| P2093 | author name string | J G Zhou | |
| | H R Wilson | |
| | G Guarneros | |
| | D L Court | |
| | L Kameyama | |
| P2860 | cites work | An RNA polymerase II elongation factor encoded by the human ELL gene | Q24321774 |
| | A long-range RNA-RNA interaction forms a pseudoknot required for translational control of the IF3-L35-L20 ribosomal protein operon in Escherichia coli | Q24562091 |
| | Conserved structures and diversity of functions of RNA-binding proteins | Q27861066 |
| | rRNA transcription rate in Escherichia coli | Q30442384 |
| | NusA protein is necessary and sufficient in vitro for phage lambda N gene product to suppress a rho-independent terminator placed downstream of nutL. | Q33566502 |
| | Bacteriophage lambda N protein alone can induce transcription antitermination in vitro | Q33621540 |
| | Post-transcriptional regulation accounts for the trans-activation of the human T-lymphotropic virus type III. | Q34161762 |
| | Secondary structure of the leader transcript from the Escherichia coli S10 ribosomal protein operon | Q34164092 |
| | Tumor Suppression and Transcription Elongation: The Dire Consequences of Changing Partners | Q34303968 |
| | Autogenous control of the S10 ribosomal protein operon of Escherichia coli: genetic dissection of transcriptional and posttranscriptional regulation | Q34346681 |
| | Bacteriophage T4 regA protein binds to mRNAs and prevents translation initiation | Q34362535 |
| | Target site of Escherichia coli ribosomal protein S15 on its messenger RNA. Conformation and interaction with the protein | Q34374215 |
| | Bipartite function of a small RNA hairpin in transcription antitermination in bacteriophage lambda | Q34408409 |
| | Unusual mRNA pseudoknot structure is recognized by a protein translational repressor | Q34413810 |
| | Enhanced activity of the bacteriophage lambda PL promoter at low temperature | Q34574794 |
| | Effects of all single base substitutions in the loop of boxB on antitermination of transcription by bacteriophage lambda's N protein | Q35236767 |
| | How the phage lambda N gene product suppresses transcription termination: communication of RNA polymerase with regulatory proteins mediated by signals in nascent RNA | Q35384285 |
| | Genetic analysis of the rnc operon of Escherichia coli | Q35424534 |
| | Evidence that ribosomal protein S10 participates in control of transcription termination | Q35424757 |
| | Translation of trpG in Bacillus subtilis is regulated by the trp RNA-binding attenuation protein (TRAP). | Q35591124 |
| | trp RNA-binding attenuation protein (TRAP)-trp leader RNA interactions mediate translational as well as transcriptional regulation of the Bacillus subtilis trp operon. | Q35598116 |
| | Control of transcription processivity in phage lambda: Nus factors strengthen the termination-resistant state of RNA polymerase induced by N antiterminator | Q35739925 |
| | Mutations of the phage lambda nutL region that prevent the action of Nun, a site-specific transcription termination factor | Q36110298 |
| | Ribosomal protein S15 from Escherichia coli modulates its own translation by trapping the ribosome on the mRNA initiation loading site. | Q36296408 |
| | A pSC101-derived plasmid which shows no sequence homology to other commonly used cloning vectors | Q36587315 |
| | Ribosomal protein L4 stimulates in vitro termination of transcription at a NusA-dependent terminator in the S10 operon leader | Q37732339 |
| | Transcription elongation and eukaryotic gene regulation | Q37935764 |
| | A protein-RNA interaction network facilitates the template-independent cooperative assembly on RNA polymerase of a stable antitermination complex containing the lambda N protein | Q38289201 |
| | HIV TAR: an RNA enhancer? | Q38708348 |
| | The N protein of bacteriophage lambda, defined by its DNA sequence, is highly basic | Q39300148 |
| | Suppressors of the secY24 mutation: identification and characterization of additional ssy genes in Escherichia coli | Q39967492 |
| | Regulation of the Bacillus subtilis trp operon by an RNA-binding protein | Q40666950 |
| | Antitermination and absence of processing of the leftward transcript of coliphage lambda in the RNAase III-deficient host | Q40751740 |
| | RNA recognition by the human immunodeficiency virus Tat and Rev proteins | Q40767437 |
| | Common mechanisms for the control of eukaryotic transcriptional elongation | Q40797242 |
| | Transcriptional antitermination | Q40825617 |
