Yeast RAD14 and human xeroderma pigmentosum group A DNA-repair genes encode homologous proteins.

Xeroderma pigmentosum (XP), a human autosomal recessive disorder, is characterized by extreme sensitivity to sunlight and high incidence of skin cancers. XP cells are defective in the incision step of excision repair of DNA damaged by ultraviolet light. Cell fusion studies have defined seven XP complementation groups, XP-A to XP-G. Similar genetic complexity of excision repair is observed in the yeast Saccharomyces cerevisiae. Mutations in any one of five yeast genes, RAD1, RAD2, RAD3, RAD4, and RAD10, cause a total defect in incision and an extreme sensitivity to ultraviolet light. Here we report the characterization of the yeast RAD14 gene. The available rad14 point mutant is only moderately ultraviolet-sensitive, and it performs a substantial amount of incision of damaged DNA. Our studies with the rad14 deletion (delta) mutation indicate an absolute requirement of RAD14 in incision. RAD14 encodes a highly hydrophilic protein of 247 amino acids containing zinc-finger motifs, and it is similar to the protein encoded by the human XPAC gene that complements XP group A cell lines.     

Isolation of UV-resistant revertants from a xeroderma pigmentosum complementation group A cell line

Xeroderma pigmentosum (XP) is an autosomal recessive disease. Cells cultured from XP patients are hypersensitive to the lethal effects of UV light. Most XP cells are defective in an early stage in DNA repair of UV light-induced damage. The nature of the genetic defect of the XP syndrome has not been defined. To address this problem, we attempted to isolate UV-resistant cells from a cell line derived from an XP complementation group A (XPA) patient. By using a selection scheme capable of detecting one UV-resistant cell in a population of 10(8) cells, several UV-resistant clones were isolated at frequencies between 1 X 10(-7) and 2 X 10(-8). Here we describe the isolation and initial characterization of these phenotypic revertants.     

新的人羧肽酶A抑制物cDNA的克隆、定位和表达谱分析

从人的胎脑cDNA文库中,克隆到一条全新的人类羧肽酶A抑制物基因,此cDNA序列全长1049bp,包括翻译起始位点附近的Kozak序列,669bp 的开放读框以及3端的加尾信号,共编码222个氨基酸,它编码的蛋白与小鼠Latexin蛋白和大鼠Latexin蛋白分别有高达85％和84％的同源性,因此命名为人类LATEXIN基因,应用辐射杂交方法,将该基因伫位在人3号染色体3q24区段,位于分子标记D3S1605和D3S1553之间,采用基因芯片杂交的方法研究其在某些组织或细胞中的表达情况,发现在前列腺癌中表达量较高。     

Isolation of a cDNA clone corresponding to an X-linked gene family (XLR) closely linked to the murine immunodeficiency disorder xid

The striking number of human and murine immunodeficiency disorders which map to the X chromosome suggests that genes localized on this chromosome must have important roles in lymphocyte development. At least seven distinct disorders in the human and two in the mouse disrupt lymphocyte maturation, particularly that of B cells, at characteristic stages. As functional genes mapping to the X chromosome in one mammal are found on the X chromosome in all other mammals, the same genes regulating lymphocyte development are expected to be found on the X chromosome in mouse and man. Investigations into the possible mechanisms of these X-linked disorders have been hampered by the lack of molecular probes for the genes or gene products affected; because of this, and the possibility of correlating one or more of the several hundred B- or T-cell-specific genes with a specific mutation, we surveyed 15 different B- and T-cell-specific cDNA clones for localization to the X chromosome. We report here the characterization of one of these murine cDNA clones, which hybridizes with a large, X-linked gene family, designated XLR (X-linked, lymphocyte-regulated). We show that the XLR gene family is closely linked to the X-linked immunodeficiency described in the CBA/N mouse strain (xid), by restriction fragment length polymorphism (RFLP) analysis of DNA from mice congeneic for xid. This finding, together with data on the expression of the XLR locus in B cells, indicates that this gene family either includes the locus defined by the xid mutation or is adjacent to it in a gene complex which may be important in lymphocyte differentiation.     

