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Query: UNIPROT:P01350 (
gastrin
)
9,683
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Elements that confer identity to a
tRNA
in the cellular environment, where all aminoacyl-
tRNA
synthetases are competing for substrates, may be delineated by in vivo experiments using suppressor tRNAs. Here we describe the selection of active Escherichia coli tRNAAsp amber mutants and analyze their identity. Starting from a library containing randomly mutated
tRNA
(CUA)Asp genes, we isolated four amber suppressors presenting either lysine, alanine, or glutamine activity. Two of them, presenting mainly alanine or lysine activity, were further submitted to a second round of mutagenesis selection in order to improve their efficiency of suppression. Eleven suppressors were isolated, each containing two or three mutations. Ten presented identities of the two parental mutants, whereas one had switched from lysine to arginine identity. Analysis of the different mutants revealed (or confirmed for some nucleotides) their role as positive and/or negative determinants in AlaRS, LysRS, and ArgRS recognition. More generally, it appears that tRNAAsp presents identity characteristics closely related to those of tRNALys, as well as a structural basis for acquiring alanine or arginine identity upon moderate mutational changes; these consist of addition or suppression of the corresponding positive or negative determinants, as well as tertiary interactions. Failure to isolate aspartic acid-inserting suppressors is probably due to elimination of the important
G34
identity element and its replacement by an antideterminant when changing the anticodon of the tRNAAsp to the CUA triplet.
...
PMID:Selection of tRNA(Asp) amber suppressor mutants having alanine, arginine, glutamine, and lysine identity. 880 18
Coaxially stacked RNA helices are a determined of RNA tertiary structure, but their presence is rarely detected using conventional chemical modification methods. In this report we describe a porphyrin ion photoreaction that enables one to monitor RNA stacking interactions and the folding of coaxially stacked RNA helices. The porphyrin cations meso-tetrakis(4-N-methylpyridyl)porphine, meso-tetrakis-(para-N-trimethylanilinium)porphine, and meso-tetrakis(2-N-methylpyridyl)porphine were used to characterize
tRNA
(Phe) and the human immunodeficiency virus type-I Rev response element RNA. Nucleosides at the bases of contiguous RNA helices in each RNA are efficiently modified by the porphyrin cations following irradiation of porphyrin-RNA mixtures. These photomodifications are markedly reduced for RNA equilibrated in ionic buffers that lead to enhanced stabilization of coaxially stacked helices. The porphyrin cation photoreaction specifically modifies G18, G20, and
G34
in the
tRNA
folding produced by Mg(II). These nucleobases are exposed to solvent in the native
tRNA
structure and thus available to stack with solvent-borne porphyrin molecules. The describe porphyrin cation photochemical method provides a novel approach to study the solvent accessibility of nucleobases in RNA structure and to monitor the folding of coaxially stacked helices in RNA.
...
PMID:Efficient modification of RNA by porphyrin cation photochemistry: monitoring the folding of coaxially stacked RNA helices in tRNA(Phe) and the human immunodeficiency virus type 1 rev response element RNA. 881 Sep 11
Multiple molecular dynamics trajectories of the solvated and neutralized 17-residue
tRNA
(Asp) anticodon hairpin were generated for a total of 3 ns. Explicit treatment of all long-ranged electrostatic interactions by the particle mesh Ewald algorithm, as implemented in the AMBER MD software package, effected a degree of structural stabilization not previously achieved by use of a long 16-A solvent interaction truncation scheme. The increased stability of this multiple molecular dynamics set was appropriate for an in-depth analysis of the six 500-ps-long trajectories and allowed the characterization of a number of key structural interactions. The dynamical behavior of the standard Watson-Crick base pairs, the noncanonical G30-U40 "wobble" base pair, and the psi 32-C38 pseudo-base pair is presented as well as that of two C--H... O hydrogen bonds found to contribute to the array of tertiary interactions that stabilize the seven-nucleotide native loop conformation. The least mobile residue in the loop is U33, which forms the U-turn motif and which participates in several hydrogen-bonding interactions, whereas the most mobile residue is the apical residue
G34
at the wobble position, a factor undoubtedly important in its biological function. The set of multiple molecular dynamics trajectories obtained does not converge on a 500-ps time scale to a unique dynamical model but instead describes an ensemble of structural microstates accessible to the system under the present simulation protocol, which is the result of local structural heterogeneity rather than of global conformational changes.
