about
Deep sequencing analysis of small noncoding RNA and mRNA targets of the global post-transcriptional regulator, HfqDifferential RNA-seq of Vibrio cholerae identifies the VqmR small RNA as a regulator of biofilm formationComparative genomics boosts target prediction for bacterial small RNAsSigmaE-dependent small RNAs of Salmonella respond to membrane stress by accelerating global omp mRNA decayTarget activation by regulatory RNAs in bacteriaSmall RNAs endow a transcriptional activator with essential repressor functions for single-tier control of a global stress regulonA conserved small RNA promotes discoordinate expression of the glmUS operon mRNA to activate GlmS synthesisCoding sequence targeting by MicC RNA reveals bacterial mRNA silencing downstream of translational initiationA conserved RpoS-dependent small RNA controls the synthesis of major porin OmpDSpecific and pleiotropic patterns of mRNA regulation by ArcZ, a conserved, Hfq-dependent small RNASystematic deletion of Salmonella small RNA genes identifies CyaR, a conserved CRP-dependent riboregulator of OmpX synthesisTargeted decay of a regulatory small RNA by an adaptor protein for RNase E and counteraction by an anti-adaptor RNARegulatory RNA in bacterial pathogensSmall RNA-mediated activation of sugar phosphatase mRNA regulates glucose homeostasisEvidence for an autonomous 5' target recognition domain in an Hfq-associated small RNAIn Vivo Cleavage Map Illuminates the Central Role of RNase E in Coding and Non-coding RNA PathwaysSmall non-coding RNAs and the bacterial outer membrane.An atlas of Hfq-bound transcripts reveals 3' UTRs as a genomic reservoir of regulatory small RNAs.Acid stress activation of the sigma(E) stress response in Salmonella enterica serovar Typhimurium.The transcriptional landscape and small RNAs of Salmonella enterica serovar Typhimurium.A qrr noncoding RNA deploys four different regulatory mechanisms to optimize quorum-sensing dynamics.The ancestral SgrS RNA discriminates horizontally acquired Salmonella mRNAs through a single G-U wobble pair.Gifsy-1 Prophage IsrK with Dual Function as Small and Messenger RNA Modulates Vital Bacterial Machineries.Small RNA-based feedforward loop with AND-gate logic regulates extrachromosomal DNA transfer in SalmonellaThe VrrA sRNA controls a stationary phase survival factor Vrp of Vibrio cholerae.Functional determinants of the quorum-sensing non-coding RNAs and their roles in target regulation.Quorum sensing signal-response systems in Gram-negative bacteria.Multiple target regulation by small noncoding RNAs rewires gene expression at the post-transcriptional level.Small RNA functions in carbon metabolism and virulence of enteric pathogens.Interplay of regulatory RNAs and mobile genetic elements in enteric pathogens.Superfolder GFP reporters validate diverse new mRNA targets of the classic porin regulator, MicF RNA.A Vibrio cholerae autoinducer-receptor pair that controls biofilm formation.A small RNA activates CFA synthase by isoform-specific mRNA stabilization.Pervasive