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Query: EC:3.1.27.5 (
RNase
)
17,967
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A protein homologous to SRP54, a subunit of the mammalian
signal recognition particle
(
SRP
), was identified in Mycoplasma mycoides. The mycoplasma protein was expressed in E.coli and purified to near homogeneity. It was shown to bind specifically in vitro to a small mycoplasma RNA with structural features related to the RNA component of
SRP
. These findings provide evidence of a ribonucleoprotein complex in mycoplasma reminiscent of
SRP
. A part of the RNA was protected from
ribonuclease
digestion in the presence of the SRP54 homologue. The protected region contains structural elements that have been highly conserved in
SRP
RNAs during evolution.
...
PMID:A Mycoplasma protein homologous to mammalian SRP54 recognizes a highly conserved domain of SRP RNA. 128 Aug 9
The mammalian
signal recognition particle
(
SRP
) is a small cytoplasmic ribonucleoprotein required for the cotranslational targeting of secretory proteins to the endoplasmic reticulum membrane. The heterodimeric protein subunit SRP9/14 was previously shown to be essential for
SRP
to cause pausing in the elongation of secretory protein translation.
RNase
protection and filter binding experiments have shown that binding of SRP9/14 to
SRP
RNA depends solely on sequences located in a domain of
SRP
RNA that is strongly homologous to the Alu family of repetitive DNA sequences. In addition, the use of hydroxyl radicals, as RNA-cleaving reagents, has revealed four distinct regions in this domain that are in close contact with SRP9/14. Surprisingly, the nucleotide sequence in one of these contact sites, predicted to be mostly single stranded, was found to be extremely conserved in
SRP
RNAs of evolutionarily distant organisms ranging from eubacteria and archaebacteria to yeasts and higher eucaryotic cells. This finding suggests that SRP9/14 homologs may also exist in these organisms, where they possibly contribute to the regulation of protein synthesis similar to that observed for mammalian
SRP
in vitro.
...
PMID:Binding sites of the 9- and 14-kilodalton heterodimeric protein subunit of the signal recognition particle (SRP) are contained exclusively in the Alu domain of SRP RNA and contain a sequence motif that is conserved in evolution. 171
The secondary structure of the 7SL RNA in the
signal recognition particle
was determined by applying both a theoretical and an experimental approach. The compensatory base change approach was taken comparing the published sequences of human, Drosophila and Xenopus 7SL RNA's. The deduced secondary structure was confirmed by post-labeling of an
RNase
V1-nicked dog SRP with P32-pCp and RNA-ligase and analysis of the labeled RNA-fragments by non-denaturing/denaturing 2D polyacrylamide gel electrophoresis. Two interesting features in the secondary structure were revealed: Firstly, bases at positions 122 to 127 of the human 7SL RNA are not only able to pair with bases at positions 167 to 170, but also with a single-stranded region of the bases at positions 223 to 228, suggesting an alternative base pairing scheme for the 7SL RNA in all three organisms. In agreement with this finding, four different conformations were identified after transcription of the 7SL RNA from the genomic human clone. The involvement of the particular basepairing interaction postulated was confirmed by the analysis of a 7SL RNA deletion mutant (Sma1-409). Secondly, a significant sequence homology of the paired bases at positions 236 to 255 and 104 to 109 in 7SL RNA with bases in 5S ribosomal RNA at the positions 84 to 110 was noticed, suggesting that 5S ribosomal and 7SL RNA interact with the same target during protein biosynthesis. These findings are summarized by proposing a mechanism for the translational arrest of protein synthesis by the
signal recognition particle
using specific sequences and an alternative configuration in the 7SL RNA.
...
PMID:The secondary structure of the 7SL RNA in the signal recognition particle: functional implications. 241 23
We have studied the effects of mutations in a 6-base segment of Schizosaccharomyces pombe 7SL RNA, which lies within a 35-nucleotide domain whose sequence and secondary structure are conserved in RNAs from many divergent organisms, including the 7SL component of human
signal recognition particle
(
SRP
). Surprisingly, many changes in this region can be tolerated under normal growth conditions. An exception is the lethality of several mutations at positions 159 and 160, 2 nucleotides previously shown to be protected from
RNase
digestion by the 19-kDa canine
SRP
protein. Nucleotide 160 is, in addition, the most highly conserved base in a consensus sequence for the most common tetranucleotide loop in ribosomal RNAs. Mutations that are likely to affect the stability and/or conformation of the RNA give rise to a conditional phenotype: when osmolarity of the medium is raised, the RNAs become partially or completely defective in function at high temperature.
