Hypermutation of immunoglobulin genes in memory B cells of DNA repair-deficient mice.

To investigate the possible involvement of DNA repair in the process of somatic hypermutation of rearranged immunoglobulin variable (V) region genes, we have analyzed the occurrence, frequency, distribution, and pattern of mutations in rearranged Vlambda1 light chain genes from naive and memory B cells in DNA repair-deficient mutant mouse strains. Hypermutation was found unaffected in mice carrying mutations in either of the following DNA repair genes: xeroderma pigmentosum complementation group (XP)A and XPD, Cockayne syndrome complementation group B (CSB), mutS homologue 2 (MSH2), radiation sensitivity 54 (RAD54), poly (ADP-ribose) polymerase (PARP), and 3-alkyladenine DNA-glycosylase (AAG). These results indicate that both subpathways of nucleotide excision repair, global genome repair, and transcription-coupled repair are not required for somatic hypermutation. This appears also to be true for mismatch repair, RAD54-dependent double-strand-break repair, and AAG-mediated base excision repair.

Disruption of mouse ERCC1 results in a novel repair syndrome with growth failure, nuclear abnormalities and senescence.

BACKGROUND: The structure-specific ERCC1/XPF endonuclease complex that contains the ERCC1 and XPF subunits is implicated in the repair of two distinct types of lesions in DNA: nucleotide excision repair (NER) for ultraviolet-induced lesions and bulky chemical adducts; and recombination repair of the very genotoxic interstrand cross-links. RESULTS: Here, we present a detailed analysis of two types of mice with mutations in ERCC1, one in which the gene is 'knocked out', and one in which the encoded protein contains a seven amino-acid carboxy-terminal truncation. In addition to the previously reported symptoms of severe runting, abnormalities of liver nuclei and greatly reduced lifespan (which appeared less severe in the truncation mutant), both types of ERCC1-mutant mouse exhibited an absence of subcutaneous fat, early onset of ferritin deposition in the spleen, kidney malfunction, gross abnormalities of ploidy and cytoplasmic invaginations in nuclei of liver and kidney, and compromised NER and cross-link repair. We also found that heterozygosity for ERCC1 mutations did not appear to provide a selective advantage for chemically induced tumorigenesis. An important clue to the cause of the very severe ERCC1-mutant phenotypes is our finding that ERCC1-mutant cells undergo premature replicative senescence, unlike cells from mice with a defect only in NER. CONCLUSIONS: Our results strongly suggest that the accumulation in ERCC1-mutant mice of endogenously generated DNA interstrand cross-links, which are normally repaired by ERCC1-dependent recombination repair, underlies both the early onset of cell cycle arrest and polyploidy in the liver and kidney. Thus, our work provides an insight into the molecular basis of ageing and highlights the role of ERCC1 and interstrand DNA cross-links.

Molecular cloning and biological characterization of the human excision repair gene ERCC-3.

In this report we present the cloning, partial characterization, and preliminary studies of the biological activity of a human gene, designated ERCC-3, involved in early steps of the nucleotide excision repair pathway. The gene was cloned after genomic DNA transfection of human (HeLa) chromosomal DNA together with dominant marker pSV3gptH to the UV-sensitive, incision-defective Chinese hamster ovary (CHO) mutant 27-1. This mutant belongs to complementation group 3 of repair-deficient rodent mutants. After selection of UV-resistant primary and secondary 27-1 transformants, human sequences associated with the induced UV resistance were rescued in cosmids from the DNA of a secondary transformant by using a linked dominant marker copy and human repetitive DNA as probes. From coinheritance analysis of the ERCC-3 region in independent transformants, we deduce that the gene has a size of 35 to 45 kilobases, of which one essential segment has so far been refractory to cloning. Conserved unique human sequences hybridizing to a 3.0-kilobase mRNA were used to isolate apparently full-length cDNA clones. Upon transfection to 27-1 cells, the ERCC-3 cDNA, inserted in a mammalian expression vector, induced specific and (virtually) complete correction of the UV sensitivity and unscheduled DNA synthesis of mutants of complementation group 3 with very high efficiency. Mutant 27-1 is, unlike other mutants of complementation group 3, also very sensitive toward small alkylating agents. This unique property of the mutant is not corrected by introduction of the ERCC-3 cDNA, indicating that it may be caused by an independent second mutation in another repair function. By hybridization to DNA of a human x rodent hybrid cell panel, the ERCC-3 gene was assigned to chromosome 2, in agreement with data based on cell fusion (L. H. Thompson, A. V. Carrano, K. Sato, E. P. Salazar, B. F. White, S. A. Stewart, J. L. Minkler, and M. J. Siciliano, Somat. Cell. Mol. Genet. 13:539-551, 1987).

