Abstract. Ca 2+ is a key regulator not only of multiple cytosolic enzymes, but also of a variety of metabolic pathways occurring within the lumen of intracellular organelles. Until recently, no technique to selectively monitor the Ca 2+ concentration within defined cellular compartments was available. We have recently proposed the use of molecularly engineered Ca2÷-sensitive photoproteins to obtain such a result and demonstrated the application of this methodology to the study of mitochondrial and nuclear Ca 2+ dynamics. We here describe in more detail the use of chimeric recombinant aequorin targeted to the mitochondria. The technique can be applied with equivalent results to different cell models, transiently or permanently transfected. In all the cell types we analyzed, mitochondrial Ca :+ concentration ([Ca2+]m) increases rapidly and transiently upon stimulation with agonists coupled to InsP3 generation. We confirm that the high speed of mitochondrial Ca 2+ accumulation with this type of stimuli depends on the generation of local gradients of Ca 2÷ in the cytosol, close to the channels sensitive to InsP3. In fact, only activation of these channels, but not the simple release from internal stores, as that elicited by blocking the intracellular Ca 2÷ ATPases, results in a fast mitochondrial Ca ~+ accumulation. We also provide evidence in favor of a microheterogeneity among mitochondria of the same cells, about 30% of them apparently sensing the microdomains of high cytosolic Ca 2+ concentration ([Ca2+]c). The changes in [Ca2+]m appear sufficiently large to induce a rapid activation of mitochondrial dehydrogenases, which can be followed by monitoring the level of NAD(P)H fluorescence. A general scheme can thus be envisaged by which the triggering of a plasma membrane receptor coupled to InsP3 generation raises the Ca 2+ concentration both in the cytoplasm (thereby triggering energy-consuming processes, such as cell proliferation, motility, secretion, etc.) and in the mitochondria, where it activates the metabolic activity according to the increased cell needs.T HE development of specific probes for measuring the Ca2. + concentration in the cytoplasm of living cells (lslen et al., 1982; Grynkiewicz et al., 1985) has led to major progress in the understanding of the mechanisms controlling cellular Ca 2+ homeostasis and of the role played by this cation in the chain of events coupling membrane receptor stimulation to cell activation (Berridge and Irvine, 1989;Pietrobon et al., 1990;Meldolesi et al., 1990). We now know that, in a variety of cell types, stimuli as diverse as hormones and growth factors, cell-cell interaction and synaptic transmission induce rises of the cytosolic free calcium concentration ([Ca2+]o). The Ca e+ ions then bind to a number of effector proteins, which, in turn, modulate a variety of cellular processes, such as motility, secretion, enzyme activation, etc. Rises in [Ca2+]c depend either on influx from the extracellular medium and/or release from intracellular stores. In both cases, Ca 2+...
