Xingjuan Chao scite author profile

Signal transduction underlying bacterial chemotaxis involves excitatory phosphorylation and feedback control through deamidation and methylation of sensory receptors. The structure of a complex between the signal-terminating phosphatase, CheC, and the receptor-modifying deamidase, CheD, reveals how CheC mimics receptor substrates to inhibit CheD and how CheD stimulates CheC phosphatase activity. CheD resembles other cysteine deamidases from bacterial pathogens that inactivate host Rho-GTPases. CheD not only deamidates receptor glutamine residues contained within a conserved structural motif but also hydrolyzes glutamyl-methyl-esters at select regulatory positions. Substituting Gln into the receptor motif of CheC turns the inhibitor into a CheD substrate. Phospho-CheY, the intracellular signal and CheC target, stabilizes the CheC:CheD complex and reduces availability of CheD. A point mutation that dissociates CheC from CheD impairs chemotaxis in vivo. Thus, CheC incorporates an element of an upstream receptor to influence both its own effect on receptor output and that of its binding partner, CheD.

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Structure and Function of an Unusual Family of Protein PhosphatasesThe Bacterial Chemotaxis Proteins CheC and CheX

PARK

Chao

Gonzalez-Bonet

et al. 2004

Molecular Cell

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In bacterial chemotaxis, phosphorylated CheY levels control the sense of flagella rotation and thereby determine swimming behavior. In E. coli, CheY dephosphorylation by CheZ extinguishes the switching signal. But, instead of CheZ, many chemotactic bacteria contain CheC, CheD, and/or CheX. The crystal structures of T. maritima CheC and CheX reveal a common fold unlike that of any other known protein. Unlike CheC, CheX dimerizes via a continuous beta sheet between subunits. T. maritima CheC, as well as CheX, dephosphorylate CheY, although CheC requires binding of CheD to achieve the activity of CheX. Structural analyses identified one conserved active site in CheX and two in CheC; mutations therein reduce CheY-phosphatase activity, but only mutants of two invariant asparagine residues are completely inactive even in the presence of CheD. Our structures indicate that the flagellar switch components FliY and FliM resemble CheC more closely than CheX, but attribute phosphatase activity only to FliY.

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Structure and Function of an Unusual Family of Protein Phosphatases

et al. 2004

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Complex between the chemotaxis deamidase CheD and the chemotaxis phosphatase CheC from Thermotoga maritima

Chao¹,

Park²,

Bilwes³

et al. 2006

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Xingjuan Chao

A Receptor-Modifying Deamidase in Complex with a Signaling Phosphatase Reveals Reciprocal Regulation

Structure and Function of an Unusual Family of Protein PhosphatasesThe Bacterial Chemotaxis Proteins CheC and CheX

Structure and Function of an Unusual Family of Protein Phosphatases

Complex between the chemotaxis deamidase CheD and the chemotaxis phosphatase CheC from Thermotoga maritima

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