Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0026936 (Mycoplasma)
14,761 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have used a protein-synthesizing in vitro system programmed with the phage message MS2-RNA to investigate the ability of glycyl-tRNAs with different anticodons to read the glycine codons. Under conditions of no competition, when the glycyl-tRNA analyzed was the only source of glycine for protein synthesis, each of the isoacceptors tested, tRNA1Gly (anticodon CCC), tRNA2Gly (anticodon N/UCC), tRNA3Gly (anticodon GCC) from Escherichia coli, and tRNAGly (anticodon UCC) from Mycoplasma mycoides, could read all of the glycine codons in the MS2 coat protein cistron (GGU, GGC, GGA, and GGG). However, tRNA1Gly seemed to have difficulties reading through the whole cistron. Experiments in which two glycyl-tRNAs competed for the same codon showed that the mycoplasma tRNAGly (anticodon UCC) was almost as efficient in the unorthodox reading of the codons GGU and GGC as it was in conventional reading. It would seem to be the only tRNAGly present in Mycoplasma mycoides and our results are consistent with this finding since the mycoplasma tRNAGly appears to have been designed to read all four glycine codons with approximately equal efficiency. The competition experiments furthermore showed that E. coli tRNA1Gly (anticodon CCC) reads the codon GGA more efficiently than it reads GGU and GGC suggesting that the mispair C . A between the wobble position of the anticodon and the third codon position might have appreciable stability.
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PMID:Unconventional reading of the glycine codons. 635 4

Five small stable RNA species have been isolated from Mycoplasma capricolum. Together with the previously found RNA species, M.capricolum contains at least six small RNAs besides rRNAs and tRNAs. The sequences of these RNAs, designated MCS1 to MCS6, have been determined. MCS1 RNA is homologous to 4.5S RNA of E. coli, MCS5 to 10Sa RNA and MCS6 to M1 RNA (RNase P RNA). Unexpectedly, MCS4 RNA revealed an extensive sequence similarity to eukaryotic U6 snRNAs. MCS6, 10Sa RNA homolog, contains a tRNA-like structure in the 5'- and 3'-terminal sequences.
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PMID:Small stable RNAs in Mycoplasma capricolum. 750 41

The 33 genes encoding the complete set of tRNA species in Mycoplasma pneumoniae have been cloned and sequenced. They are organized into 5 clusters in addition to 9 single genes. No redundant gene was found, indicating that 33 tRNAs correspond to 32 different anticodons and decode all 62 codons used in this organism. There is only one single tRNA for each of the Ala, Leu, Pro, and Val family boxes. Therefore, a simplified decoding system resembling that recently described for Mycoplasma capricolum (1) has to also exist in M.pneumoniae. However, analysis of the anticodon set and codon usage revealed features characteristic of the latter: (i) there is no obvious preference toward AT rich synonymous codons, (ii) CGG codons are assigned for arginine and are translated by tRNA Arg(UCG), and (iii) CNN or GNN anticodons are encountered in the Ser, Thr, Arg, and Gly family boxes. We thus propose that this codon-anticodon recognition pattern has emerged in the 'M.pneumoniae cluster' under a genomic economization strategy but without the influence of AT pressure.
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PMID:Codon reading scheme in Mycoplasma pneumoniae revealed by the analysis of the complete set of tRNA genes. 751 47

The stable RNAs, whose sequences are homologous to 10Sa RNA of Escherichia coli, have been isolated from Mycoplasma capricolum and Bacillus subtilis, both belonging to the Gram-positive bacterial group. The total nucleotide sequences of the RNAs have been determined by partial RNA sequencing and DNA sequencing of their genes. A comparison of the sequences, together with those of other bacterial 10Sa RNAs so far known, has shown that the 5'- and 3'-end sequences are well conserved among species, while the central parts reveal little homologies. Unexpectedly, the conserved 5'- and 3'-regions can be folded in a common tRNA-like structure containing an amino acid-acceptor stem and a T phi C-stem/loop. The 3'-terminal CCA sequence of B.subtilis 10Sa RNA is not encoded on the DNA, but is added after transcription. Furthermore, the RNA is aminoacylatable with alanine in vitro, and binds to the 70S ribosome in vivo.
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PMID:tRNA-like structures in 10Sa RNAs of Mycoplasma capricolum and Bacillus subtilis. 752 27

Expression of mycoplasma sequences in Escherichia coli is often hindered by an unusual mycoplasmal codon usage pattern: the UGA stop codon is utilized for tryptophan. This may result in the truncation of cloned proteins and may prevent the detection of products of many cloned genes. To circumvent this translation barrier, we have developed an expression system for the production of mycoplasma proteins in E. coli. The efficiency of an opal suppressor tRNA (trpT176) was augmented with other suppressor mutations (prfB3 or rrsB(SuUGA-delta C1054)) which influence termination events. System efficacy was analyzed by employing suppressor mutations in the expression of TGA-containing sequences from the P1 protein-encoding gene of Mycoplasma pneumoniae.
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PMID:Enhanced readthrough of opal (UGA) stop codons and production of Mycoplasma pneumoniae P1 epitopes in Escherichia coli. 769 87

