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Query: UNIPROT:P01350 (
gastrin
)
9,683
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Analogues of yeast alanyl
tRNA
with I34 replaced by A34 or
G34
were synthesized. Synthetic analogues of yeast alanyl tRNT occupy the same position as the natural yeast alanyl
tRNA
on polyacrylamide gel electrophoresis, and their purity is about 95% after electrophoresis on a 10% or 20% polyacrylamide gel. The two terminal and nearest neighbour nucleotides of the analogues are all correct. The accepting activity of the synthetic analogues is similar to that of the reconstituted natural yeast alanyl
tRNA
. The incorporation activity of alanine into proteins of the synthetic analogues is about 30% of that of the natural of reconstituted natural yeast alanyl
tRNA
when I34 is replaced by A, and is 90% when I34 is replaced by G. The reason of the variation in biological function of the analogues of yeast alanyl
tRNA
after I34 replaced by A or G was discussed.
...
PMID:Biological function of modified nucleotides in tRNA molecules--synthesis and biological activity of the analogues of yeast alanyl tRNA with I34 replaced by A34 or G34. 321 91
tRNAPheE.coli was modified at accessible guanosine, cytidine, and adenosine residues using the chemical modification method described by Peattie and Gilbert [Proc. Natl Acad. Sci. USA, 77, 4679-4689 (1980)]. Modification characteristics of the
tRNA
in the free state, in the ternary complex with elongation factor EF-Tu and GTP and in the ribosomal A and P sites were compared. A special procedure was devised to monitor, exclusively,
tRNA
molecules in the aminoacylated state. In the free
tRNA
, the most reactive bases are confined to the A73-C-C-A sequence of the aminoacyl stem, the anticodon loop, the D-loop and the extra loop and the results correlate well with the three-dimensional structure of tRNAPheyeast determined by X-ray studies. The pattern of reactivity was not affected either by charging the
tRNA
with phenylalanine or by labelling the 3' terminus with pCp. In the ternary complex, with elongation factor EF-Tu and GTP, changes in modification were observed at two sites, A73-C-C-A at the 3' terminus and C-13 and C-17 in the D-loop region, which are about 6 nm apart; no difference was observed in the anticodon loop. tRNAPhe bound at the ribosomal A or P sites exhibited similar, but not identical, modification patterns. Whereas nucleotides C-74 and C-75 were strongly protected at both sites, the adjacent A-73 showed an enhanced reactivity in the A site. The anticodon region
G34
-A-A-ms2.6(1)A was also strongly protected at both sites. In addition, nucleotide A-21 was protected during A-site, but not P-site, binding.
...
PMID:Comparison of Escherichia coli tRNAPhe in the free state, in the ternary complex and in the ribosomal A and P sites by chemical probing. 618 69
A combination of several enzymes, RNase-T1, nuclease S1, T4-polynucleotide kinase and T4-RNA ligase were used to prepare and modify different fragments of yeast tRNAAsp (normal anticodon G U C). This allowed us to reconstitute, in vitro, a chimeric
tRNA
that has any of the four bases G, A, U or C, as the first anticodon nucleotide, labelled with (32p) in its 3' position. Such reconstituted (32p) labelled yeast tRNAAsp were microinjected into the cytoplasm or the nucleus of the frog oocyte and checked for their stability as well as for their potential to work as a substrate for the maturation (modifying) enzymes under in vivo conditions. Our results indicate that the chimeric yeast tRNAsAsp were quite stable inside the frog oocyte. Also, the
G34
was effectively transformed inside the cytoplasm of frog oocyte into Q34 and mannosyl-Q34; U34 into mcm5s2U and mcm5U. In contrast, C34 and A34 were not transformed at all neither in the cytoplasm nor in the nucleus of the frog oocyte. The above procedure constitutes a new approach in order to detect the presence of a given modifying enzyme inside the frog oocyte; also it provides informations about its cellular location and possibility about its specificity of interaction with foreign
tRNA
.
...
