Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0039483 (giant cell arteritis)
 3,204 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Mutants of the Escherichia coli initiator tRNA (tRNA(fMet)) have been used to examine the role of the anticodon and discriminator base in in vivo aminoacylation of tRNAs by cysteinyl-tRNA synthetase. Substitution of the methionine anticodon CAU with the cysteine anticodon GCA was found to allow initiation of protein synthesis by the mutant tRNA from a complementary initiation codon in a reporter protein. Sequencing of the protein revealed that cysteine comprised about half of the amino acid at the N terminus. An additional mutation, converting the discriminator base of tRNA(GCAfMet) from A73 to the base present in tRNA(Cys) (U73), resulted in a 6-fold increase in the amount of protein produced and insertion of greater than or equal to 90% cysteine in response to the complementary initiation codon. Substitution of C73 or G73 at the discriminator position led to insertion of little or no cysteine, indicating the importance of U73 for recognition of the tRNA by cysteinyl-tRNA synthetase. Single base changes in the anticodon of tRNA(GCAfMet) containing U73 from GCA to UCA, GUA, GCC, and GCG (changes underlined) eliminated or dramatically reduced cysteine insertion by the mutant initiator tRNA indicating that all three cysteine anticodon bases are essential for specific aminoacylation of the tRNA with cysteine in vivo.
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PMID:The anticodon and discriminator base are major determinants of cysteine tRNA identity in vivo. 137 31

In the course of a systematic survey of wheat mitochondrial tRNA genes, we have sequenced chloroplast-like serine (trnS-GGA), phenylalanine (trnF-GAA) and cysteine (trnC-GCA) tRNA genes and their flanking regions. These genes are remnants of 'promiscuous' chloroplast DNA that has been incorporated into wheat mtDNA in the course of its evolution. Each gene differs by one or a few nucleotides from the authentic chloroplast homolog previously characterized in wheat or other plants, and each could potentially encode a functional tRNA whose secondary structure shows no deviations from the generalized model. To determine whether these chloroplast-like tRNA genes are actually expressed, wheat mitochondrial tRNAs were resolved by a series of polyacrylamide gel electrophoreses, after being specifically end-labeled in vitro by 3'-CCA addition mediated by wheat tRNA nucleotidyltransferase. Subsequent direct RNA sequence analysis identified prominent tRNA species corresponding to the mitochondrial and not the chloroplast trnS, trnF and trnC genes. This analysis also revealed chloroplast-like elongator methionine, asparagine and tryptophan tRNAs. Our results suggest that at least some chloroplast-like tRNA genes in wheat mtDNA are transcribed, with transcripts undergoing processing, post-transcriptional modification and 3'-CCA addition, to produce mature tRNAs that may participate in mitochondrial protein synthesis.
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PMID:Chloroplast-like transfer RNA genes expressed in wheat mitochondria. 276 45

DNA sequence analysis of dtxR has shown that the M(r) 25,316 regulatory protein contains a single cysteine residue at position 102. DtxR readily forms inactive disulfide-linked dimers. We have used saturation site-directed mutagenesis of the cysteine codon (TGC) at position 102 in order to determine the role of this residue in metal ion binding. We show that the insertion of amino acids other than cysteine or aspartic acid into this position abolishes DtxR function both in vitro and in recombinant Escherichia coli DH5 alpha:lambda RS45toxPO/lacZ. Only those mutant alleles in which the TGC codon for Cys-102 was replaced by either TGT (Cys) or GCA (Asp) were found to direct the expression of active forms of DtxR that regulate the expression of beta-galactosidase from the toxPO/lacZ transcriptional fusion.
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PMID:Cysteine-102 is positioned in the metal binding activation site of the Corynebacterium diphtheriae regulatory element DtxR. 837 26

We have isolated and sequenced chloroplast (chl) and cytoplasmic (cyt) cysteine tRNAs from Nicotiana rustica. Both tRNAs carry a GCA anticodon but beyond that differ considerably in their nucleotide sequences. One obvious distinction resides in the presence of N6-isopentenyladenosine (i6A) and 1-methylguanosine (m1G) at position 37 in chl and cyt tRNA(Cys) respectively. In order to study the potential suppressor activity of tRNAs(Cys) we used in vitro synthesized zein mRNA transcripts in which an internal UGA stop codon had been placed in either the tobacco rattle virus (TRV)- or tobacco mosaic virus (TMV)-specific codon context. In vitro translation was carried out in a messenger- and tRNA-dependent wheat germ extract. Both tRNA(Cys) isoacceptors stimulate read-through over the UGA stop codon, however, chl tRNA(GCA)Cys is more efficient than the cytoplasmic counterpart. The UGA in the two viral codon contexts is suppressed to about the same extent by either of the two tRNAs(Cys), whereas UGA in the beta-globin context is not recognized at all. The interaction of tRNA(GCA)Cys with UGA requires an unconventional G:A base pair in the wobble position, as postulated earlier for plant tRNA(G psi A)Tyr misreading the UAA stop codon. This is the first case that a cysteine-accepting tRNA has been characterized as a natural UGA suppressor.
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PMID:Cysteine tRNAs of plant origin as novel UGA suppressors. 852 47

