Revealing the many roles of RNA in regulating gene expression
For decades after the discoveries of messenger RNA, transfer RNA, and ribosomal RNA, it was largely assumed that the role of RNA in the cell was limited to shuttling the genomic message, chaperoning amino acids, and toiling in the ribosomes.
Eventually, hints that RNA molecules might have regulatory roles began to appear. With the advent of genomics and bioinformatics, it became evident that numerous other RNA forms exist and have specific functions, including small RNAs (sRNA), RNA thermometers, and riboswitches to regulate core metabolic pathways, bacterial pathogenesis, iron homeostasis, quorum sensing, and biofilm formation.
All of these functions, and more, are presented in Regulating with RNA in Bacteria and Archaea, written by RNA biologists from around the globe. Divided into eight sections-RNases and Helicases, Cis-Acting RNAs, Cis Encoded Base Pairing RNAs, Trans-Encoded Base Pairing RNAs, Protein Titration and Scaffolding, General Considerations, Emerging Topics, and Resources-this book serves as an excellent resource for established RNA biologists and for the many scientists who are studying regulated cellular systems.
It is no longer a fair assumption that gene expression regulation is the provenance of proteins only or that control is exerted primarily at the level of transcription. This book makes clear that regulatory RNAs are key partners along with proteins in controlling the complex interactions and pathways found within prokaryotes.
Autorentext
Gisela Storz is an NIH Distinguished Investigator in the Eunice Kennedy Shriver National Institute of Child Health and Human Development in Bethesda, Maryland. She carried out graduate work with Dr. Bruce Ames at the University of California, Berkeley and postdoctoral work with Dr. Sankar Adhya at the National Cancer Institute and Dr. Fred Ausubel at Harvard Medical School. As a result of the serendipitous discovery of the peroxide-induced OxyS RNA in E. coli, one of the first small, regulatory RNAs to be found, much of the work in her lab has focused on the genome-wide identification of small RNAs and their characterization.
Kai Papenfort is a Professor of Microbiology at the Ludwig Maximilians University of Munich, Germany. He received a diploma in biology from the University of Marburg and carried out graduate work with Dr. Jörg Vogel at the Max Planck Institute for Infection Biology and the Humboldt University of Berlin. In his postdoctoral work at the University of Würzburg and Princeton University, Dr. Papenfort studied the regulatory functions of small RNA in bacterial pathogens and their involvement in bacterial communication processes such as quorum sensing. His laboratory focuses on the molecular mechanisms underlying the regulation by small RNAs in the major human pathogen, Vibrio cholerae.
Klappentext
Regulating with RNA in Bacteria and Archaea
First Edition
Revealing the many roles of RNA in regulating gene expression
For decades after the discoveries of messenger RNA, transfer RNA, and ribosomal RNA, it was largely assumed that the role of RNA in the cell was limited to shuttling the genomic message, chaperoning amino acids, and toiling in the ribosomes.
Eventually, hints that RNA molecules might have regulatory roles began to appear. With the advent of genomics and bioinformatics, it became evident that numerous other RNA forms exist and have specific functions, including small RNAs (sRNA), RNA thermometers, and riboswitches to regulate core metabolic pathways, bacterial pathogenesis, iron homeostasis, quorum sensing, and biofilm formation.
All of these functions, and more, are presented in Regulating with RNA in Bacteria and Archaea, written by RNA biologists from around the globe. Divided into eight sections-RNases and Helicases, Cis-Acting RNAs, Cis Encoded Base Pairing RNAs, Trans-Encoded Base Pairing RNAs, Protein Titration and Scaffolding, General Considerations, Emerging Topics, and Resources-this book serves as an excellent resource for established RNA biologists and for the many scientists who are studying regulated cellular systems.
It is no longer a fair assumption that gene expression regulation is the provenance of proteins only or that control is exerted primarily at the level of transcription. This book makes clear that regulatory RNAs are key partners along with proteins in controlling the complex interactions and pathways found within prokaryotes.
Zusammenfassung
Revealing the many roles of RNA in regulating gene expression
For decades after the discoveries of messenger RNA, transfer RNA, and ribosomal RNA, it was largely assumed that the role of RNA in the cell was limited to shuttling the genomic message, chaperoning amino acids, and toiling in the ribosomes.
Eventually, hints that RNA molecules might have regulatory roles began to appear. With the advent of genomics and bioinformatics, it became evident that numerous other RNA forms exist and have specific functions, including small RNAs (sRNA), RNA thermometers, and riboswitches to regulate core metabolic pathways, bacterial pathogenesis, iron homeostasis, quorum sensing, and biofilm formation.
All of these functions, and more, are presented in Regulating with RNA in Bacteria and Archaea, written by RNA biologists from around the globe. Divided into eight sections-RNases and Helicases, Cis-Acting RNAs, Cis Encoded Base Pairing RNAs, Trans-Encoded Base Pairing RNAs, Protein Titration and Scaffolding, General Considerations, Emerging Topics, and Resources-this book serves as an excellent resource for established RNA biologists and for the many scientists who are studying regulated cellular systems.
It is no longer a fair assumption that gene expression regulation is the provenance of proteins only or that control is exerted primarily at the level of transcription. This book makes clear that regulatory RNAs are key partners along with proteins in controlling the complex interactions and pathways found within prokaryotes.
Inhalt
Contributors
Foreword
Preface
Acknowledgments
About the Editors
Section I: RNases and Helicases
1. RNase E and the High-Fidelity Orchestration of RNA Metabolism
Katarzyna J. Bandyra and Ben F. Luisi
2. Enzymes Involved in Posttranscriptional RNA Metabolism in Gram-Negative Bacteria
Bijoy K. Mohanty and Sidney R. Kushner
3. RNases and Helicases in Gram-Positive Bacteria
Sylvain Durand and Ciarán Condon
Section II: Cis-acting RNAs
4. RNA Thermometers in Bacterial Pathogens
Edmund Loh, Francesco Righetti, Hannes Eichner, Christian Twittenhoff, Franz Narberhaus
5. Small Molecule-Binding Riboswitches
Thea S. Lotz and Beatrix Suess
6. The T-Box Riboswitch: tRNA as an Effector to Modulate Gene Regulation
Kiel D. Kreuzer and Tina M. Henkin
7. rRNA Mimicry in RNA Regulation of Gene Expression
Michelle M. Meyer
8. Processive Antitermination
Jonathan R. Goodson and Wade C. Winkler
9. Genes within genes in bacterial genomes
Sezen Meydan, Nora Vázquez-Laslop, and Alexander S. Mankin
10. Leaderless mRNAs in the Spotlight: Ancient but Not Outdated!
Heather J. Beck and Isabella Moll
Section III: Cis-encoded base pairing RNAs
11. Type I Toxin-Antitoxin Systems: Regulating Toxin Expression via Shine-Dalgarno Sequence Sequestration and Small RNA Binding
Sara Masachis and Fabien Darfeuille
12. Widespread Antisense Transcription in Prokaryotes
Jens Georg and Wolfgang R. Hess
Section IV: Trans-encoded base p…