The human T-cell receptor alpha-chain gene maps to chromosome 14

The T-cell receptor for antigen has been identified as a disulphide-linked heterodimeric glycoprotein of relative molecular mass (Mr) 90,000 comprising an alpha- and a beta-chain. The availability of complementary DNA clones encoding mouse and human beta-chains has allowed a detailed characterization of the genomic organization of the beta-chain gene family and has revealed that functional beta-chain genes in T cells are generated from recombination events involving variable (V), diversity (D), joining (J) and constant (C) gene segments. Recently, cDNA clones encoding mouse and human alpha-chains have been described; the sequences of these clones have indicated that functional alpha-chain genes are also generated from multiple gene segments. It is possible that chromosomal translocations involving T-cell receptor alpha- and beta-chain genes have a role in T-cell neoplasms in much the same way as translocations involving immunoglobulin genes are associated with oncogenic transformation in B cells. In the latter case, the chromosomal localization of the immunoglobulin genes provided one of the first indications of the involvement of such translocations in oncogenic transformation. The chromosomal assignment of the alpha- and beta-chain genes may, therefore, provide equally important clues for T-cell neoplastic transformation. The chromosomal location of the mouse and human beta-chain gene family has been determined: the murine gene lies on chromosome 6 (refs 12, 13) whereas the human gene is located on chromosome 7 (refs 13, 14). Here we use a cDNA clone encoding the human alph-chain to map the corresponding gene to chromosome 14.     

Molecular identification of a human DNA repair gene following DNA-mediated gene transfer

Although it has long been evident that the response of eukaryotes to DNA damaging agents is determined by the effectiveness of a variety of DNA repair systems, there is little detailed knowledge of the nature of these systems or the genes which control them. In humans, a number of hereditary conditions, including xeroderma pigmentosum, ataxia telangiectasia and Fanconi's anaemia, exhibit increased sensitivity to a variety of DNA damaging agents and a predisposition to cancer, suggesting a defect in some aspect of DNA repair. This report describes the identification of a human DNA repair gene following DNA-mediated gene transfer into Chinese hamster ovary (CHO) mutant cells, that like xeroderma pigmentosum cells, are sensitive to a variety of DNA damaging agents and are defective in the initial incision step of DNA repair. The resulting transformants exhibit normal resistance to DNA damaging agents and independent transformants demonstrate a common set of human DNA sequences associated with a human DNA repair gene. These observations provide the basis for the isolation and characterization of the human genes responsible for DNA repair.     

The mapping of a cDNA from the human X-linked Duchenne muscular dystrophy gene to the mouse X chromosome

The recent discovery of sequences at the site of the Duchenne muscular dystrophy (DMD) gene in humans has opened up the possibility of a detailed molecular analysis of the genes in humans and in related mammalian species. Until relatively recently, there was no obvious mouse model of this genetic disease for the development of therapeutic strategies. The identification of a mouse X-linked mutant showing muscular dystrophy, mdx, has provided a candidate mouse genetic homologue to the DMD locus; the relatively mild pathological features of mdx suggest it may have more in common with mutations of the Becker muscular dystrophy type at the same human locus, however. But the close genetic linkage of mdx to G6PD and Hprt on the mouse X chromosome, coupled with its comparatively mild pathology, have suggested that the mdx mutation may instead correspond to Emery Dreifuss muscular dystrophy which itself is closely linked to DNA markers at Xq28-qter in the region of G6PD on the human X chromosome. Using an interspecific mouse domesticus/spretus cross, segregating for a variety of markers on the mouse X chromosome, we have positioned on the mouse X chromosome sequences homologous to a DMD cDNA clone. These sequences map provocatively close to the mdx mutation and unexpectedly distant from sparse fur, spf, the mouse homologue of OTC (ornithine transcarbamylase) which is closely linked to DMD on the human X chromosome.     

Retinal degeneration in the rd mouse is caused by a defect in the beta subunit of rod cGMP-phosphodiesterase

Mice homozygous for the rd mutation display hereditary retinal degeneration and the classic rd lines serve as a model for human retinitis pigmentosa. In affected animals the retinal rod photoreceptor cells begin degenerating at about postnatal day 8, and by four weeks no photoreceptors are left. Degeneration is preceded by accumulation of cyclic GMP in the retina and is correlated with deficient activity of the rod photoreceptor cGMP-phosphodiesterase. We have recently isolated a candidate complementary DNA for the rd gene from a mouse retinal library and completed the characterization of cDNAs encoding all subunits of bovine photoreceptor phosphodiesterase. The candidate cDNA shows strong homology with a cDNA encoding the bovine phosphodiesterase beta subunit. Here we present evidence that the candidate cDNA is the murine homologue of bovine phosphodiesterase beta cDNA. We conclude that the mouse rd locus encodes the rod photoreceptor cGMP-phosphodiesterase beta subunit.     