...
PMID:H-bond stability in the tRNA(Asp) anticodon hairpin: 3 ns of multiple molecular dynamics simulations. 884 34
Structure/function relationships accounting for specific
tRNA
charging by class II aspartyl-
tRNA
synthetases from Saccharomyces cerevisiae, Escherichia coli and Thermus thermophilus are reviewed. Effects directly linked to
tRNA
features are emphasized and aspects about synthetase contribution in expression of
tRNA
(Asp) identity are also covered. Major identity nucleotides conferring aspartate specificity to yeast, E coli and T thermophilus tRNAs comprise
G34
, U35, C36, C38 and G73, a set of nucleotides conserved in
tRNA
(Asp) molecules of other biological origin. Aspartate specificity can be enhanced by negative discrimination preventing, eg mischarging of native yeast
tRNA
(Asp by yeast arginyl-tRNA synthetase. In the yeast system crystallography shows that identity nucleotides are in contact with identity amino acids located in the catalytic and anticodon binding domains of the synthetase. Specificity of RNA/protein interaction involves a conformational change of the
tRNA
that optimizes the H-bonding potential of the identity signals on both partners of the complex. Mutation of identity nucleotides leads to decreased aspartylation efficiencies accompanied by a loss of specific H-bonds and an altered adaptation of
tRNA
on the synthetase. Species-specific characteristics of aspartate systems are the number, location and nature of minor identity signals. These features and the structural variations in aspartate tRNAs and synthetases are correlated with mechanistic differences in the aminoacylation reactions catalyzed by the various aspartyl-
tRNA
synthetases. The reality of the aspartate identity set is verified by its functional expression in a variety of RNA frameworks. Inversely a number of identities can be expressed within a
tRNA
(Asp) framework. From this emerged the concept of the RNA structural frameworks underlying expression of identities which is illustrated with data obtained with engineered tRNAs. Efficient aspartylation of minihelices is explained by the primordial role of G73. From this and other considerations it is suggested that aspartate identity appeared early in the history of
tRNA
aminoacylation systems.
...
PMID:Aspartate identity of transfer RNAs. 895 4
Primary structures of phage T5- and Escherichia coli-encoded
tRNA
(Phe) are distinct at four out of 11 positions known as identity elements for E. coli phenylalanyl-tRNA synthetase (FRS). In order to reveal structural requirements for FRS recognition, aminoacylation of wild-type phage T5
tRNA
(Phe) gene transcript and mutants containing substitutions of the identity elements at positions 20, 34, 35 and 36 was compared with E. coli
tRNA
(Phe) gene transcript. The wild-type phage T5 transcript can be aminoacylated with the same catalytic efficiency as the E. coli counterpart. However, the maximal aminoacylation rate for T5 and E. coli transcripts was reached at different Mg2+ concentrations: 4 and 15 mM, respectively. Aminoacylation assays with
tRNA
(Phe) mutants revealed that (i) phage transcripts with the substituted anticodon bases at positions 35 and 36 were efficient substrates for aminoacylation at 15 mM Mg2+ but not at optimal 4 mM Mg2+; (ii) any change of
G34
in phage transcripts dramatically decreased the aminoacylation efficiency at both 4 and 15 mM Mg2+ whereas G34A mutation in the E. coli transcript exhibits virtually no influence on aminoacylation rate at 15 mM Mg2+; (iii) substitution of A20 with U in the phage transcript caused no significant change in the aminoacylation rate at both Mg2+ concentrations; (iv) phage transcripts with double substitutions A20U+A35C and A20U+A36C were very poor substrates for FRS. Collectively, the results indicate the non-identical mode of
tRNA
(Phe) recognition by E. coli FRS at low and high Mg2+ concentrations. Probably, along with identity elements, the local
tRNA
conformation is essential for recognition by FRS.
