The arginines of cytochrome c. The reduction-binding site for 2,3-butanedione and ascorbate

Positive modulation of the α9α10 nicotinic cholinergic receptor by ascorbic acid

BACKGROUND AND PURPOSE

The activation of α9α10 nicotinic cholinergic receptors (nAChRs) present at the synapse between efferent olivocochlear fibres and cochlear hair cells can prevent acoustic trauma. Hence, pharmacological potentiators of these receptors could be useful therapeutically. In this work, we characterize ascorbic acid as a positive modulator of recombinant α9α10 nAChRs.

EXPERIMENTAL APPROACH

ACh-evoked responses were analysed under two-electrode voltage-clamp recordings in Xenopus laevis oocytes injected with α9 and α10 cRNAs.

KEY RESULTS

Ascorbic acid potentiated ACh responses in X. laevis oocytes expressing α9α10 (but not α4β2 or α7) nAChRs, in a concentration-dependent manner, with an effective concentration range of 1-30 mM. The compound did not affect the receptor's current-voltage profile nor its apparent affinity for ACh, but it significantly enhanced the maximal evoked currents (percentage of ACh maximal response, 240 ± 20%). This effect was specific for the L form of reduced ascorbic acid. Substitution of the extracellular cysteine residues present in loop C of the ACh binding site did not affect the potentiation. Ascorbic acid turned into a partial agonist of α9α10 nAChRs bearing a point mutation at the pore domain of the channel (TM2 V13'T mutant). A positive allosteric mechanism of action rather than an antioxidant effect of ascorbic acid is proposed.

CONCLUSIONS AND IMPLICATIONS

The present work describes one of the few agents that activates or potentiates α9α10 nAChRs and leads to new avenues for designing drugs with potential therapeutic use in inner ear disorders.

Maillard reaction of ribose 5-phosphate generates superoxide and glycation products for bovine heart cytochrome c reduction

Ribose 5-phosphate (R5P) is a sugar known to undergo the Maillard reaction (glycation) at a rapid rate. In a reaction with the lysines of bovine heart cytochrome c, R5P generates superoxide (O2-) that subsequently reduces ferri-cytochrome c to ferro-cytochrome c. The rate equation for the observed cytochrome c reduction is first order in respect to cytochrome c and half order in respect to R5P. The addition of amines to the cytochrome c-R5P system greatly increases the O2- generation with rates of approximately 1.0 μMmin(-1) being observed with millimolar levels of R5P and amine at 37°C. Pre-incubation of R5P with the amine prior to cytochrome c addition further enhances the rate of cytochrome c reduction approximately twofold for every 30 min of incubation. While clearly accounting for a portion of the reduction of cytochrome c, O2- is not the sole reductant of the system as the use of superoxide dismutase only partially limits cytochrome c reduction, and the contribution of O2- proportionally decreases with longer amine-R5P incubation times. The remainder of the cytochrome c reduction is attributed to either the Amadori product or a cross-linked Schiff base created when a Maillard reaction-derived dicarbonyl compound(s) reacts with the amine. It is believed that these compounds directly transfer electrons to ferri-cytochrome c and subsequently become stable free-radical cations. ATP, a putative regulator of cytochrome c activity, does not inhibit electron transport from O2- or the cross-linked Schiff base but does prevent R5P from reacting with surface lysines to generate superoxide. The spontaneous reaction between R5P and amines could serve as an alternative system for generating O2- in solution.

Remarkably high activities of testicular cytochrome c in destroying reactive oxygen species and in triggering apoptosis

