T. Sivaraman

The Mechanism of 2,2,2-Trichloroacetic Acid-Induced Protein Precipitation

The mechanism of 2,2,2-trichloroacetic acid (TCA)-induced precipitation of proteins is studied. The TCA-induced protein precipitation curves are observed to be U-shaped. It is bound that the protein-precipitate-inducing effects of TCA are due to the three chloro groups in the molecule. Using cardiotoxin III (CTX III) isolated from the Taiwan cobra (Naja naja atra), as a model protein, we attempt to understand the molecular basis for the TCA-induced effects. Employing circular dichroism, proton–deuterium exchange in conjunction with conventional 2D NMR techniques, and 1-anilino naphthalene-8-sulfonate-binding experiments, we demonstrate that CTX III is in a partially structured state similar to the ‘A state’ in 3% w/v TCA. It is postulated that the formation of this ‘sticky’ partial structured ‘A state’ in the TCA-induced unfolding pathway is responsible for the acid-induced protein precipitation.

EVENTS IN THE KINETIC FOLDING PATHWAY OF A SMALL, ALL BETA -SHEET PROTEIN

The folding of cardiotoxin analogue III (CTX III), a small (60 amino acids), all β-sheet protein from the venom of the Taiwan Cobra (Naja naja atra) is here investigated. The folding kinetics is monitored by using a variety of techniques such as NMR, fluorescence, and circular dichroism spectroscopy. The folding of the protein is complete within a time scale of 200 ms. The earliest detectable event in the folding pathway of CTX III is the formation of a hydrophobic cluster, which possess strong affinity to bind to nonpolar dye such as 1-anilino-8-napthalene-sulfonic acid. Quenched-flow deuterium-hydrogen exchange experiments indicate that the segment spanning residues 51–55 along with Lys23, Ile39, Val49, Tyr51 and Val52 could constitute the “hydrophobic cluster.” Folding kinetics of CTX III based on the amide-protection data reveals that the triple-stranded, antiparallel β-sheet segment, which is located in the central core of the molecule, appears to fold faster than the double-stranded β-sheet segment.

Destabilisation of native tertiary structural interactions is linked to helix-induction by 2,2,2-trifluoroethanol in proteins

The effect of 2,2,2-trifluoroethanol (TFE) on the structure of an all beta-sheet protein, cardiotoxin analogue 111 (CTX III) from the Taiwan cobra (Naja naja atra) is studied. It is found that high concentrations (> 80% v/v) of TFE induced a beta-sheet to alpha-helix structural transition. It is found that in denatured and reduced CTX III (rCTX III) helical conformation is induced even upon addition of low concentrations (> 10% v/v) of TFE. Using three other proteins, namely, ribonuclease A (RNase A), lysozyme and alpha-lactalbumin, it is been observed that helix-induction by TFE is intricately linked to drastic destabilization of native tertiary structural interactions in the proteins.

ACETONITRILE-INDUCED CONFORMATIONAL TRANSITIONS IN POLY-L-LYSINE

The effect of acetonitrile on the random coil, alpha-helix and beta-sheet conformations induced in poly-L-lysine is studied. It is found that acetonitrile at higher concentrations transforms the backbone of polylysine from a random coil to a helical conformation. Addition of acetonitrile to polylysine (pH 11.5) in the alpha-helix conformation, induces conformational changes in two stages. At concentrations below 60% v/v, acetonitrile stabilizes the helical conformation and at higher concentrations (> 70% v/v), it destabilizes the helix. beta-sheet-->alpha-helix-->random coil conformational transitions are found to occur when polylysine in the heat-induced conformation is titrated with acetonitrile. The possible mechanism(s) of action of acetonitrile in inducing these structural transitions is discussed.

Thermal denaturation of an all beta-sheet protein - Identification of a stable partially structured intermediate at high temperature

The thermal unfolding of an all beta-sheet protein, cardiotoxin analogue III, from the Taiwan Cobra (Naja naja atra) is studied at pH 2.0, 4.0 and 6.0. At pH 4.0, using circular dichroism and 1-anilino naphthalene-8-sulphonic acid (ANS) fluorescence binding studies, a stable partially structured intermediate is detected at 90 degrees C.

The role of acetic acid in the prevention of salt-induced aggregation of snake venom cardiotoxins.

Snake venom cardiotoxins (CTXs) exhibit a strong tendency to aggregate upon desalting and hence it is extremely difficult to prepare salt‐free cardiotoxin(s). In the present study, we describe a new method for preparation of salt‐free CTX based on dialysis against acetic acid. Based on experimental observation and the three dimensional solution structure of cardiotoxin analogue III from the Taiwan cobra (Naja naja atra), a molecular mechanism for the prevention of aggregation of cardiotoxins by acetic acid is discussed. In our opinion, the results obtained in the present study would pave way for elucidating the structural basis for the broad spectrum of biological activities exhibited by snake venom cardiotoxins.

Influence of Disulfide Bonds on the Induction of Helical Conformation in Proteins

The effect(s) of TFE (2,2,2-trifluoroethanol) on three different conformational states (native, denatured, and carboxymethylated) of CTX III and RNase A has been examined. Contrary to the general belief, the results of the present study reveal that TFE can induce helical conformation in a protein which has no sequence propensity to form a helix. It is found that the helix induction in TFE is intricately related to the destabilization of the tertiary structural conformation in proteins. More importantly, the disulfide bonds in proteins are found to have significant influence on the TFE-mediated helix induction. The results obtained in this study strongly suggest that information pertaining to the influence of disulfide bonds on helix induction need to be considered to improve the accuracy of secondary structure prediction algorithms.