Showing papers by "Claire Simons published in 2012"

Use of hydrogen peroxide as a biocide: new consideration of its mechanisms of biocidal action

Abstract: Hydrogen peroxide is extensively used as a biocide, particularly in applications where its decomposition into non-toxic by-products is important. Although increasing information on the biocidal efficacy of hydrogen peroxide is available, there is still little understanding of its biocidal mechanisms of action. This review aims to combine past and novel evidence of interactions between hydrogen peroxide and the microbial cell and its components, while reflecting on alternative applications that make use of gaseous hydrogen peroxide. It is currently believed that the Fenton reaction leading to the production of free hydroxyl radicals is the basis of hydrogen peroxide action and evidence exists for this reaction leading to oxidation of DNA, proteins and membrane lipids in vivo. Investigations of DNA oxidation suggest that the oxidizing radical is the ferryl radical formed from DNA-associated iron, not hydroxyl. Investigations of protein oxidation suggest that selective oxidation of certain proteins might occur, and that vapour-phase hydrogen peroxide is a more potent oxidizer of protein than liquidphase hydrogen peroxide. Few studies have investigated membrane damage by hydrogen peroxide, though it is suggested that this is important for the biocidal mechanism. No studies have investigated damage to microbial cell components under conditions commonly used for sterilization. Despite extensive studies of hydrogen peroxide toxicity, the mechanism of its action as a biocide requires further investigation.

Comparative modeling of 25-hydroxycholesterol-7α-hydroxylase (CYP7B1): ligand binding and analysis of hereditary spastic paraplegia type 5 CYP7B1 mutations

Abstract: CYP7B1 mutations have been linked directly with the neurodegenerative disease hereditary spastic paraplegia (HSP), with mutations in the CYP7B1 gene identified as being directly responsible for autosomal recessive HSP type 5A (SPG5). To evaluate the potential impact of CYP7B1 mutations identified in SPG5 on binding and protein function, a comparative model of cytochrome P450 7B1 (CYP7B1) was constructed using human CYP7A1 as a template during model construction. The secondary structure was predicted using the PSIPRED and GOR4 prediction methods, the lowest energy CYP7B1 model was generated using MOE, and then this model was assessed in terms of stereochemical quality and the side chain environment using RAMPAGE, Verify3D and ProSA. Evaluation of the active site residues of the CYP7B1 model and validation of the active site architecture were performed via molecular docking experiments: the docking of the substrates 25-hydroxycholesterol and 27-hydroxycholesterol and the inhibitor 3α-Adiol identified structurally and functionally important residues. Mutational analysis of CYP7B1 amino acid mutations related to hereditary spastic paraplegia type 5 considered phosphorylation, ligand/substrate binding and the structural roles of mutated amino acid residues, with R112, T297 and S363 mutations expected to have a direct impact on ligand binding, while mutations involving R417 would indirectly affect ligand binding as a result of impairment in catalytic function.