post-transcriptional control of genes involved in amino acid metabolism by the Hfq-dependent GcvB small RNA.Hfq and Hfq-dependent small RNAs are major contributors to multicellular development in Salmonella enterica serovar Typhimurium.Microbes at their best: first Mol Micro Meeting Würzburg.Sweet Business: Spot42 RNA Networks with CRP to Modulate Catabolite RepressionThree autoinducer molecules act in concert to control virulence gene expression in Vibrio choleraemRNA dynamics and alternative conformations adopted under low and high arginine concentrations control polyamine biosynthesis in SalmonellaA conserved RNA seed-pairing domain directs small RNA-mediated stress resistance in enterobacteria
P50
Q21145046-6243DE69-2658-4846-9603-BD5B5474656AQ24490182-EF2C8F42-8B1C-46A8-97B5-9F10D59E9AEAQ24621557-D54C4E1F-EAA3-4FD7-9FD9-8193B104536EQ24669800-4170903B-0BA2-4883-8461-01043DAD4954Q28081126-BFA1B847-A90F-4C6E-A94F-A28C95B504ABQ28243536-186E4F30-2DBB-4E5A-BBC7-89BB7769AC5DQ28248562-06DBBA9D-4742-4AF2-90B5-B15D62A2B6FCQ28252581-E30C9FE2-F5BD-47CE-BB53-DE03CF15F373Q28255704-70BC5912-A1DD-4A38-B424-07BDB29273E4Q28257497-EDE21325-DB3C-4AF3-8012-03F0912F6154Q28275777-1CE5C538-C869-4B67-9A14-9411959E3D32Q28286931-ED5E738C-2A42-4BA6-8101-5AABF10CF9CCQ28288142-D047A1DB-0B9D-4528-AEE0-E442043DD4C5Q28288849-3599A682-B5AA-4199-9708-0AD6A0354229Q28297881-D2D43ADF-C801-4BA1-804F-7024A573AEE1Q28583172-B0E1861D-4905-4823-8693-B721BEF2A758Q34000397-14947B5D-18E1-42DB-9BDD-FB5737876E30Q34033315-0DA6890B-6298-4150-89FC-BACE1173B6B2Q34147553-B7D29A72-6A66-4414-889F-A435D6F624DBQ34248983-BFC1BFFB-BE11-4EE5-866C-E9FC4CD22D5CQ35036974-812B2778-DD90-48B4-AFA6-3D2FC6602F99Q35882335-5B7C9FAA-2EEA-42B1-94DA-525ED561B6D0Q35983412-0587D4A0-A37B-4886-B756-F7AE0D3B169CQ36008348-3562259F-1C93-4703-A4B8-E9C5A8EF722EQ36191630-5FCDFDB7-7D1D-4BA2-8519-EE7618373BC7Q37061489-7F08827A-7988-4E9A-AC44-0814E113E03AQ37324474-CA4A35AC-3CD7-4540-BE6C-A291F66D23A7Q37444341-CF6BCC24-9462-4454-B534-93F59D6363EBQ38235406-B8B2B4D9-F668-444A-822D-D1B219341716Q38846031-0C9681A6-5450-4655-B99E-A80ABBF20257Q40028342-CD9EBC46-A3CD-4385-B6C9-721CCCDE5068Q41716508-D85DD3AF-1692-4262-B06F-ECBAE11433F7Q42883177-EB682A46-24A5-4A4D-80D0-128AFFFB4ED4Q43576806-E956C043-5349-4C0C-A149-5C402234B5A0Q50030594-B2DAD2CD-D7EB-4672-9B6D-EF73D31C5AF8Q51670865-5F7CE611-B959-4618-81F3-9AB123ED1A13Q57826101-DDBF58DD-3EED-42A9-B412-25E066381844Q64226550-FF77773C-2131-450F-A2FE-91F478D08BF3Q64272263-26163835-1707-4F80-9485-3D7C4F322D99Q76319373-7884D4B0-3F98-4713-9F06-469F008FF7B2
P50
description
hulumtues
@sq
researcher
@en
ricercatore
@it
wetenschapper
@nl
հետազոտող
@hy
name
Kai Papenfort
@ast
Kai Papenfort
@en
Kai Papenfort
@es
Kai Papenfort
@nl
Kai Papenfort
@sl
type
label
Kai Papenfort
@ast
Kai Papenfort
@en
Kai Papenfort
@es
Kai Papenfort
@nl
Kai Papenfort
@sl
prefLabel
Kai Papenfort
@ast
Kai Papenfort
@en
Kai Papenfort
@es
Kai Papenfort
@nl
Kai Papenfort
@sl
P108
P214
P1053
L-3187-2017
P106
P21
P214
P31
P3829
P496
0000-0002-5560-9804
P735
P7859
viaf-122274734