In vivo measurement of cytosolic and mitochondrial pH using a pH-sensitive GFP derivative in Saccharomyces cerevisiae reveals a relation between intracellular pH and growth The specific pH values of cellular compartments affect virtually all biochemical processes, including enzyme activity, protein folding and redox state. Accurate, sensitive and compartmentspecific measurements of intracellular pH (pH i ) dynamics in living cells are therefore crucial to the understanding of stress response and adaptation. We used the pH-sensitive GFP derivative 'ratiometric pHluorin' expressed in the cytosol and in the mitochondrial matrix of growing Saccharomyces cerevisiae to assess the variation in cytosolic pH (pH cyt ) and mitochondrial pH (pH mit ) in response to nutrient availability, respiratory chain activity, shifts in environmental pH and stress induced by addition of sorbic acid. The in vivo measurement allowed accurate determination of organelle-specific pH, determining a constant pH cyt of 7.2 and a constant pH mit of 7.5 in cells exponentially growing on glucose. We show that pH cyt and pH mit are differentially regulated by carbon source and respiratory chain inhibitors. Upon glucose starvation or sorbic acid stress, pH i decrease coincided with growth stasis. Additionally, pH i and growth coincided similarly in recovery after addition of glucose to glucose-starved cultures or after recovery from a sorbic acid pulse. We suggest a relation between pH i and cellular energy generation, and therefore a relation between pH i and growth.
INTRODUCTIONMicrobes are able to adapt to a wide range of stressful environments such as deviant temperature, high or low osmotic pressure, oxidative stress and exposure to weak organic acids. The mechanisms by which they adapt to these environments are often poorly understood. To study these adaptive responses we rely on techniques that focus on various levels of cellular regulation, such as transcription profiles, protein levels and metabolic flux analysis. However, global physiological parameters such as intracellular pH (pH i ) affect nearly all processes in a living cell. pH i directly influences the redox state of the cell by influencing the NAD + /NADH equilibrium (Veine et al., 1998) and determines pH gradients necessary for transport over membranes (Goffeau & Slayman, 1981;Wohlrab & Flowers, 1982). Additionally, the effect of pH is very prominent in enzyme kinetics, as pH influences ionization states of acidic or basic amino acid side-chains and thereby influences the structure, solubility and activity of most, if not all, enzymes.The different organelles in the cell all maintain their own specific pH, which is used to define and maintain the processes associated with each organelle. Yeast vacuoles, for instance, are reported to have an acidic pH (Preston et al., 1989;Brett et al., 2005; Martínez-Muñoz & Kane, 2008). The proton gradient across the vacuolar membrane has been shown to be essential for the transport of various compounds (Nishimura et al., 1998;Ohsumi & Anraku, ...
