Relationship between serum concentration, functional parameters and cell bioenergetics in IPEC-J2 cell line

Although glycolysis is a biochemical pathway that evolved under ancient anaerobic terrestrial conditions, recent studies have provided evidence that some glycolytic enzymes are more complicated, multifaceted proteins rather than simple components of the glycolytic pathway. These glycolytic enzymes have acquired additional non-glycolytic functions in transcriptional regulation [hexokinase (HK)-2, lactate dehydrogenase A, glyceraldehyde-3-phosphate dehydrogenase (GAPD) and enolase 1], stimulation of cell motility (glucose-6-phosphate isomerase) and the regulation of apoptosis (glucokinase, HK and GAPD). The existence of multifaceted roles of glycolytic proteins suggests that links between metabolic sensors and transcription are established directly through enzymes that participate in metabolism. These roles further underscore the need to consider the non-enzymatic functions of enzymes in proteomic studies of cells and tissues.

Members of the PGC-1 family of coactivators have been revealed as key players in the regulation of energy metabolism. Early gain- and loss-of-function studies led to the conclusion that all members of the PGC-1 family (PGC-1α, PGC-1β and PRC) play redundant roles in the control of mitochondrial biogenesis by regulating overlapping gene expression programs. Regardless of this, all PGC-1 coactivators also appeared to differ in the stimuli to which they respond to promote mitochondrial gene expression. Although PGC-1α was found to be induced by different physiological or pharmacological cues, PGC-1β appeared to be unresponsive to such stimuli. Consequently, it has long been widely accepted that PGC-1α acts as a mediator of mitochondrial biogenesis induced by cues that signal high-energy needs, whereas the role of PGC-1β is restricted to the maintenance of basal mitochondrial function. By contrast, the function of PRC appears to be restricted to the regulation of gene expression in proliferating cells. However, recent studies using tissue-specific mouse models that lack or overexpress different PGC-1 coactivators have provided emerging evidence not only supporting new roles for PGC-1s, but also redefining some of the paradigms related to the precise function and mode of action of PGC-1 coactivators in mitochondrial biogenesis. The present review discusses some of the new findings regarding the control of mitochondrial gene expression by PGC-1 coactivators in a tissue-specific context, as well as newly-uncovered functions of PGC-1s beyond mitochondrial biogenesis, and their link to pathologies, such as diabetes, muscular dystrophies, neurodegenerative diseases or cancer.