Brian J. Cantwell scite author profile

Two-component signal transduction systems are abundant in prokaryotes. They enable cells to adjust multiple cellular functions in response to changing environmental conditions. These systems are also found, although in much smaller numbers, in lower eukaryotes and plants, where they appear to control a few very specific functions. Two-component systems have evolved in Bacteria from much simpler one-component systems bringing about the benefit of extracellular versus intracellular sensing. We review reports establishing the origins of two-component systems and documenting their occurrence in major lineages of Life.

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CheZ Phosphatase Localizes to Chemoreceptor Patches via CheA-Short

Cantwell

et al. 2003

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We have investigated the conditions required for polar localization of the CheZ phosphatase by using a CheZ-green fluorescent protein fusion protein that, when expressed from a single gene in the chromosome, restored chemotaxis to a ⌬cheZ strain. Localization was observed in wild-type, ⌬cheZ, ⌬cheYZ, and ⌬cheRB cells but not in cells with cheA, cheW, or all chemoreceptor genes except aer deleted. Cells making only CheA-short (CheA S ) or CheA lacking the P2 domain also retained normal localization, whereas cells producing only CheA-long or CheA missing the P1 and P2 domains did not. We conclude that CheZ localization requires the truncated C-terminal portion of the P1 domain present in CheA S . Missense mutations targeting residues 83 through 120 of CheZ also abolished localization. Two of these mutations do not disrupt chemotaxis, indicating that they specifically prevent interaction with CheA S while leaving other activities of CheZ intact.

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The Myxococcus xanthus asgA gene encodes a novel signal transduction protein required for multicellular development

Plamann

Cantwell

et al. 1995

J Bacteriol

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The Myxococcus xanthus asgA gene is one of three known genes necessary for the production of extracellular A-signal, a cell density signal required early in fruiting body development. We determined the DNA sequence of asgA. The deduced 385-amino-acid sequence of AsgA was found to contain two domains: one homologous to the receiver domain of response regulators and the other homologous to the transmitter domain of histidine protein kinases. A kanamycin resistance (Km r ) gene was inserted at various positions within or near the asgA gene to determine the null phenotype. Those strains with the Km r gene inserted upstream or downstream of asgA are able to form fruiting bodies, while strains containing the Km r gene inserted within asgA fail to develop. The nature and location of the asgA476 mutation were determined. This mutation causes a leucine-to-proline substitution within a conserved stretch of hydrophobic residues in the N-terminal receiver domain. Cells containing the insertion within asgA and cells containing the asgA476 substitution have similar phenotypes with respect to development, colony color, and expression of an asg-dependent gene. An analysis of expression of a translational asgA-lacZ fusion confirms that asgA is expressed during growth and early development. Finally, we propose that AsgA functions within a signal transduction pathway that is required to sense starvation and to respond with the production of extracellular A-signal.

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Evidence that asgB encodes a DNA-binding protein essential for growth and development of Myxococcus xanthus

et al. 1994

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The asg mutants of Myxococcus xanthus are defective in production of extracellular A-signal, which serves as a cell density signal for fruiting-body development. The DNA sequence of asgB, one of the three asg genes, was determined. The deduced amino acid sequence of AsgB contains a DNA-binding helix-turn-helix motif near the C terminus. This putative helix-turn-helix is highly similar to the helix-turn-helix in region 4.2 of major sigma factors, which is the region that recognizes and interacts with -35 sequences of promoters. We propose that AsgB is a transcription factor that binds to DNA sequences similar to the -35 hexamer, TTGACA. Analyses ofasgB RNA levels and expression of an asgB-lacZ translational fusion indicate that expression ofasgB remains fairly constant during the transition from growth into early development. The mutation within the asgB480 allele was identified as an A-to-G transition that results in a threonine-to-alanine substitution in the predicted protein product. Attempts to replace the wild-type copy of asgB with a null allele failed, indicating that asgB may be essential for growth.

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Cellulases: ambiguous nonhomologous enzymes in a genomic perspective

Sukharnikov

Cantwell

Podar

et al. 2011

Trends in Biotechnology

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The key material for bioethanol production is cellulose, one of the main components of the plant cell wall. Enzymatic depolymerization of cellulose, an essential step in bioethanol production, can be accomplished by fungal and bacterial cellulases. Most of the biochemically characterized bacterial cellulases come from only a few of cellulose degrading bacteria thus limiting our knowledge of a range of cellulolytic activities that exist in nature. The recent explosion of genomic data offers a unique opportunity to search for novel cellulolytic activities; however, the absence of clear understanding of structural and functional features that are important for reliable computational identification of cellulases precludes their exploration in the genomic datasets. Here we explore the diversity of cellulases and propose a genomic approach to overcome this bottleneck.

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Brian J. Cantwell

Evolution and phyletic distribution of two-component signal transduction systems

CheZ Phosphatase Localizes to Chemoreceptor Patches via CheA-Short

The Myxococcus xanthus asgA gene encodes a novel signal transduction protein required for multicellular development

Evidence that asgB encodes a DNA-binding protein essential for growth and development of Myxococcus xanthus

Cellulases: ambiguous nonhomologous enzymes in a genomic perspective

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