Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
about
Clamp loader ATPases and the evolution of DNA replication machinery.Crystal structure of HIV-1 reverse transcriptase in complex with a polypurine tract RNA:DNACrystallographic studies of chemically modified nucleic acids: a backward glanceRNase H activity: structure, specificity, and function in reverse transcriptionStructural features of the guide:target RNA duplex required for archaeal box C/D sRNA-guided nucleotide 2'-O-methylation2'-deoxy-2'-fluoro-beta-D-arabinonucleic acid (2'F-ANA) modified oligonucleotides (ON) effect highly efficient, and persistent, gene silencingCrystal structure of a DNA.RNA hybrid duplex with a polypurine RNA r(gaagaagag) and a complementary polypyrimidine DNA d(CTCTTCTTC)Solution structure of an arabinonucleic acid (ANA)/RNA duplex in a chimeric hairpin: comparison with 2'-fluoro-ANA/RNA and DNA/RNA hybridsNMR structure of an -L-LNA:RNA hybrid: structural implications for RNase H recognitionCrystal structures of DNA:DNA and DNA:RNA duplexes containing 5-(N-aminohexyl)carbamoyl-modified uracils reveal the basis for properties as antigene and antisense moleculesInsights into RNA/DNA hybrid recognition and processing by RNase H from the crystal structure of a non-specific enzyme-dsDNA complexThe Mechanism of ATP-Dependent Primer-Template Recognition by a Clamp Loader ComplexHow a DNA Polymerase Clamp Loader Opens a Sliding ClampThe Role of Mg(II) in DNA Cleavage Site Recognition in Group II Intron RibozymesUnlocking the sugar "steric gate" of DNA polymerasesPhosphoryl migration during the chemical synthesis of RNA.NMR characterization of a kissing complex formed between the TAR RNA element of HIV-1 and a DNA aptamerThe solution structure of [d(CGC)r(aaa)d(TTTGCG)](2): hybrid junctions flanked by DNA duplexesThe orientation and dynamics of the C2'-OH and hydration of RNA and DNA.RNA hybridsEffects of 3' untranslated region mutations on plus-strand priming during moloney murine leukemia virus replication.Deletion of a short, untranslated region adjacent to the polypurine tract in Moloney murine leukemia virus leads to formation of aberrant 5' plus-strand DNA ends in vivo.Structure and function of HIV-1 reverse transcriptase: molecular mechanisms of polymerization and inhibition.Alternate polypurine tracts (PPTs) affect the rous sarcoma virus RNase H cleavage specificity and reveal a preferential cleavage following a GA dinucleotide sequence at the PPT-U3 junction.Two step synthesis of (-) strong-stop DNA by avian and murine reverse transcriptases in vitro.Structural characteristics of 2'-O-(2-methoxyethyl)-modified nucleic acids from molecular dynamics simulations.Revisiting plus-strand DNA synthesis in retroviruses and long terminal repeat retrotransposons: dynamics of enzyme: substrate interactions.Reversion of a Moloney murine leukemia virus RNase H mutant at a second site restores enzyme function and infectivitySequence and structural determinants required for priming of plus-strand DNA synthesis by the human immunodeficiency virus type 1 polypurine tract.A single side chain prevents Escherichia coli DNA polymerase I (Klenow fragment) from incorporating ribonucleotides.Crystal structure of RNA-DNA duplex provides insight into conformational changes induced by RNase H bindingDirect observation of processive exoribonuclease motion using optical tweezers.Crystallization and preliminary X-ray analysis of Escherichia coli RNase HI-dsRNA complexes.Structural probing of the HIV-1 polypurine tract RNA:DNA hybrid using classic nucleic acid ligands.2'-Fluoroarabino- and arabinonucleic acid show different conformations, resulting in deviating RNA affinities and processing of their heteroduplexes with RNA by RNase HFidelity of plus-strand priming requires the nucleic acid chaperone activity of HIV-1 nucleocapsid protein.Dynamics and stability of individual base pairs in two homologous RNA-DNA hybrids.Effects of mutations in the G tract of the human immunodeficiency virus type 1 polypurine tract on virus replication and RNase H cleavageHIV-1 reverse transcriptase-associated RNase H cleaves RNA/RNA in arrested complexes: implications for the mechanism by which RNase H discriminates between RNA/RNA and RNA/DNASite-specific crosslinking of 4-thiouridine-modified human tRNA(3Lys) to reverse transcriptase from human immunodeficiency virus type I.2'-fluoro-4'-thioarabino-modified oligonucleotides: conformational switches linked to siRNA activity.
