Charge interactions of cytochrome c with cytochrome c oxidase

Electrostatic effects in trypsin reactions. Influence of salts

The influence of inorganic salts on trypsin-catalyzed reactions has been studied. It is shown that: (a) monovalent cations are reversible competitive inhibitors of tryptic hydrolysis of cationic substrates, whereas their binding has no effect on the reaction of neutral substrates; (b) a nonelectrostatic salt effect on the binding of both cationic and non-ionic substrates is caused by changes in the thermodynamic activity coefficient of the substrate; (c) the rate of trypsin active-site acylation is not affected by inorganic salts with monovalent cations. The data suggest that low-molecular-mass substrates are extracted into the enzyme microphase during substrate binding and further chemical transformations proceed without an access from surrounding medium. It is proposed that formation of a properly oriented dipole in the trypsin binding pocket by the cationic group of the substrate and Asp189 carboxyl is responsible for the elevated acylation rate of trypsin active site by substrates containing lysine and arginine. Introduction of additional negative charges into the enzyme molecule by chemical modification of lysyl residues by pyromellitic anhydride increased the specificity of trypsin towards cationic substrates and inhibitors. Lysine residues are therefore considered as suitable targets for site-directed mutagenesis aimed at the improvement of selectivity and catalytic properties of trypsin.

Surface potential changes of mitoplasts in the presence of pyridoxal phosphate modified cytochromes c

1. The addition of native cytochrome c to mitoplasts leads to a decrease of surface potential of the mitoplast membrane. However the surface potential is slightly decreased (approximately 3 mV) when PLP(Lys 86)-cytochrome c and PLP(Lys 79)-cytochrome c were added. 2. The native and PLP-modified cytochromes c do not influence the order parameters S and isotropic constant a when both spin probe I and probe II were used. It is shown that cytochrome c binding to the membrane does not affect the hydrophobic intermembrane area as well as the lipid arrangements of the mitoplast membrane. 3. At low ionic strength there was observed a significant difference in the membrane potential when PLP-cytochromes c were added to the mitoplasts. 4. At high ionic strength the addition of native or PLP-modified cytochromes c does not change the membrane potential.

Interaction of pyridoxal phosphate modified cytochromes c with mitoplasts

1. The stability of the native conformation of the heme crevice of pyridoxal phosphate (PLP)-ferricytochromes c as assayed by the pK, for 695 nm absorption band varies considerably. The pKa values are 8.76 for cytochrome c modified by PLP at lysine 79[PLP(Lys 79)-cyt. c], 9.23 for cytochrome c modified by PLP at lysine 86 [PLP(Lys 86)-cyt.c], 9.34 for doubly PLP substituted cytochrome c at lysines 79 and 86 [(PLP)2-cyt. c], 9.50 for triply substituted cytochrome c [(PLP)3-cyt. c] and 9.06 for native cytochrome c, which indicates less stable heme crevice of PLP-cytochrome c. 2. The singly PLP-modified cytochrome c indicate decreased activities with mitochondrial cytochrome c oxidase in the following order: PLP(Lys 86)-cyt. c less than PLP(Lys 79)-cyt. c less than native cytochrome c. The high affinity Km for PLP(Lys 86)-cyt. c, PLP(Lys 79)-cyt. c and native cytochrome c are 0.28 microM, 0.16 microM and 0.02 microM respectively. 3. PLP-cytochromes c show decreased binding affinities to fluorescence probes 12-(9-antroyl)-stearic acid and pyrene-labelled mitoplasts. The quenching of singly PLP-modified cytochrome c depends significantly on the ionic strength.

The effects of pH and ionic strength on cytochrome c oxidase steady-state kinetics reveal a catalytic and a non-catalytic interaction domain for cytochrome c

The influence of pH and ionic strength on the steady-state kinetics of purified bovine cytochrome c oxidase was studied by spectrophotometry. At low ionic strength, increasing the pH in the range between 5.4 and 8.6 resulted in a slight decrease in maximal turnover numbers of the high-affinity and the low-affinity reactions. The high-affinity Km was also found to decrease with increasing pH. The ionic-strength dependence of the steady-state kinetics of positively charged cytochrome c oxidase at pH 6.2 and that of negatively charged cytochrome c oxidase at pH 7.8 were similar; in both cases, high-affinity Km values and high-affinity and low-affinity TNmax values increased with ionic strength. The low-affinity Km was independent of both pH and ionic strength. Above I = 100 mM, no low-affinity reaction could be observed. A description of the electrostatic interactions between cytochrome c and cytochrome c oxidase, based on the overall monopoles and overall dipoles of the two proteins, could not explain our data. We propose that at I greater than or equal to 25 mM such an approximation cannot be used for electrostatic interactions between large proteins, since the assumption that all charges on the surfaces of the reacting proteins would contribute equally to the electrostatic interaction is not valid. A qualitative description of electrostatic interactions between the two cytochromes based on limited electrostatic interaction domains on the cytochrome c oxidase surface was found to be in good agreement with all our data and supports the model of Speck et al. (Speck, S.H., Dye, D. and Margoliash, E. (1984) Proc. Natl. Acad. Sci. USA 81, 347-351), who proposed one catalytic and one non-catalytic cytochrome c binding site. It is proposed that the allosteric effect of the cytochrome c at the non-catalytic site is of an electrostatic nature. At high ionic strength (occurring in vivo), this cytochrome c molecule would then no longer affect the catalytic site, resulting in the absence of the low-affinity reaction.