The Fanconi anaemia group G gene FANCG is identical with XRCC9.

Fanconi anemia (FA) is an autosomal recessive disease with diverse clinical symptoms including developmental anomalies, bone marrow failure and early occurrence of malignancies. In addition to spontaneous chromosome instability, FA cells exhibit cell cycle disturbances and hypersensitivity to cross-linking agents. Eight complementation groups (A-H) have been distinguished, each group possibly representing a distinct FA gene. The genes mutated in patients of complementation groups A (FANCA; refs 4,5) and C (FANCC; ref. 6) have been identified, and FANCD has been mapped to chromosome band 3p22-26 (ref. 7). An additional FA gene has recently been mapped to chromosome 9p (ref. 8). Here we report the identification of the gene mutated in group G, FANCG, on the basis of complementation of an FA-G cell line and the presence of pathogenic mutations in four FA-G patients. We identified the gene as human XRCC9, a gene which has been shown to complement the MMC-sensitive Chinese hamster mutant UV40, and is suspected to be involved in DNA post-replication repair or cell cycle checkpoint control. The gene is localized to chromosome band 9p13 (ref. 9), corresponding with a known localization of an FA gene.

Inactivation of Fac in mice produces inducible chromosomal instability and reduced fertility reminiscent of Fanconi anaemia.

Fanconi anaemia (FA) is an autosomal recessive disease characterized by bone marrow failure, variable congenital malformations and predisposition to malignancies. Cells derived from FA patients show elevated levels of chromosomal breakage and an increased sensitivity to bifunctional alkylating agents such as mitomycin C (MMC) and diepoxybutane (DEB). Five complementation groups have been identified by somatic cell methods, and we have cloned the gene defective in group C (FAC)(7). To understand the in vivo role of this gene, we have disrupted murine Fac and generated mice homozygous for the targeted allele. The -/- mice did not exhibit developmental abnormalities nor haematologic defects up to 9 months of age. However, their spleen cells had dramatically increased numbers of chromosomal aberrations in response to MMC and DEB. Homozygous male and female mice also had compromised gametogenesis, leading to markedly impaired fertility, a characteristic of FA patients. Thus, inactivation of Fac replicates some of the features of the human disease.

Expression cloning of a cDNA for the major Fanconi anaemia gene, FAA.

Fanconi anaemia (FA) is an autosomal recessive disorder characterized by a diversity of clinical symptoms including skeletal abnormalities, progressive bone marrow failure and a marked predisposition to cancer. FA cells exhibit chromosomal instability and hyper-responsiveness to the clastogenic and cytotoxic effects of bifunctional alkylating (cross-linking) agents, such as diepoxybutane (DEB) and mitomycin C (MMC). Five complementation groups (A-E) have been distinguished on the basis of somatic cell hybridization experiments, with group FA-A accounting for over 65% of the cases analysed. A cDNA for the group C gene (FAC) was reported and localized to chromosome 9q22.3 (ref.8). Genetic map positions were recently reported for two more FA genes, FAA (16q24.3) and FAD (3p22-26). Here we report the isolation of a cDNA representing the FAA gene, following an expression cloning method similar to the one used to clone the FAC gene. The 5.5-kb cDNA has an open reading frame of 4,368 nucleotides. In contrast to the 63-kD cytosolic protein encoded by the FAC gene, the predicted FAA protein (M(r) 162, 752) contains two overlapping bipartite nuclear localization signals and a partial leucine zipper consensus, which are suggestive of a nuclear localization.

Hematopoietic compartment of Fanconi anemia group C null mice contains fewer lineage-negative CD34+ primitive hematopoietic cells and shows reduced reconstruction ability.

