UMLS:C0162871 - FACTA Search

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Query: UMLS:C0162871 (abdominal aortic aneurysm)
8,664 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A patient with bilateral retinoblastoma and subsequent multiple primary osteosarcomas has been described previously. Osteosarcoma cell lines established from this patient were shown to express a shortened RB1 mRNA transcript and no detectable normal Rb protein. We now show that the osteosarcoma cell lines have lost one TP53 allele and contain a mutation in exon 8 codon 286 [GAA to AAA (Glu to Lys)] in the remaining allele. Consequently, the osteosarcoma cell lines have no normal Rb protein and no normal p53 protein. Neither constitutional DNA nor DNA extracted from a retinoblastoma of the left eye of the patient contained the TP53 mutation, suggesting that the TP53 mutation in the osteosarcoma cells may represent a tumor-promoting mutation, which confers a selective growth advantage. If both RB1 and TP53 are involved in the initiation of osteosarcoma, the mechanisms for development of the retinoblastoma and osteosarcoma tumors are different.
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PMID:A TP53 mutation detected in cells established from an osteosarcoma, but not in the retinoblastoma of a patient with bilateral retinoblastoma and multiple primary osteosarcomas. 133 9

The redundant genetic codons NNU and NNC (where N is A, T, G, or C) specify the same amino acid and are decoded by their cognate tRNAs, which contain either a guanosine or a modified base in the wobble position of the anticodons. Since tRNAs with an adenosine in the wobble position of the anticodon, which are complementary to the NNU codons, are not found naturally, we have generated a tRNA(Phe) with AAA anticodon and examined how an adenosine in the wobble position would affect its biological function in Escherichia coli. We found that the tRNA(Phe) with GAA anticodon (wild-type) repressed the expression of the pheA gene via tRNA(Phe)-mediated attenuation of transcription, whereas the tRNA(Phe) with AAA anticodon did not influence the expression of the pheA gene. Furthermore, elevated levels of tRNA(Phe)(AAA) did not support the growth of an E. coli strain carrying a temperature-sensitive mutation in the pheS gene at 42 degrees C. Since the presence of a multicopy plasmid carrying the gene that encodes tRNA(Phe)(GAA), a substrate for phenylalanyl tRNA synthetase, enables the E. coli strain carrying the pheS(Ts) mutation to grow at 42 degrees C, the above observation suggests that unlike tRNA(Phe)(GAA), tRNA(Phe)(AAA) is not a good substrate for phenylalanyl-tRNA synthetase. Therefore, we postulate that the presence of adenosine at the wobble position of anticodons was specifically eliminated and the tRNAs with guanosine or a modified base in the wobble position were selected to decode both NNU and NNC codons in E. coli.
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PMID:The tRNA species for redundant genetic codons NNU and NNC. A thought on the absence of phenylalanine tRNA with AAA anticodon in Escherichia coli. 137 Aug 14

About 50% of Japanese have been estimated to possess at least one ALDH2*2 allele with a substitution of AAA for GAA at codon 487 of the aldehyde dehydrogenase gene. This mutation is tightly associated with the sensitivity of an individual to alcohol. We developed a method of identifying the ALDH2*2 allele by a non-radioactive technique. DNA from individuals was subjected to polymerase chain reaction in which part of the aldehyde dehydrogenase 2 gene was amplified. After dot-blotting onto nylon membranes, the DNA was hybridized with biotin-labelled allele-specific oligonucleotides. Determination of genotypes on 77 unrelated healthy Japanese individuals, using the conventional method and our new method with gradient hybridization temperature and competitive oligonucleotides, indicated that the latter was superior to the former.
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PMID:A non-radioactive method for the detection of a common mutant allele of aldehyde dehydrogenase 2. 152 4

A polymerase chain reaction method was carried out to address the possible presence of estrogen receptor (ER) mutations in murine transformed cell lines. The segment of ER cDNA coding the C and D domains was amplified and cloned into pUC 19. Mammary carcinoma cell line (SC-3) did not show any mutation in this segment. However, the sequence analysis of ER in the Leydig cell line (B-1 F) revealed a single base change at acidic Glu-279 (GAA) to basic Lys-279 (AAA) compared with murine uterus ER cDNA. The biological significance of this mutation is discussed.
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PMID:A single nucleotide substitution in the D domain of estrogen receptor cDNA causes amino acid alteration from Glu-279 to Lys-279 in a murine transformed Leydig cell line (B-1 F). 167 3

