Topo IIIalpha and BLM act within the Fanconi anemia pathway in response to DNA-crosslinking agents.

The Bloom protein (BLM) and Topoisomerase IIIalpha are found in association with proteins of the Fanconi anemia (FA) pathway, a disorder manifesting increased cellular sensitivity to DNA crosslinking agents. In order to determine if the association reflects a functional interaction for the maintenance of genome stability, we have analyzed the effects of siRNA-mediated depletion of the proteins in human cells. Depletion of Topoisomerase IIIalpha or BLM leads to increased radial formation, as is seen in FA. BLM and Topoisomerase IIIalpha are epistatic to the FA pathway for suppression of radial formation in response to DNA interstrand crosslinks since depletion of either of them in FA cells does not increase radial formation. Depletion of Topoisomerase IIIalpha or BLM also causes an increase in sister chromatid exchanges, as is seen in Bloom syndrome cells. Human Fanconi anemia cells, however, do not demonstrate increased sister chromatid exchanges, separating this response from radial formation. Primary cell lines from mice defective in both Blm and Fancd2 have the same interstrand crosslink-induced genome instability as cells from mice deficient in the Fancd2 protein alone. These observations demonstrate that the association of BLM and Topoisomerase IIIalpha with Fanconi proteins is a functional one, delineating a BLM-Topoisomerase IIIalpha-Fanconi pathway that is critical for suppression of chromosome radial formation.

Mammalian SNM1 is required for genome stability.

The protein encoded by SNM1 in Saccharomyces cerevisiae has been shown to act specifically in DNA interstrand crosslinks (ICL) repair. There are five mammalian homologs of SNM1, including Artemis, which is involved in V(D)J recombination. Cells from mice constructed with a disruption in the Snm1 gene are sensitive to the DNA interstrand crosslinker, mitomycin (MMC), as indicated by increased radial formation following exposure. The mice reproduce normally and have normal life spans. However, a partial perinatal lethality, not seen in either homozygous mutant alone, can be noted when the Snm1 disruption is combined with a Fancd2 disruption. To explore the role of hSNM1 and its homologs in ICL repair in human cells, we used siRNA depletion in human fibroblasts, with cell survival and chromosome radials as the end points for sensitivity following treatment with MMC. Depletion of hSNM1 increases sensitivity to ICLs as detected by both end points, while depletion of Artemis does not. Thus hSNM1 is active in maintenance of genome stability following ICL formation. To evaluate the epistatic relationship between hSNM1 and other ICL repair pathways, we depleted hSNM1 in Fanconi anemia (FA) cells, which are inherently sensitive to ICLs. Depletion of hSNM1 in an FA cell line produces additive sensitivity for MMC. Further, mono-ubiquitination of FANCD2, an endpoint of the FA pathway, is not disturbed by depletion of hSNM1 in normal cells. Thus, hSNM1 appears to represent a second pathway for genome stability, distinct from the FA pathway.

Fifty-four new gene-based canine microsatellite markers.

Fifty-four new markers were developed to fill in gaps in the current map of canine microsatellites and to complement existing markers that may not be sufficiently informative in highly inbred canine pedigrees. Canine genes contained on the radiation hybrid map were used to obtain the sequence of the human homolog. A BLAST search versus the canine whole genome shotgun (wgs) sequence resource was used to obtain the sequence of the canine genomic contigs containing the homolog of the corresponding human gene. Canine sequences that contained microsatellites and mapped back to the correct location in the human genome were used to design primers for amplification of the microsatellites from canine genomic DNA. Heterozygosities of the markers were tested by genotyping grandparental DNAs obtained from the Nestle Purina Reference family DNA distribution center plus DNAs from unrelated Bouviers and Irish wolfhounds. Canine map positions of markers on the July 2004 freeze of the canine genome assembly were determined by in silico PCR or BLAST.

Novel lamin A/C mutations in two families with dilated cardiomyopathy and conduction system disease.