Fanconi anemia (FA) is a complex recessive genetic disease that causes bone marrow failure in children. The mechanism by which the gene for FA group C (Fancc) impinges on the normal hematopoietic program is unknown. Here we demonstrate that the bone marrow from Fancc-/- mice have reduced ability for primary and secondary long-term reconstitution of myeloablated recipients compared to wild-type or heterozygous mice, indicating that the Fancc gene product is required for the maintenance of normal numbers of hematopoietic stem cells. Long-term and secondary transplant studies suggested that there also were qualitative changes in their developmental potential. Consistent with the reduction in reconstitution, flow cytometric analysis of the primitive subfractions of hematopoietic cells obtained from the bone marrow of Fancc -/- mice demonstrated that they contained 40 to 70% fewer lineage-negative (Lin-)Thy1.2-/lowScal(+) c-Kit(+)CD34+ cells compared to controls. In contrast, the number of Lin Thy1.2-/ lowScal(+)c-Kit CD34(-)cells was comparable to that of wild-type mice. The differential behavior of Lin(-)Thy1.2-/lowScal+c-Kit+CD34+ and Lin(-)Thy1.2-/lowScal(+)c-Kit CD34 subfractions also was observed in mice treated with the DNA cross-linking agent mitomycin C(MMC). Fancc-/- mice treated with MMC had an 92% reduction of CD34 cells as compared to Fancc+/+ mice. The number of CD34 cells only was reduced about 20%. These results suggest that the Fancc gene may act at a stage of primitive hematopoietic cell development identified by CD34 expression.

Functional retroviral vector for gene therapy of xeroderma pigmentosum group D patients.

Xeroderma pigmentosum (XP) is an autosomal recessive genetic disorder characterized by an increased frequency of skin cancer following minimal sunlight exposure. Cells isolated from XP patients are also hypersensitive to UV rays and UV-like chemicals. This sensitivity is directly related to a defect in the early steps of nucleotide excision repair (NER) of damaged DNA. No efficient treatment is available for this disease and skin cancer prevention can only be achieved by strict avoidance of sunlight exposure. Thus, we are developing a model for gene therapy in XP, particularly for patients belonging to group D. We report here the construction of a retroviral vector (LXPDSN) containing the XPD (ERCC2) cDNA, which fully complements the DNA repair deficiency of primary skin fibroblasts. Efficient integration, mRNA synthesis, and protein expression of the XPD gene were obtained in all LXPDSN-transduced XP-D fibroblasts tested. Full correction of the DNA repair defect was observed with all DNA repair assays used, such as an increased survival after UV-radiation of the transduced cells, a normal level of DNA repair synthesis (UDS), and the reactivation of a UV-irradiated reporter vector. This retroviral vector will be used to modify keratinocytes genetically to produce repair proficient reconstituted skin for engraftment to XP patients.

Transcription-dependent and independent DNA excision repair pathways in human cells.

alpha-Amanitin, an inhibitor of RNA polymerase II, has little effect on either UV-induced incision or repair synthesis in cultured normal human fibroblasts but almost completely inhibits both processes in xeroderma pigmentosum group C fibroblasts. Cycloheximide, at a concentration which inhibits protein synthesis by 75-80%, has no effect on incision or repair synthesis in either cell type, which argues that the effects of alpha-amanitin on repair occur at the level of transcription. Cot analysis demonstrates that UV-induced repair synthesis occurs at similar levels in highly repetitive, middle repetitive and single copy sequence in both normal and xeroderma group C cells. We conclude that normal cells must have at least two excision repair pathways for repair of UV-induced damage, one dependent on transcription and the other independent.

Drug sensitivity spectra in Fanconi anemia lymphoblastoid cell lines of defined complementation groups.

Fanconi anemia (FA) is one of several genetic diseases with characteristic cellular hypersensitivity to DNA crosslinking agents which suggest that FA proteins may function as part of DNA repair processes. At the clinical level, FA is characterized by bone marrow failure that affects children at an early age. The clinical phenotype is heterogeneous and includes various congenital malformations as well as cancer predisposition. FA patients are distributed into eight complementation groups suggesting a complex molecular pathway. Three of the eight possible FA genes have been cloned, although their function(s) have not been identified. FA cells are highly sensitive to DNA crosslinking agents (mitomycin C (MMC) and diepoxybutane), with some variability between cell lines. Sensitivity to monofunctional alkylating agents has been reported in some cases, although these studies were performed with genetically unclassified FA cells. To further analyse and characterize the newly identified FA complementation groups, we tested their sensitivity to UV radiation, monofunctional and bifunctional alkylating agents and to the X-ray mimetic drug bleomycin. We found that FA complementation groups D to H show increased sensitivity to the X-ray mimetic drug bleomycin. Furthermore, the single known FA-H cell line shows increased sensitivity to ethylethane sulfonate (EMS), methylmethane sulfonate (MMS) in addition to the characteristic sensitivity to crosslinking agents, suggesting a broader spectrum of drug sensitivities in FA cells.

