In vivo somatic mutations in human lymphocytes frequently result from major gene alterations

Somatic mutations, either spontaneous or produced by identifiable mutagens, are thought to be important in the aetiology of cancer and in the ageing process. The study of somatic mutations in human cells in vivo has recently been made possible by the development of techniques for enumeration and clonal expansion of lymphocytes mutated at the chromosome X-linked hypoxanthine phosphoribosyl transferase (HPRT) locus. We have studied the molecular basis of in vivo hprt mutations in human lymphocytes and report here that a surprisingly high proportion (57%) involve substantial gene alterations which are not evident cytogenetically. These major gene alterations include deletions, exon amplifications and novel, sometimes amplified, bands on Southern analysis. Such changes emphasize the fluid nature of information in DNA and may be indicative of general mechanisms by which functional gene loss is involved in the aetiology of cancer and the homeostatic failure of ageing.     

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.     

Alterations of the hprt gene in human in vivo-derived 6-thioguanine-resistant T lymphocytes

Investigations into the extent and significance of somatic gene mutations occurring in vivo in humans have been hampered by the lack of a means of unambiguously defining the mutational origin of in vivo-derived variant cells. Several years ago we proposed that 6-thioguanine-resistant T lymphocytes, present at low frequencies in human peripheral blood, might be useful markers of in vivo somatic mutation. We and others have since described methods for the isolation and study of these unusual cells. The thioguanine-resistant T cell stably lack hypoxanthine-guanine phosphoribosyltransferase (HPRT) activity, suggesting that they are somatic equivalents in normal individuals to cells from individuals with the X-chromosomal hprt Lesch-Nyhan germinal mutation. We now report that in vivo-derived thioguanine-resistant T-cell colonies from a single normal individual show a variety of hprt structural alterations, as determined by Southern blot analysis. This finding demonstrates unequivocally that these cells are genetic mutants and validates their use for fundamental and applied mutational studies in humans.     

A potential animal model for Lesch-Nyhan syndrome through introduction of HPRT mutations into mice

The human Lesch-Nyhan syndrome is a rare neurological and behavioural disorder, affecting only males, which is caused by an inherited deficiency in the level of activity of the purine salvage enzyme hypoxanthine-guanosine phosphoribosyl transferase (HPRT). How the resulting alterations in purine metabolism lead to the severe symptoms characteristic of Lesch-Nyhan patients is still not understood. No mutations at the Hprt locus leading to loss of activity have been described in laboratory animals. To derive an animal model for the Lesch-Nyhan syndrome, we have used cultured mouse embryonic stem cells, mutagenized by retroviral insertion and selected for loss of HPRT activity, to construct chimaeric mice. Two clonal lines carrying different mutant Hprt alleles have given rise to germ cells in chimaeras, allowing the derivation of strains of mutant mice having the same biochemical defect as Lesch-Nyhan patients. Male mice carrying the mutant alleles are viable and analysis of their cells shows a total lack of HPRT activity.     

5例原发性痛风患者HPRT基因的克隆和序列分析

原发性痛风是先天性嘌呤代谢缺陷症，与嘌呤代谢相关两次黄嘌呤—鸟嘌呤磷酸核糖转移酶(HPRT，EC2．4．2．8)、磷酸核糖焦磷酸合成酶(PRS)等缺陷有关。克隆了正常中国人和4个中国原发性痛风家族5位患的HPRT基因，序列分析表明，正常中国人及Case5患的HPRT编码区序列与报道的序列(GeneBank登录号M26434)完全一致，而在3个中国痛风家族4位患的HPRT基因编码区中共发现11个新突变，包括3个同义突变、1个元义突变和7个错义突变。这是关于中国大陆原发性痛风患HPRT基因突变的首次报道。     

