Chemotaxis System (chemotaxis + system)

Distribution by Scientific Domains


Selected Abstracts


The diverse CheC-type phosphatases: chemotaxis and beyond

MOLECULAR MICROBIOLOGY, Issue 5 2008
Travis J. Muff
Summary A new class of protein phosphatases has emerged in the study of bacterial/archaeal chemotaxis, the CheC-type phosphatases. These proteins are distinct and unrelated to the well-known CheY-P phosphatase CheZ, though they have convergently evolved to dephosphorylate the same target. The family contains a common consensus sequence D/S-X3 -E-X2 -N-X22 -P that defines the phosphatase active site, of which there are often two per protein. Three distinct subgroups make up the family: CheC, FliY and CheX. Further, the CheC subgroup can be divided into three classes. Bacillus subtilis CheC typifies the first class and might function as a regulator of CheD. Class II CheCs likely function as phosphatases in systems other than chemotaxis. Class III CheCs are found in the archaeal class Halobacteria and might function as class I CheCs. FliY is the main phosphatase in the B. subtilis chemotaxis system. CheX is quite divergent from the rest of the family, forms a dimer and some may function outside chemotaxis. A model for the evolution of the family is discussed. [source]


FrzZ, a dual CheY-like response regulator, functions as an output for the Frz chemosensory pathway of Myxococcus xanthus

MOLECULAR MICROBIOLOGY, Issue 1 2007
Yuki F. Inclán
Summary Myxococcus xanthus utilizes two distinct motility systems for movement (gliding) on solid surfaces: adventurous motility (A-motility) and social motility (S-motility). Both systems are regulated by the Frz signal transduction pathway, which controls cell reversals required for directed motility and fruiting body formation. The Frz chemosensory system, unlike the Escherichia coli chemotaxis system, contains proteins with multiple response regulator domains: FrzE, a CheA,CheY hybrid protein, and FrzZ, a CheY,CheY hybrid protein. Previously, the CheY domain of FrzE was hypothesized to act as the response regulator output of the Frz system. In this study, using a genetic suppressor screen, we identified FrzZ and showed FrzZ is epistatic to FrzE, demonstrating that FrzZ is the principal output component of the pathway. We constructed M. xanthus point mutations in the phosphoaccepting aspartate residues of FrzZ and demonstrated the respective roles of these residues in group and single cell motility. We also performed in vitro assays and showed rapid phosphotransfer between the CheA domain of FrzE and each of the CheY domains of FrzZ. These experiments showed that FrzZ plays a direct role as an output of the Frz chemosensory pathway and that both CheY domains of FrzZ are functional. [source]


Expression and function of CXCL16 in a novel model of gout

ARTHRITIS & RHEUMATISM, Issue 8 2010
Jeffrey H. Ruth
Objective To better define the activity of soluble CXCL16 in the recruitment of polymorphonuclear neutrophils (PMNs) in vivo, utilizing a novel animal model of gout involving engraftment of SCID mice with normal human synovial tissue (ST) injected intragraft with gouty human synovial fluid (SF). Methods For in vitro studies, a modified Boyden chemotaxis system was used to identify CXCL16 as an active recruitment factor for PMNs in gouty SF. Migration of PMNs could be reduced by neutralization of CXCL16 activity in gouty SF. For in vivo analyses, fluorescent dye,tagged PMNs were injected intravenously into SCID mice while, simultaneously, diluted gouty SF containing CXCL16, or depleted of CXCL16 by antibody blocking, was administered intragraft. In addition, the receptor for CXCL16, CXCR6, was inhibited by incubating PMNs with a neutralizing anti-CXCR6 antibody prior to injection into the mouse chimeras. Recruitment of PMNs to the gouty SF,injected normal human ST was then examined in this SCID mouse chimera system. Results CXCL16 concentrations were highly elevated in gouty SF, and PMNs were observed to migrate in response to CXCL16 in vitro. Normal human ST,SCID mouse chimeras injected intragraft with gouty SF that had been depleted of CXCL16 during PMN transfer showed a significant reduction of 50% in PMN recruitment to engrafted tissue as compared with that after administration of sham-depleted gouty SF. Similar findings were achieved when PMNs were incubated with a neutralizing anti-CXCR6 antibody before injection into chimeras. Conclusion Overall, the results of this study outline the effectiveness of the human,SCID mouse chimera system as a viable animal model of gout, serving to identify the primary function of CXCL16 as a significant mediator of in vivo recruitment of PMNs to gouty SF. [source]


Phenotypic analyses of frz and dif double mutants of Myxococcus xanthus

FEMS MICROBIOLOGY LETTERS, Issue 2 2000
Wenyuan Shi
Abstract Myxococcus xanthus is a Gram-negative gliding bacterium that aggregates and develops into multicellular fruiting bodies in response to starvation. Two chemosensory systems (frz and dif), both of which are homologous to known chemotaxis proteins, were previously identified through characterization of various developmental mutants. This study aims to examine the interaction between these two systems since both of them are required for fruiting body formation of M. xanthus. Through detailed phenotypic analyses of frz and dif double mutants, we found that both frz and dif are involved in cellular reversal and social motility; however, the frz genes are epistatic in controlling cellular reversal, whereas the dif genes are epistatic in controlling social motility. The study suggests that the integration of these two chemotaxis systems may play a central role in controlling the complicated social behaviors of M. xanthus. [source]