The recognition of transfer RNAs (tRNAs) by aminoacyl tRNA synthetases is a critical step in establishing the fidelity of translation. For E. coli cysteine tRNA synthetase, recognition of tRNA(Cys) and discrimination from all other tRNAs is based on the U73 discriminator base, the GCA anticodon, and a G15:G48 tertiary base pair. While the discriminator base and the anticodon sequence are often used by many synthetases as the determinants for tRNA recognition, the dependence on a tertiary interaction in the cognate tRNA for recognition is unique to the cysteine enzyme. Here the structural basis for recognition at the G15:G48 tertiary interaction of E. coli tRNA(Cys) is explored by structural modeling, chemical modifications, and kinetic analysis. The results established an unusual RNA tertiary interaction that provides a plausible mechanism for recognition by cysteine tRNA synthetase.
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PMID:RNA recognition based on a pair of tertiary hydrogen interaction. 864 62

Mutations in the PKD1 gene on the short arm of chromosome 16 account for 85%-90% of polycystic kidney disease patients in the Caucasian population. After the recent characterization of the gene, we started a search for mutations in its 3 -end unique portion in Cypriot patients, by using the method of single-strand conformation polymorphism (SSCP). In one large family, we identified a nucleotide substitution at position 12258 of the cDNA; this substitutes cysteine-4086 by a premature termination codon (C4086X). It has been inherited by every affected family member but not by unaffected members, nor by patients from 13 other Cypriot families. A new polymerase chain reaction (PCR) primer has been designed to engineer a novel DdeI recognition site upon PCR amplification, thereby allowing easy detection of the mutation by PCR-restriction digestion. The premature STOP codon is expected to remove 217 residues from the putative C-terminal intracellular domain of the gene product, polycystin and thus identifies this part as being critical to the production of the disease phenotype, possibly by interfering with the transmission of signals from the extracellular matrix to the cytoplasm. We also describe the identification of the first polymorphism within the encoding region of the gene. It is at alanine 4091, which is encoded by either GCA or GCG. With a heterozygosity of 35%, it should be extremely useful in informative families, especially because the gene lies in an unstable region and is prone to rearrangements. This polymorphism is readily detectable by PCR-restriction digestion with Bsp 12861.
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PMID:Detection of a novel nonsense mutation and an intragenic polymorphism in the PKD1 gene of a Cypriot family with autosomal dominant polycystic kidney disease. 879 18

Germline mutations in the RET proto-oncogene have been shown to be the underlying cause of multiple endocrine neoplasia type 2 (MEN 2A and 2B) and familial medullary thyroid carcinoma (FMTC). Some cases of sporadic medullary thyroid carcinoma (sporadic MTC) are reported to have specific codon 918, 883 and 768 mutations of the RET gene in tumor tissues. We examined RET gene mutations in 40 Japanese cases who had previously undergone surgery for sporadic MTC. DNA extracted from formalin-fixed tumor tissues and corresponding normal thyroid tissues or peripheral blood leukocytes was analyzed for mutations of exon 10, 11, 13, 14 and 16 of the RET gene by DNA sequencing and by mutation-specific restriction enzyme analysis. Germline RET point mutations were found in six of 40 cases (15%), cysteine residues at codon 618 in two, codon 634 in three and valine residue at codon 804 in one, and were newly identified as heritable MTC. Of the remaining 34 sporadic MTC cases, four (12%) had tumor-specific RET point mutations. Two were found in exon 16; one case showed an ATG to ACG (Met to Thr) mutation at codon 918, and the other showed two point mutations, ATG to ACG (Met to Thr) at codon 918 and GCA to GTA (Ala to Val) at codon 919 with loss of the wild-type allele, suggesting that both alleles at the RET locus were altered. The other two were found in exon 13; one case showed a CCG to TCG (Pro to Ser) mutation at codon 766 and the other showed a silent mutation, GTC to GTT (Val) at codon 778 with loss of the wild-type allele. There was no association of sporadic mutations with recurrence or prognosis in patients with sporadic MTC. The low rate of somatic RET mutation at codon 918 in our sporadic MTC suggests that as yet unknown factors may be involved. Genetic alterations in both alleles may have an important role in small fraction of sporadic MTCs.
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PMID:Novel point mutations and allele loss at the RET locus in sporadic medullary thyroid carcinomas. 961 47