Effect of ageing on reactivation of the human X-linked HPRT locus

In mammals, X-chromosome dosage compensation is achieved by inactivating one X chromosome in female cells. To test the hypothesis that genes on the silent X chromosome reactivate as a consequence of ageing, we examined the X-linked hypoxanthine phosphoribosyltransferase (HPRT) locus in 41 women who are heterozygous for mutations at this locus, leading to severe deficiency of the enzyme (Lesch-Nyhan syndrome). We find that heterozygotes who are more than 10 yr old have an excess of HPRT+ skin fibroblast clones (59% rather than the 50% expected as a consequence of random X inactivation) but this excess does not increase with age. Further studies of eight of these heterozygotes show that the silent locus does not detectably reactivate spontaneously in culture, but only in response to treatment with 5-aza-2-deoxycytidine, a potent inhibitor of methylation. There is no age difference in the frequency of this reactivation as assayed by HATr clones, and a more sensitive autoradiographic assay shows only a twofold difference between young and old heterozygotes. Thus, age-related reactivation is not a feature of all X-linked loci, and may have species, tissue and locus-specific determinants.     

Clusters of CpG dinucleotides implicated by nuclease hypersensitivity as control elements of housekeeping genes

DNA sequences of the X-chromosome-linked hypoxanthine phosphoribosyltransferase (HPRT) and glucose 6-phosphate dehydrogenase (G6PD) genes have revealed the presence of clusters of CpG dinucleotides, raising the possibility that such clusters are involved in the control of expression of these genes, which are expressed in all tissues. Although CpG clusters are not exclusive features of the X chromosome, the analysis of X-linked genes provides the means to determine whether CpG clusters are control elements; one of the two homologous X loci in female mammals is not expressed, so that active and inactive versions of the gene can be compared. In fact, it has been shown that these CpG clusters are undermethylated when the gene is active and extensively methylated when the gene is inactive. In addition to hypomethylation, chromatin hypersensitivity to endonuclease digestion is a known hallmark of regulatory sequences in eukaryotic genes. We report here that the CpG clusters of the active hprt and g6pd genes are not only undermethylated, but also hypersensitive to MspI, DNase I and S1 nuclease, further supporting the suggestion that they are involved in the control of expression of these genes.     

HPRT-deficient (Lesch-Nyhan) mouse embryos derived from germline colonization by cultured cells

Embryonal stem (ES) cell lines, established in culture from peri-implantation mouse blastocysts, can colonize both the somatic and germ-cell lineages of chimaeric mice following injection into host blastocysts. Recently, ES cells with multiple integrations of retroviral sequences have been used to introduce these sequences into the germ-line of chimaeric mice, demonstrating an alternative to the microinjection of fertilized eggs for the production of transgenic mice. However, the properties of ES cells raise a unique possibility: that of using the techniques of somatic cell genetics to select cells with genetic modifications such as recessive mutations, and of introducing these mutations into the mouse germ line. Here we report the realization of this possibility by the selection in vitro of variant ES cells deficient in hypoxanthine guanine phosphoribosyl transferase (HPRT; EC 2.4.2.8), their use to produce germline chimaeras resulting in female offspring heterozygous for HPRT-deficiency, and the generation of HPRT-deficient preimplantation embryos from these females. In human males, HPRT deficiency causes Lesch-Nyhan syndrome, which is characterized by mental retardation and self-mutilation.     

Micronuclei rate and hypoxanthine phosphoribosyl transferase mutation in radon-exposed rats

The genetic changes in rats with radon exposure were studied by the micronucleus technology and detection of hypoxanthine phosphoribosyl transferase （hprt） mutations. The rate of the micronuclei in peripheral blood lymphocytes and tracheal-bronchial epithelial cells in the radon-inhaled rats was higher than that of the controls （P 〈 0.05）. A similar result was obtained from the hprt assay, which showed a higher mutation frequency in radon-exposed rats. Our results suggested that micronuclei rate and hprt deficiency could be used as biomarkers for the genetic changes with radon exposure.     

Targetted correction of a mutant HPRT gene in mouse embryonic stem cells

Two recent developments suggest a route to predetermined alterations in mammalian germlines. These are, first, the characterization of mouse embryonic stem (ES) cells that can still enter the germline after genetic manipulation in culture and second, the demonstration that homologous recombination between a native target chromosomal gene and exogenous DAN can be used in culture to modify specifically the target locus. We here use gene targetting functionally to correct the mutant hypoxanthine-guanine phosphoribosyl transferase (HPRT) gene in the ES cell line which has previously been isolated and used to produce an HPRT-deficient mouse. This modification of a chosen gene in pluripotent ES cells demonstrates the feasibility of this route to manipulating mammalian genomes in predetermined ways.     

