Abstract
Changes of quantity and/or morphology of cell mitochondria are often associated with metabolic modulation, pathology, and apoptosis. Exogenous fluorescent probes used to investigate changes in mitochondrial content and dynamics are strongly dependent, for their internalization, on the mitochondrial membrane potential and composition, thus limiting the reliability of measurements. To overcome this limitation, genetically encoded recombinant fluorescent proteins, targeted to different cellular districts, were used as reporters. Here, we explored the potential use of mitochondrially targeted red fluorescent probe (mtRFP) to quantify, by flow cytometry, mitochondrial mass changes in cells exposed to different experimental conditions. We first demonstrated that the mtRFP fluorescence intensity is stable during cell culture and it is related with the citrate synthase activity, an established marker of the mitochondrial mass. Incidentally, the expression of mtRFP inside mitochondria did not alter the oxygen consumption rate under both state 3 and 4 respiration conditions. In addition, using this method, we showed for the first time that different inducers of mitochondrial mass change, such as hypoxia exposure or resveratrol treatment of cells, could be consistently detected. We suggest that transfection and selection of stable clones expressing mtRFP is a reliable method to monitor mitochondrial mass changes, particularly when pathophysiological or experimental conditions change ΔΨm, as it occurs during mitochondrial uncoupling or hypoxia/anoxia conditions.
Highlights
Mitochondria play a pivotal role in cellular homeostasis mainly by providing energy, regulating the redox state of the cell, the calcium homeostasis, releasing signaling messengers, and in many circumstances inducing cell death
Dysregulation of mitophagy and mitochondrial biogenesis and in turn mitochondria mass have been related to many pathological conditions, the evaluation of both mitochondrial mass and network interconnection have become crucial to understanding the mechanisms of cell adaptation to pathological conditions and to specific therapies
The mitochondrially targeted red fluorescent probe (mtRFP) Fluorescence Is Stable in Osteosarcoma Transfected Cells
Summary
Mitochondria play a pivotal role in cellular homeostasis mainly by providing energy, regulating the redox state of the cell, the calcium homeostasis, releasing signaling messengers, and in many circumstances inducing cell death. Alterations in nutrient availability, temperature, and molecular stimuli that determine the activation of hormones and growth factor-initiated intracellular signaling pathways enhance the expression of the master regulators of the mitochondrial biogenesis PGC-1α and PGC-1β. Increased levels of those transcriptional coactivators were related to the increase of both mitochondrial mass and mitochondrial activities, including ROS-scavenging enzymes, OXPHOS components, metabolic pathways, import complexes, fission and fusion proteins, and mitochondrial sirtuins [13,14,15]. Dysregulation of mitophagy and mitochondrial biogenesis and in turn mitochondria mass have been related to many pathological conditions, the evaluation of both mitochondrial mass and network interconnection have become crucial to understanding the mechanisms of cell adaptation to pathological conditions and to specific therapies
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