PMID:Enzymatic replacement in vitro of the first anticodon base of yeast tRNAAsp: application to the study of tRNA maturation in vivo, after microinjection into frog oocytes. 628 19
We have investigated the specificity of the enzymes Q-insertase and mannosyl-Q transferase that replace the guanosine at position 34 (wobble base) in the anticodon of several tRNAs by Q or mannosyl-Q derivatives. We have restructured in vitro the normal anticodon of yeast
tRNA
-Asp-GUC, yeast tRNAArgICG and yeast tRNALeuUAG. With yeast
tRNA
-Asp-GUC, we have replaced one or several nucleotides in the vicinity of
G34
by one of the four canonical nucleotides or by pseudouridylic acid; we have also constructed a tRNAAsp with eight bases instead of seven in the anticodon loop. With yeast tRNAArgICG and yeast tRNALeuUAG, we have replaced their anticodon by the trinucleotide GUC, coding for aspartic acid. The chimerical tRNAs were microinjected into the cytoplasm of Xenopus laevis oocytes and after 72 h the amount of Q34 and mannosyl-Q34 incorporated was measured. Our results show that the U33G34U35 sequence, within an anticodon loop of seven bases in chimerical yeast
tRNA
-Asp-GUC, tRNAArgGUC or tRNALeuGUC, is the main determinant for Q-insertase activity at position 34; the rest of the
tRNA
sequence has only a slight influence. For mannosyl-Q transferase, however, a much broader structural feature of the
tRNA
than just the U33G34U35 sequence is important for the efficiency of Q34 transformation into mannosyl-Q34.
...
PMID:Site-directed in vitro replacement of nucleosides in the anticodon loop of tRNA: application to the study of structural requirements for queuine insertase activity. 635 8
The stereochemistry and the dynamics of two loops of yeast
tRNA
-asp, the thymine loop and the anticodon loop, are compared in the hope of a better understanding of the relationships between loop sequence and loop topology. Both loops are seven residues long and both present sharp turns after the second residue, U33 and psi 55, stabilized by hydrogen bonds between N3-H of the pyrimidine and the phosphates of C36 and A58 and stacking interactions of the pyrimidine ring with the phosphates of U35 and A57, respectively. In the thymine loop, the two purines following C56, A57 and A58, open up to leave space for the intercalation of the first invariant guanine residue of the D-loop, while the two pyrimidine bases, which follow A58, turn away from the stacking pattern of the thymine arm and stack instead with the last base pair of the dihydrouridine arm A15-U48. In the anticodon loop, however, the bases
G34
to C38 form an helical stack in continuity with the anticodon stem on the 3'-end. At the same time C36 forms Watson-Crick hydrogen bonds with
G34
of a twofold symmetrically related molecule. The anticodon-anticodon base pairing interactions between symmetrically-related molecules are stabilized by stacking with the modified base G37 on both sides of the triplet. Some comparisons are made with the structure of yeast
tRNA
-phe and some implications about the structure of mitochondrial tRNAs are discussed.
...
PMID:Loop stereochemistry and dynamics in transfer RNA. 640 Nov 14
Various tumor cells contain chromatographically distinct isoacceptor
tRNA
species. To decide whether the tumor-specific species represent an expression of a separate
tRNA
gene or only an undermodified form of normal tRNAPhe, nucleotide sequences of tRNAPhe isolated from neuroblastoma and normal mouse liver were determined by postlabeling techniques. The results showed identical sequences except for the changes of post-transcriptional modifications in the anticodon loop. Normal mouse liver tRNAPhe contained Cm32, Gm34, and the hypermodified YOH next to the 3' end of the anticodon. On the contrary, tRNAPhe from neuroblastoma contained C32,
G34
, and, instead of YOH base m1G. A small proportion of tRNAPhe species contained an undermodified YOH base. For the examination of the conditions leading to the undermodified tRNAPhe, Vero cells derived from the kidney of African green monkey in culture were used. In these cells, deprivation of methionine or lysine resulted in changes in tRNAPhe modification similar to those in tumor cells. Ehrlich ascites tumor cells were examined to determine whether the presence of altered tRNAPhe species in various tumors is also the result of starvation of some nutritional factors. Results obtained with these cells showed that tRNAPhe species lacking the Y base disappeared in tumor-bearing mice after intraperitoneal injection with a mixture of amino acids and vitamins. Thus it is concluded that tumor-specific tRNAPhe species are the products of aberrant post-transcriptional modification, not the transcripts of different, normally repressed genes.
...
PMID:Alterations in post-transcriptional modification of the Y base in phenylalanine tRNA from tumor cells. 640 57
To evaluate the role of the modified nucleosides in
tRNA
function, especially their involvement in regulatory mechanisms of development, differentiation, or neoplastic transformation we use the following organisms: eubacteria, the slime mold D. discoideum, the topminnow Xiphophorus, and mice. Ribosylthymine, a common modified nucleoside at position 54 in tRNAs of prokaryotes and the major class of eukaryotic elongator tRNAs, is involved in the binding to the ribosomal A-site and is important for the proper functioning of
tRNA
during translation. Alterations in the extent of this modification occur early in the development of D. discoideum. The fully methylated species are found on polysomes, actively synthesizing protein. The partially methylated tRNAs accumulate in the nuclei, and might be involved in regulatory mechanisms at the transcriptional level. The Q base, a modified deazaguanine derivative, is present at position 34, the first position of the anticodon of tRNAAsn, tRNATyr, and tRNAHis. Alterations in the extent of this modification occur in corresponding tRNAs during the first minutes after the onset of development in D. discoideum and before final differentiation into spores, indicating that Q is important for developmental processes. Changes in the modification of
G34
to Q34 in specific tRNAs of the melanophoric system of the topminnow Xiphophorus further support the view that Q is necessary in differentiation. In plasmacytomas and in Ehrlich ascites tumor cells of mice, the amount of unmodified
G34
in corresponding tRNAs is correlated to the growth rate, density, or age of the tumor cells.