BACKGROUND: The LMNA gene, one of 6 autosomal disease genes implicated in familial dilated cardiomyopathy, encodes lamins A and C, alternatively spliced nuclear envelope proteins. Mutations in lamin A/C cause 4 diseases: Emery-Dreifuss muscular dystrophy, limb girdle muscular dystrophy type 1B, Dunnigan-type familial partial lipodystrophy, and dilated cardiomyopathy. METHODS AND RESULTS: Two 4-generation white families with autosomal dominant familial dilated cardiomyopathy and conduction system disease were found to have novel mutations in the rod segment of lamin A/C. In family A a missense mutation (nucleotide G607A, amino acid E203K) was identified in 14 adult subjects; disease was manifest as progressive conduction disease in the fourth and fifth decades. Death was caused by heart failure. In family B a nonsense mutation (nucleotide C673T, amino acid R225X) was identified in 10 adult subjects; disease was also manifest as progressive conduction disease but with earlier onset (third and fourth decades), ventricular dysrhythmias, left ventricular enlargement, and systolic dysfunction. Death was caused by heart failure and sudden cardiac death. Skeletal muscle disease was not observed in either family. CONCLUSIONS: Novel rod segment mutations in lamin A/C cause variable conduction system disease and dilated cardiomyopathy without skeletal myopathy.

Localization of the Fanconi anemia complementation group D gene to a 200-kb region on chromosome 3p25.3.

Fanconi anemia (FA) is a rare autosomal recessive disease manifested by bone-marrow failure and an elevated incidence of cancer. Cells taken from patients exhibit spontaneous chromosomal breaks and rearrangements. These breaks and rearrangements are greatly elevated by treatment of FA cells with the use of DNA cross-linking agents. The FA complementation group D gene (FANCD) has previously been localized to chromosome 3p22-26, by use of microcell-mediated chromosome transfer. Here we describe the use of noncomplemented microcell hybrids to identify small overlapping deletions that narrow the FANCD critical region. A 1.2-Mb bacterial-artificial-chromosome (BAC)/P1 contig was constructed, bounded by the marker D3S3691 distally and by the gene ATP2B2 proximally. The contig contains at least 36 genes, including the oxytocin receptor (OXTR), hOGG1, the von Hippel-Lindau tumor-suppressor gene (VHL), and IRAK-2. Both hOGG1 and IRAK-2 were excluded as candidates for FANCD. BACs were then used as probes for FISH analyses, to map the extent of the deletions in four of the noncomplemented microcell hybrid cell lines. A narrow region of common overlapping deletions limits the FANCD critical region to approximately 200 kb. The three candidate genes in this region are TIGR-A004X28, SGC34603, and AA609512.

Autosomal-dominant congenital cataract associated with a deletion mutation in the human beaded filament protein gene BFSP2.

Congenital cataracts are a common major abnormality of the eye that frequently cause blindness in infants. At least one-third of all cases are familial; autosomal-dominant congenital cataract appears to be the most-common familial form in the Western world. Elsewhere, in family ADCC-3, we mapped an autosomal-dominant cataract gene to chromosome 3q21-q22, near the gene that encodes a lens-specific beaded filament protein gene, BFSP2. By sequencing the coding regions of BFSP2, we found that a deletion mutation, DeltaE233, is associated with cataracts in this family. This is the first report of an inherited cataract that is caused by a mutation in a cytoskeletal protein.

Embryonic stem cells can be used to construct hybrid cell lines containing a single, selectable murine chromosome.

Microcell-mediated chromosome transfer is a useful technique for the study of gene function, gene regulation, gene mapping, and functional cloning in mammalian cells. Complete panels of donor cell lines, each containing a different human chromosome, have been developed. These donor cell lines contain a single human chromosome marked with a dominant selectable gene in a rodent cell background. However, a similar panel does not exist for murine chromosomes. To produce mouse monochromosomal donor hybrids, we have utilized embryonic stem (ES) cells with targeted gene disruptions of known chromosomal location as starting material. ES cells with mutations in aprt, fyn, and myc were utilized to generate monochromosomal hybrids with neomycin phosphotransferase-marked murine Chr 8, 10, or 15 respectively in a hamster or rat background. This same methodology can be used to generate a complete panel of marked mouse chromosomes for somatic cell genetic experimentaion.

Complementation group assignments in Fanconi anemia fibroblast cell lines from North America.

Fanconi anemia is a rare autosomal recessive disease characterized by developmental defects of the thumb and radius, childhood onset of pancytopenic anemia and increased risk of leukemia. At least five complementation groups (A-E) have been defined but only the FAC gene has been cloned. Cells can be assigned to complementation group C by direct mutation analysis. To facilitate the search for additional FA genes and to measure the frequency of complementation groups, we have established new genetically marked immortalized FA-A and FA-D fibroblast cell lines and show their usefulness as universal fusion donors. These reference FA cell lines facilitated somatic cell fusion analysis and enabled us to assign the complementation group in 16 unrelated FA patients from North America. The majority of patients, belong to FA complementation group A (69%), followed by FA-C (18%), FA-D (4%) and FA-B or FA-E (9%).

