Tight binding of the 5' exon to domain I of a group II self-splicing intron requires completion of the intron active site.
(1/1426)
Group II self-splicing requires the 5' exon to form base pairs with two stretches of intronic sequence (EBS1 and EBS2) which also bind the DNA target during retrotransposition of the intron. We have used dimethyl sulfate modification of bases to obtain footprints of the 5' exon on intron Pl.LSU/2 from the mitochondrion of the alga Pylaiella littoralis, as well as on truncated intron derivatives. Aside from the EBS sites, which are part of the same subdomain (ID) of ribozyme secondary structure, three distant adenines become either less or more sensitive to modification in the presence of the exon. Unexpectedly, one of these adenines in subdomain IC1 is footprinted only in the presence of the distal helix of domain V, which is involved in catalysis. While the loss of that footprint is accompanied by a 100-fold decrease in the affinity for the exon, both protection from modification and efficient binding can be restored by a separate domain V transcript, whose binding results in its own, concise footprint on domains I and III. Possible biological implications of the need for the group II active site to be complete in order to observe high-affinity binding of the 5' exon to domain I are discussed. (+info)
The C-terminal region of hPrp8 interacts with the conserved GU dinucleotide at the 5' splice site.
(2/1426)
A U5 snRNP protein, hPrp8, forms a UV-induced crosslink with the 5' splice site (5'SS) RNA within splicing complex B assembled in trans- as well as in cis-splicing reactions. Both yeast and human Prp8 interact with the 5'SS, branch site, polypyrimidine tract, and 3'SS during splicing. To begin to define functional domains in Prp8 we have mapped the site of the 5'SS crosslink within the hPrp8 protein. Immunoprecipitation analysis limited the site of crosslink to the C-terminal 5060-kDa segment of hPrp8. In addition, size comparison of the crosslink-containing peptides generated with different proteolytic reagents with the pattern of fragments predicted from the hPrp8 sequence allowed for mapping of the crosslink to a stretch of five amino acids in the C-terminal portion of hPrp8 (positions 1894-1898). The site of the 5'SS:hPrp8 crosslink falls within a segment spanning the previously defined polypyrimidine tract recognition domain in yPrp8, suggesting that an overlapping region of Prp8 may be involved both in the 5'SS and polypyrimidine tract recognition events. In the context of other known interactions of Prp8, these results suggest that this protein may participate in formation of the catalytic center of the spliceosome. (+info)
The influence of junction conformation on RNA cleavage by the hairpin ribozyme in its natural junction form.
(3/1426)
In the natural form of the hairpin ribozyme the two loop-carrying duplexes that comprise the majority of essential bases for activity form two adjacent helical arms of a four-way RNA junction. In the present work we have manipulated the sequence around the junction in a way known to perturb the global folding properties. We find that replacement of the junction by a different sequence that has the same conformational properties as the natural sequence gives closely similar reaction rate and Arrhenius activation energy for the substrate cleavage reaction. By comparison, rotation of the natural sequence in order to alter the three-dimensional folding of the ribozyme leads to a tenfold reduction in the kinetics of cleavage. Replacement with the U1 four-way junction that is resistant to rotation into the antiparallel structure required to allow interaction between the loops also gives a tenfold reduction in cleavage rate. The results indicate that the conformation of the junction has a major influence on the catalytic activity of the ribozyme. The results are all consistent with a role for the junction in the provision of a framework by which the loops are presented for interaction in order to create the active form of the ribozyme. (+info)
The 3' end CCA of mature tRNA is an antideterminant for eukaryotic 3'-tRNase.