Mutational analysis of ERCC3, which is involved in DNA repair and transcription initiation: identification of domains essential for the DNA repair function.

The human ERCC3 gene, which corrects specifically the nucleotide excision repair defect in human xeroderma pigmentosum group B and cross-complements the repair deficiency in rodent UV-sensitive mutants of group 3, encodes a presumed DNA helicase that is identical to the p89 subunit of the general transcription factor TFIIH/BTF2. To examine the significance of the postulated functional domains in ERCC3, we have introduced mutations in the ERCC3 cDNA by means of site-specific mutagenesis and have determined the repair capacity of each mutant to complement the UV-sensitive phenotype of rodent group 3 cells. A conservative substitution of arginine for the invariant lysine residue in the ATPase motif (helicase domain I), six deletion mutations in the other helicase domains, and a deletion in the potential helix-turn-helix DNA-binding motif fail to complement the ERCC3 excision repair defect of rodent group 3 mutants, which implies that the helicase domains as well as the potential DNA-binding motif are required for the repair function of ERCC3. Analysis of carboxy-terminal deletions suggests that the carboxy-terminal exon may comprise a distinct determinant for the DNA repair function. In addition, we show that a functional epitope-tagged version of ERCC3 accumulates in the nucleus. Deletion of the putative nuclear location signal impairs neither the nuclear location nor the repair function, indicating that other sequences may (also) be involved in translocation of ERCC3 to the nucleus.

Cloning of a human homolog of the yeast nucleotide excision repair gene MMS19 and interaction with transcription repair factor TFIIH via the XPB and XPD helicases.

Nucleotide excision repair (NER) removes UV-induced photoproducts and numerous other DNA lesions in a highly conserved 'cut-and-paste' reaction that involves approximately 25 core components. In addition, several other proteins have been identified which are dispensable for NER in vitro but have an undefined role in vivo and may act at the interface of NER and other cellular processes. An intriguing example is the Saccharomyces cerevisiae Mms19 protein that has an unknown dual function in NER and RNA polymerase II transcription. Here we report the cloning and characterization of a human homolog, designated hMMS19, that encodes a 1030 amino acid protein with 26% identity and 51% similarity to S.cerevisiae Mms19p and with a strikingly similar size. The expression profile and nuclear location are consistent with a repair function. Co-immunoprecipitation experiments revealed that hMMS19 directly interacts with the XPB and XPD subunits of NER-transcription factor TFIIH. These findings extend the conservation of the NER apparatus and the link between NER and basal transcription and suggest that hMMS19 exerts its function in repair and transcription by interacting with the XPB and XPD helicases.

The role of nucleotide excision repair in protecting embryonic stem cells from genotoxic effects of UV-induced DNA damage.

In this study the role of nucleotide excision repair (NER) in protecting mouse embryonic stem (ES) cells against the genotoxic effects of UV-photolesions was analysed. Repair of cyclobutane pyrimidine dimers (CPD) in transcribed genes could not be detected whereas the removal of (6-4) photoproducts (6-4PP) was incomplete, already reaching its maximum (30%) 4 h after irradiation. Measurements of repair replication revealed a saturation of NER activity at UV doses >5 J/m2 while at a lower dose (2.5 J/m2) the repair kinetics were similar to those in murine embryonic fibroblasts (MEFs). Cytotoxic and mutagenic effects of photolesions were determined in ES cells differing in NER activity. ERCC1-deficient ES cells were hypermutable (10-fold) compared to wild-type cells, indicating that at physiologically relevant doses ES cells efficiently remove photolesions. The effect of the NER deficiency on cytoxicity was only 2-fold. Exposure to high UV doses (10 J/m2) resulted in a rapid and massive induction of apoptosis. Possibly, to avoid the accumulation of mutated cells, ES cells rely on the induction of a strong apoptotic response with a simultaneous shutting down of NER activity.

Disruption of the mouse xeroderma pigmentosum group D DNA repair/basal transcription gene results in preimplantation lethality.