Hydrogen peroxide (H(2)O(2)) is the major reactive oxygen species (ROS) produced in sperm. High concentrations of H(2)O(2) in sperm induce nuclear DNA fragmentation and lipid peroxidation and result in cell death. The respiratory chain of the mitochondrion is one of the most productive ROS generating systems in sperm, and thus the destruction of ROS in mitochondria is critical for the cell. It was recently reported that H(2)O(2) generated by the respiratory chain of the mitochondrion can be efficiently destroyed by the cytochrome c-mediated electron-leak pathway where the electron of ferrocytochrome c migrates directly to H(2)O(2) instead of to cytochrome c oxidase. In our studies, we found that mouse testis-specific cytochrome c (T-Cc) can catalyze the reduction of H(2)O(2) three times faster than its counterpart in somatic cells (S-Cc) and that the T-Cc heme has the greater resistance to being degraded by H(2)O(2). Together, these findings strongly imply that T-Cc can protect sperm from the damages caused by H(2)O(2). Moreover, the apoptotic activity of T-Cc is three to five times greater than that of S-Cc in a well established apoptosis measurement system using Xenopus egg extract. The dramatically stronger apoptotic activity of T-Cc might be important for the suicide of male germ cells, considered a physiological mechanism that regulates the number of sperm produced and eliminates those with damaged DNA. Thus, it is very likely that T-Cc has evolved to guarantee the biological integrity of sperm produced in mammalian testis.

Role of arginine-38 in regulation of the cytochrome c oxidation-reduction equilibrium

Arg-38 is an internal residue of mitochondrial cytochrome c that is close to heme propionate-7. Previous work comparing the behavior of cytochromes c from several species [Moore, G. R., Harris, D. E., Leitch, F. A., & Pettigrew, G. W. (1984) Biochim. Biophys. Acta 764, 331-342] has suggested that Arg-38 lowers the pKa of this propionate group and thereby accounts for the relative pH independence of the cytochrome c reduction potential from pH 5 to pH 8. The influence of Arg-38 on the oxidation-reduction equilibrium of yeast iso-1-cytochrome c has now been investigated by electrochemical, NMR, and theoretical analysis of six specifically mutated forms of this protein in which Arg has been replaced by Lys, His, Gln, Asn, Leu, or Ala. As the electron-withdrawing character of the residue at position 38 decreases, the reduction potential of the protein also decreases, with the largest decrease (ca. 50 mV) observed for the Ala variant. However, the variation in the reduction potentials of the mutants as a function of pH was similar to that observed for the wild-type protein. The effects of some of these mutations on the pKa values of His-33 and His-39 have been determined by NMR spectroscopy and found to be minimal. Calculations of the electrostatic free energy for the Leu-38 variant predict a decrease in the reduction potential of this mutant that is remarkably close to that observed experimentally. This work establishes that while Arg-38 contributes to the relatively high reduction potential of cytochrome c, this residue does not appear to be the sole functionality responsible for lowering the heme propionate-7 pKa.

Methionine-oxidized horse heart cytochrome c. III. Ascorbate reduction and the methionine-80-sulfur-iron linkage

The ascorbate reduction of the CT-cytochromes--two chemically generated forms of horse heart cytochrome c, FIII and FII, with both methionines, 80 and 65, as methionine sulfoxides, no iron-sulfur linkage, and potentiometric and physiological oxidoreduction properties distinct from those of the native protein and one another (J. Pande et al., 1987)--has been investigated using a stopped-flow technique. The reaction was monitored at 550 nm, and studies were conducted in 10 mM phosphate + 0.17 M NaCl buffer, pH 7.4. Both CT-cytochromes are reduced by triphasic profiles, a faster and an intermediate ascorbate-dependent reaction and a slow, ascorbate-independent process. Both CT-cytochromes contain three molecular forms in slow equilibrium, two reducing directly by reaction with ascorbate and a third through conversion to one of the reducible forms. Like the reaction of the native protein, the ascorbate dependence of both the rapid and the intermediate process is nonlinear, approaching saturation values at high concentrations. The ascorbate profiles of the pseudo-first-order reduction constants are typical of the model for the reduction reaction of the unmodified protein, binding followed by a first-order reduction reaction (Myer et al., 1980; Myer and Kumar, 1984), but with distinct kinetic parameters, the first-order reduction constants and the protein-ascorbate stability constants. It has been concluded that the functional-conformational differences between the two CT-cytochromes are not operational to any significant extent in the reduction reaction with ascorbate. The methionine-80-sulfur-iron linkage of the protein is not a crucial requirement for the ascorbate reduction of the protein. The mechanism of the reaction in the main is also insensitive to the replacement of Met-80-S from heme coordination and/or the associated conformational-oxidoreduction properties of the protein. Of the two aspects of the reaction, the efficiency of the electron-transfer reaction and the stability of the ascorbate dianion-protein complex, the former is dependent on the integrity of the structural-conformational state of the molecule.