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Free keywords:
Chaperonin; Protein folding; Thermosome; Sans; Small-angle neutron scattering.; Group-ii chaperonin; Angle neutron-scattering; Archaeal chaperonin; Groel; Conformation; Complex; Cycle; Microscopy; Filaments; Domain.; Biochemistry & Biophysics in Current Contents(R)/Life Sciences.
Abstract:
Protein folding by chaperonins is powered by ATP binding and hydrolysis. ATPase activity drives the folding machine through a series of conformational rearrangements, extensively described for the group I chaperonin GroEL from Escherichia coli but still poorly understood for the group II chaperonins. The latter-archaeal thermosome and eukaryotic TMUCCT-function independently of a GroES-like cochaperonin and are proposed to rely on protrusions of their own apical domains for opening and closure in an ATP-controlled fashion. Here we use small-angle neutron scattering to analyze structural changes of the recombinant a-only and the native alpha beta -thermosome from Thermoplasma acidophilum upon their ATPase cycling in solution. We show that specific high-salt conditions, but not the presence of MgATP alone, induce formation of higher order thermosome aggregates. The mechanism of the open-closed transition of the thermosome is strongly temperature-dependent. ATP binding to the chaperonin appears to be a two-step process: at lower temperatures an open state of the ATP-thermosome is predominant, whereas heating to physiological temperatures induces its switching to a closed state. Our data reveal an analogy between the ATPase cycles of the two groups of chaperonins and enable us to put forward a model of thermosome action. (C) 2001 Academic Press. [References: 24]
