrin promoter. In these mice, the beta-spectrin Agamma-globin (betasp/Agamma) transgene was expressed at high levels in erythroid cells throughout development. Transgenic mice containing a 40-kb cosmid construct with the micro-LCR, betasp/Agamma-, psibeta-, delta-, and beta-globin genes showed no developmental switching and expressed both human gamma- and beta-globin mRNAs in erythroid cells throughout development. Mice containing control cosmids with the Agamma-globin gene promoter showed developmental switching and expressed Agamma-globin mRNA in yolk sac and fetal liver erythroid cells and beta-globin mRNA in fetal liver and adult erythroid cells. Our results suggest that replacement of the gamma-globin promoter with the beta-spectrin promoter allows the expression of the beta-globin gene. We conclude that the gamma-globin promoter is necessary and sufficient to suppress the expression of the beta-globin gene in yolk sac erythroid cells.     

Gene structure of the human MHC region

The human major histocompatibility complex (MHC) encodes the highly polymorphic human leukocyte antigens (HLA) responsible for antigen presentation to T cells. The HLA gene complex is located on the short arm of chromosome 6 within 6p21.3 and covers a distance of about 4,000 kb that has arisen through repeated gene duplication and conversion during evolution. The HLA class I region is about 2,000 kb in size, while the class II region is about 1,000 kb. The remainder comprises the HLA class III region. There are presently 19 HLA or HLA-like expressed genes and about 80 non-HLA expressed genes as well as 27 pseudogenes or gene fragments localized within the HLA region, although the function of most of these genes is still uncertain. This paper provides a comprehensive overview of non-HLA genes as well as HLA genes which are so far identified in this region.     

Genetic mapping of the human and mouse phospholipase C genes

To determine chromosome positions for 10 mouse phospholipase C (PLC) genes, we typed the progeny of two sets of genetic crosses for inheritance of restriction enzyme polymorphisms of each PLC. Four mouse chromosomes, Chr 1, 11, 12, and 19, contained single PLC genes. Four PLC loci, Plcb1, Plcb2, Plcb4, and Plcg1, mapped to three sites on distal mouse Chr 2. Two PLC genes, Plcd1 and Plcg2, mapped to distinct sites on Chr 8. We mapped the human homologs of eight of these genes to six chromosomes by analysis of human x rodent somatic cell hybrids. The map locations of seven of these genes were consistent with previously defined regions of conserved synteny; Plcd1 defines a new region of homology between human Chr 3 and mouse Chr 8.     

The human histone gene cluster at the D6S105 locus

The sequences and organization of the histone genes in the histone gene cluster at the chromosomal marker D6S105 have been determined by analyzing the Centre d'Etude du Polymorphisme Humain yeast artificial chromosome (YAC) 964f1. The insert of the YAC was subcloned in cosmids. In the established contig of the histone-gene-containing cosmids, 16 histone genes and 2 pseudogenes were identified: one H1 gene (H1.5), five H2A genes, four H2B genes and one pseudogene of H2B, three H3 genes, and three H4 genes plus one H4 pseudogene. The cluster extends about 80 kb with a nonordered arrangement of the histone genes. The dinucleotide repeat polymorphic marker D6S105 was localized at the telomeric end of this histone gene cluster. Almost all human histone genes isolated until now have been localized within this histone gene cluster and within the previously described region of histone genes, about 2 Mb telomeric of the newly described cluster or in a small group of histone genes on chromosome 1. We therefore conclude that the data presented here complete the set of human histone genes. This now allows the general organization of the human histone gene complement to be outlined on the basis of a compilation of all known histone gene clusters and solitary histone genes.     

Chromosomal localization of the human and mouse hyaluronan synthase genes

We have recently identified a new vertebrate gene family encoding putative hyaluronan (HA) synthases. Three highly conserved related genes have been identified, designated HAS1, HAS2, and HAS3 in humans and Has1, Has2, and Has3 in the mouse. All three genes encode predicted plasma membrane proteins with multiple transmembrane domains and approximately 25% amino acid sequence identity to the Streptococcus pyogenes HA synthase, HasA. Furthermore, expression of any one HAS gene in transfected mammalian cells leads to high levels of HA biosynthesis. We now report the chromosomal localization of the three HAS genes in human and in mouse. The genes localized to three different positions within both the human and the mouse genomes. HAS1 was localized to the human chromosome 19q13.3-q13.4 boundary and Has1 to mouse Chr 17.HAS2 was localized to human chromosome 8q24.12 and Has2 to mouse Chr 15. HAS3 was localized to human chromosome 16q22.1 and Has3 to mouse Chr 8. The map position for HAS1 reinforces the recently reported relationship between a small region of human chromosome 19q and proximal mouse chromosome 17. HAS2 mapped outside the predicted critical region delineated for the Langer-Giedion syndrome and can thus be excluded as a candidate gene for this genetic syndrome.     

Regulation of human globin gene expression in mouse erythroleukemia x human fibroblast hybrid cells

A somatic cell hybrid, XX-8, was obtained from a fusion of tetraploid mouse erythroleukemia cells with human Lesch-Nyhan skin fibroblasts. This hybrid cell was previously shown (1) to produce human beta- but no human gamma-globin mRNA sequences after induction with dimethylsulfoxide. In this study we show that: (a) human beta- and gamma-globin genes are present in XX-8 cells in approximately equal numbers; (b) no human gamma-globin mRNA sequences can be detected in either the cytoplasmic or nuclear RNA fractions even with several different inducers; (c) after induction the human beta-globin gene is converted from a DNase I insensitive or closed structure to a DNase I open configuration, while the human gamma-globin gene remains closed; and (d) no human beta-globin polypeptide can be detected in the intact induced cells, indicating that fibroblast globin genes, even when induced to make mRNA in an erythroid environment, do not synthesize an RNA that is translated efficiently.     

