Browsing by Author "Chow, JYH"
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- ItemCalmodulin binds a highly extended HIV-1 MA protein that refolds upon its release(Cell Press, 2012-08-08) Taylor, JEN; Chow, JYH; Jeffries, CM; Kwan, AH; Duff, AP; Hamilton, WA; Trewhella, JCalmodulin (CaM) expression is upregulated upon HIV-1 infection and interacts with proteins involved in viral processing, including the multifunctional HIV-1 MA protein. We present here the results of studies utilizing small-angle neutron scattering with contrast variation that, when considered in the light of earlier fluorescence and NMR data, show CaM binds MA in an extended open-clamp conformation via interactions with two tryptophans that are widely spaced in sequence and space. The interaction requires a disruption of the MA tertiary fold such that MA becomes highly extended in a long snakelike conformation. The CaM-MA interface is extensive, covering ∼70% of the length of the MA such that regions known to be important in MA interactions with critical binding partners would be impacted. The CaM conformation is semiextended and as such is distinct from the classical CaM-collapse about short α-helical targets. NMR data show that upon dissociation of the CaM-MA complex, either by the removal of Ca2+ or increasing ionic strength, MA reforms its native tertiary contacts. Thus, we observe a high level of structural plasticity in MA that may facilitate regulation of its activities via intracellular Ca2+-signaling during viral processing. © 2012 Biophysical Society.
- ItemCalmodulin disrupts the structure of the HIV-1 MA protein(Elsevier, 2010-07-23) Chow, JYH; Jeffries, CM; Kwan, AH; Guss, JM; Trewhella, JThe MA protein from HIV-1 is a small, multifunctional protein responsible for regulating various stages of the viral replication cycle. To achieve its diverse tasks, MA interacts with host cell proteins and it has been reported that one of these is the ubiquitous calcium-sensing calmodulin (CaM), which is up-regulated upon HIV-1 infection. The nature of the CaM–MA interaction has been the subject of structural studies, using peptides based on the MA sequence, that have led to conflicting conclusions. The results presented here show that CaM binds intact MA with 1:1 stoichiometry in a Ca2+-dependent manner and that the complex adopts a highly extended conformation in solution as revealed by small-angle X-ray scattering. Alterations in tryptophan fluorescence suggest that the two buried tryptophans (W16 and W36) located in the first two alpha-helices of MA mediate the CaM interaction. Major chemical shift changes occur in the NMR spectrum of MA upon complex formation, whereas chemical shift changes in the CaM spectrum are quite modest and are assigned to residues within the normal target protein-binding hydrophobic clefts of CaM. The NMR data indicate that CaM binds MA via its N- and C-terminal lobes and induces a dramatic conformational change involving a significant loss of secondary and tertiary structure within MA. Circular dichroism experiments suggest that MA loses ~ 20% of its α-helical content upon CaM binding. Thus, CaM binding is expected to impact upon the accessibility of interaction sites within MA that are involved in its various functions. © 2010, Elsevier Ltd.
- Item(Corrected) Calmodulin binds a highly extended HIV-1 MA protein that refolds upon its release(Elsevier, 2023-05-02) Taylor, JEN; Chow, JYH; Jeffries, CM; Kwan, AH; Duff, AP; Hamilton, WA; Trewhella, Jill(Biophysical Journal 103, August 2012; 541–549) The authors identified an omission in this article. The figure legend for Figure S2 should include the following: “The model displayed here includes full-length calcium-bound CaM and the matrix protein sequence spanning amino acids 1–113; i.e., it does not include the flexible C-terminal tail (amino acids 114–133).” None of the article's conclusions are affected by this omission. In addition, after publication of the article, the SAXS and SANS data and modeling for this article were deposited in the Small Angle Scattering Biological Data Bank (SASBDB; https://www.sasbdb.org/) under accession code SASDKR3. Finally, the first author's name should appear as “James E. N. Taylor” rather than “James E. Taylor.”
- ItemPicornaviral loop-to-loop replication complex.(Elsevier, 2009-06) Claridge, JK; Headey, SJ; Chow, JYH; Schwalbe, M; Edwards, PJ; Jeffries, CM; Venugopal, H; Trewhella, J; Pascal, SMPicornaviruses replicate their RNA genomes through a highly conserved mechanism that involves an interaction between the principal viral protease (3C(pro)) and the 5'-UTR region of the viral genome. The 3C(pro) catalytic site is the target of numerous replication inhibitors. This paper describes the first structural model of a complex between a picornaviral 3C(pro) and a region of the 5'-UTR, stem-loop D (SLD). Using human rhinovirus as a model system, we have combined NMR contact information, small-angle X-ray scattering (SAXS) data, and previous mutagenesis results to determine the shape, position and relative orientation of the 3C(pro) and SLD components. The results clearly identify a 1:1 binding stoichiometry, with pronounced loops from each molecule providing the key binding determinants for the interaction. Binding between SLD and 3C(pro) induces structural changes in the proteolytic active site that is positioned on the opposite side of the protease relative to the RNA/protein interface, suggesting that subtle conformational changes affecting catalytic activity are relayed through the protein. © 2009, Elsevier Ltd.