Signal Recognition
Sensory Mechanisms in Bacteria
from Sensory Mechanisms in Bacteria: Molecular Aspects of Signal Recognition
Bacteria have evolved extraordinary abilities to detect physical and chemical signals, both within their own cells and in the extracellular environment. The interaction of a signal with its receptor (usually a protein or RNA molecule) triggers a series of events that lead to reprogramming of cellular physiology, typically as a consequence of altered patterns of gene expression. In this way, the bacterial cell is able to mount appropriate and effective responses to changing physical and/or chemical environments. The versatility with which many bacteria adapt to environmental change underlies many important aspects of microbiology. For example, pathogens encounter multiple environments as they invade a host from the outside, and then progress through different sites within host tissues. There is growing evidence that pathogenic bacteria make use of physical and chemical cues to signal their presence in a suitable host, and need to adapt to the host environment in order to mount a successful infection. On the other hand, it should not be assumed that all signals to which bacteria must respond originate in the extracellular environment. For many species, even the cosseted life in a laboratory shake flask is 'stressful', in the sense that there is often a need to avoid or reverse the effects of harmful intermediates or by-products of metabolism. For example, all organisms that use dioxygen as a terminal electron acceptor have to deal with the reactive oxygen species that arise as adventitious by-products of aerobic metabolism. In bacteria, multiple protein receptors for oxygen radicals have been described, which control the expression of genes encoding enzymes that detoxify oxygen radicals or repair the damage that they cause.
Further reading: Sensory Mechanisms in Bacteria: Molecular Aspects of Signal Recognition
Bacteria have evolved extraordinary abilities to detect physical and chemical signals, both within their own cells and in the extracellular environment. The interaction of a signal with its receptor (usually a protein or RNA molecule) triggers a series of events that lead to reprogramming of cellular physiology, typically as a consequence of altered patterns of gene expression. In this way, the bacterial cell is able to mount appropriate and effective responses to changing physical and/or chemical environments. The versatility with which many bacteria adapt to environmental change underlies many important aspects of microbiology. For example, pathogens encounter multiple environments as they invade a host from the outside, and then progress through different sites within host tissues. There is growing evidence that pathogenic bacteria make use of physical and chemical cues to signal their presence in a suitable host, and need to adapt to the host environment in order to mount a successful infection. On the other hand, it should not be assumed that all signals to which bacteria must respond originate in the extracellular environment. For many species, even the cosseted life in a laboratory shake flask is 'stressful', in the sense that there is often a need to avoid or reverse the effects of harmful intermediates or by-products of metabolism. For example, all organisms that use dioxygen as a terminal electron acceptor have to deal with the reactive oxygen species that arise as adventitious by-products of aerobic metabolism. In bacteria, multiple protein receptors for oxygen radicals have been described, which control the expression of genes encoding enzymes that detoxify oxygen radicals or repair the damage that they cause.
Further reading: Sensory Mechanisms in Bacteria: Molecular Aspects of Signal Recognition
Signal Recognition Book
Stephen Spiro and Ray Dixon (Texas, USA and Norwich,UK; respectively) present a new publication Sensory Mechanisms in Bacteria: Molecular Aspects of Signal Recognition
This book reviews a selection of important model systems, providing a timely snapshot of the current state of research in the field. The book opens with an introductory chapter that reviews the diversity of signal recognition mechanisms, illustrating the breadth of the field. Subsequent chapters include descriptions of the sensing of ligands (alpha-ketoglutarate, adenylate energy charge, glutamine and xenobiotic compounds), chemoreceptors, iron-sulfur cluster-based sensors, metal-dependent and metal-responsive sensors, thiol-based sensors, and PDZ domains as sensors of other proteins read more ....
This book reviews a selection of important model systems, providing a timely snapshot of the current state of research in the field. The book opens with an introductory chapter that reviews the diversity of signal recognition mechanisms, illustrating the breadth of the field. Subsequent chapters include descriptions of the sensing of ligands (alpha-ketoglutarate, adenylate energy charge, glutamine and xenobiotic compounds), chemoreceptors, iron-sulfur cluster-based sensors, metal-dependent and metal-responsive sensors, thiol-based sensors, and PDZ domains as sensors of other proteins read more ....
 | Edited by: Stephen Spiro and Ray Dixon ISBN: 978-1-904455-69-1 Publisher: Caister Academic Press Publication Date: September 2010 Cover: Hardback |
New Book on Signal Recognition
Category: Books
The following new book has been announced:
| Edited by: Stephen Spiro and Ray Dixon ISBN: 978-1-904455-69-1 Publisher: Caister Academic Press Publication Date: September 2010 Cover: Hardback read more ... |