Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nephropathic cystinosis, an autosomal recessively inherited lysosomal storage disease, results from impaired transport of the disulfide amino acid cystine out of cellular lysosomes. The consequent accumulation and crystallization of cystine destroys tissues, causing growth retardation in infancy, renal failure at 10 years of age, and a variety of other complications. Early oral therapy with the cystine-depleting agent cysteamine prevents renal deterioration and enhances growth. Although the lysosomal cystine carrier has been extensively studied, its molecular structure remains unknown. The lysosomal cystine transporter gene has been mapped by linkage analysis to human chromosome 17p between polymorphic microsatellite markers D17S1583 and D17S1584. Pertinent recombination events and homozygosity by descent has verified that the cystinosis gene lies in the 3.6 cM genetic interval between these two markers. The cystinosis region has been substantially reduced in size by the observation of recombination events in cystinosis patients between markers D17S1828 and D17S2167. According to radiation hybrid analysis, these two markers are separated by 10.2 cR8000 (centirad using 8000 rad radiation hybrids). Estimates of the physical size of this interval range from 187 to 510 kb. Four yeast artificial chromosomes have been identified which form a contig covering the original cystinosis region. Two P1 clones together may span the new, smaller interval, meaning that the cystinosis gene would lie on one of them. Current efforts are being directed toward using these P1 clones to isolate candidate cDNAs by a variety of methods. The ultimate cloning of the cystinosis gene will reveal how functional lysosomal porters are synthesized, targeted, processed, and integrated into the lysosomal membrane.
J Mol Med (Berl) 1998 Apr
PMID:Clinical and molecular aspects of nephropathic cystinosis. 958 63

Computational analysis of the Fanconi anemia (FA) complementation group A protein suggests that it contains a peroxidase domain. FA proteins may be part of a general mechanism that protects cells from oxidative damage.
Mol Genet Metab 1998 Mar
PMID:The Fanconi anemia complementation group A protein contains a peroxidase domain. 960 46

Mutations in genes controlling the correct functioning of the replicative, repair and recombination machineries may lead to genomic instability. A high level of spontaneous chromosomal aberrations amplified by treatment with DNA cross-linking agents is the hallmark of Fanconi anemia (FA), an inherited chromosomal instability syndrome associated with cancer proneness. Two of the eight FA genes have been cloned (FAA and FAC), but their function has not yet been defined. The lack of homology with known genes suggests the involvement of FA genes in a novel pathway specific to vertebrates. Using a DNA end-joining assay in cultured cells, we studied the processing of both blunt and cohesive-ended double strand breaks (DSB) in normal and FA cells. The results show that: (i) the overall ligation efficiency is normal in FA lymphoblasts; (ii) in FA-C, error-free processing of blunt-ended DSB is markedly decreased, resulting in a higher deletion frequency and larger deletion size; (iii) the fidelity of processing of blunt-DSB is completely restored in FACC cells (complemented with wild-type FAC gene) and the deletion size shifted to values similar to that observed in normal cells; (iv) the fidelity of cohesive end-joining is not affected in FA cells; (v) activities and/or expression of known factors involved in DSB processing, such as the components of the DNA-PK complex and XRCC4, are normal in FA cells. Our results provide strong evidence that the lack of a functional FAC gene results in loss of fidelity of end-joining, which likely accounts for the FA-C phenotype of chromosome instability. We conclude that FAC, and perhaps all FA gene products, are likely to play a role in the fidelity of end-joining of specific DSB.
J Mol Biol 1998 Jun 05
PMID:Fanconi anemia C gene product plays a role in the fidelity of blunt DNA end-joining. 964 44

Abnormalities precipitated by a targeted truncation in the murine gene Brca2 define its involvement in DNA repair. In culture, cells harboring truncated Brca2 exhibit a proliferative impediment that worsens with successive passages. Arrest in the G1 and G2/M phases is accompanied by elevated p53 and p21 expression. Increased sensitivity to genotoxic agents, particularly ultraviolet light and methylmethanesulfonate, shows that Brca2 function is essential for the ability to survive DNA damage. But checkpoint activation and apoptotic mechanisms are largely unaffected, thereby implicating Brca2 in repair. This is substantiated by the spontaneous accumulation of chromosomal abnormalities, including breaks and aberrant chromatid exchanges. These findings define a function of Brca2 in DNA repair, whose loss precipitates replicative failure, mutagen sensitivity, and genetic instability reminiscent of Bloom syndrome and Fanconi anemia.
Mol Cell 1998 Feb
PMID:Involvement of Brca2 in DNA repair. 966 Sep 19

