| Record ID | marc_columbia/Columbia-extract-20221130-009.mrc:79686673:3747 |
| Source | marc_columbia |
| Download Link | /show-records/marc_columbia/Columbia-extract-20221130-009.mrc:79686673:3747?format=raw |
LEADER: 03747fam a2200385 a 4500
001 4063051
005 20221027030203.0
008 991217s2000 nyua b 001 0 eng
010 $a 99087811
020 $a0198503547 (alk. paper)
035 $a(OCoLC)50667383
035 $a(OCoLC)ocm50667383
035 $9AQW2781HS
035 $a(NNC)4063051
035 $a4063051
040 $aDLC$cDLC$dNNC-M$dOrLoB-B
042 $apcc
050 00 $aQH450.2$b.W34 2000
082 00 $a572.8/845$221
100 1 $aWagner, Rolf,$d1948-$0http://id.loc.gov/authorities/names/n00000854
245 10 $aTranscription regulation in prokaryotes /$cRolf Wagner.
260 $aNew York :$bOxford University Press,$c2000.
300 $axiv, 365 pages :$billustrations ;$c24 cm
336 $atext$btxt$2rdacontent
337 $aunmediated$bn$2rdamedia
504 $aIncludes bibliographical references and index.
505 00 $g1.$tGeneral introduction.$g1.1.$tFlow of genetic information.$g1.2.$tDistinctive features of prokaryotic gene regulation.$g1.3.$tBiochemical nature of the transcription reaction.$g1.4.$tWhat makes RNA transcription different from DNA replication?$g1.5.$tThe products of transcription --$g2.$tThe 'players' or cellular components necessary for transcription.$g2.1.$tTranscription start sites: the promoter.$g2.2.$tRNA polymerase.$g2.3.$tAlternative [sigma] factors.$g2.4.$tThe three-dimensional structure of RNA polymerase.$g2.5.$tIs RNA polymerase modified during different stages of transcription? --$g3.$tInitiation of transcription.$g3.1.$tPromoter location.$g3.2.$tThe closed RNA polymerase-promoter complex.$g3.3.$tFormation of open complexes.$g3.4.$tBinding of substrate NTPs - the ternary complexes.$g3.5.$tPromoter clearance and the formation of elongation complexes.$g3.6.$tThe kinetics and thermodynamics of transcription initiation --$g4.$tTranscription elongation.
505 80 $g4.1.$tThe architecture of elongating complexes - what is known about the different functional sites?$g4.2.$tThe rate of elongation.$g4.3.$tRNA polymerase pauses during transcription.$g4.4.$tTranscript cleavage factors.$g4.5.$t'Traffic problems' at the bacterial genome: collisions between transcription and replication machineries --$g5.$tTermination of transcription.$g5.1.$tFactor-independent termination.$g5.2.$tFactor-dependent termination.$g5.3.$tAttenuation of transcription.$g5.4.$tAntitermination --$g6.$tThe role of DNA structure in transcription regulation.$g6.1.$tIs DNA methylation involved in regulation?$g6.2.$tEffects of DNA curvature on transcription initiation.$g6.3.$tDNA supercoiling and transcription --$g7.$tRegulation by transcription factors.$g7.1.$tRepressors and operators - the classical model.$g7.2.$tThe modular structure of transcription factors.$g7.3.$tLysR, a representative of a large family of transcription factors.$g7.4.$tDNA loops - regulation through dynamic structures.
505 80 $g7.5.$tRegulation by DNA structuring proteins.$g7.6.$tTwo-component regulatory systems --$g8.$tRegulatory networks.$g8.1.$tThe SOS response.$g8.2.$tThe heat-shock response.$g8.3.$tStationary phase control.$g8.4.$tThe Lrp regulon.$g8.5.$tThe stringent control.$g8.6.$tGrowth rate regulation.$g8.7.$tLessons from a manifold regulated system - the synthesis of ribosomal RNA.
650 0 $aGenetic transcription$xRegulation.$0http://id.loc.gov/authorities/subjects/sh87001691
650 0 $aProkaryotes.$0http://id.loc.gov/authorities/subjects/sh85107388
650 0 $aMicrobial genetics.$0http://id.loc.gov/authorities/subjects/sh85084760
650 12 $aGenetics, Microbial.$0https://id.nlm.nih.gov/mesh/D005827
650 12 $aProkaryotic Cells.$0https://id.nlm.nih.gov/mesh/D011387
852 00 $boff,hsl$hQH450.2$i.W34 2000