Suppressors of thermosensitive mutations in the DNA polymerase δ gene of Saccharomyces cerevisiae

DNA polymerases (Pol) α, δ and ε are necessary for replication of nuclear DNA. Po1δ interacts permanently or transiently with numerous accessory proteins whose identification may shed light on the function(s) of Po18. In vitro mutagenesis was used to induce thermosensitive (ts) mutations in the DNA polymerase δ gene (POL3). We have attempted to clone two recessive extragenic suppressors of such is mutants (sdp1 for mutation pol3-14 and sdp5-1 for mutation pol3-11) by transforming thermoresistant haploid strains pol3-14 sdpl and pol3-11 sdp5-1 with wild-type genomic libraries in singlecopy or multicopy vectors. None of the thermosensitive transformants so obtained was identified as being sdp1 or sdp5-1. Instead, three genes were cloned whose products interfere with the activity of suppressors. One of them is the type 1 protein phosphatase gene, D1S2. Another is a novel gene, ASM4, whose gene product is rich in asparagine and glutamine residues.     

Validation of the determination of ΔF508 mutations of the cystic fibrosis gene in over 11000 mouthwashes

Mouthwashes can be used as a DNA resource for mutation detection and, because collection and DNA isolation is simple and cheap, they could in particular, be used for large numbers of samples. To determine the failure rate (the proportion of mouth samples in which no PCR product was obtained) and the specificity of buccal epithelial cell mutation detection in large numbers of samples, we collected mouthwashes and blood samples from 11413 blood donors and tested the mouthwashes for the F508 mutation, which has an estimated frequency of 75% among cystic fibrosis chromosomes in The Netherlands. Blood samples were tested for the F508 mutations only if the mutation was identified in the mouthwash or in the case of a failure to obtain PCR products. The sensitivity of the test was determined in mouthwashes of 75 F508 carriers known from earlier family studies. These samples were offered blindly between the mouthwashes of the blood donors. Both specificity and sensitivity of the mouthwash procedure were 100%. The overall failure rate was 5.6%. This large figure was caused mainly by insufficient rinsing of the mouth in one particular blood bank. Exclusion of the results of this blood bank reduced the failure rate to 1.8%. Our results also confirm that for a large number of samples the mouthwash procedure is suitable for mutation detection and, with proper instructions, can be used in community screening.     

Novel and recurrent mutations in the tyrosinase gene and the P gene in the German albino population

Albinism is a heterogeneous group of genetic disorders resulting from deficiencies in pigmentation. Clinically, it is divided into ocular (OA) and oculocutaneous albinism (OCA). OCA involves lack of pigment in the skin, hair, and eyes and results from mutations in the tyrosinase gene or in the P gene. OA mainly affects pigmentation in the visual system and may be a mild form of OCA or may be caused by other genetic defects. Clinical diagnosis of albinism type is difficult, because of the observed range of phenotypic variation. Thus, genetic analysis may be helpful with respect to a more accurate diagnosis. Here, we report the mutational profile, determined by genetic analysis of the tyrosinase and P genes, of a large German albino population. We have revealed a total of 42 distinct mutations, 19 of which are novel. Of the 74 unrelated patients screened, 32 (43%) had mutations in the tyrosinase gene, 16 (22%) had P gene mutations, and 26 (35%) patients had no detectable genetic abnormalities. This defines a population of albino patients who are tyrosinase-gene- and P-gene-negative and who thus may represent a good study group for searching for additional genes associated with albinism.     

Suppressors of thermosensitive mutations in the DNA polymerase δ gene of Saccharomyces cerevisiae

DNA polymerases (Pol) , and are necessary for replication of nuclear DNA. Po1 interacts permanently or transiently with numerous accessory proteins whose identification may shed light on the function(s) of Po18. In vitro mutagenesis was used to induce thermosensitive (ts) mutations in the DNA polymerase gene (POL3). We have attempted to clone two recessive extragenic suppressors of such is mutants (sdp1 for mutation pol3-14 and sdp5-1 for mutation pol3-11) by transforming thermoresistant haploid strains pol3-14 sdpl and pol3-11 sdp5-1 with wild-type genomic libraries in singlecopy or multicopy vectors. None of the thermosensitive transformants so obtained was identified as being sdp1 or sdp5-1. Instead, three genes were cloned whose products interfere with the activity of suppressors. One of them is the type 1 protein phosphatase gene, D1S2. Another is a novel gene, ASM4, whose gene product is rich in asparagine and glutamine residues.     

Point mutations in the upstream region of the α-galactosidase A gene exon 6 in an atypical variant of Fabry disease

Summary Single point mutations in the upstream region of exon 6 of the -galactosidase A gene were found in two Japanese cases of the cardiac form of Fabry disease; ³⁰¹ArgGln (⁹⁰²GA) in a case that has already been published and ²⁷⁹GlnGlu (⁸³⁵CG) in a new case. They both expressed markedly low, but significant, amounts of residual activity in COS-1 cells. In contrast, two unrelated cases with classic Fabry disease were found to have different point mutations, which showed a complete loss of enzyme activity in a transient expression assay; ³²⁸GlyArg (⁹⁸²GA) in the downstream region of exon 6 in one case and two combined mutations, ⁶⁶GluGln (¹⁹⁶GC)/¹¹²ArgCys (³³⁴CT), in exon 2 in the other. We conclude, on the basis of the results recorded in this study and those in previous reports, that the pathogenesis of atypical Fabry disease is closely associated with point mutations in the upstream region of exon 6 of the -galactosidase A gene.     