Cells from patients with Fanconi anemia (FA) show decreased viability and decreased chromosome stability after treatment with DNA cross-linking agents, compared to normal cells. FA cells also show a relative accumulation at the G2/M transition after such treatment. This has suggested a possible checkpoint abnormality. In the studies presented here, treatment with hydroxyurea, caffeine or inhibitors of cell cycle kinases did not reveal abnormalities in survival or chromosome stability in FA-A or FA-D cells. Chromosomal breaks introduced by hydrogen peroxide or methyl methanesulfonate accumulated to the same extent in FA-A or FA-D cells as in normal cells. We conclude that FA-A and FA-D cells respond normally to agents known to alter the cell cycle or introduce DNA strand breaks. FA cells process strand breaks and a variety of DNA monoadducts normally. Our results are compatible with repair of DNA crosslinks being slower in FA than in normal cells and FA cells having normal cell cycle checkpoints.
Somat Cell Mol Genet 1997 Nov
PMID:Fanconi anemia group A and D cell lines respond normally to inhibitors of cell cycle regulation. 966

In mammalian cells, nonhomologous end-joining is the predominant mechanism to eliminate DNA double strand breaks. Such events are at the origin of deletion mutagenesis and chromosomal rearrangements. The hallmark of Fanconi anemia, an inherited cancer prone disorder, is increased chromosomal breakage associated to over-production of deletions. Knowing that double strand breaks are at the origin of deletion mutagenesis, the question arises whether their processing is affected in FA. We set up a "host cell end-joining assay" to analyze the fate of double strand breaks into extrachromosomal substrates transiently replicated in normal and FA-D lymphoblasts. Although no difference in plasmid survival was found, blunt-ended breaks were sealed with significantly lower fidelity in FA cells, resulting in a higher deletion frequency and a larger deletion size. The results suggest that FA-D and FA-B gene products are likely to play a role in end-joining fidelity of specific DNA double strand breaks.
Somat Cell Mol Genet 1997 Nov
PMID:The fidelity of double strand breaks processing is impaired in complementation groups B and D of Fanconi anemia, a genetic instability syndrome. 966 3

Fanconi anemia (FA) is an autosomal recessive cancer susceptibility syndrome with at least eight complementation groups (A-H). Two of the FA genes (FAA and FAC) have been cloned, and mutations in these genes account for approximately 80% of FA patients. Subtyping of FA patients is an important first step toward identifying candidates for FA gene therapy. In the current study, we analyzed a reference group of 26 FA patients of known subtype. Most of the patients (18/26) were confirmed as either type A or type C by immunoblot analysis with anti-FAA and anti-FAC antisera. In order to resolve the subtype of the remaining patients, we generated retroviral constructs expressing FAA and FAC for transduction of FA cell lines (pMMP-FAA and pMMP-FAC). The pMMP-FAA construct specifically complemented the abnormal phenotype of cell lines from FA-A patients, while pMMP-FAC complemented FA-C cells. In summary, the combination of immunoblot analysis and retroviral-mediated phenotypic correction of FA cells allows a rapid method of FA subtyping.
Mol Med 1998 Jul
PMID:Subtyping analysis of Fanconi anemia by immunoblotting and retroviral gene transfer. 971 25

