Macromolecular crowding plays an inevitable role in all biological processes influencing association, conformation, and other characteristics of proteins. Present study is based on the effect of macromolecular crowding on structure of horseradish peroxidase (HRP) enzyme. Concentration-dependent conformational changes induced by crowding agents, dextran 70 and polyethylene glycol (PEG)-4000, were monitored employing a range of biophysical techniques. The intrinsic fluorescence spectra showed transition of protein from native to unfolded state. Marked increase in 8-Anilino-1-naphthalene-sulphonoic acid and Thioflavin T fluorescence indicated presence of non-native moieties with 80 mg/mL dextran. Enhanced absorbance in turbidity, Soret, and Congo red in corroboration with scattering intensity at 350nm results revealed incidence of HRP aggregates. A new peak around 218 nm in CD spectra pointed towards change in secondary structure towards β-sheets. Significant loss of enzyme activity upon structural disruption was seen. Comet assay demonstrated DNA damage and genotoxic nature of HRP aggregates, supporting spectroscopic, and fluorescence results. The normalized resultswere obtained with 120 mg/mL PEG-4000 close to that of native HRP implying no disruptive effect on structure. It can be hypothesized that macromolecular crowding is a vital element, which can have diverse effects. In this study, dextran 70 was observed to have pro-aggregatory effect while enhanced stability of native enzyme was witnessed with PEG. Hence, it can be stated that PEG has potentially better crowder as it helps retain the native enzyme structure. Routine addition of crowding agents is recommended if biological molecules are to be studied under more physiologically appropriate environments.
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