Yersinia enterocolitica type III secretion chaperone SycH. Recombinant expression, purification, characterisation, and crystallisation

“…This suggests that it is the chaperone that directs the effector toward the ATPase. This finding is in line with our recently presented model of type III secretion, predicting that TTSS ATPases act as unfoldases using the TTSS chaperones to encounter the secretion substrates (21,24,43). After displacement of the chaperone by the ATPase, the chaperone-binding site of the effector, lacking tertiary structure, is distinguished as an ideal starting point for unraveling the effector.…”

“…A on the conformation of their substrates is restricted to the binding sites identified close to the N termini (9,14,17,21,24). Here, for the first time, an interaction between the catalytic domain of an effector, YopT, and its specific chaperone, SycT, was revealed.…”

“…ComplexesWork from several groups suggests that the influence of class I TTSS chaperones on the folding of their substrates is restricted to the binding site generally encompassing about 50 -100 amino acid residues (9,14,17,21,24). To understand the functioning of these chaperones, high resolution structural data on complete type III effectors in complex with their respective chaperones are required.…”

“…The SycN/YscB complex is an exception in that SycN and YscB form a heterodimer (17) with a fold similar to that of the typical homodimers. The SycH fold also resembles that of the aforementioned chaperones (16); however, its biologically relevant oligomerization state is not unambiguously clear (21). The fold of the class IB chaperone Spa15 is very similar to that of class IA chaperones; dimer formation, however, is different, with the subunits rotated relative to each other (19).…”

“…The effector domain is wrapped around the chaperone dimer in an expanded form retaining secondary structure elements. Work from several groups further suggests that the C-terminally located effector domains are folded and catalytically active in the presence of their respective chaperones (9,14,21,24). Only recently, the structure of the secretable regulatory TTSS component YopN from Yersinia in complex with the heterodimeric chaperone SycN/YscB was presented (17).…”

Crystal Structure of the Yersinia enterocolitica Type III Secretion Chaperone SycT

“…This suggests that it is the chaperone that directs the effector toward the ATPase. This finding is in line with our recently presented model of type III secretion, predicting that TTSS ATPases act as unfoldases using the TTSS chaperones to encounter the secretion substrates (21,24,43). After displacement of the chaperone by the ATPase, the chaperone-binding site of the effector, lacking tertiary structure, is distinguished as an ideal starting point for unraveling the effector.…”

“…A on the conformation of their substrates is restricted to the binding sites identified close to the N termini (9,14,17,21,24). Here, for the first time, an interaction between the catalytic domain of an effector, YopT, and its specific chaperone, SycT, was revealed.…”

“…ComplexesWork from several groups suggests that the influence of class I TTSS chaperones on the folding of their substrates is restricted to the binding site generally encompassing about 50 -100 amino acid residues (9,14,17,21,24). To understand the functioning of these chaperones, high resolution structural data on complete type III effectors in complex with their respective chaperones are required.…”

“…The SycN/YscB complex is an exception in that SycN and YscB form a heterodimer (17) with a fold similar to that of the typical homodimers. The SycH fold also resembles that of the aforementioned chaperones (16); however, its biologically relevant oligomerization state is not unambiguously clear (21). The fold of the class IB chaperone Spa15 is very similar to that of class IA chaperones; dimer formation, however, is different, with the subunits rotated relative to each other (19).…”

“…The effector domain is wrapped around the chaperone dimer in an expanded form retaining secondary structure elements. Work from several groups further suggests that the C-terminally located effector domains are folded and catalytically active in the presence of their respective chaperones (9,14,21,24). Only recently, the structure of the secretable regulatory TTSS component YopN from Yersinia in complex with the heterodimeric chaperone SycN/YscB was presented (17).…”

Crystal Structure of the Yersinia enterocolitica Type III Secretion Chaperone SycT

On the role of specific chaperones, the specific ATPase, and the proton motive force in type III secretion

Yersinia enterocolitica type III secretion chaperone SycD: Recombinant expression, purification and characterization of a homodimer