The xeroderma pigmentosum (XP) group D (XPD) gene encodes a DNA helicase that is a subunit of the transcription factor IIH complex, involved both in nucleotide excision repair of UV-induced DNA damage and in basal transcription initiation. Point mutations in the XPD gene lead either to the cancer-prone repair syndrome XP, sometimes in combination with a second repair condition; Cockayne syndrome; or the non-cancer-prone brittle-hair disorder trichothiodystrophy. To study the role of XPD in nucleotide excision repair and transcription and its implication in human disorders, we isolated the mouse XPD gene and generated a null allele via homologous recombination in embryonic stem cells by deleting XPD helicase domains IV-VI. Heterozygous cells and mice are normal without any obvious defect. However, when intercrossing heterozygotes, homozygous XPD mutant mice were selectively absent from the offspring. Furthermore, we could not detect XPD-/- embryos at day 7.5 of development. In vitro growth experiments with preimplantation-stage embryos obtained from heterozygous intercrosses showed a significantly higher fraction of embryos that died at the two-cell stage, compared to wild-type embryos. These results establish the essential function of the XPD protein in mammals and in cellular viability and are consistent with the notion that only subtle XPD mutations are found in XP, XP/Cockayne syndrome, and trichothiodystrophy patients.

Mouse model for the DNA repair/basal transcription disorder trichothiodystrophy reveals cancer predisposition.

Patients with the nucleotide excision repair (NER) disorder xeroderma pigmentosum (XP) are highly predisposed to develop sunlight-induced skin cancer, in remarkable contrast to photosensitive NER-deficient trichothiodystrophy (TTD) patients carrying mutations in the same XPD gene. XPD encodes a helicase subunit of the dually functional DNA repair/basal transcription complex TFIIH. The pleiotropic disease phenotype is hypothesized to be, in part, derived from a repair defect causing UV sensitivity and, in part, from a subtle, viable basal transcription deficiency accounting for the cutaneous, developmental, and the typical brittle hair features of TTD. To understand the relationship between deficient NER and tumor susceptibility, we used a mouse model for TTD that mimics an XPD point mutation of a TTD patient in the mouse germline. Like the fibroblasts from the patient, mouse cells exhibit a partial NER defect, evident from the reduced UV-induced DNA repair synthesis (residual repair capacity approximately 25%), limited recovery of RNA synthesis after UV exposure, and a relatively mild hypersensitivity to cell killing by UV or 7,12-dimethylbenz[a]anthracene. In accordance with the cellular studies, TTD mice exhibit a modestly increased sensitivity to UV-induced inflammation and hyperplasia of the skin. In striking contrast to the human syndrome, TTD mice manifest a dear susceptibility to UV- and 7,12-dimethylbenz[a]anthracene-induced skin carcinogenesis, albeit not as pronounced as the totally NER-deficient XPA mice. These findings open up the possibility that TTD is associated with a so far unnoticed cancer predisposition and support the notion that a NER deficiency enhances cancer susceptibility. These findings have important implications for the etiology of the human disorder and for the impact of NER on carcinogenesis.

Influence of nucleotide excision repair on N-hydroxy-2-acetylaminofluorene-induced mutagenesis studied in lambda lacZ-transgenic mice.

To study the influence of nucleotide excision repair (NER) on mutagenesis in vivo, ERCC1 +/-, XPA-/-, and wild-type (ERCC1+/+ and XPA+/+, respectively) lambda lacZ-transgenic mice were treated i.p. with N-hydroxy-2-acetylaminofluorene (N-OH-AAF) and lacZ mutant frequencies were determined in liver. No significant effect of the treatment on the mutant frequency in wild-type or ERCC1-heterozygous mice was observed. The liver mutant frequency appeared to be significantly increased in treated XPA-/- mice only. To distinguish N-OH-AAF-induced from spontaneous mutations, lacZ mutants derived from treated XPA-/- mice were subjected to DNA-sequence analysis and the spectrum obtained was compared to that established for lacZ mutants in liver of PBS-treated lambda lacZ-transgenic mice of the parent strain 40.6. The N-OH-AAF-induced mutation spectrum appeared to be significantly different from the spontaneous mutation spectrum: the former consisted of mainly (19/22) single bp substitutions targeted at G, of which the majority (12/19) were G:C-->T:A transversions, suggesting that N-(deoxyguanosin-8-yl)-2-aminofluorene [dG-C8-AF], the major DNA adduct in N-OH-AAF-treated mice, is the premutagenic lesion. After analysis of 21 spontaneous mutants, only ten single bp substitutions targeted at G were found, of which five were G:C-->T:A transversions. This study with XPA-/- lambda lacZ-transgenic mice shows that one of the components of NER, that is, the XPA protein, suppresses mutagenesis in vivo.

The cloned human DNA excision repair gene ERCC-1 fails to correct xeroderma pigmentosum complementation groups A through I.