New mutations in the human p53 gene — a regulator of the cell cycle and carcinogenesis

Mutations in the tumor suppressor gene p53 often lead to disarrangement of the cell cycle and of genetic integrity control of cells that may contribute to tumor development. We studied p53 gene mutations in 26 primary tumors of colorectal cancer patients. Mutations in p53 were found in 17 tumors (65.4%). All point mutations affected the DNA binding domain of p53 and were localized in exons 4-8 of the gene. Mutant p53 isoforms with altered domain structure and/or with alternative C-terminus arising from frameshift mutations or abnormal splicing were found in six tumors. Mutations Leu111Gln and Ser127Phe were shown in colorectal cancer for the first time. Isoforms p53-305 with C(4) insertion in codons 300/301 and p53i9* including an additional 44 nucleotides of the 3 -end of intron 9 were discovered for the first time. Mutations of p53 were associated with lymph node metastases and III/IV stage of tumors that are signs of unfavorable prognosis in colorectal cancer.     

Two novel missense mutations in the cystathionine β-synthase gene in homocystinuric patients

Direct sequencing of the coding region of the cystathionine -synthase (CBS) gene in two homocystinuric patients revealed the presence of two novel missense mutations. The first mutation, a 1111G A transition, resulted in the substitution of the evolutionary conserved valine-371 by a methionine residue (V371M) and created a new NlaIII restriction site. The second mutation, a GA transition at base-pair 494, resulted in an amino acid change from cysteine to tyrosine (C165Y) and abolished a BsoFI restriction site. Both mutations were found in a compound heterozygous state with the previously described 833T C transition.     

Is the mismatch repair deficient type of Muir-Torre syndrome confined to mutations in the hMSH2 gene?

The Muir-Torre syndrome (MTS) is a rare autosomal-dominant condition characterized by the occurrence of sebaceous skin lesions and internal tumours in a patient. It has been demonstrated that at least a subgroup of MTS exhibits clinical and molecular genetic features of hereditary nonpolyposis colorectal cancer, including microsatellite instability in skin and visceral tumours, because of mutations in DNA mismatch repair genes. We have identified germline mutations in the hMSH2 gene in two unrelated MTS patients ascertained because of their skin tumours. Our results, together with published MTS cases, support the hypothesis that MTS with its characteristic skin lesions is confined to mutations in the hMSH2 gene. Received: 22 July 1996 / Revised: 12 August 1996     

Direct selection of mutations in the human mitochondrial tRNAThr gene: reversion of an ‘uncloneable’ phenotype

Several regions of the human mitochondrial genome are refractory to cloning in plasmid and bacteriophage DNA vectors. For example, recovery of recombinant M13 clones containing a 462 basepair MboI-Kpn I restriction fragment that spans nucleotide positions 15591 to 16053 of HeLa cell mitochondrial DNA was as much as 100-fold lower than the recovery of M13 clones containing other regions of the human mitochondrial genome. All of 50 recombinant M13 clones containing this ‘uncloneable’ fragment had one or more changes in nucleotide sequence. Each clone contained at least one alteration in two nucleotide positions within the tRNA^Thr gene that encode portions of the anticodon loop and D-stem of the HeLa mitochondrial tRNA^Thr. These results imply that the HeLa mitochondrial tRNA^Thr gene is responsible for the ‘uncloneable’ phenotype of this region of human mitochondrial (mt) DNA.A total of 61 nucleotide sequence alterations were identified in 50 independent clones containing the HeLa mt tRNA^Thr gene. 56 mutations were single-base substitutions; 5 were deletions. Approximately 80% of the base substitution mutations were A:T → G:C transitions. A preference for A:T → G:C transition mutations also characterizes polymorphic base substitution variants in the mitochondrial DNA of unrelated individuals. This similarity suggests that human mitochondrial DNA sequence variation within and between individuals may have a common origin.     

Do all of the neurologic diseases in patients with DNA repair gene mutations result from the accumulation of DNA damage?