...
PMID:Alteration of tRNA modification in eukaryotes: causes and consequences. 684 95
Nucleotide sequences of normal mouse liver tRNAPhe and tumor-specific tRNAPhes isolated from Ehrlich ascites tumor and neuroblastoma cells were examined by post-labeling techniques. The results showed that their sequences are identical, except for changes in post-transcriptional modifications that are located in the anticodon region. Normal mouse liver tRNAPhe contained Cm32, Gm34 and YOH37. On the other hand, tumor-specific tRNAPhes were found in one of two possible configurations: 1) Cm32, Gm34 and Y*OH37 (under-modified YOH) or 2) C32,
G34
and m1G37. The ratio of the two forms of tRNAPhes differed in different tumor cells; Ehrlich ascites tumor tRNAPhe had mainly Y*OH-containing tRNAPhe whereas neuroblastoma tRNAPhe has predominantly m1G-containing tRNAPhe. It was concluded that tumor-specific tRNAPhes are products of different extents of modification, rather than of new
tRNA
transcription.
...
PMID:Changes of post-transcriptional modification of wye base in tumor-specific tRNAPhe. 692 49
In vivo yeast precursor tRNAs have been identified using a modification of the Northern-hybridization procedure. Two species of pre-
tRNA
Tyr, 1 species of pre-
tRNA
Ser2 and 2 species of pre-
tRNA
Serminor have been found in all yeast strains examined, including parental strains and strains harboring mutations affecting
tRNA
function. One of the
tRNA
Tyr strains harboring and one of the pre-
tRNA
SerUCG are the same size as the unspliced pre-tRNAs which accumulate in the yeast mutant rna1. The in vivo
tRNA
Tyr precursors detected in these studies also appear similar with the RNA species identified when cloned yeast
tRNA
Tyr is transcribed and processed by Xenopus oocytes and/or Xenopus extracts. We have also studied the precursor and mature
tRNA
Tyr species from 22 mutants which contain mutations in the SUP4 tyrosine-inserting suppressor locus. The RNA from 2 mutants mapping at the
G52
position showing an aberrantly migrating "mature"
tRNA
Tyr. Although several of those cloned mutant genes showed transcript products of altered size in in vitro transcription studies (1), we did not detect such altered transcripts in vivo.
...
PMID:tRNA synthesis: identification of in vivo precursor tRNAs from parental and mutant yeast strains. 701 84
The nucleotide sequence of initiator
tRNA
(tRNAiMet) from Euphausia sperba, which was harvested in the Antarctic Sea, was determined to be pA-G-C-A-G-A-G-U-m1G-m2G-C-G-C-A-G-U-G-G-A-A-G-C-G-U-m2G-C-U-G-G-G-C-C-C-A-U-t6 A-A-C-C-C-A-G-A-G-m7G-U-C-G-G-U-A-G-A-psi-C-G-m1A-A-A-C-U-A-C-U-C-U-C-U-G-C-U-A -C-C-AOH by using post-labeling methods recently developed. The nucleotide sequence was very similar to that of mammalian tRNAiMet except for changes in six bases and three modifications: C16, U55, D47 and m5C48 are replaced by U16, psi 55 and unmodified U47 and C48, respectively. A50-U64 and
G52
-C62 base pairs of mammalian tRNAiMet are reversed in Euphausia tRNAiMet. In addition, the G49-C65 pair of the former is replaced by a less stable G49-U65 pair in Euphausia tRNAiMet. The sequence homology was compared between Euphausia tRNAiMet and over ten different species of eucaryotic tRNAiMet so far sequenced. The melting temperature of Euphausia tRNAiMet was 72.5 degrees C, which is 4.2 degrees C and 8.3 degrees C lower than those of rat liver and yeast tRNAiMet's, respectively. The origin of the thermal instability of Euphausia tRNAiMet is discussed in comparison of its secondary structure compared with those of other eucaryotic tRNAiMet's.
...
PMID:Chemical structure and thermal properties of initiator tRNA from Euphausia sperba in comparison with those of other eucaryotic initiator tRNAs. 704 Mar 53
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