The human DNA excision repair gene ERCC-1 complements the ultraviolet light (UV) and mitomycin C (MMC) sensitivity of CHO mutants of complementation group 1. We have investigated whether ERCC-1 is the mutated gene in cell lines from xeroderma pigmentosum (XP) complementation groups A through I by analyzing the endogenous gene in XP cells and by introduction of the gene followed by repair assays. Our studies show that ERCC-1 is not deleted or grossly rearranged in representative cell lines of 9 XP groups. Furthermore, Northern blot analysis revealed correct transcription of ERCC-1 in all groups. The cloned human ERCC-1 gene was introduced into immortalized XP cells by DNA transfection (groups A, C, D, E and F). The presence of the integrated transfected sequences was verified on Southern blots and by selection for 2 dominant marker genes that flank the ERCC-1 gene on the transfected cos43-34 DNA. ERCC-1 failed to confer a normal UV survival and UV-induced unscheduled DNA synthesis (UDS) to transfected populations. In the case of the remaining XP complementation groups (B, G, H and I), nuclear microinjection was used to introduce an ERCC-1 cDNA construct driven by an SV40 promoter into primary fibroblasts. Coinjection of the SV40 large T gene and analysis of its expression served as a control for the injection. The ERCC-1 cDNA failed to induce increased levels of UDS in the microinjected fibroblasts. We infer from these experiments that ERCC-1 is not the mutated gene in the 9 XP complementation groups examined. From a similar type of experiments we conclude that ERCC-1 is not the defective gene in UV-sensitive Cockayne's syndrome cells.

Genetic analysis of nucleotide excision repair in mammalian cells.

Nucleotide excision repair is a versatile process and is one of the best known systems that prevents the deleterious consequences of DNA damage induced by environmental agents and cellular metabolites. Without repair, persisting lesions can interfere with proper functioning of DNA-metabolizing processes, notably transcription and replication, and give rise to mutations. The effect of inefficient or deficient repair is illustrated by genetic repair diseases that predispose individuals to cancer due to the fact that mutations accumulate at a high rate. Here we describe the progress that has been made from the initial cloning and characterization of nucleotide excision repair genes to the current understanding of their function in the complex nucleotide excision repair process.

Genes controlling nucleotide excision repair in eukaryotic cells.

The maintenance of genetic integrity is of vital importance to all living organisms. However, DNA--the carrier of genetic information--is continuously subject to damage induced by numerous agents from the environment and endogenous cellular metabolites. To prevent the deleterious consequences of DNA injury, an intricate network of repair systems has evolved. The biological impact of these repair mechanisms is illustrated by a number of genetic diseases that are characterized by a defect in one of the repair machineries and in general predispose individuals to cancer. This article intends to review our current understanding of the complex nucleotide excision repair pathway, a universal repair system with a broad lesion specificity. Emphasis will be on the recent advances in the genetic analysis of this process in mammalian cells.

The DNA-dependent ATPase activity associated with the class II basic transcription factor BTF2/TFIIH.

BTF2/TFIIH from human, delta from rat, and factor b from yeast are multisubunit basal transcription factors that have been shown to be closely associated with a protein kinase capable of phosphorylating the carboxyl-terminal domain of the large subunit of RNA polymerase II (Lu, H., Zawel, L., Fischer, L., Egly, J. M., and Reinberg, D. (1992) Nature 358, 641-645; Serizawa, H., Conaway, R. C., and Conaway, J. W. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 7476-7480; Feaver, W. J., Gileadi, O., and Kornberg, R. D. (1991) Cell 67, 1223-1230). We report here that a DNA-dependent ATPase and the previously characterized helicase (Schaeffer, L., Roy, R., Humbert, S., Moncollin, V., Vermeulen, W., Hoeijmakers, J., Chambon, P., and Egly, J. M. (1993) Science 260, 58-63) are both associated with BTF2 and reside with the p89 polypeptide subunit. The DNA requirement, the effect of Sarkosyl and staurosporine inhibitors, as well as nucleotide competition experiments, clearly distinguished ATPase/helicase from the carboxyl-terminal domain kinase. Using recombinant wild type or mutated p89/ERCC3 polypeptides and different forms of DNA template, we show the connection between ATPase and the helicase.

The workload of trainees in general practice.

During their first training period in general practice the authors felt that they did not encounter the balanced workload which is the foundation for learning to be a GP. Previous studies confirmed the existence of differences in overall and specific workload between trainees and trainers. From their own experience and from the relevant literature they addressed several factors which might affect the workload of trainees. A study was undertaken to determine differences in workload between trainees and trainers, and to investigate whether certain characteristics of practice and of trainees affect the workload of trainees. Details of surgery consultations with 34 trainee-trainer partnerships were recorded in the north of the Netherlands over 2 weeks. Questionnaires were filled in by trainers, trainees and practice assistants from these 34 general practices. The total number of contacts recorded was 10,103. It was found that trainees see fewer elderly and female patients, less chronic and oncological conditions, but more minor illnesses. They see only 30% of patients with problem behavior. Factors that influence the trainees' workload, as compared to their trainers' are: list size; selection in the allocation of patients; trainee's experience prior to starting the training stage, and the trainee's sex. Except for problem behaviour, trainees generally see a cross-section of their trainer's practice population. Selection would provide a more balanced workload for trainees.