When a single RNA sequence is read in either the 5'-3' or 3'-5 direction, the translated peptides often are hydropathically similar even though their sequences may be different. To investigate whether hydropathically similar peptides might also be antigenically related, two peptides were synthesized from the substance P anti-sense RNA transcript: CAU CAA UCC AAA GAA CUG CUG AGG CUU GGG UCG. Translation of this RNA in the 5'-3' direction and in the 3'-5' direction resulted in two different peptides. HQSKELLRLGS and AGFGVVKKPNY, respectively. As anticipated, both peptides shared similar hydropathic profiles but were quite different with respect to their sequences. To examine their antigenic relatedness, mice were immunized with either peptide, and monoclonal antibodies were produced. Using an enzyme-linked immunosorbent assay, it was possible to demonstrate that the majority of monoclonal antibodies, selected for reactivity against the original immunogen, also reacted with the other peptide. The observed binding was determined to be specific since reactivity could be blocked with either soluble peptide. Thus, we demonstrate that hydropathically similar peptides obtained from the same RNA but translated in opposite directions are antigenically related despite difference in amino acid sequences.
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PMID:5'-3' and 3'-5' translation of the same RNA results in hydropathically similar peptides that are antigenically related. 170 18

About half of all Japanese lack the activity of aldehyde dehydrogenase 2 (ALDH2), and suffer a flush after alcohol intake due to the marked elevation of blood acetaldehyde concentration. The cause of ALDH2 deficiency is thought to be a single point mutation in codon 487 of the ALDH2 gene. However, this mutant ALDH2 gene has not yet been cloned and sequenced. We amplified and cloned the exon 12 of the ALDH2 gene using polymerase chain reaction (PCR), and revealed that normal GAA coding glutamic acid is replaced for AAA coding lysine in codon 487 of the mutant ALDH2 gene. Based on this finding, we performed the genotyping of the ALDH2 gene using PCR and allele-specific oligonucleotide probes. The genotypes of 13 subjects with ALDH2-active phenotype were all homozygous for the normal ALDH2 gene (ALDH2(1)), while in 9 subjects with ALDH2-deficient phenotype 2 subjects were homozygous for the mutant ALDH2 gene (ALDH2(2)) and the other 7 subjects were heterozygous for both genes, indicating that the mutant ALDH2 gene is dominant. In 20 normal control subjects, the prevalence of ALDH2(1)/ALDH2(1), ALDH2(1)/ALDH2(2) and ALDH2(2)/ALDH2(2) was 45%, 45% and 10% respectively. On the other hand, in 36 alcoholic liver disease patients, the prevalence of the genotypes was 83%, 17% and 0%. These results confirmed the previous observation that the incidence of ALDH2 deficiency is much lower in alcoholic liver disease patients than in the general population, and suggested that most of the ALDH2 deficient patients with alcoholic liver disease are heterozygous for the normal and mutant ALDH2 genes.
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PMID:Genotyping of the aldehyde dehydrogenase 2 (ALDH2) gene using the polymerase chain reaction: evidence for single point mutation in the ALDH2 gene of ALDH2-deficiency. 191 52

Factor X (FX) "Vorarlberg" is a congenital FX deficiency characterized clinically by a mild bleeding tendency. Homozygous individuals have a FX activity of less than 10% in the extrinsic system and 25% in the intrinsic system. FX antigen is 20%. Using molecular techniques, two point mutations were detected in the coding sequence of the FX Vorarlberg gene: a G----A at base pair 160 in exon II resulting in a change of Gla14 (GAA) to Lys (AAA); a G----A at base pair 424 in exon V resulting in a change from Glu102 (GAG) to Lys (AAG). The mutations abolished a TaqI restriction site in exon II and an MnlI site in exon V. To determine whether these mutations are present on one or on both alleles, restriction analyses of amplified exon II and exon V fragments were performed. Analysis of the pedigree showed that the genotype for the mutation on exon II (homozygous versus heterozygous) correlates with the severity of the phenotypic coagulation defect. We therefore conclude that the mutation in exon II is responsible for the functional defect in FX Vorarlberg. We have also purified the mutant FX protein from patient plasma. Purified FX Vorarlberg is indistinguishable from normal FX on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Its activity is 15% of normal FX upon activation with factor VIIa/tissue factor, 75% upon activation with factor IXa/factor VIIIa, and 100% upon activation with RVV. Activation at varying Ca2+ concentrations shows that the affinity of FX Vorarlberg for Ca2+ is decreased. Factor Xa Vorarlberg is able to convert prothrombin at a normal rate but also shows decreased affinity for Ca2+ in this interaction. Upon addition of Ca2+, FX Vorarlberg does not undergo the same conformational change as normal FX. Our data show that FX Vorarlberg has a decreased affinity for Ca2+ which impedes a normal conformational change. This leads to a decreased rate of activation by factor VIIa/tissue factor and by factor IXa. The decrease is much more marked for the extrinsic than for the intrinsic pathway.
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PMID:Molecular defect (Gla+14----Lys) and its functional consequences in a hereditary factor X deficiency (factor X "Vorarlberg"). 197 67