...
PMID:Transfer RNA(Phe) isoacceptors possess non-identical set of identity elements at high and low Mg2+ concentration. 924 56
The wild-type transcript of Escherichia coli tRNASec, characterized by a peculiar core architecture and a large variable region, was shown to be aspartylatable by yeast AspRS. Similar activities were found for tRNASec mutants with methionine, leucine, and tryptophan anticodons. The charging efficiency of these molecules was found comparable to that of a minihelix derived from tRNAAsp and is accounted for by the presence of the discriminator residue G73, which is a major aspartate identity determinant. Introducing the aspartate identity elements from the anticodon loop (
G34
, U35, C36, C38) into tRNASec transforms this molecule into an aspartate acceptor with kinetic properties identical to tRNAAsp. Expression of the aspartate identity set in tRNASec is independent of the size of its variable region. The functional study was completed by footprinting experiments with four different nucleases as structural probes. Protection patterns by AspRS of transplanted tRNASec and tRNAAsp were found similar. They are modified, particularly in the anticodon loop, upon changing the aspartate anticodon into that of methionine. Altogether, it appears that recognition of a
tRNA
by AspRS is more governed by the presence of the aspartate identity set than by the structural framework that carries this set.
...
PMID:The peculiar architectural framework of tRNASec is fully recognized by yeast AspRS. 1019 66
The active site of yeast aspartyl-tRNA synthetase has been characterised by structural and functional approaches. However, residues or structural elements that indirectly contribute to the active site organisation have still to be described. They have not been assessed by simple analysis of structural data or site-directed mutagenesis analysis, since rational targetting has proven difficult. Here, we attempt to locate these functional features by using a genetic selection method to screen a randomly mutated yeast AspRS library for mutations lethal for cell growth. This approach is an efficient method to map the active site residues, since of the 23 different mutations isolated, 13 are in direct contact with the substrates. Most of the mutations are located in a 15 A radius sphere around the ATP molecule, where they affect the very conserved residues of the class-defining motifs. The results also showed the importance of the dimer interface for the enzyme activity: a single mutation of the invariant proline residue of motif 1 led to a structural defect inactivating the enzyme. From in vivo complementation studies it appeared that the enzyme activity can be recovered by reconstitution of an intact interface through the formation of heterodimers. We also show that a single mutation affecting an interaction with
G34
of the
tRNA
can inactivate the enzyme by inducing a relaxation of the
tRNA
recognition specificity. Finally, several mutants whose functional importance could not be assessed from the structural data were selected, demonstrating the importance of this type of approach in the context of a structure-function relationship study.
...
PMID:Active site mapping of yeast aspartyl-tRNA synthetase by in vivo selection of enzyme mutations lethal for cell growth. 1032 39
Mitochondrial (mt)
tRNA
(Trp),
tRNA
(Ile),
tRNA
(Met),
tRNA
(Ser)GCU,
tRNA
(Asn)and
tRNA
(Lys)were purified from Drosophila melanogaster (fruit fly) and their nucleotide sequences were determined.
tRNA
(Lys)corresponding to both AAA and AAG lysine codons was found to contain the anticodon CUU, C34 at the wobble position being unmodified.
tRNA
(Met)corresponding to both AUA and AUG methionine codons was found to contain 5-formylcytidine (f(5)C) at the wobble position, although the extent of modification is partial. These results suggest that both C and f(5)C as the wobble bases at the anticodon first position (position 34) can recognize A at the codon third position (position 3) in the fruit fly mt translation system.
tRNA
(Ser)GCU corresponding to AGU, AGC and AGA serine codons was found to contain unmodified G at the anticodon wobble position, suggesting the utilization of an unconventional
G34
-A3 base pair during translation. When these
tRNA
anticodon sequences are compared with those of other animal counterparts, it is concluded that either unmodified C or G at the wobble position can recognize A at the codon third position and that modification from A to t(6)A at position 37, 3'-adjacent to the anticodon, seems to be important for
tRNA
possessing C34 to recognize A3 in the mRNA in the fruit fly mt translation system.
