Influence of surface charge on the incorporation and orientation of cytochrome c oxidase in liposomes.

Cytochrome c-oxidase is usually oriented 80-90% right-side-out when reconstituted with asolectin by the cholate dialysis method. Transformation of positively charged lysine groups at the matrix domain into negatively charged groups with succinic anhydride results in random orientation. A random orientation is also found after reconstitution in phosphatidylcholine, which can be changed into predominant right-side-out orientation by addition of cardiolipin. It is concluded that electrostatic interaction between positively charged groups of cytochrome c-oxidase with negative groups of phospholipids determines the asymmetric orientation of the enzyme in liposomes.

Effect of chemical modification of lysine amino groups on redox and protonmotive activity of bovine heart cytochrome c oxidase reconstituted in phospholipid membranes.

A study is presented of the effect of chemical modification of lysine amino groups on the redox and protonmotive activity of bovine heart cytochrome c oxidase. Treatment of soluble oxidase with succinic acid anhydride resulted in succinylation of lysines in all the subunits of the enzyme. The consequent change of surface charges from positive to negative resulted in inversion of the orientation of the reconstituted enzyme from right-side-out to inside-out. Reconstitution of the oxidase in phospholipid vesicles prevented succinylation of subunits III and Vb and depressed that of other subunits with the exception of subunits II and IV which were predominantly labeled in a concentration-dependent manner by succinic acid anhydride. This modification of lysines produced a decoupling effect on redox-linked proton ejection, which was associated with a decrease of the respiratory control exerted by the delta pH component of PMF. The decoupling effect was directly shown to be exerted at the level of the pH-dependent rate-limiting step in intramolecular electron flow located on the oxygen side of heme a.

Alterations in nuclear anatomy by chemical modification of proteins in isolated rat liver nuclei.

Whole rat liver nuclei were treated with citraconic anhydride, a reagent specific for primary amines. Dramatic changes were observed in nuclear morphology and light scattering properties. An analysis for DNA and RNA content suggested that DNA was released from the nuclei with a short half-time, approximately 2-4s demonstrating a biphasic release profile. RNA was similarly released but with a monophasic profile. Analysis of SDS-PAGE gels of modified nuclei demonstrated a progressive enrichment of nuclear matrix (lamins) polypeptides with extent of modification. H1 histone was quantitatively lost as a function of modification reagent concentration, while approx. 50% of the nucleosomal histones cosedimented with DNA- and RNA-free nuclei. Modification in the presence of 2 mM EGTA released all the DNA and RNA [less than or equal to 1% remaining) while retaining structures characteristic of nuclear matrix, nucleoli, and ribonucleoprotein (predominantly hnRNA group A and B). These nucleic acid-deficient structures have been termed nuclear fossils to differentiate them from high salt detergent-prepared empty nuclear sacks, nuclear remnants, or nuclear scaffolds. Modification in the presence of 2% Triton X-100 results in structures similar to the nuclear fossils (EGTA treatment), but missing the double bilayer and a 51K polypeptide that is a major component of the other structures. The use of chemical modification on the nucleus provides an experimental approach for examining the role of ionic interactions in controlling nuclear structure. Citraconylation may thus serve two functions: (a) as a protein-specific perturbant of nuclei capable of simply and rapidly preparing a range of structural variants for the analysis of nuclear interactions; (b) offer a paradigm for control of nucleic acid-polypeptide interactions based on post-translational alterations in protein charge.