Most potent mutators heretofore detected in Escherichia coli are associated with defects in epsilon subunit of DNA polymerase III, encoded by the dnaQ gene. To elucidate the role of the alpha subunit, the catalytic subunit of the polymerase, in maintaining the high fidelity of DNA replication, we isolated a mutator mutant, the mutation (dnaE173) of which resides on the dnaE gene, encoding the alpha subunit. The dnaE173 mutant was unable to grow in salt-free L broth at temperatures exceeding 44.5 degrees C and exhibited an increased frequency of spontaneous mutations, 1,000 to 10,000-fold the wild type level, at permissive temperatures. The mutator effect of dnaE173 mutation is dominant over the wild type allele. These phenotypes are caused by a single base substitution, resulting in one amino acid change, Glu612 (GAA)----Lys(AAA), in the alpha subunit molecule. DNA polymerase III purified from the dnaE173 mutant contained both alpha and epsilon subunits, in a normal molar ratio. We found no differences between wild type and mutant polymerases in the Vmax, thermolabilities, and salt sensitivities. However, the apparent Km for the substrate nucleotide of the mutant polymerase was 1/6 of that determined with the wild type polymerase. Although the mutant polymerase retained a normal level of 3'----5' exonuclease activity, the proofreading capacity determined by "turnover assay" was significantly lower in the mutant polymerase, as compared with findings in the normal enzyme. It seems likely that the enhanced mutability in the dnaE173 strain results from, at least in part, a defect in the editing function of DNA polymerase III, and further suggests that a portion of the alpha subunit in which the amino acid change resides may be important for the proper setting of the two subunits at the replication fork so as to facilitate efficient editing during the DNA replication.
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PMID:A strong mutator effect caused by an amino acid change in the alpha subunit of DNA polymerase III of Escherichia coli. 200 48

In response to low (approximately 1 microM) levels of selenium, Escherichia coli synthesizes tRNA(Glu) and tRNA(Lys) species that contain 5-methylaminomethyl-2-selenouridine (mnm5Se2U) instead of 5-methylaminomethyl-2-thiouridine (mnm5S2U). Purified glutamate- and lysine-accepting tRNAs containing either mnm5Se2U (tRNA(SeGlu), tRNA(SeLys] or mnm5S2U (tRNA(SGlu), tRNA(SLys] were prepared by RPC-5 reversed-phase chromatography, affinity chromatography using anti-AMP antibodies and DEAE-5PW ion-exchange HPLC. Since mnm5Se2U, like mnm5S2U, appears to occupy the wobble position of the anticodon, the recognition of glutamate codons (GAA and GAG) and lysine codons (AAA and AAG) was studied. While tRNA(SGlu) greatly preferred GAA over GAG, tRNA(SeGlu) showed less preference. Similarly, tRNA(SGlu) preferred AAA over AAG, while tRNA(SeLys) did not. In a wheat germ extract--rabbit globin mRNA translation system, incorporation of lysine and glutamate into protein was generally greater when added as aminoacylated tRNA(Se) than as aminoacylated tRNA(S). In globin mRNA the glutamate and lysine codons GAG and AAG are more numerous than GAA and AAA, thus a more efficient translation of globin message with tRNA(Se) might be expected because of facilitated recognition of codons ending in G.
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PMID:Selenium-containing tRNA(Glu) and tRNA(Lys) from Escherichia coli: purification, codon specificity and translational activity. 267 51

A temperature-sensitive uvrD mutant, HD323 uvrD4, was isolated from the uvrD mutant HD4 uvrD3. The temperature sensitivity of the uvrD4 gene product was reversible. The suppressor mutation uvrD44 which rendered the uvrD3 mutant temperature-sensitive could be separated from the uvrD3 mutation by replacing the PstI fragment, which encodes the C-terminal half of the UvrD protein. The uvrD44 mutation was found to make host bacteria lethal at non-permissive temperatures only when cloned on a low copy vector pMF3. The nucleotide sequence of the uvrD3 and uvrD4 mutant genes was determined. The nucleotide change found in the uvrD3 at +1235, GAA to AAA, only alters the amino acid sequence from Glu at 387 to Lys. The uvrD44 has another nucleotide change at +1859, GAA to AAA (Glu at 595 to Lys), which is considered to be the suppressor mutation uvrD44.
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PMID:Intragenic suppression in the uvrD gene of Escherichia coli. I. Temperature-sensitive uvrD mutations. 296 13

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