...
PMID:Codon reading patterns in Drosophila melanogaster mitochondria based on their tRNA sequences: a unique wobble rule in animal mitochondria. 1051 23
The specific aminoacylation of
tRNA
by yeast tyrosyl-tRNA synthetase does not rely on the presence of modified residues in
tRNA
(Tyr), although such residues stabilize its structure. Thus, the major tyrosine identity determinants were searched by the in vitro approach using unmodified transcripts produced by T7 RNA polymerase. On the basis of the tyrosylation efficiency of
tRNA
variants, the strongest determinants are base pair C1-G72 and discriminator residue A73 (the 5'-phosphoryl group on C1, however, is unimportant for tyrosylation). The three anticodon bases
G34
, U35, and A36 contribute also to the tyrosine identity, but to a lesser extent, with
G34
having the most pronounced effect. Mutation of the GUA tyrosine anticodon into a CAU methionine anticodon, however, leads to a loss of tyrosylation efficiency similar to that obtained after mutation of the C1-G72 or A73 determinants. Transplantation of the six determinants into four different
tRNA
frameworks and activity assays on heterologous Escherichia coli and Methanococcus jannaschii
tRNA
(Tyr) confirmed the completeness of the tyrosine set and the eukaryotic character of the C1-G72 base pair. On the other hand, it was found that tyrosine identity in yeast does not rely on fine architectural features of the
tRNA
, in particular the size and sequence of the D-loop. Noticeable, yeast TyrRS efficiently charges a variant of E. coli
tRNA
(Tyr) with a large extra-region provided its G1-C72 base pair is changed to a C1-G72 base pair. Finally, tyrosylation activity is compatible with a +1 shift of the anticodon in the 3'-direction but is strongly inhibited if this shift occurs in the opposite 5'-direction.
...
PMID:Identity of tRNA for yeast tyrosyl-tRNA synthetase: tyrosylation is more sensitive to identity nucleotides than to structural features. 1067 21
Out of more than 500 sequenced cytosolic tRNAs, there is only one with an unmodified adenosine in the wobble position (position 34). The reason for this rare occurrence of A34 is that it is mostly deaminated to inosine-34 (I34). I34 is a common constituent in the wobble position of tRNAs and has a decoding capacity different from that of A34. We have isolated a mutant (proL207) of Salmonella typhimurium, in which the wobble nucleoside
G34
has been replaced by an unmodified A in
tRNA
(Pro)(GGG), which is the only
tRNA
that normally reads the CCC codon. Thus, this mutant apparently has no
tRNA
that is considered cognate for the codon CCC. Despite this, the mutant grows normally. As expected, Pro-
tRNA
selection at the CCC codon in the A-site in a mutant deleted for the proL gene, which encodes the
tRNA
(Pro)(GGG), was severely reduced. However, in comparison this rate of selection was only slightly reduced in the proL207 mutant with its A34 containing
tRNA
(Pro)(AGG) suggesting that this
tRNA
reads CCC. Moreover, measurements of the interference by a
tRNA
residing in the P-site on the apparent termination efficiency at the A-site indicated that indeed the A34 containing
tRNA
reads the CCC codon. We conclude that A34 in a cytosolic
tRNA
is not detrimental to the cell and that the mutant
tRNA
(Pro)(AGG) is able to read the CCC codon like its wild-type counterpart
tRNA
(Pro)(GGG). We suggest that the decoding of the CCC codon by a 5'-AGG-3' anticodon occurs by a wobble base-pair between a protonated A34 and a C in the mRNA.
...
PMID:A cytosolic tRNA with an unmodified adenosine in the wobble position reads a codon ending with the non-complementary nucleoside cytidine. 1195 4
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