Development and characterization of immortalized fibroblastoid cell lines from an FA(C) mouse model.

Fanconi anemia (FA) is an autosomal recessive disorder, characterised by multiple congenital malformations, bone marrow failure and a predisposition to developing malignancies, especially leukemia. FA cells show increased levels of spontaneous chromosomal aberrations and a hypersensitivity to DNA cross-linking agents such as mitomycin C (MMC) and diepoxybutane (DEB). There are at least eight complementation groups involved in FA, and the genes for two of these groups, FA(A) and FA(C), have been isolated and cloned. Mouse models for FA(C) have been developed by replacing exon 8 or exon 9 of Fac with the neo gene. Mice homozygous for Fac mutations show reduced fertility and hypersensitivity to induction of chromosomal aberrations by MMC and DEB. To facilitate the study of cellular defects in vitro, transformed mouse fibroblast cell lines were established. Cell-killing experiments and cytogenetic analyses were performed on these cells following treatment with MMC and DEB. Fac-/- showed significant hypersensitivity to MMC and DEB as compared with Fac+/+ and +/- for both cellular phenotypes. This is consistent with results obtained from similar studies on human fibroblasts and lymphoblastoid cell lines. Therefore, these isogenic transformed mouse fibroblasts provide as in vitro model for further investigation of the hypersensitivity of Fanconi anemia cells to DNA cross-linking agents.

Fanconi's anemia: what have we learned from the genes so far?

Fanconi's anemia (FA) is a rare genetic disorder affecting children at an early age; patients suffer from progressive bone marrow failure and, in many cases, from congenital malformations. As cells from FA patients have an increased sensitivity to DNA-crosslinking agents, FA has been included among the group of DNA repair disorders. However, identification of a specific DNA repair defect in FA has not been firmly established. None the less, this cellular phenotype has allowed the classification of FA patients into eight complementation groups defining eight possible FA genes. Two of these genes have now been cloned and, although they have raised more questions than they have answered, are facilitating the identification of cellular processes implicated in the pathophysiology of FA, and the design of new therapies.

The Fanconi anemia genes.

Until recently, it had been thought that Fanconi anemia patients were distributed into five complementation groups. However, evidence now points to the existence of three new complementation groups, making the genetic basis of the disease more complicated than anticipated. Also, during the past year, the cloning of a second Fanconi anemia gene by both functional complementation and positional cloning has accelerated research of this disease. Although two genes of the eight characterized complementation groups have now been cloned, the function of their gene products still needs to be identified.

Bronchoalveolar lavage cell differential on microscope glass cover. A simple and accurate technique.