The hallmark of Fanconi anemia (FA), a rare inherited cancer prone disorder, is a high level of chromosome breakage, spontaneous and induced by cross-linking agents. The increased genomic instability of FA is reflected at the gene level by an overproduction of intragenic deletions. Two of the eight FA genes have been cloned, however, their function remains unknown. We recently demonstrated that the lack of functional FA genes lead to a marked decrease in the fidelity of non-homologous end-joining, a pathway that mammalian cells predominantly use to repair DNA double-strand breaks (DSB). Knowing that specific DSB are generated during V(D)J recombination, here we have examined the molecular features of V(D)J rearrangements in normal and FA lymphoblasts belonging to complementation groups C and D. Using appropriate extrachromosomal recombination substrates, V(D)J coding and signal joint formation have been analysed quantitatively and qualitatively. Our results show that the frequency of coding and signal joint formation was not significantly different in normal and FA cells. However, when the fidelity of the V(D)J reaction was examined, we found that in normal human lymphoblasts V(D)J recombination proceeds with high precision, whereas, in FA cells a several fold increase in the frequency of aberrant rearrangements is associated with V(D)J coding joint formation. The abnormal recombinants that we recovered in FA are consistent with excessive degradation of DNA ends generated during the V(D)J reaction. On the basis of these findings, we propose a working model in which FA genes play a role in the control of the fidelity of rejoining of specific DNA ends. Such a defect may explain several basic features of FA, such as chromosomal instability and deletion proneness.
J Mol Biol 1998 Sep 04
PMID:Abnormal rearrangements associated with V(D)J recombination in Fanconi anemia. 971 37

Fanconi anemia (FA) is an autosomal recessive disease characterized by genomic instability, cancer susceptibility, and cellular hypersensitivity to DNA-cross-linking agents. Eight complementation groups of FA (FA-A through FA-H) have been identified. Two FA genes, corresponding to complementation groups FA-A and FA-C, have been cloned, but the functions of the encoded FAA and FAC proteins remain unknown. We have recently demonstrated that FAA and FAC interact to form a nuclear complex. In this study, we have analyzed a series of mutant forms of the FAA protein with respect to functional activity, FAC binding, and nuclear localization. Mutation or deletion of the amino-terminal nuclear localization signal (NLS) of FAA results in loss of functional activity, loss of FAC binding, and cytoplasmic retention of FAA. Replacement of the NLS sequence with a heterologous NLS sequence, derived from the simian virus 40 T antigen, results in nuclear localization but does not rescue functional activity or FAC binding. Nuclear localization of the FAA protein is therefore necessary but not sufficient for FAA function. Mutant forms of FAA which fail to bind to FAC also fail to promote the nuclear accumulation of FAC. In addition, wild-type FAC promotes the accumulation of wild-type FAA in the nucleus. Our results suggest that FAA and FAC perform a concerted function in the cell nucleus, required for the maintenance of chromosomal stability.
Mol Cell Biol 1998 Oct
PMID:Functional activity of the fanconi anemia protein FAA requires FAC binding and nuclear localization. 974 12

Selenium-dependent extracellular glutathione peroxidase (E-GPx) is found in plasma and other extracellular fluids. Previous studies have indicated that patients with chronic renal failure on dialysis have low plasma GPx activity. In this study, dialysis patients had approximately 40% of control plasma GPx activity, while anephric individuals had lowest plasma GPx activities ranging from 2 to 22% of control. The residual plasma GPx activity in anephric individuals could be completely precipitated by anti-E-GPx antibodies, indicating that all plasma GPx activity can be attributed to E-GPx in both normal and anephric individuals. Plasma GPx activity rises rapidly following kidney transplantation, often reaching normal values within 10 days. The plasma GPx activity in some transplanted patients rises to levels higher than the normal range, followed by a return to the normal range. Since E-GPx in the kidney is primarily synthesized in the proximal tubules, we investigated whether nephrotoxic agents known to disrupt proximal tubule function also affected plasma GPx activity. The beta-lactam antibiotic cephaloglycin rapidly caused a decrease in plasma GPx activity in rabbits. In addition, the chemotherapeutic agent ifosfamide caused a decrease in plasma GPx activity in pediatric osteosarcoma patients. Fanconi syndrome associated with either ifosfamide therapy or valproic acid therapy also caused a decrease in plasma GPx activity. Thus plasma GPx activity is related to kidney function and is decreased in certain situations where nephrotoxic drugs are administered. Monitoring plasma GPx activity may have predictive value in evaluating the function of transplanted kidneys or in predicting those patients particularly at risk of nephrotoxic injury associated with certain medications.
Mol Genet Metab 1998 Nov
PMID:Plasma glutathione peroxidase and its relationship to renal proximal tubule function. 985 89


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