Department of Biochemistry

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Browsing Department of Biochemistry by Author "Adriaanse, Craig Vernon"

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    An investigation into the complex formation of membrane bound cytochrome b5 isolated from ovine liver microsomes
    (Stellenbosch : Stellenbosch University, 2013-12) Adriaanse, Craig Vernon; Swart, P.; Rautenbach, Marina; Stellenbosch University. Faculty of Science. Dept. of Biochemistry.
    ENGLISH ABSTRACT: Membrane bound cytochrome b5 is a ubiquitous protein with an average molecular weight of 16 kDa. The protein is involved in a number of reactions providing electrons directly to cytochrome P450 enzymes or to other enzymes involved in lipid biosynthesis. It is also known that the protein influences the activities of certain enzymes via an allosteric effect. It has been accepted in the literature that the cytochrome b5 exists primarily in the monomeric form, however, recently it has been shown that it forms homomeric complexes in vivo. In this study, we investigate the cytochrome b5 complex formation using a variety of analytical tools. Cytochrome b5 was isolated from ovine liver microsomes and the purity verified using sodium dodecyl sulphate polyacrylamide gel electrophoresis and electrospray ionisation mass spectrometry. The latter analysis confirmed the presence of a single heme containing protein with Mr=15865 Da, while separation on the polyacrylamide gel revealed oligomeric complex formation with the tetrameric form the most prominent oligomer. Using different and particularly harsh denaturing conditions we found that the observed oligomeric aggregates persisted, indicating highly stable complexes. The most prominent tetrameric aggregate was identified to be cytochrome b5 by mass spectrometric sequencing. Further complex formation studies, using a fluorescent dye (1-anilinonaphthalene-8-sulfonic acid) that interact with hydrophobic cavities formed during oligomerisation, provided evidence of protein assembly in oligomeric complexes or aggregation. The formation of the cytochrome b5 complexes was dependent on ionic strength and protein concentration. Previously it was shown that the hydrophobic membrane anchoring domain plays a pivotal role in the cytochrome b5’s homomeric complexes. Using a peptide (IITTIDSNSS), resembling a portion of this domain, together with circular dichroism we showed more organized structure present for the wildtype peptide vs. a mutated control peptide (LLSSLKAVAV). A modified ELISA interaction assay also revealed that the wild-type peptide had a specific interaction with cytochrome b5, providing further evidence that the membrane anchoring domain plays a role in complex formation. These studies also indicated that a hydrogen bond network in this domain may be important for the formation of the homomeric complexes of cytochrome b5.