Compensatory mutations demonstrate that P8 and P6 are RNA secondary structure elements important for processing of a group I intron.
about
A self-splicing group I intron in the nuclear pre-rRNA of the green alga, Ankistrodesmus stipitatus.A conserved base pair within helix P4 of the Tetrahymena ribozyme helps to form the tertiary structure required for self-splicingAn in vitro-selected RNA receptor for the GAAC loop: modular receptor for non-GNRA-type tetraloop.Selection of novel forms of a functional domain within the Tetrahymena ribozyme.Catalytic activity is retained in the Tetrahymena group I intron despite removal of the large extension of element P5.A region of group I introns that contains universally conserved residues but is not essential for self-splicingPutative intermediary stages for the molecular evolution from a ribozyme to a catalytic RNP.Design and development of a catalytic ribonucleoprotein.Selections for constituting new RNA-protein interactions in catalytic RNP.Site-specific isotope labeling of long RNA for structural and mechanistic studies.Sequence specificity of the P6 pairing for splicing of the group I td intron of phage T4.Modulation of group I ribozyme activity by cationic porphyrinsP5abc of the Tetrahymena ribozyme consists of three functionally independent elementsA two-piece derivative of a group I intron RNA as a platform for designing self-assembling RNA templates to promote Peptide ligation.Heterodimerization of Group I Ribozymes Enabling Exon Recombination through Pairs of Cooperative trans-Splicing Reactions.Tecto-GIRz: Engineered Group I Ribozyme the Catalytic Ability of Which Can Be Controlled by Self-Dimerization.A deteriorated triple-helical scaffold accelerates formation of the Tetrahymena ribozyme active structure.Three-dimensional folding of Tetrahymena thermophila rRNA IVS sequence: a proposal.
P2860
Q30447108-FF889AD2-A724-4BF6-8C82-B97740EF441FQ30460005-2F02E177-695A-4E68-A3A2-07A2CB5BB082Q34574660-A0C56D2F-C7B6-4807-A77F-EF5566BE3C98Q34837988-F810ADF3-B93A-40FC-A2BE-1D4D7E448C96Q35948736-CE0CF484-993E-49D5-84E4-5A45365AE137Q37278817-719D6EBA-14F8-499E-8575-C15FDE4F45A9Q38357472-8FA49772-AAC1-4C75-9F56-EB2B9C6420FFQ39645888-9359EA91-31F7-4A09-A9AD-D69E4FACB4F9Q39698001-44149EEC-2020-438D-BDA9-54AF70355A65Q39991106-F314AF12-393C-424D-8550-3BF056497300Q40539107-BAA0DE1A-052C-415E-A322-03EE000C141DQ41148710-9CC49137-D710-4CC2-80EC-CF40EAD9A998Q41865435-C3E9F35B-6AF4-41D8-9EDC-960A90FA9D02Q42322520-B026E47E-6F9C-4A45-BEC5-A004062787F7Q50859460-227D0F4D-5489-479D-9792-2B6377DCA7DDQ51309615-EFC6BE47-BE0F-4203-840D-3B5E3FD992F0Q52542712-28FDC4E7-71D3-4B5B-BC9B-EA59A88B5167Q54427163-D23FA80D-04E4-44F0-9012-EACA1A6A7E52
P2860
Compensatory mutations demonstrate that P8 and P6 are RNA secondary structure elements important for processing of a group I intron.
description
1989 nî lūn-bûn
@nan
1989年の論文
@ja
1989年論文
@yue
1989年論文
@zh-hant
1989年論文
@zh-hk
1989年論文
@zh-mo
1989年論文
@zh-tw
1989年论文
@wuu
1989年论文
@zh
1989年论文
@zh-cn
name
Compensatory mutations demonst ...... rocessing of a group I intron.
@en
type
label
Compensatory mutations demonst ...... rocessing of a group I intron.
@en
prefLabel
Compensatory mutations demonst ...... rocessing of a group I intron.
@en
P2093
P2860
P356
P1476
Compensatory mutations demonst ...... rocessing of a group I intron.
@en
P2093
C L Williamson
P2860
P304
P356
10.1093/NAR/17.2.675
P577
1989-01-01T00:00:00Z