...
PMID:Genetic analysis of Schizosaccharomyces pombe 7SL RNA: a structural motif that includes a conserved tetranucleotide loop is important for function. 265 42
We have partially purified ribonucleoproteins (RNPs) from Schizosaccharomyces pombe and Yarrowia lipolytica with properties resembling those of mammalian
signal recognition particle
(
SRP
). In both species of yeast we have identified a single major RNA species in the size range of
SRP
RNA (256 nucleotides in S. pombe and 270 nucleotides in Y. lipolytica) present in postribosomal salt extracts of the cytoplasm. The RNPs containing these RNAs sediment in sucrose gradients at 11 S and 10 S for S. pombe and Y. lipolytica, respectively. Analysis of genomic clones of these RNAs has revealed that (i) they are encoded by single copy genes; (ii) they share two short conserved sequences that match the A and B boxes defined for polymerase III promoters; (iii) they can be folded into secondary structures that closely match that defined by phylogenetic analysis of higher eukaryotic
SRP
RNAs; and (iv) they show primary sequence conservation in short regions predicted to be single stranded. Both of the yeast RNAs bind under stringent conditions to canine
SRP
proteins. Most importantly,
RNase
protection of the S. pombe RNA by the individual canine
SRP
proteins, p19 and p68/72, shows that the proteins recognize homologous elements of the mammalian and yeast RNA. Taken together these data suggest strongly that we have identified yeast
SRP
homologues.
...
PMID:Small ribonucleoproteins in Schizosaccharomyces pombe and Yarrowia lipolytica homologous to signal recognition particle. 283 64
The structure of 4.5S RNA, the Escherichia coli homologue of the
signal recognition particle
(
SRP
) RNA, alone and in the
SRP
complex with protein P48 (Ffh) was probed both enzymatically and chemically. The molecule is largely resistant against single strand-specific nucleases, indicating a highly base paired structure. Reactivity appears mainly in the apical tetraloop and in one of the conserved internal loops. Although some residues are found reactive toward dimethylsulphate and kethoxal in regions predicted to be unpaired by the phylogenetic secondary structure model of 4.5S RNA, generally the reactivity is low, and some residues in internal loops are not reactive at all.
RNase
V1 cleaves the RNA at multiple sites that coincide with predicted helices, although the cleavages show a pronounced asymmetry. The binding of protein P48 to 4.5S RNA results in a protection of residues in the apical part of the molecule homologous to eukaryotic
SRP
RNA (domain IV), whereas the cleavages in the conserved apical tetraloop are not protected. Hydroxyl radical treatment reveals an asymmetric pattern of backbone reactivity; in particular, the region encompassing nucleotides 60-82, i.e., the 3' part of the conserved domain IV, is protected. The data suggest that a bend in the domain IV region, most likely at the central asymmetric internal loop, is an important element of the tertiary structure of 4.5S RNA. Hyperchromicity and lead cleavage data are consistent with the model as they reveal the unfolding of a higher-order structure between 30 and 40 degrees C. Protection by protein P48 occurs in this region of the RNA and, more strongly, in the 5' part of domain IV (nt 26-50, most strongly from 35 to 49). It is likely that P48 binds to the outside of the bent form of 4.5S RNA.
...
PMID:Structure of 4.5S RNA in the signal recognition particle of Escherichia coli as studied by enzymatic and chemical probing. 860 48
The
signal recognition particle
(
SRP
) RNA helix 6 of archaea and eukaryotes is essential for the binding of protein SRP19 and the assembly of a functional complex. The conserved adenosine at the third position of the tetraloop of helix 6 (A149) is crucial for the binding of protein SRP19 in the mammalian
SRP
. Here we investigated the significance of the equivalent adenosine residue at position 159 (A159) of Archaeoglobus fulgidus
SRP
RNA. The A159 of A. fulgidus and A149 of human
SRP
RNA were changed to C, G or U, and fragments containing helix 6 or helices 6 and 8 were synthesized by run-off transcription with T7 RNA polymerase. The ability of recombinant A. fulgidus and human SRP19 to form ribonucleoprotein complexes was measured in vitro. The simultaneous presence of A149 and helix 8 is required for the high-affinity binding of SRP19 to the human
SRP
RNA. In contrast, A. fulgidus SRP19 binds to the
SRP
RNA fragments with high affinity irrespective of the nature of the nucleotide, demonstrating that A159 does not directly participate in protein binding. Instead, as indicated by the resistance of the wild-type A. fulgidus RNA towards digestion by
RNase A
, this residue allows the formation of a tightly folded RNA molecule. The high affinity between A.fulgidus
SRP
19 and RNA molecules that contain both helices 6 and 8 suggests that A159 is likely to initiate archaeal
SRP
assembly by forming a conserved tertiary RNA-RNA interaction.