| | Control of transcription termination by RNA-binding proteins | Q40835318 |
| | Coliphage λnutL−: A unique class of mutants defective in the site of gene N product utilization for antitermination of leftward transcription | Q40957739 |
| | Transcription antitermination: the lambda paradigm updated | Q41034487 |
| | Independence of gene N and tof functions of bacteriophage lambda | Q41874420 |
| | Supercoiling, integration host factor, and a dual promoter system, participate in the control of the bacteriophage lambda pL promoter | Q42608606 |
| | Integration host factor stimulates the phage lambda pL promoter | Q42630876 |
| | Identification of a T4 gene required for bacteriophage mRNA processing | Q42639972 |
| | Sequence-specific recognition of RNA hairpins by bacteriophage antiterminators requires a conserved arginine-rich motif | Q43418894 |
| | RNaselll activation of bacteriophage ? N synthesis | Q43671645 |
| | The nut site of bacteriophage lambda is made of RNA and is bound by transcription antitermination factors on the surface of RNA polymerase | Q43800197 |
| | The relationship between function and DNA sequence in an intercistronic regulatory region in phage λ | Q44424132 |
| | Transcription-dependent competition for a host factor: the function and optimal sequence of the phage lambda boxA transcription antitermination signal. | Q44453257 |
| | An antitermination protein engages the elongating transcription apparatus at a promoter-proximal recognition site | Q44558029 |
| | Host factor requirements for processive antitermination of transcription and suppression of pausing by the N protein of bacteriophage lambda | Q44680057 |
| | Recognition of boxA antiterminator RNA by the E. coli antitermination factors NusB and ribosomal protein S10 | Q44700986 |
| | Insertional disruption of the nusB (ssyB) gene leads to cold-sensitive growth of Escherichia coli and suppression of the secY24 mutation | Q45049536 |
| | A nuclear translational block imposed by the HIV-1 U3 region is relieved by the Tat-TAR interaction | Q45256281 |
| | Trans-activation of human immunodeficiency virus occurs via a bimodal mechanism | Q45830933 |
| | Conservation of genome form but not sequence in the transcription antitermination determinants of bacteriophages lambda, phi 21 and P22. | Q46580568 |
| | HIV-1 TAT "activates" presynthesized RNA in the nucleus | Q48291503 |
| | lambda N antitermination system: functional analysis of phage interactions with the host NusA protein. | Q50201406 |
| | Protein degradation in E. coli: the lon mutation and bacteriophage lambda N and cII protein stability. | Q51257910 |
| | The bacteriophage T4 regB ribonuclease. Stimulation of the purified enzyme by ribosomal protein S1. | Q52213554 |
| | Bacteriophage lambda N-dependent transcription antitermination. Competition for an RNA site may regulate antitermination. | Q54640587 |
| | Ribosomal protein L4 of Escherichia coli: in vitro analysis of L4-mediated attenuation control | Q54696361 |
| | Processing of the major leftward mRNA of coliphage lambda | Q67457806 |
| | Escherichia coli threonyl-tRNA synthetase and tRNA(Thr) modulate the binding of the ribosome to the translational initiation site of the thrS mRNA | Q68626034 |
| | Bacteriophage lambda N gene leader RNA. RNA processing and translational initiation signals | Q70042877 |
| | Transcription antitermination by bacteriophage lambda N gene product | Q70531443 |
| | Ribosome Initiation Complex Formation with the Pseudoknotted α Operon Messenger RNA | Q72070098 |
| | E. coli ribosomal protein L4 is a feedback regulatory protein | Q72148038 |
| | Transcription antitermination in vitro by lambda N gene product: requirement for a phage nut site and the products of host nusA, nusB, and nusE genes | Q72388921 |
| | The nusA recognition site. Alteration in its sequence or position relative to upstream translation interferes with the action of the N antitermination function of phage lambda | Q72411588 |
| | Escherichia coli nusB mutations that suppress nusA1 exhibit λ N specificity | Q72790354 |
| | Suppression of Transcription Termination by Phage Lambda | Q72931068 |
| P433 | issue | 17 | |
| P304 | page(s) | 2204-2213 | |
| P577 | publication date | 1997-09-01 | |
| P1433 | published in | Genes & Development | Q1524533 |
| P1476 | title | Translational repression by a transcriptional elongation factor | |
| P478 | volume | 11 | |