Frequency of Smad gene mutations in human cancers

Much excitement has recently been generated by the discovery of the Smad genes, encoding proteins that transduce signals from the transforming growth factor beta family of cytokines. Here, we report the completion of cloning of the six known human Smads, providing novel sequences for Smad5 and Smad6. Previously, Smad4 and Smad2 were shown to be mutated in human cancers. However, analysis of the other four Smad genes revealed no mutations in a total of 167 tumors, including those from colon, breast, lung, and pancreas. These results suggest that the various Smad genes have different functions and demonstrate that mutations in these four genes do not, in general, account for the widespread resistance to transforming growth factor beta that is found in human tumors.     

Structure and chromosome mapping of the human small maf-genes MAFG and MAFK

The newly emerged Maf family proteins possess a highly conserved basic leucine zipper (bZip) domain in common and are subdivided into large and small Maf proteins. The Maf family proteins appear to regulate cell differentiation processes and also cellular functions as partner molecules of CNC family proteins. To facilitate understanding of the function of small Maf proteins, we isolated the genes (MAFG and MAFK) encoding human small Maf proteins MafG and MafK and characterized their structures and organization by means of restriction enzyme mapping, Southern blot hybridization and nucleotide sequence analysis. Organization of the small maf genes are highly conserved in vertebrates, suggesting an important functional contribution of the gene products. We also examined the location of these genes within the human genome by fluorescence in situ hybridization (FISH) analysis. Human MAFG and MAFK are located at 17q25 and 7p22, respectively. Thus, small maf genes are not clustered in a single locus.     

Triplex targets in the human rhodopsin gene

We have explored the application of triplex technology to the human rhodopsin gene, which encodes a G-protein-linked receptor involved in the genetic disorder autosomal dominant retinitis pigmentosa (ADRP). Our results support the hypothesis that most human genes contain high-affinity triplex sites and further refine the rules governing identification and successful targeting of triplex-forming oligonucleotides (TFOs) to these sites. Using a computer search for sites 15 nucleotides in length and greater than 80% purine, we found 143 distinct sites in the rhodopsin gene and comparable numbers of sites in several other human genes. By applying more stringent criteria, we selected 17 potential target sites in the rhodopsin gene, screened them with a plasmid binding assay, and found 8 that bound TFOs with submicromolar affinity (Kd = 10(-)9-10(-)7 M). We compared purine (GA) and mixed (GT) TFOs at each site, and found that GA-TFOs consistently bound with higher affinity, and were less sensitive to pyrimidine interruptions in the target strand. High G-content favored high-affinity binding; only sites with >54% G-content bound TFOs with Kd 相似文献   

The human obesity gene map: the 1997 update

An update of the human obesity gene map incorporating published results up to October 1997 is presented. Evidence from Mendelian disorders exhibiting obesity as a clinical feature; single-gene mutation rodent models; quantitative trait loci uncovered in human genome-wide scans and in crossbreeding experiments with mouse, rat, and pig models; association and case-control studies with candidate genes; and linkage studies with genes and other markers is reviewed. All chromosomal locations of the animal loci are converted into human genome locations based on syntenic relationships between the genomes. A complete listing of all of these loci reveals that all but chromosome Y of the 24 human chromosomes are represented. Some chromosomes show at least three putative loci related to obesity on both arms (1, 2, 6, 8, 11, and 20) and several on one chromosome arm only (3p, 4q, 5q, 7q, 12q, 13q, 15q, 15p, 22q, and Xq). Studies reporting negative association and linkage results are also listed, with the exception of the unlinked markers from genome-wide scans.     

Number of CpG islands and genes in human and mouse

Estimation of gene number in mammals is difficult due to the high proportion of noncoding DNA within the nucleus. In this study, we provide a direct measurement of the number of genes in human and mouse. We have taken advantage of the fact that many mammalian genes are associated with CpG islands whose distinctive properties allow their physical separation from bulk DNA. Our results suggest that there are approximately 45,000 CpG islands per haploid genome in humans and 37,000 in the mouse. Sequence comparison confirms that about 20% of the human CpG islands are absent from the homologous mouse genes. Analysis of a selection of genes suggests that both human and mouse are losing CpG islands over evolutionary time due to de novo methylation in the germ line followed by CpG loss through mutation. This process appears to be more rapid in rodents. Combining the number of CpG islands with the proportion of island-associated genes, we estimate that the total number of genes per haploid genome is approximately 80,000 in both organisms.     

Comparative mapping of 9 human chromosome 22q loci in the laboratory mouse

We present a comparative map of genes on human chromosome 22q and homologous loci in the mouse genome. Gene order in humans was established using a panel of somatic cell hybrids. Genetic maps spanning homologous segments on three mouse chromosomes were generated using an interspecific backcross. The conserved linkage between human chromosome 22 and mouse chromosome 16 includes two closely linked loci, Comt and IgI-1. The second conserved linkage involves human chromosome 22 and mouse chromosome 11 and contains two genetically and physically linked loci, Lif and Nfh. Finally, conserved synteny involving mouse chromosome 15 and human chromosome 22 spans 30 cM and contains five loci (Acr, Bzrp, Dia-1, Il2rb and Pdgfb). Loci within this conserved synteny have been sublocalized to different portions of human chromosome 22. The order of genes on mouse chromosome 15 and human chromosome 22 provides further evidence for chromosomal rearrangements within the conserved synteny that have occurred since the divergence of lineages leading to mice and humans.