Title: The rapid mode of calcium uptake into heart mitochondria (RaM): comparison to RaM in liver mitochondria.

Authors: Buntinas, L; Gunter, K K; Sparagna, G C; Gunter, T E

Published In Biochim Biophys Acta, (2001 Apr 02)

Abstract: A mechanism of Ca(2+) uptake, capable of sequestering significant amounts of Ca(2+) from cytosolic Ca(2+) pulses, has previously been identified in liver mitochondria. This mechanism, the Rapid Mode of Ca(2+) uptake (RaM), was shown to sequester Ca(2+) very rapidly at the beginning of each pulse in a sequence [Sparagna et al. (1995) J. Biol. Chem. 270, 27510-27515]. The existence and properties of RaM in heart mitochondria, however, are unknown and are the basis for this study. We show that RaM functions in heart mitochondria with some of the characteristics of RaM in liver, but its activation and inhibition are quite different. It is feasible that these differences represent different physiological adaptations in these two tissues. In both tissues, RaM is highly conductive at the beginning of a Ca(2+) pulse, but is inhibited by the rising [Ca(2+)] of the pulse itself. In heart mitochondria, the time required at low [Ca(2+)] to reestablish high Ca(2+) conductivity via RaM i.e. the 'resetting time' of RaM is much longer than in liver. RaM in liver mitochondria is strongly activated by spermine, activated by ATP or GTP and unaffected by ADP and AMP. In heart, RaM is activated much less strongly by spermine and unaffected by ATP or GTP. RaM in heart is strongly inhibited by AMP and has a biphasic response to ADP; it is activated at low concentrations and inhibited at high concentrations. Finally, an hypothesis consistent with the data and characteristics of liver and heart is presented to explain how RaM may function to control the rate of oxidative phosphorylation in each tissue. Under this hypothesis, RaM functions to create a brief, high free Ca(2+) concentration inside mitochondria which may activate intramitochondrial metabolic reactions with relatively small amounts of Ca(2+) uptake. This hypothesis is consistent with the view that intramitochondrial [Ca(2+)] may be used to control the rate of ADP phosphorylation in such a way as to minimize the probability of activating the Ca(2+)-induced mitochondrial membrane permeability transition (MPT).

PubMed ID: 11245789

MeSH Terms: Adenosine Diphosphate/pharmacology; Adenosine Monophosphate/pharmacology; Adenosine Triphosphate/pharmacology; Adenylate Kinase/metabolism; Animals; Biological Transport; Calcium Channels; Calcium Radioisotopes; Calcium-Binding Proteins/metabolism; Calcium/metabolism*; Calcium/pharmacology; Chickens; Mitochondria, Heart/drug effects; Mitochondria, Heart/metabolism*; Mitochondria, Liver/drug effects; Mitochondria, Liver/metabolism*; Ruthenium Red; Spermine/pharmacology