Multiple phosphorylation of pp30, a rat brain polyribosomal protein, sensitive to polyamines and corticotropin.

A rat brain polyribosomal protein with an apparent Mr of 30 000, designated pp30, was further characterized. The protein was identified by its phosphorylation by an endogenous protein kinase sensitive to both corticotropin and spermine. Two-dimensional separation of a polyribosomal fraction was applied, combining non-equilibrium pH-gradient-gel electrophoresis in the first and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis in the second dimension. In this system, pp30 was separated into at least five defined phosphoprotein spots. Pulse-labelling with [gamma-32P]ATP followed by a chase for various time periods with excess unlabelled ATP resulted in a shift of the distribution of radioactivity and protein staining along the spots towards the anode. This suggests that the various spots of pp30 may represent multiple phosphorylation states. Limited proteolysis of the five spots with three different proteinases resulted in the same one-dimensional peptide maps with a given proteinase, indicating that all five spots represent different forms of a single phosphoprotein. Inhibition of the overall phosphorylation of pp30 by corticotropin or spermine was accompanied by a shift in the recovery of labelled phosphate towards spots nearer the cathode. Immunoblotting with monoclonal antibodies directed against ribosomal protein S6 stained only one band, a protein that had an apparent Mr of 34 000 and was clearly distinct from pp30.

Affinity purification of human DNA repair/transcription factor TFIIH using epitope-tagged xeroderma pigmentosum B protein.

TFIIH is a high molecular weight complex with a remarkable dual function in nucleotide excision repair and initiation of RNA polymerase II transcription. Mutations in the largest subunits, the XPB and XPD helicases, are associated with three inherited disorders: xeroderma pigmentosum, Cockayne's syndrome, and trichothiodystrophy. To facilitate the purification and biochemical characterization of this intricate complex, we generated a cell line stably expressing tagged XPB, allowing the immunopurification of the XPB protein and associated factors. Addition of two tags, a N-terminal hexameric histidine stretch and a C-terminal hemagglutinin epitope, to this highly conserved protein did not interfere with its functioning in repair and transcription. The hemagglutinin epitope allowed efficient TFIIH immunopurification to homogeneity from a fractionated whole cell extract in essentially one step. We conclude that the predominant active form of TFIIH is composed of nine subunits and that there is one molecule of XPB per TFIIH complex. The affinity-purified complex exhibits all expected TFIIH activities: DNA-dependent ATPase, helicase, C-terminal domain kinase, and participation in in vitro and in vivo nucleotide excision repair and in vitro transcription. The affinity purification procedure described here is fast and simple, does not require extensive chromatographic procedures, and yields highly purified, active TFIIH.

Structure and expression of the human XPBC/ERCC-3 gene involved in DNA repair disorders xeroderma pigmentosum and Cockayne's syndrome.

The human XPBC/ERCC-3 was cloned by virtue of its ability to correct the excision repair defect of UV-sensitive rodent mutants of complementation group 3. The gene appeared to be in addition implicated in the human, cancer prone repair disorder xeroderma pigmentosum group B, which is also associated with Cockayne's syndrome. Here we present the genomic architecture of the gene and its expression. The XPBC/ERCC-3 gene consists of at least 14 exons spread over approximately 45 kb. Notably, the donor splice site of the third exon contains a GC instead of the canonical GT dinucleotide. The promoter region, first exon and intron comprise a CpG island with several putative GC boxes. The promoter was confined to a region of 260 bp upstream of the presumed cap site and acts bidirectionally. Like the promoter of another excision repair gene, ERCC-1, it lacks classical promoter elements such as CAAT and TATA boxes, but it shares with ERCC-1 a hitherto unknown 12 nucleotide sequence element, preceding a polypyrimidine track. Despite the presence of (AU)-rich elements in the 3'-untranslated region, which are thought to be associated with short mRNA half-life actinomycin-D experiments indicate that the mRNA is very stable (t 1/2 greater than 3h). Southern blot analysis revealed the presence of XPBC/ERCC-3 cross-hybridizing fragments elsewhere in the genome, which may belong to a related gene.