Multicellular organisms must be able to adapt to cellular events to accommodate prevailing conditions. Sensory-response circuits operate by making use of a phosphorylation control mechanism known as the "two-component system." Sections include: Computational Analyses of Sequences and Sequence Alignments Biochemical and Genetic Assays of Individual Components of Signaling Systems Physiological Assays and Readouts
Presents detailed protocols
Includes troubleshooting tips
Multicellular organisms must be able to adapt to cellular events to accommodate prevailing conditions. Sensory-response circuits operate by making use...
Multicellular organisms must be able to adapt to cellular events to accommodate prevailing conditions. Sensory-response circuits operate by making use of a phosphorylation control mechanism known as the "two-component system."
Sections in Two-Component Signaling Systems, Part B include:
Structural Approaches
Reconstitution of Heterogeneous Systems
Intracellular Methods and Assays
Genome-Wide Analyses of Two-Component Systems
Presents detailed protocols
Includes troubleshooting tips
Multicellular organisms must be able to adapt to cellular events to accommodate prevailing conditions. Sensory-response circuits operate by making ...
Multicellular organisms must be able to adapt to cellular events to accommodate prevailing conditions. Sensory-response circuits operate by making use of a phosphorylation control mechanism known as the "two-component system." This volume, the third in a three-volume treatment edited by the same group of editors, includes a wide range of methods, including those dealing with the Sln-1 kinase pathway, triazole sensitivity in C. albicans, and histidine kinases in cyanobacteria circadian clock.
Includes time-tested core methods and new innovations applicable to any...
Multicellular organisms must be able to adapt to cellular events to accommodate prevailing conditions. Sensory-response circuits operate by making ...