We describe a quick and easy technique to perform cell differentials on bronchoalveolar lavage: the microscope glass cover. Lavage fluids of 72 subjects were analyzed by 3 techniques: glass cover, filter, and cytocentrifuge preparations. Seventy-seven other lavages were analyzed by glass cover and cytocentrifuge preparations alone. Data for the 72 subjects studied by all 3 techniques showed that the cell counts on glass cover and filter preparations were similar, e.g., lymphocytes, 19.2% (range, 0.5 to 94%) and 20.9% (range, 3 to 95%), respectively (Spearman's correlation coefficient, 0.98). However, on cytocentrifuge preparations, lymphocyte counts were lower (8.3%; range, zero to 87%) and macrophage counts were higher (p less than 0.005). Comparison of glass cover and cytocentrifuge preparation mixtures with varying amounts (20 to 80%) of purified blood leukocytes labeled with 51Cr (greater than or equal to 72% lymphocytes) showed that a significant amount of radioactive cells was lost during the cytocentrifuge technique in contrast to the glass cover technique. Because neutrophils represented a low proportion of lavage cells, we also evaluated cell suspensions with known neutrophil contents (10 to 70%); we found no difference in neutrophil counts obtained with the 3 techniques. Lavage data analysis of 40 young nonsmoking volunteers showed that glass cover lymphocyte count was also higher than counts on cytocentrifuge preparations: 16.5% (range, 3 to 45%) and 8.2% (range, 2.5 to 35%), respectively. In this group, the distribution of glass cover lymphocyte percentages was normal (p = 0.21, chi 2 test), and the one-tailed 95% confidence interval was 18.6 to 34.7% (mean plus 1.65 standard deviation).(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolism of arachidonic acid through the 5-lipoxygenase pathway in normal human peritoneal macrophages.

Peritoneal macrophages (PM), obtained from 39 healthy women with normal laparoscopy findings, were stimulated with the ionophore A23187 or/and arachidonic acid (AA) both in adherence and in suspension. AA lipoxygenase metabolites were determined by reversed-phase HPLC. The major metabolites identified were 5-hydroxyeicosatetraenoic acid (5-HETE), leukotriene (LT)B4 and LTC4. The 20-hydroxy-LTB4, 20-carboxy-LTB4, and 15-HETE were not detected. Incubations of adherent PM with 2 microM A23187 induced the formation of LTB4, 110 +/- 19 pmol/10(6) cells, 5-HETE, 264 +/- 53 pmol/10(6) cells and LTC4, 192 +/- 37 pmol/10(6) cells. When incubated with 30 microM exogenous AA, adherent PM released similar amounts of 5-HETE (217 +/- 67 pmol/10(6) cells), but sevenfold less LTC4 (27 +/- 12 pmol/10(6) cells) (p less than 0.01). In these conditions LTB4 was not detectable. These results indicate that efficient LT synthesis in PM requires activation of the 5-lipoxygenase/LTA4 synthase, as demonstrated previously for blood phagocytes. When stimulated with ionophore, suspensions of Ficoll-Paque-purified PM produced the same lipoxygenase metabolites. The kinetics of accumulation of the 5-lipoxygenase/LTA4 synthase products in A23187-stimulated adherent cells varied for the various metabolites. LTB4 reached a plateau by 5 min, whereas LTC4 levels increased up to 60 min, the longest incubation time studied. Levels of 5-HETE were maximal at 5 min, and then slowly decreased with time. Thus, normal PM, in suspension or adherence, have the capacity to produce significant amounts of 5-HETE, LTB4, and LTC4. The profile of lipoxygenase products formed by the PM and the reactivity of this cell to AA and ionophore A23187 are similar to those of the human blood monocyte, but different from those of the human alveolar macrophage.

Loss of FancC function results in decreased hematopoietic stem cell repopulating ability.

Fanconi anemia (FA) is a complex genetic disorder characterized by progressive bone marrow (BM) aplasia, chromosomal instability, and acquisition of malignancies, particularly myeloid leukemia. We used a murine model containing a disruption of the murine homologue of FANCC (FancC) to evaluate short- and long-term multilineage repopulating ability of FancC -/- cells in vivo. Competitive repopulation assays were conducted where "test" FancC -/- or FancC +/+ BM cells (expressing CD45.2) were cotransplanted with congenic competitor cells (expressing CD45.1) into irradiated mice. In two independent experiments, we determined that FancC -/- BM cells have a profound decrease in short-term, as well as long-term, multilineage repopulating ability. To determine quantitatively the relative production of progeny cells by each test cell population, we calculated test cell contribution to chimerism as compared with 1 x 10(5) competitor cells. We determined that FancC -/- cells have a 7-fold to 12-fold decrease in repopulating ability compared with FancC +/+ cells. These data indicate that loss of FancC function results in reduced in vivo repopulating ability of pluripotential hematopoietic stem cells, which may play a role in the development of the BM failure in FA patients. This model system provides a powerful tool for evaluation of experimental therapeutics on hematopoietic stem cell function.