...
PMID:The conserved adenosine in helix 6 of Archaeoglobus fulgidus signal recognition particle RNA initiates SRP assembly. 1581 Apr 37
The human
signal recognition particle
(
SRP
) is a large RNA-protein complex that targets secretory and membrane proteins to the endoplasmic reticulum membrane. The S domain of
SRP
is composed of roughly half of the 7SL RNA and four proteins (SRP19, SRP54, and the SRP68/72 heterodimer). In order to understand how the binding of proteins induces conformational changes of RNA and affects subsequent binding of other protein subunits, we have performed chemical and enzymatic probing of all S domain assembly intermediates. Ethylation interference experiments show that phosphate groups in helices 5, 6 and 7 that are essential for the binding of SRP68/72 are all on the same face of the RNA. Hydroxyl radical footprinting and dimethylsulphate (DMS) modifications show that SRP68/72 brings the lower part of helices 6 and 8 closer. SRP68/72 binding also protects the SRP54 binding site (helix 8 asymmetric loop) from chemical modification and
RNase
cleavage, whereas, in the presence of both SRP19 and SRP68/72, the long strand of helix 8 asymmetric loop becomes readily accessible to chemical and enzymatic probes. These results indicate that the RNA platform observed in the crystal structure of the SRP19-SRP54M-RNA complex already exists in the presence of SRP68/72 and SRP19. Therefore, SRP68/72, together with SRP19, rearranges the 7SL RNA in an SRP54 binding competent state.
...
PMID:Protein-induced conformational changes of RNA during the assembly of human signal recognition particle. 1725
Small cytoplasmic RNA (scRNA) of Bacillus subtilis is the RNA component of the
signal recognition particle
. scRNA is transcribed as a 354-nt precursor, which is processed to the mature 271-nt scRNA. Previous work demonstrated the involvement of the RNase III-like endoribonuclease, Bs-RNase III, in scRNA processing. Bs-RNase III was found to cleave precursor scRNA at two sites (the 5' and 3' cleavage sites) located on opposite sides of the stem of a large stem-loop structure, yielding a 275-nt RNA, which was then trimmed by a 3' exoribonuclease to the mature scRNA. Here we show that Bs-RNase III cleaves primarily at the 5' cleavage site and inefficiently at the 3' site.
RNase
J1 is responsible for much of the cleavage that releases scRNA from downstream sequences. The subsequent exonucleolytic processing is carried out largely by RNase PH.
...
PMID:Processing of Bacillus subtilis small cytoplasmic RNA: evidence for an additional endonuclease cleavage site. 1757 66
Stable RNA maturation is a key process in the generation of functional RNAs, and failure to correctly process these RNAs can lead to their elimination through quality control mechanisms. Studies of the maturation pathways of ribosomal RNA and transfer RNA in Bacillus subtilis showed they were radically different from Escherichia coli and led to the identification of new B. subtilis-specific enzymes. We noticed that, despite their important roles in translation, a number of B. subtilis small stable RNAs still did not have characterised maturation pathways, notably the tmRNA, involved in ribosome rescue, and the RNase P RNA, involved in tRNA maturation. Here, we show that tmRNA is matured by RNase P and RNase Z at its 5' and 3' extremities, respectively, whereas the RNase P RNA is matured on its 3' side by
RNase
Y. Recent evidence that several RNases are not essential in B. subtilis prompted us to revisit maturation of the scRNA, a component of the
signal recognition particle
involved in co-translational insertion of specific proteins into the membrane. We show that
RNase
Y is also involved in 3' processing of scRNA. Lastly, we identified some of the enzymes involved in the turnover of these three stable RNAs.
...
PMID:Small stable RNA maturation and turnover in Bacillus subtilis. 2540 10
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