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Publication Details
AFRICAN RESEARCH NEXUS
SHINING A SPOTLIGHT ON AFRICAN RESEARCH
Formation of an unfolding intermediate state of soluble chloride intracellular channel protein CLIC1 at acidic pH
Biochemistry, Volume 47, No. 44, Year 2008
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Description
CLIC proteins function as anion channels when their structures convert from a soluble form to an integral membrane form. While very little is known about the mechanism of the conversion process, channel formation and activity are highly pH-dependent. In this study, the structural properties and conformational stability of CLIC1 were determined as a function of pH in the absence of membranes to improve our understanding of how its conformation changes when the protein encounters the acidic environment at the surface of a membrane. Although the global conformation and size of CLIC1 are not significantly altered by pH in the range of 5.5-8.2, equilibrium unfolding studies reveal that the protein molecule becomes destabilized at low pH, resulting in the formation of a highly populated intermediate with a solvent-exposed hydrophobic surface. Unlike the intermediates formed by many soluble pore-forming proteins for their insertion into membranes, the CLIC1 intermediate is not a molten globule. Acid-induced destabilization and partial unfolding of CLIC1 involve helix α-which is the major structural element of the transmembrane region. We propose that the acidic environment encountered by CLICs at the surface of membranes primes the transmembrane region in the N-domain, thereby lowering the energy barrier for the conversion of soluble CLICs to their membrane-inserted forms. © 2008 American Chemical Society.
Authors & Co-Authors
Fanucchi, Sylvia
South Africa, Johannesburg
University of the Witwatersrand
Adamson, Roslin J.
South Africa, Johannesburg
University of the Witwatersrand
Dirr, Heini W.
South Africa, Johannesburg
University of the Witwatersrand
Statistics
Citations: 57
Authors: 3
Affiliations: 1
Identifiers
Doi:
10.1021/bi801147r