Multiple inhibitory cytokines induce deregulated progenitor growth and apoptosis in hematopoietic cells from Fac-/- mice.

We used a murine model containing a disruption of the murine homologue (Fac) of Fanconi Anemia group C (FAC) to evaluate the role of Fac in the pathogenesis of bone marrow (BM) failure. Methylcellulose cultures of BM cells from Fac-/- and Fac+/+ mice were established to examine the growth of multipotent and lineage-restricted progenitors containing inhibitory cytokines, including interferon-gamma (IFN-gamma), tumor necrosis factor-alpha (TNF-alpha), and macrophage inflammatory protein-1alpha (MIP-1alpha). Clonogenic growth of Fac-/- progenitors was reduced by 50% at 50- to 100-fold lower concentrations of all inhibitory cytokines evaluated. We hypothesized that the aberrant responsiveness to inhibitory cytokines in clonogenic cells may be a result of deregulated apoptosis. To test this hypothesis, we performed the TUNEL assay on purified populations of primary BM cells enriched for hematopoietic progenitors or differentiated myeloid cells. After stimulation with TNF-alpha, accentuated apoptosis was observed in both populations of Fac-/- cells. In addition, deregulated apoptosis was also noted in the most immature phenotypic population of hematopoietic cells after stimulation with MIP-1alpha. Together these data suggest a role of Fac in affecting the signaling of multiple cytokine pathways and support cytokine-mediated apoptosis as a major mechanism responsible for BM failure observed in FA patients.

Bone marrow failure in the Fanconi anemia group C mouse model after DNA damage.

Fanconi anemia (FA) is a pleiotropic inherited disease that causes bone marrow failure in children. However, the specific involvement of FA genes in hematopoiesis and their relation to bone marrow (BM) failure is still unclear. The increased sensitivity of FA cells to DNA cross-linking agents such as mitomycin C (MMC) and diepoxybutane (DEB), including the induction of chromosomal aberrations and delay in the G2 phase of the cell cycle, have suggested a role for the FA genes in DNA repair, cell cycle regulation, and apoptosis. We previously reported the cloning of the FA group C gene (FAC) and the generation of a Fac mouse model. Surprisingly, the Fac -/- mice did not show any of the hematologic defects found in FA patients. To better understand the relationship of FA gene functions to BM failure, we have analyzed the in vivo effect of an FA-specific DNA damaging agent in Fac -/- mice. The mice were found to be highly sensitive to DNA cross-linking agents; acute exposure to MMC produced a marked BM hypoplasia and degeneration of proliferative tissues and caused death within a few days of treatment. However, sequential, nonlethal doses of MMC caused a progressive decrease in all peripheral blood parameters of Fac -/- mice. This treatment targeted specifically the BM compartment, with no effect on other proliferative tissues. The progressive pancytopenia resulted from a reduction in the number of early and committed hematopoietic progenitors. These results indicate that the FA genes are involved in the physiologic response of hematopoietic progenitor cells to DNA damage.

Development of a new easy complementation assay for DNA repair deficient human syndromes using cloned repair genes.

Nucleotide excision repair (NER)-deficient human cells have been assigned so far to a genetic complementation group by a somatic cell fusion assay and, more recently, by microinjection of cloned DNA repair genes. We describe a new technique, based on the host cell reactivation assay, for the rapid determination of the complementation group of NER-deficient xeroderma pigmentosum (XP), Cockayne's syndrome (CS) and photosensitive trichothiodystrophy (TTD) human cells by cotransfection of a UV-irradiated reporter plasmid with a second vector containing a cloned repair gene. Expression of the reporter gene, either chloramphenicol acetyltransferase (CAT) or luciferase, reflects the DNA repair ability restored by the introduction of the appropriate repair gene. All genetically characterized XP, CS and TTD/XP-D cells tested failed to express the UV-irradiated reporter gene, this reflecting their NER deficiency whereas cotransfection with the repair plasmid expressing a gene specific for the given complementation group increased the enzyme activity to the level reached by normal cells. Selective recovery of both reporter enzyme activities was observed after cotransfection with the XPC gene for the XP17VI cells and with the XPA gene for both XP18VI and XP19VI cells. Using this method, we assigned three new NER-deficient human cells obtained from patients presenting clinical symptoms described as classical XP to either XP group A (XP18VI and XP19VI) and XP group C (XP17VI). Therefore, this technique increases the range of methods now available to determine the complementation group of new NER deficient patients with the advantage, unlike the somatic cell fusion assay or the microinjection procedure, of being simple, rapid, and inexpensive.