一个犬凝集素基因VIP36的人类同源基因cDNA的克隆、染色体定位和表达谱分析

从人的胎脑cDNA文库中克隆到一条犬凝集素基因VIP36的人类同源基因,此cDNA序列全长2430bp,拟编码一个382个氨基酸残基的蛋白,它编码的蛋白与犬VIP36有52％的同源性,因此将其命名为人类VIP36L基因,应用辐射杂交方法,钭该基因定位在人2号染色体的分子标记D2S388和D2S113之间,采用基因芯片杂交的方法研究其表达谱情况,发现该基因在胎皮和肝癌组织中表达量较高。     

Reciprocal chromosome translocation between c-myc and immunoglobulin gamma 2b genes

Specific chromosome translocations have been observed in transformed cell lines of both man and mouse and may be implicated in the origin or maintenance of malignancy. In mouse plasmacytomas, translocations have been identified that bring the immunoglobulin alpha heavy-chain gene (C alpha, normally located on chromosome 12) into proximity with c-myc (normally located on chromosome 15), c-myc being the mouse cellular homologue of the avian myelocytomatosis virus transforming gene (v-myc). Here we identify a DNA rearrangement in a mouse hybridoma that has brought c-myc close to C gamma 2b and show that this rearrangement occurred by reciprocal chromosome translocation, as recombinant clones were isolated from the same cell line in which a rearranged variable-region (VH) gene has been brought close to 5' c-myc sequences. The translocation has resulted in the net loss of 7 base pairs (bp) of chromosome 15 sequence as well as in the presence of an additional base of unknown provenance. This reciprocal translocation was analysed in DNA from a mouse hybridoma cell line but is shown to be characteristic of the X63Ag8 myeloma parent.     

一条在人睾丸中高表达的新的环指蛋白(RNF20)

从人胎脑构建的cDNA文库中,通过大规模测序筛选的方法获得一条新基因,该基因蛋白序列含有1个环指（RING finger)基序及2个进核信号（nuclear localization signal NLS)序列,钭此基因命名为RNF20（RING Finger 20),用放射杂交细胞系（Radial hybrid RH)方法定位此基因在人染色体的9q22上,Northern杂交表明,其mRNA在睾丸组织中高表达,用小鼠睾丸做原位杂交表明,小鼠的同源基因在精原细胞及初级精母细胞中高表达,未成年小鼠睾丸中的精原细胞没有发达,提示RNF20可能参与精子发生的调控作用。     

Ryanodine receptor gene is a candidate for predisposition to malignant hyperthermia

Malignant hyperthermia (MH) is a potentially lethal condition in which sustained muscle contracture, with attendant hypercatabolic reactions and elevation in body temperature, are triggered by commonly used inhalational anaesthetics and skeletal muscle relaxants. In humans, the trait is usually inherited in an autosomal dominant fashion, but in halothane-sensitive pigs with a similar phenotype, inheritance of the disease is autosomal recessive or co-dominant. A simple and accurate non-invasive test for the gene is not available and predisposition to the disease is currently determined through a halothane- and/or caffeine-induced contracture test on a skeletal muscle biopsy. Because Ca2+ is the chief regulator of muscle contraction and metabolism, the primary defect in MH is believed to lie in Ca2+ regulation. Indeed, several studies indicate a defect in the Ca2+ release channel of the sarcoplasmic reticulum, making it a prime candidate for the altered gene product in predisposed individuals. We have recently cloned complementary DNA and genomic DNA encoding the human ryanodine receptor (the Ca2(+)-release channel of the sarcoplasmic reticulum) and mapped the ryanodine receptor gene (RYR) to region q13.1 of human chromosome 19 (ref. 14), in close proximity to genetic markers that have been shown to map near the MH susceptibility locus in humans and the halothane-sensitive gene in pigs. As a more definitive test of whether the RYR gene is a candidate gene for the human MH phenotype, we have carried out a linkage study with MH families to determine whether the MH phenotype segregates with chromosome 19q markers, including markers in the RYR gene. Co-segregation of MH with RYR markers, resulting in a lod score of 4.20 at a linkage distance of zero centimorgans, indicates that MH is likely to be caused by mutations in the RYR gene.     

人原肌球蛋白结合蛋白3(TMOD3)cDNA的克隆及功能初步分析

从人的胎脑cDNA文库到中克隆到1条人原肌球蛋白结合蛋白3（TMOD3）基因,该基因cDNA序列长1402bp,可以编码352个氨基酸残基组成的蛋白,与大鼠,果蝇和线虫的原肌球结合蛋白同源性分别为82％,41％和35％,TMOD3基因定位在人15q21.1-q21.2,位于遗传位标D15S146和D15S117之间,采用基因芯片杂交的方法研究其表达谱概况,发现该基因在多种,组织和细胞中均表达。     

Comparison of transformation efficiency of human active and inactive X-chromosomal DNA