Using an in vitro protein-synthesizing system that allowed us to monitor separately the reading of each glycine codon, we have previously shown, that in constructs based on glycine tRNA1 from Escherichia coli the nature of the nucleotide in position 32 determines the ability of the anticodon UCC to discriminate between the glycine codons. Thus, with a U in position 32 the anticodon UCC discriminated according to the wobble rules, but with a C in this position it had lost its ability to discriminate. In the present paper we show that the same is true also for constructs based on mycoplasma glycine tRNA. When C32 in the wild type was changed to U32, the anticodon UCC discriminated between the glycine codons, while in wild type mycoplasma glycine tRNA it did not. Furthermore, when U32 was changed to C32 in glycine tRNA1(CCC), the anticodon CCC loses its ability to discriminate. We therefore conclude that the nature of the nucleotide in position 32 determines the discriminatory ability of both anticodons UCC and CCC in the glycine tRNA1 structural background, and that the same is true for the anticodon UCC in the mycoplasma glycine tRNA background.
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PMID:Glycine codon discrimination and the nucleotide in position 32 of the anticodon loop. 770 68

The gene encoding lysyl-tRNA synthetase (lysS) in Mycoplasma hominis was cloned and sequenced. The gene was found to have an open reading frame of 1466 bp encoding a polypeptide with a predicted molecular mass of 57 kDa. The amino acid sequence showed 44.3% and 43.7% identity to the Escherichia coli lysyl-tRNA synthetases, encoded by lysS and lysU. Only one lysyl-tRNA synthetase encoding gene was found in M. hominis. The G + C content of the gene was found to be 28.6%, which is significantly lower than in other prokaryotes. The gene was located 4 kb upstream of the M. hominis PG21 rRNA B operon.
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PMID:Characterization of a Mycoplasma hominis gene encoding lysyl-tRNA synthetase (LysRS). 818 99

1. The genetic code was thought to be identical ("universal") in all biological systems until 1981, when it was discovered that the coding system in mammalian mitochondria differed from the universal code in the use of codons AUA, UGA, AGA and AGG. 2. Many other differences have since been discovered, some in mitochondria of various phyla, others in bacteria, ciliated protozoa, algae and yeasts. 3. The original thesis that the code was universal and "frozen" depended on the precept that any mutational change in the code would be lethal, because it would produce widespread alterations in the amino acid sequences of proteins. Such changes would destroy protein function, and hence would be intolerable. 4. The objection was "by-passed" by nature. It is possible for a codon to disappear from mRNA molecules, often as a result of directional mutation pressure in DNA: thus all UGA stop codons can be replaced by UAA. 5. The missing UGA codon can then reappear when some UGG tryptophan codons mutate to UGA. The new UGA codons will be translated as tryptophan, as is the case in non-plant mitochondria and Mycoplasma. Therefore, no changes have taken place in the amino acid sequences of proteins. 6. Variations of this procedure have occurred, affecting various codons, and discoveries are still being made. The findings illustrate the evolutionary interplay between tRNA, release factors and codon-anticodon pairing.
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PMID:Evolutionary changes in the genetic code. 828 49

We have investigated the influence of structures in the tRNA anticodon loop and stem on the ability of the anticodon to discriminate among codons. We had previously shown that anticodon UCC, when placed in the structural context of tRNA(Gly1) from Escherichia coli, discriminated efficiently between the glycine codons, as required by the wobble rules. Thus, this anticodon read GGA and GGG but did not read GGU and GGC, whereas in mycoplasma tRNA(Gly), the same anticodon did not discriminate among the glycine codons. We have now determined the reading properties of three constructions based on tRNA(Gly1) containing the anticodon UCC in different structural contexts. In one of these constructs, tRNA(Gly1-ASL), the anticodon loop and stem are the same as in mycoplasma tRNA(Gly). The second construct, tRNA(Gly1-AS), has an anticodon stem identical with the mycoplasma tRNA(Gly), whereas in the last construct, tRNA(Gly1-C32), the only difference from tRNA(Gly1)(UCC) is that the uridine in position 32 of the anticodon loop has been replaced by cytidine. These constructs were tested for ability to read glycine codons in an in vitro protein-synthesizing system that allowed us to monitor separately the reading of each codon. We found that the anticodon UCC, when present in tRNA(Gly1-AS), discriminated among the glycine codons, whereas in the constructs tRNA(Gly1-ASL) and tRNA(Gly1-C32), the same anticodon had lost its ability to discriminate--i.e., it behaved as in mycoplasma tRNA(Gly). These results strongly suggest that nt 32 of the anticodon loop of tRNA(Gly1)(UCC) decisively influences the reading properties of the anticodon UCC.
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PMID:The nucleotide in position 32 of the tRNA anticodon loop determines ability of anticodon UCC to discriminate among glycine codons. 847 78

To investigate the reading properties of adenosine in the wobble position we have used site-directed mutagenesis of the Escherichia coli glycine tRNA1(CCC) gene to substitute the nucleotide A in the wobble position of the corresponding tRNA. The effect of this change on the ability of the tRNA to discriminate between the nucleotides in the third position of the glycine codons has been investigated. We have compared the ability of the mutant glycine tRNA1(UCC) and glycine tRNA1(ACC) as well as the mycoplasma glycine tRNA(UCC) to read the glycine codons. The results showed that glycine tRNA1(ACC) unlike glycine tRNA1(UCC) did not fully discriminate between the glycine codons. These experiments were carried out using a new in vitro protein synthesizing system that allows us to monitor the reading of all four glycine codons. In the present paper we give a detailed description of this new in vitro system.
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PMID:Undiscriminating codon reading with adenosine in the wobble position. 847 31


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