Abstract
Six-domain gelsolin regulates actin structural dynamics through its abilities to sever, cap and uncap F-actin. These activities are modulated by various cellular parameters like Ca2+ and pH. Until now, only the molecular activation mechanism of gelsolin by Ca2+ has been understood relatively well. The fragment comprising the first domain and six residues from the linker region into the second domain has been shown to be similar to the full-length protein in F-actin severing activity in the absence of Ca2+ at pH 5. To understand how this gelsolin fragment is activated for F-actin severing by lowering pH, we solved its NMR structures at both pH 7.3 and 5 in the absence of Ca2+ and measured the pKa values of acidic amino acid residues and histidine residues. The overall structure and dynamics of the fragment are not affected significantly by pH. Nevertheless, local structural changes caused by protonation of His29 and Asp109 result in the activation on lowering the pH, and protonation of His151 directly effects filament binding since it resides in the gelsolin/actin interface. Mutagenesis studies support that His29, Asp109 and His151 play important roles in the pH-dependent severing activity of the gelsolin fragment.
Highlights
Recent truncation studies have shown that the minimal gelsolin fragment consisting of domain 1 (G1) and the linker between domains G1 and G2 depolymerizes F-actin more efficiently than the full-length protein and other truncation mutants in vitro and in animal models[10]
In order to address how G1+is activated by lowering pH, we solved its structures at pH 7.3 and 5, and measured the pKa values of Asp, Glu, and His residues by nuclear magnetic resonance (NMR) spectroscopy
S1) which were derived from nuclear Overhauser effects (NOEs) and chemical shifts, respectively
Summary
Recent truncation studies have shown that the minimal gelsolin fragment (residues 28–161) consisting of domain 1 (G1) and the linker between domains G1 and G2 depolymerizes F-actin more efficiently than the full-length protein and other truncation mutants in vitro and in animal models[10]. SAXS-based structure reconstructions suggested a pH-activated “open” state of gelsolin in which G1 is detached from domain G3 and domains G2-G6 still retain the inactive-like structure. This inhibition is overcome by protonation of His[29] and released by removal of the sidechain (His29Ala mutation)
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