Clinical and genetic analysis of two Chinese families with benign familial neonatal convulsions

Benignfamilialneonatalconvulsions(BFNC)is arareautosomaldominantinheritedepilepsysyn dromecharacterizedbyunprovokedpartialorgeneral izedseizures.Theseizuresusuallyoccurfromthesec onddayofbirthtothesixthmonthandremitsponta neouslyafterseveralweekstomonths.Mostindivid ualsareseizure freebytheageofsixmonths.The serumchemistryandneuroradiologicalexaminations,interictalelectroencephalogram(EEG),andpsy chomotordevelopmentareusuallynormal.However,10%to15%ofpatientshavetheriskofseizurere currencela…     

Clinical and genetic analysis of two Chinese families with benign familial neonatal convulsions

Benign familial neonatal convulsions (BFNC) is a rare autosomal dominant inherited epilepsy syndrome. Two voltage-gated potassium channel genes, KCNQ2 and KCNQ3, have been identified as the genes responsible for BFNC. Here we report two Chinese families with clinical histories of typical BFNC. Using six microsatellite markers, two located at KCNQ2 locus and four at KCNQ3 locus, linkage analysis was performed in the two families, which excluded the linkage of BFNC to KCNQ3, but could not exclude the linkage to KCNQ2. Direct DNA sequencing of the KCNQ2 gene in the two families was performed, and two formerly unknown polymorphisms were identified, but no KCNQ2 mutation was found in the two families. Our study suggests the genetic heterogeneity in Chinese families with BFNC and proves the existence of a new gene locus for BFNC.     

The beta-subunit of follicle-stimulating hormone is deleted in patients with aniridia and Wilms' tumour, allowing a further definition of the WAGR locus

One in 10,000 children develops Wilms' tumour, an embryonal malignancy of the kidney. Although most Wilms' tumours are sporadic, a genetic predisposition is associated with aniridia, genito-urinary malformations and mental retardation (the WAGR syndrome). Patients with this syndrome typically exhibit constitutional deletions involving band p13 of one chromosome 11 homologue. It is likely that these deletions overlap a cluster of separate but closely linked genes that control the development of the kidney, iris and urogenital tract (the WAGR complex). A discrete aniridia locus, in particular, has been defined within this chromosomal segment by a reciprocal translocation, transmitted through three generations, which interrupts 11p13. In addition, the specific loss of chromosome 11p alleles in sporadic Wilms' tumours has been demonstrated, suggesting that the WAGR complex includes a recessive oncogene, analogous to the retinoblastoma locus on chromosome 13. In WAGR patients, the inherited 11p deletion is thought to represent the first of two events required for the initiation of a Wilms' tumour, as suggested by Knudson from epidemiological data. We have now isolated the deleted chromosomes 11 from four WAGR patients in hamster-human somatic cell hybrids, and have tested genomic DNA from the hybrids with chromosome 11-specific probes. We show that 4 of 31 markers are deleted in at least one patient, but that of these markers, only the gene encoding the beta-subunit of follicle-stimulating hormone (FSHB) is deleted in all four patients. Our results demonstrate close physical linkage between FSHB and the WAGR locus, suggest a gene order for the four deleted markers and exclude other markers tested from this region. In hybrids prepared from a balanced translocation carrier with familial aniridia, the four markers segregate into proximal and distal groups. The translocation breakpoint, which identifies the position of the aniridia gene on 11p, is immediately proximal to FSHB, in the interval between FSHB and the catalase gene.     

A gene deleted in Kallmann's syndrome shares homology with neural cell adhesion and axonal path-finding molecules

Kallmann's syndrome (clinically characterized by hypogonadotropic hypogonadism and inability to smell) is caused by a defect in the migration of olfactory neurons, and neurons producing hypothalamic gonadotropin-releasing hormone. A gene has now been isolated from the critical region on Xp22.3 to which the syndrome locus has been assigned: this gene escapes X inactivation, has a homologue on the Y chromosome, and shows an unusual pattern of conservation across species. The predicted protein has significant similarities with proteins involved in neural cell adhesion and axonal pathfinding, as well as with protein kinases and phosphatases, which suggests that this gene could have a specific role in neuronal migration.