The interactions among bovine, rabbit, and porcine serum albumins and single-chain cationic surfactant cetyltrimethylammonium bromide (CTAB) versus its gemini counterpart (designated as G4) have been studied. The studies were carried out in an aqueous medium at pH 7.0 using UV, intrinsic and extrinsic fluorescence spectroscopy, and far-UV circular dichroism techniques. The results indicate that compared to CTAB, G4 interacts strongly with the serum albumins, resulting in a significantly larger unfolding or decrease in alpha-helical content as reflected by the significantly larger decrease in ellipticity in the far-UV range. Unlike CTAB, a remarkable increase in the alpha-helical content of BSA at 625 microM G4 and at 250 microM G4 for RSA and PSA is observed. The appearance of conformational changes and saturation points in the proteins occurs at considerably lower [G4] compared to [CTAB]. The results obtained from the multi-technique approach are ascribed to the stronger forces in G4 owing to the presence of two charged headgroups and two hydrocarbon tails. Keeping the results in view, it is suggested that the gemini surfactants may be effectively used in the renaturation of proteins produced in genetically engineered cells via the artificial chaperone protocol and may also prove useful in drug delivery as solubilizing agents to recover proteins from insoluble inclusion bodies.
The interaction of bovine serum albumin (BSA) with cetyltrimethylammonium bromide (CTAB), C(16)C(4)C(16)Br(2), Brij58, and their binary mixtures has been studied using tensiometry, spectrofluorometry, and circular dichroism at physiological pH and 25 degrees C. The tensiometric profiles of CTAB and C(16)C(4)C(16)Br(2) in the presence of BSA exhibit a single break at a lower surfactant concentration termed as C(1) (concentration corresponding to saturation of the interface) compared to their critical micelle concentration (CMC) in the buffered solution. However, for Brij58, CTAB+Brij58, and C(16)C(4)C(16)Br(2)+Brij58, two breaks were observed, first at the critical aggregation concentration (CAC), corresponding to onset of interaction with BSA and the second at C(1) corresponding to saturation of the interface. The interaction of CTAB+Brij58 and C(16)C(4)C(16)Br(2)+Brij58 mixtures with the BSA solution is discussed in terms of competition between surfactant-surfactant and surfactant-BSA interactions. CTAB+Brij58 and C(16)C(4)C(16)Br(2)+Brij58 mixtures show nonideality with respect to mixed micelle formation, which is reflected in their interaction with the BSA. The interaction of CTAB+Brij58 with BSA decreases with increase in the mole fraction of CTAB in the mixture, whereas in C(16)C(4)C(16)Br(2)+Brij58 the reverse is the case. The results of the present study may prove fruitful in optimizing the properties of surfactant-protein mixtures relevant for many formulations.
To gain insights into the comparative effect of single-chain/gemini surfactants on proteins and the possible implications, the interaction of human serum albumin (HSA) with cationic single-chain surfactant cetyltrimethylammonium bromide (CTAB) and its gemini counterpart bis(cetyldimethylammonium)butane dibromide with spacer -(CH(2))(4)- (designated as G4) using turbidity measurements, far-UV and near-UV circular dichroism (CD), intrinsic fluorescence and extrinsic fluorescence spectroscopy at pH 7.0 are reported in this contribution. A decrease of 33.5% alpha-helical content at 22.5 microM G4 was monitored compared to a 15% decrease at 2,250 microM CTAB. Against a 3.5% increase at 11,250 microM CTAB, a rise of 21.1% in the alpha-helical content was observed 375 microM G4. The result is related to the stronger electrostatic and hydrophobic forces in G4, owing to the presence of two charged headgroups and two hydrophobic hydrocarbon tails that make it to bind strongly to the protein compared to its single chain counterpart, CTAB, resulting in larger unfolding. The stabilization at higher concentrations is attributed to the highly hydrophobic microdomain of the G4 aggregates formed at such concentrations. The results of the multi-technique approach are consistent with the fact that the gemini surfactants are more efficient than their conventional single-chain counterparts and hence may be used more effectively in the renaturation of proteins produced in the genetically engineered cells via the artificial chaperone protocol, as solubilizing agents to recover proteins from insoluble inclusion bodies and in drug delivery.
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