Respiration, oxidative phosphorylation, and uncoupling protein in Candida albicans

The respiration, membrane potential (Dy), and oxidative phosphorylation of mitochondria in situ were determined in spheroplasts obtained from Candida albicans control strain ATCC 90028 by lyticase treatment. Mitochondria in situ were able to phosphorylate externally added ADP (200 µM) in the presence of 0.05 percent BSA. Mitochondria in situ generated and sustained stable mitochondrial Dy respiring on 5 mM NAD-linked substrates, 5 mM succinate, or 100 µM N,N,N',N'-tetramethyl-p-phenylenediamine dihydrochloride plus 1 mM ascorbate. Rotenone (4 µM) inhibited respiration by 30 percent and 2 µM antimycin A or myxothiazole and 1 mM cyanide inhibited it by 85 percent. Cyanide-insensitive respiration was partially blocked by 2 mM benzohydroxamic acid, suggesting the presence of an alternative oxidase. Candida albicans mitochondria in situ presented a carboxyatractyloside-insensitive increase of Dy induced by 5 mM ATP and 0.5 percent BSA, and Dy decrease induced by 10 µM linoleic acid, both suggesting the existence of an uncoupling protein. The presence of this protein was subsequently confirmed by immunodetection and respiration experiments with isolated mitochondria. In conclusion, Candida albicans ATCC 90028 possesses an alternative electron transfer chain and alternative oxidase, both absent in animal cells. These pathways can be exceptional targets for the design of new chemotherapeutic agents. Blockage of these respiratory pathways together with inhibition of the uncoupling protein (another potential target for drug design) could lead to increased production of reactive oxygen species, dysfunction of Candida mitochondria, and possibly to oxidative cell death.

Important amino acid residues of potato plant uncoupling protein (StUCP)

Chemical modifications were used to identify some of the functionally important amino acid residues of the potato plant uncoupling protein (StUCP). The proton-dependent swelling of potato mitochondria in K+-acetate in the presence of linoleic acid and valinomycin was inhibited by mersalyl (Ki = 5 æM) and other hydrophilic SH reagents such as Thiolyte MB, iodoacetate and 5,5'-dithio-bis-(2-nitrobenzoate), but not by hydrophobic N-ethylmaleimide. This pattern of inhibition by SH reagents was similar to that of brown adipose tissue uncoupling protein (UCP1). As with UCP1, the arginine reagent 2,3-butadione, but not N-ethylmaleimide or other hydrophobic SH reagents, prevented the inhibition of StUCP-mediated transport by ATP in isolated potato mitochondria or with reconstituted StUCP. The results indicate that the most reactive amino acid residues in UCP1 and StUCP are similar, with the exception of N-ethylmaleimide-reactive cysteines in the purine nucleotide-binding site

Ca2+ transport and oxidative damage of mitochondria

1. Mitochondria from a wide range of sources have the ability to accumulate Ca2+ down their electrochemical gradient mediated by a uniport mechanism. 2. Ca2+ efflux occurs via two separate pathways: a Na+/Ca2+ exchanger that predominates in mitochondria from excitable tissues and a Na(+)-independent pathway that predominates in mitochondria from non-excitable tissues. 3. The kinetic characteristics of these calcium influx-efflux pathways appear to be incompatible with any role for mitochondria as cytosolic Ca2+ buffers, under resting normal physiological conditions. Instead, the biological role of this Ca(2+)-transporting system seems to be the regulation of matrix Ca2+ in a range that permits the regulation of three intramitochondrial Ca(2+)-dependent dehydrogenases which catalyze rate-limiting reactions of the Krebs cycle. 4. Under conditions in which a high cytosolic Ca2+ concentration is sustained, the matrix Ca2+ concentration may attain levels that lead to impairment of mitochondrial functions such as inhibition of oxidative phosphorylation and increase in inner membrane permeability. 5. Accumulation of Ca2+ by mitochondria under conditions of oxidative stress induces an increase in inner membrane permeability by a mechanism that appears to be mediated by protein polymerization due to thiol cross-linking

ATP and Ca2+ homeostasis in Trypanosoma cruzi

Cell viability requires the perfect functioning of the processes controlling ATP and Ca2+ homeostasis. It is known that cell death caused by a variety of toxins or pathological conditions is associated with disruption of ATP and Ca2+ homeostasis. Therefore, the study of the mechanisms by which different T. cruzi stages regulate the intracellular Ca2+ distribution and the ATP supply to maintain cell viability could provide new insights into the physiology of these parasites. One important objective of these studies is the identification of possible metabolic differences between host and parasite that could be exploited for the rational design of new and more effective trypanocidal drugs