Sandip Vyas scite author profile

In the search for the molecular mechanism of insulin fibrillation, the kinetics of insulin fibril formation were studied under different conditions using the fluorescent dye thioflavin T (ThT). The effect of insulin concentration, agitation, pH, ionic strength, anions, seeding, and addition of 1-anilinonaphthalene-8-sulfonic acid (ANS), urea, TMAO, sucrose, and ThT on the kinetics of fibrillation was investigated. The kinetics of the fibrillation process could be described by the lag time for formation of stable nuclei (nucleation) and the apparent rate constant for the growth of fibrils (elongation). The addition of seeds eliminated the lag phase. An increase in insulin concentration resulted in shorter lag times and faster growth of fibrils. Shorter lag times and faster growth of fibrils were seen at acidic pH versus neutral pH, whereas an increase in ionic strength resulted in shorter lag times and slower growth of fibrils. There was no clear correlation between the rate of fibril elongation and ionic strength. Agitation during fibril formation attenuated the effects of insulin concentration and ionic strength on both lag times and fibril growth. The addition of ANS increased the lag time and decreased the apparent growth rate for insulin fibril formation. The ANS-induced inhibition appears to reflect the formation of amorphous aggregates. The denaturant, urea, decreased the lag time, whereas the stabilizers, trimethylamine N-oxide dihydrate (TMAO) and sucrose, increased the lag times. The results indicated that both nucleation and fibril growth were controlled by hydrophobic and electrostatic interactions. A kinetic model, involving the association of monomeric partially folded intermediates, whose concentration is stimulated by the air-water interface, leading to formation of the critical nucleus and thence fibrils, is proposed.

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Stabilization of Secondary Structure of Alzheimer β-Protein by Aluminum(III) Ions and D-Asp Substitutions

Vyas

Duffy

1995

Biochemical and Biophysical Research Communications

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Transient Alpha-helical Structure during Folding of Src SH3 Domain at Subzero Temperatures

Qin¹,

Vyas²,

Fink³

et al. 2006

The Journal of Kansai Medical University

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Substantial questions remain about the process of protein folding, including whether transient intermediates exist with significantly different secondary structure than the final fold. The src SH3 domain is a highly beta-rich structure with five betastrands. We report here a far-UV circular dichroism investigation of the refolding of His-tagged Src SH3 at subzero temperatures. We observed a transient a-helix-rich intermediate, indicating that the early stages of protein folding can involve the formation of intermediates with very different structures from the final conformation.

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Interaction of synthetic Alzheimerβ-protein-derived analogs with aqueous aluminum: A low-field27Al NMR investigation

Vyas

Duffy

1995

J Protein Chem

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Synthetic peptides corresponding to the soluble Alzheimer beta-protein, i.e., beta 1-40 and beta 6-25, were utilized to investigate the association of aluminum using low-field 27Al nuclear magnetic resonance (NMR) spectroscopy and reversed-phase high-performance liquid chromatography (RP-HPLC). Addition of beta 1-40 or beta 6-25 to aqueous Al3+ gives rise to a 27Al NMR signal corresponding to the association of Al3+ with the peptides; this effect is not easily reversed by EDTA. Based on the relative intensity of the Al(3+)-peptide signal between pH 4 and 6, there are at least 4 Al3+ ions associated with each peptide molecule. Microheterogeneity is observed with RP-HPLC on incubating solutions of Al3+ with beta 1-40 and beta 6-25. The 27Al NMR spectra of chromatographically pure fractions of beta 1-40 and beta 6-25 indicate that the peptide-associated Al3+ is released below pH 3.5. We propose that soluble beta 1-40 provides an anchor for Al3+ to bind, eventually leading to an increased deposition of amyloid in the Alzheimer brain.

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Sandip Vyas

Effect of Environmental Factors on the Kinetics of Insulin Fibril Formation: Elucidation of the Molecular Mechanism

Stabilization of Secondary Structure of Alzheimer β-Protein by Aluminum(III) Ions and D-Asp Substitutions

Transient Alpha-helical Structure during Folding of Src SH3 Domain at Subzero Temperatures

Interaction of synthetic Alzheimerβ-protein-derived analogs with aqueous aluminum: A low-field27Al NMR investigation

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