(4/1426)
Cytoplasmic tRNAs undergo posttranscriptional 5' and 3' end processing in the eukaryotic nucleus, and CCA (which forms the mature 3' end of all tRNAs) must be added by tRNA nucleotidyl transferase before tRNA can be aminoacylated and utilized in translation. Eukaryotic 3'-tRNase can endonucleolytically remove a 3' end trailer by cleaving on the 3' side of the discriminator base (the unpaired nucleotide 3' of the last base pair of the acceptor stem). This reaction proceeds despite a wide range in length and sequence of the 3' end trailer, except that mature tRNA containing the 3' terminal CCA is not a substrate for mouse 3'-tRNase (Nashimoto, 1997, Nucleic Acids Res 25:1148-1154). Herein, we extend this result with Drosophila and pig 3'-tRNase, using Drosophila melanogaster tRNAHis as substrate. Mature tRNA is thus prevented from recycling through 3' end processing. We also tested a series of tRNAs ending at the discriminator base (-), with one C added (+C), two Cs added (+CC), and CCA added (+CCA) as 3'-tRNase inhibitors. Inhibition was competitive with both Drosophila and pig 3'-tRNase. The product of the 3'-tRNase reaction (-) is a good 3'-tRNase inhibitor, with a KI approximately two times KM for the normal 3'-tRNase substrate. KI increases with each nucleotide added beyond the discriminator base, until when tRNA+CCA is used as inhibitor, KI is approximately forty times the substrate KM. The 3'-tRNase can thus remain free to process precursors with 3' end trailers because it is barely inhibited by tRNA+CCA, ensuring that tRNA can progress to aminoacylation. The active site of 3'-tRNase may have evolved to make an especially poor fit with tRNA+CCA. (+info)
Arginine methylation and binding of Hrp1p to the efficiency element for mRNA 3'-end formation.
(5/1426)
Hrp1p is a heterogeneous ribonucleoprotein (hnRNP) from the yeast Saccharomyces cerevisiae that is involved in the cleavage and polyadenylation of the 3'-end of mRNAs and mRNA export. In addition, Hrplp is one of several RNA-binding proteins that are posttranslationally modified by methylation at arginine residues. By using functional recombinant Hrp1p, we have identified RNA sequences with specific high affinity binding sites. These sites correspond to the efficiency element for mRNA 3'-end formation, UAUAUA. To examine the effect of methylation on specific RNA binding, purified recombinant arginine methyltransferase (Hmt1p) was used to methylate Hrp1p. Methylated Hrp1p binds with the same affinity to UAUAUA-containing RNAs as unmethylated Hrpl p indicating that methylation does not affect specific RNA binding. However, RNA itself inhibits the methylation of Hrp1p and this inhibition is enhanced by RNAs that specifically bind Hrpl p. Taken together, these data support a model in which protein methylation occurs prior to protein-RNA binding in the nucleus. (+info)
Disruption of substrate binding site in E. coli RNA polymerase by lethal alanine substitutions in carboxy terminal domain of the beta subunit.
(6/1426)
Alanine substitution of four amino acids in two evolutionarily conserved motifs, PSRM and RFGEMIE, near the carboxy terminus of the beta subunit of E. coli RNA polymerase results in a dramatic loss of the enzyme's affinity to substrates with no apparent effect on the maximal rate of the enzymatic reaction or on binding to promoters. The magnitude and selectivity of the effect suggest that the mutations disrupt the substrate binding site of the active center. (+info)
An improved separation procedure for nucleoside monophosphates on polyethyleneimine-(PEI-)cellulose thin layers.
(7/1426)
A procedure is described for the two-dimensional separation of the 4 major and 16 modified nucleoside-(5') monophosphates on anion-exchange thin layers of polyethyleneimine- (PEI-)cellulose. The method, which is simple and less time-consuming than existing partition chromatographic methods, may be used for the identification of 5'-termini of RNA and RNA fragments. (+info)
Physical and functional heterogeneity in TYMV RNA: evidence for the existence of an independent messenger coding for coat protein.
(8/1426)
Turnip yellow mosaic virus RNA can be separated into two distinct components of 2 times 10(6) and 300 000 daltons molecular weight after moderate heat treatment in the presence of SDS or EDTA. The two species cannot have arisen by accidental in vitro degradation of a larger RNA, as they both possess capped 5' ends. Analysis of the newly synthesized proteins resulting from translation of each RNA by a wheat germ extract shows that the 300 000 molecular weight RNA can be translated very efficiently into coat protein. When translated in vitro the longer RNA gave a series of high molecular weight polypeptides but only very small amounts of a polypeptide having about the same mass as the coat protein. Thus our results suggest that the small RNA is the functional messenger for coat protein synthesis in infected cells. (+info)