Deviations from the universal genetic code have evolved independently several times in ciliated protozoa. Thus, in some species UAA and UAG are no longer used as termination codons, but are read as glutamine, whereas in the genus Euplotes , UGA is translated as cysteine. We have investigated the nature of the tRNACys isoacceptor responsible for decoding UGA in Euplotes cells. Southern hybridization analyses indicated that a single DNA molecule of 630 bp encoding tRNACys exists in the macronucleus of Euplotes octocarinatus . Cloning and sequencing of this fragment revealed that it contains only one copy of a tRNACys gene, which codes for a normal tRNACys with GCA anticodon. This is the first report of the characterization of a tRNA gene in any hypotrichous ciliate. It contains putative signals for initiation and termination of transcription by RNA polymerase III and can be transcribed efficiently in vitro in HeLa cell nuclear extract. Intensive studies on the DNA and tRNA level involving PCR analyses have not disclosed the existence of any tRNA Cys isoacceptor with UCA or ICA anticodons. Translation of the UGA codon by tRNA sub GCA sup Cys necessitates a G:A mispairing in the first anticodon position. We discuss a number of aspects which might contribute to the finding that a near-cognate tRNA isoacceptor efficiently translates the UGA stop codon.
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PMID:The hypotrichous ciliate Euplotes octocarinatus has only one type of tRNACys with GCA anticodon encoded on a single macronuclear DNA molecule. 975 21

The underlying basis of the genetic code is specific aminoacylation of tRNAs by aminoacyl-tRNA synthetases. Although the code is conserved, bases in tRNA that establish aminoacylation are not necessarily conserved. Even when the bases are conserved, positions of backbone groups that contribute to aminoacylation may vary. We show here that, although the Escherichia coli and human cysteinyl-tRNA synthetases both recognize the same bases (U73 and the GCA anticodon) of tRNA for aminoacylation, they have different emphasis on the tRNA backbone. The E. coli enzyme recognizes two clusters of phosphate groups. One is at A36 in the anticodon and the other is in the core of the tRNA structure and includes phosphate groups at positions 9, 12, 14, and 60. Metal-ion rescue experiments show that those at positions 9, 12, and 60 are involved with binding divalent metal ions that are important for aminoacylation. The E. coli enzyme also recognizes 2'-hydroxyl groups within the same two clusters: at positions 33, 35, and 36 in the anticodon loop, and at positions 49, 55, and 61 in the core. The human enzyme, by contrast, recognizes few phosphate or 2'-hydroxy groups for aminoacylation. The evolution from the backbone-dependent recognition by the E. coli enzyme to the backbone-independent recognition by the human enzyme demonstrates a previously unrecognized shift that nonetheless has preserved the specificity for aminoacylation with cysteine.
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PMID:Recognition of tRNA backbone for aminoacylation with cysteine: evolution from Escherichia coli to human. 1208 12

The finding that a lens under oxidative stress accumulated free and protein-bound cysteine (protein-S-S-cysteine) in the fiber cells prompted us to examine if there is an alternative source for cysteine pools besides the active cysteine transport system in the lens, namely, the transsulfuration pathway of homocysteine-cystathionine-cysteine, which utilises methionine through transmethylation. We examined the presence of the gene for cystathionine-beta-synthase (CBS), the rate limiting enzyme that converts homocysteine to cystathionine in the transsulfuration pathway, in human lens epithelial (HLE) B3 cells using PCR with primers designed based on the sequence of human liver CBS (Forward 5'-CCA CAC TGC CCC GGC AAA AT-3'; Reverse 5'-CTG GCA ATG CCC GTG ATG GT-3'). The purified DNA fragment (586 bp) from PCR analysis was sequenced and confirmed the homology with CBS gene from other human tissues. The CBS protein band (67 kDa) was present in the HLE cells, which reacted positively with the human liver anti-CBS antibody. The enzyme protein was detected in the pig and human lenses with the highest intensity in the epithelial layer, lower but equal quantities of CBS was present in the cortical and nuclear regions. Human nuclear CBS increased while epithelial CBS decreased with aging. Oxidative stress transiently upregulated the gene expression of CBS both in HLE cells (0.1 mMH2O2) and in pig lens cultured in TC 199 medium (0.5 mMH2O2). The catalytic activity for CBS, which was assayed by measuring the production of C14-cystathionine from C14-serine in the presence of homocysteine, S-adenosyl-methionine and pyridoxal phosphate, was detectable in the HLE cells and transiently activated with H2O2. Free cystathionine accumulated when HLE B3 cells were treated with propargylglycine (PGG), an inhibitor of cystathionase, the downstream enzyme that converts cystathionine to cysteine. More cystathionine accumulation occurred when the cells were simultaneously exposed to PGG and 0.1 mMH2O2. We have shown that oxidative stress of H2O2 could increase the flux of this transsulfuration pathway by committing more homocysteine to cysteine and glutathione production as H2O2 (0.1 mM) inhibited the remethylation enzyme of methionine synthase while concurrently activating the CBS enzyme. This is the first evidence that a transsulfuration pathway is present in the lens, and that it can be upregulated under oxidative stress to provide additional redox potential for the cells.
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PMID:The presence of a transsulfuration pathway in the lens: a new oxidative stress defense system. 1564 25


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