The classic model for neurodegeneration due to mutations in DNA repair genes holds that DNA damage accumulates in the absence of repair, resulting in the death of neurons. This model was originally put forth to explain the dramatic loss of neurons observed in patients with xeroderma pigmentosum neurologic disease, and is likely to be valid for other neurodegenerative diseases due to mutations in DNA repair genes. However, in trichiothiodystrophy (TTD), Aicardi-Goutières syndrome (AGS), and Cockayne syndrome (CS), abnormal myelin is the most prominent neuropathological feature. Myelin is synthesized by specific types of glial cells called oligodendrocytes. In this review, we focus on new studies that illustrate two disease mechanisms for myelin defects resulting from mutations in DNA repair genes, both of which are fundamentally different than the classic model described above. First, studies using the TTD mouse model indicate that TFIIH acts as a co-activator for thyroid hormone-dependent gene expression in the brain, and that a causative XPD mutation in TTD results in reduction of this co-activator function and a dysregulation of myelin-related gene expression. Second, in AGS, which is caused by mutations in either TREX1 or RNASEH2, recent evidence indicates that failure to degrade nucleic acids produced during S-phase triggers activation of the innate immune system, resulting in myelin defects and calcification of the brain. Strikingly, both myelin defects and brain calcification are both prominent features of CS neurologic disease. The similar neuropathology in CS and AGS seems unlikely to be due to the loss of a common DNA repair function, and based on the evidence in the literature, we propose that vascular abnormalities may be part of the mechanism that is common to both diseases. In summary, while the classic DNA damage accumulation model is applicable to the neuronal death due to defective DNA repair, the myelination defects and brain calcification seem to be better explained by quite different mechanisms. We discuss the implications of these different disease mechanisms for the rational development of treatments and therapies.     

Identification of seven novel mutations in LH β-subunit gene by SSCP

Seven new point mutations have been identified from LH -subunit gene by PCR-mediated SSCP, and sequencing. One mutation was found changing amino acid from Gln₁₀₂ to Ser₁₀₂. The remaining six mutations, which did not change the codings, were in complete linkage disequilibrium. SSCP can be used in the diagnosis of LH-related disorders.     

Contribution of gene conversion in the evolution of the human β-like globin gene family

Gene conversion is referred to as one of two types of mechanisms known to act on gene families, mainly to maintain their sequence homogeneity or, in certain cases, to produce sequence diversity. The concept of gene conversion was established 20 years ago by researchers working with fungi. A few years later, gene conversion was also observed in the human genome, i.e. the γ-globin locus. The aim of this article is to emphasize the role of genetic recombination, particularly of gene conversion, in the evolution of the human β-like globin genes and further to summarize its contribution to the convergent evolution of the fetal globin genes. Finally, this article attempts to re-examine the origin and spread of specific mutations of the β-globin cluster, such as the sickle cell or β-thalassemia mutations, on the basis of repeated gene conversion events. Received: 13 February 1997 / Accepted: 15 May 1998     

Analysis of helicase gene mutations in Japanese Werner’s syndrome patients

The profile of helicase gene mutations was studied in 89 Japanese Werner’s syndrome (WRN) patients by examining the previously described mutations 1– 4 as well as a new mutation found during this study, designated mutation 5. Of 178 chromosomes (89 patients), 89 chromosomes (50%) had mutation 4, 11 (6.2%) chromosomes had mutation 1, and two chromosomes (1.1%) contained mutation 5. Mutations 2 and 3 were not observed in this patient population. The remaining 76 (42.7%) chromosomes had none of these mutations. A significant fraction of all patients (22 total patients, 24.7%) appear to be compound heterozygotes, including those carrying mutations of both types 1 and 4. The genotype analysis of the markers surrounding the WRN helicase gene strongly suggests that most of the chromosomes carrying either mutation 1 or 4 were derived from two single founders. Received: 25 July 1996 / Revised: 20 September 1996     

Tyrosinase gene mutations in oculocutaneous albinism 1 (OCA1): definition of the phenotype

Oculocutaneous albinism (OCA) is a common human genetic condition resulting from mutations in at least twelve different genes. OCA1 results from mutations of the tyrosinase gene and presents with the life-long absence of melanin pigment after birth (OCA1A) or with the development of minimal-to-moderate amounts of cutaneous and ocular pigment (OCA1B). Other types of OCA have variable amounts of cutaneous and ocular pigment. We hypothesized that white hair at birth indicates OCA1 and tested this in a sample of 120 probands with OCA and white hair at birth. We found that 102 (85%) of the probands had OCA1 with one or two identifiable tyrosinase gene mutations, with 169 (83%) of the 204 OCA1 tyrosinase gene alleles having identifiable mutations and 35 (17%) having no identifiable change in the coding, splice junction, or proximal promoter regions of the gene. The inability to identify the mutation was more common with OCA1B (24/35, 69%) than with OCA1A (11/35, 31%) alleles. Seven probands with no tyrosinase gene mutations were found to have OCA2 with one or two P gene mutations, and in eleven, no mutations were detected in either gene. We conclude that (1) the presence of white hair at birth is a useful clinical tool suggesting OCA1 in a child or adult with OCA, although OCA2 may also have this presentation; (2) the molecular analysis of the tyrosinase and P genes are necessary for precise diagnosis; and (3) the presence of alleles without identifiable mutations of the tyrosinase gene, particularly in OCA1B, suggests that more complex mutation mechanisms of this gene are common in OCA.Electronic database Information: accession numbers and URLs for data presented in this article are as follows:Albinism Database, , for a list of published mutations of the tyrosinase geneOnline Mendelian Inheritance in Man (OMIM), , for OCA1 (MIM 203100), OCA2 (MIM 203200)