Correction by the ERCC2 gene of UV sensitivity and repair deficiency phenotype in a subset of trichothiodystrophy cells.

Trichothiodystrophy (TTD) is a rare genetic disease with heterogeneous clinical features associated with specific deficiencies in nucleotide excision repair. Patients have brittle hair due to a reduced content of cysteine-rich matrix proteins. About 50% of the cases reported in the literature are photosensitive. In these patients an altered cellular response to UV, due to a specific deficiency in nucleotide excision repair, has been observed. The majority of repair-defective TTD patients have been assigned by complementation analysis to group D of xeroderma pigmentosum (XP). Recently, the human excision repair gene ERCC2 has been shown to correct the UV sensitivity of XP-D fibroblasts. In this work we describe the effect of ERCC2 on the DNA repair deficient phenotype of XP-D and on two repair-defective TTD cell strains (TTD1VI and TTD2VI) assigned by complementation analysis to group D of XP. ERCC2 cDNA, cloned into a mammalian expression vector, was introduced into TTD and XP fibroblasts via DNA-mediated transfection or microneedle injection. UV sensitivity and cellular DNA repair properties, including unscheduled DNA synthesis and reactivation of a UV-irradiated plasmid containing the chloramphenicol acetyltransferase reporter gene (pRSVCat), were corrected to wild-type levels in both TTD and XP-D cells. These data show that a functional ERCC2 gene is sufficient to reestablish a wild-type DNA repair phenotype in TTD1VI and TTD2VI cells, confirming the genetic relationship between TTD and XP-D. Furthermore, our findings suggest that mutations at the ERCC2 locus are responsible for causing a similar phenotype in TTD and XP-D cells in response to UV irradiation, but produce quite different clinical symptoms.

Lack of interaction between hepatitis C virus and alcohol in the pathogenesis of cirrhosis. A statistical study.

BACKGROUND/AIMS: In several studies markers of hepatitis C virus infection have been shown to be present in alcoholic patients with cirrhosis. Our work was designed to test the likely hypothesis that this association is due to an interaction between hepatitis C virus and alcohol in the pathogenesis of cirrhosis. METHODS: We compared alcohol consumption and repartition of anti-HCV antibodies detected by an immunoblot recombinant assay in 101 male patients with cirrhosis and in 120 male controls. Interactions between anti-hepatitis C virus, alcohol and cirrhosis were calculated using log linear hierarchical models for frequency data. The basis of the method is that an interaction between hepatitis C virus and alcohol implies that a model built on the hypothesis of a role of hepatitis C virus and alcohol in the disease should be improved by a coefficient associated with multiplicative effects of hepatitis C virus and alcohol. RESULTS: In patients with cirrhosis the mean alcohol consumption (148 +/- 100 g per day) and the incidence of positivity for anti-HCV antibodies (45%) were significantly higher than in controls. The results were consistent with a theoretical model built with the hypothesis of an independent role of both alcohol and hepatitis C virus. The goodness of fit between this model and the actual distribution of alcohol consumption and hepatitis C virus markers was not improved by introduction of an interaction between hepatitis C virus and alcohol. CONCLUSIONS: In alcoholic subjects with hepatitis C virus infection, the probability to have cirrhosis seemed to be explained by additive effects of alcohol and hepatitis C virus. From a purely statistical point of view, no interaction between hepatitis C virus and alcohol consumption on a multiplicative scale could be demonstrated.