The mechanism of X-chromosome inactivation has been investigated recently using DNA-mediated transformation of the X-linked hypoxanthine phosphoribosyl transferase (hprt) locus. Several experiments indicate that inactive X-chromosomal DNA does not function in HPRT transformation. Liskay and Evans used DNA from hamster or mouse cells which had an hprt- allele on the active X chromosome and an hprt+ allele on the inactive X chromosome. We and others used rodent-human hybrid cell lines which had an hprt+ allele on the inactive human X chromosome alone. DNA from all of these cells failed to transform HPRT- recipients. Recently, Chapman et al. have shown that inactive X-chromosome DNA from several tissues of adult female mice is strikingly inefficient in genetic transformation for the hprt gene. On the other hand, de Jonge et al., using simian virus 40 (SV40)-transformed fibroblasts from a human heterozygous for an HPRT deficiency, observed HPRT transformation regardless of whether the hprt+ allele was on the active or the inactive X chromosome of the donor cells. We have done an experiment similar to that of deJonge et al., and report here results which clearly indicate that DNA from the inactive X chromosome functions very poorly in HPRT transformation, thus supporting the original interpretation of Liskay and Evans that inactive X-chromosomal DNA is structurally modified.     

Trembler mouse carries a point mutation in a myelin gene.

The autosomal dominant trembler mutation (Tr), maps to mouse chromosome 11 (ref. 2) and manifests as a Schwann-cell defect characterized by severe hypomyelination and continuing Schwann-cell proliferation throughout life. Affected animals move clumsily and develop tremor and transient seizures at a young age. We have recently described a potentially growth-regulating myelin protein, peripheral myelin protein-22 (PMP-22; refs 7, 8), which is expressed by Schwann cells and found in peripheral myelin. We now report the assignment of the gene for PMP-22 to mouse chromosome 11. Cloning and sequencing of PMP-22 complementary DNAs from inbred Tr mice reveals a point mutation that substitutes an aspartic acid residue for a glycine in a putative membrane-associated domain of the PMP-22 protein. Our results identify the PMP-22 gene as a likely candidate for the mouse trembler locus and will encourage the search for mutations in the corresponding human gene in pedigrees with hypertrophic neuropathies such as Charcot-Marie-Tooth and Dejerine-Sottas diseases (hereditary motor and sensory neuropathies I and III).     

The Duchenne muscular dystrophy gene product is localized in sarcolemma of human skeletal muscle

Duchenne muscular dystrophy (DMD) and its milder form, Becker muscular dystrophy (BMD), are allelic X-linked muscle disorders in man. The gene responsible for the disease has been cloned from knowledge of its map location at band Xp21 on the short arm of the X chromosome. The product of the DMD gene, a protein of relative molecular mass 400,000 (Mr 400K) recently named dystrophin, has been reported to co-purify with triads of mouse and rabbit skeletal muscle when assayed using polyclonal antibodies raised against fusion proteins encoded by regions of mouse DMD complementary DNA. Here we show that antibodies directed against synthetic peptides and fusion proteins derived from the N-terminal region of human DMD cDNA strongly react with an antigen present in skeletal muscle sarcolemma on cryostat sections of normal human muscle biopsies. This immunoreactivity is reduced or absent in muscle fibres from DMD patients but appears normal in muscle fibres from patients with other myopathic diseases. The same antibodies specifically react with a 400K protein in sodium dodecyl sulphate (SDS) extracts of normal human muscle subjected to Western blot analysis. We conclude that the product of the DMD gene is associated with the sarcolemma rather than with the triads and speculate that it strengthens the sarcolemma by anchoring elements of the internal cytoskeleton to the surface membrane.     

A candidate spermatogenesis gene on the mouse Y chromosome is homologous to ubiquitin-activating enzyme E1.

The human X-linked gene A1S9 complements a temperature-sensitive cell-cycle mutation in mouse L cells, and encodes the ubiquitin-activating enzyme E1. The gene has been reported to escape X-chromosome inactivation, but there is some conflicting evidence. We have isolated part of the mouse A1s9 gene, mapped it to the proximal portion of the X chromosome and shown that it undergoes normal X-inactivation. We also detected two copies of the gene on the short arm of the mouse Y chromosome (A1s9Y-1 and A1s9Y-2). The functional A1s9Y gene (A1s9Y-1) is expressed in testis and is lost in the deletion mutant Sxrb. Therefore A1s9Y-1 is a candidate for the spermatogenesis gene, Spy, which maps to this region. A1s9X is similar to the Zfx gene in undergoing X-inactivation, yet having homologous sequences on the short arm of the Y chromosome, which are expressed in the testis. These Y-linked genes may form part of a coregulated group of genes which function during spermatogenesis.