Immortalization of four new Fanconi anemia fibroblast cell lines by an improved procedure.

Fanconi anemia (FA) is an autosomal recessive disease characterized by birth defects, progressive bone marrow failure and increased risk for leukemia. FA cells display chromosome breakage and increased cell killing in response to DNA crosslinking agents. At least 5 genes have been defined by cell complementation studies, but only one of these, FAC has been cloned to date. Efforts to map and isolate new FA genes by functional complementation have been hampered by the lack of immortalized FA fibroblast cell lines. Here we report the use of a novel immortalization strategy to create 4 new immortalized FA fibroblast lines, including one from the rare complementation group D.

Microcell mediated chromosome transfer maps the Fanconi anaemia group D gene to chromosome 3p.

Fanconi anaemia (FA) is an autosomal recessive disorder characterized by progressive pancytopenia, short stature, radial ray defects, skin hyperpigmentation and a predisposition to cancer. Cells from FA patients are hypersensitive to cell killing and chromosome breakage induced by DNA cross-linking agents such as mitomycin C (MMC) and diepoxybutane (DEB). Consequently, the defect in FA is thought to be in DNA crosslink repair. Additional cellular phenotypes of FA include oxygen sensitivity, poor cell growth and a G2 cell cycle delay. At least 5 complementation groups for Fanconi anaemia exist, termed A through E. One of the five FA genes, FA(C), has been identified by cDNA complementation, but no other FA genes have been mapped or cloned until now. The strategy of cDNA complementation, which was successful for identifying the FA(C) gene has not yet been successful for cloning additional FA genes. The alternative approach of linkage analysis, followed by positional cloning, is hindered in FA by genetic heterogeneity and the lack of a simple assay for determining complementation groups. In contrast to genetic linkage studies, microcell mediated chromosome transfer utilizes functional complementation to identify the disease bearing chromosome. Here we report the successful use of this technique to map the gene for the rare FA complementation group D (FA(D)).

Cloning and characterization of a human cDNA (INPPL1) sharing homology with inositol polyphosphate phosphatases.

We have cloned a novel human cDNA, INPPL1 (GenBank Accession No. L36818), which maps to 11q23. The corresponding mRNA is 4657 nt in length and is widely expressed in both fetal and adult tissues. An open reading frame of 3441 nt encodes a putative polypeptide that shares several domains with inositol triphosphate phosphatases. Several polymorphisms have been mapped to the 3'-untranslated region, yet the putative coding region showed no polymorphisms in nine independent cDNA samples.

Fanconi anemia cells have a normal gene structure for topoisomerase I.

Cells from Fanconi anemia (FA) patients have defective DNA repair and are hypersensitive to DNA crosslinking agents such as mitomycin C (MMC). We examined the possibility that topoisomerase I is involved in the DNA crosslink repair system and is deficient in FA group A cells. FA cells and control cells were exposed to MMC with or without camptothecin (CPT), a topoisomerase I inhibitor. The cells did not show any increased sensitivity to killing by MMC with CPT, suggesting that the topoisomerase I is not involved in MMC-damaged DNA repair. However, FA cells showed increased sensitivity to CPT in comparison to control cells, raising the possibility of altered topoisomerase I in FA cells. Therefore, a mutation analysis was performed on topoisomerase I cDNA from FA cells by using chemical cleavage mismatch scanning and nucleotide sequencing. No mutation was detected from GM1309, a group A FA cell line. A base transition (C to T) at position 241, causing an amino acid change (His to Tyr), was found in GM2061, a FA cell line of unknown complementation group. However, allele-specific oligonucleotide hybridization analysis showed that this is a gene polymorphism. We conclude that FA cells have normal gene structure for topoisomerase I.

A common mutation in the FACC gene causes Fanconi anaemia in Ashkenazi Jews.

Fanconi anaemia is an autosomal recessive disease for which four known complementation groups exist. Recently, the gene defective in complementation group C (FACC) has been cloned. In order to determine the fraction of Fanconi anaemia caused by FACC mutations, we used reverse transcription PCR and chemical mismatch cleavage (CMC) to examine the FACC cDNA in 17 FA cell lines. 4/17 patients (23.5%) had mutations in this gene. Two Ashkenazi-Jewish individuals were homozygous for an identical splice mutation. Three additional Jewish patients bearing this allele were found upon screening 21 other families. We conclude that a common mutation in FACC accounts for the majority of Fanconi anaemia in Ashkenazi-Jewish families.