P2860
Q21245381-BEB759CB-E689-4DEF-8A77-E636A2569070Q24545723-0FA4051F-1047-4D08-A871-934C7A59C976Q24608092-A45A0AC6-6FB4-4FA9-831A-DEC215A227C0Q24643032-4A334C5F-A0FF-4254-92DE-B63455691978Q24684327-8FB42915-FDD0-47BC-AA62-698A426D167BQ25255757-FBC15794-8BB9-450D-BF1E-A7A56D334D4AQ27622296-3FEDFC0F-57D7-4AA5-8C20-A264E8C18693Q27635939-896E2AE2-2637-485A-AB77-D929CD233E1DQ27642301-FF6FEEA9-6661-42DA-92EE-425C1F209710Q27643996-116925B1-E2C1-4014-BAEB-DECEC8A7A6A0Q27651744-0B4773E8-A013-4F94-A5CA-CA20A314D6BFQ27655502-278031ED-7116-4D9F-85E0-6141499241E4Q27676381-6F3E0207-F04C-4DA0-99B7-B93A80EE1E52Q27684064-7F7AF540-94A2-4499-B22B-DD247F36B4E7Q28303047-8C5BA8C3-01E0-45D7-A815-1443EAAF5BEBQ30450745-2652DE4A-7A6B-4DB8-B95B-4F9FA30AEAFDQ30909558-94F5017C-CAA5-4354-874F-08C437D44835Q31524630-A3694590-EB6E-4F7D-BD11-81BD00124463Q32060910-EBCC9915-7A5A-45DA-B223-C5F397A6E17AQ33640102-51EE7342-B0CC-4184-82BB-183DF2EF4B60Q33804828-71CBFADE-0840-47D0-9544-4E271765E654Q33896402-1B962D4C-2B0A-48AB-B428-267CD757BC6BQ34092714-239FCBD4-4772-4E1E-99D1-E012A6E4150DQ34625646-D3993640-5938-41C3-B804-F7E5F0D10C03Q34674518-C91E3F6F-4BD5-4431-BA0D-F847E6EB2F63Q35259898-30B7A4DB-83BB-4ECC-92EA-0D92FB2223D2Q35845242-BF071999-77C3-4A89-B9C4-7A7E78622E85Q35866117-250AF4FF-B28F-4B90-9594-65103AD2047FQ36000833-FDC5E427-1659-4FAC-971D-4F98EB8E3858Q36189486-A1DFD8BB-D6AE-46CB-BD9B-36CBAB203FD2Q36371429-421000C9-128B-433D-8F53-54C5D8CF3D92Q36580411-1FA4DD97-2F90-4B86-8855-41FB889AAC9FQ36649670-D5BAFE2C-3CE2-452A-8C74-5F39C52BF33BQ36908756-C611121B-C733-4582-9A0F-DB4D9C68CD80Q37149739-B3A9828A-7A6D-4263-A3D3-0481CEABA543Q37378462-F92E5E6B-E9C7-4F8B-804F-EFCD057816E5Q37596444-A7337273-C12F-470D-9A34-6B26E829002AQ37694538-775FA0FB-D3B2-472C-856B-43B713B739AEQ37698214-A89CB5A3-C224-4609-8F70-5DC22C6256A0Q38305021-F29539CD-E3C4-4FC0-8F90-8915BCAF76EB
P2860
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
description
1993 nî lūn-bûn
@nan
1993 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
1993 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
1993年の論文
@ja
1993年論文
@yue
1993年論文
@zh-hant
1993年論文
@zh-hk
1993年論文
@zh-mo
1993年論文
@zh-tw
1993年论文
@wuu
name
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@ast
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@en
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@nl
type
label
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@ast
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@en
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@nl
prefLabel
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@ast
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@en
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@nl
P2093
P1476
Structure of a DNA:RNA hybrid duplex. Why RNase H does not cleave pure RNA
@en
P2093
P304
P407
P577
1993-10-05T00:00:00Z