New Study Reveals Mitochondria Split Functions for Energy and Molecular Synthesis in Low-Nutrient Environments

A groundbreaking study has revealed a new “division of labor” within mitochondria, showing that different subpopulations of mitochondria take on distinct functions when cells face nutrient scarcity. Led by Dr. Craig Thompson, a cell biologist at Memorial Sloan Kettering Cancer Center, the research team discovered that under low-nutrient conditions, some mitochondria focus on energy production, while others shift to molecular synthesis for cellular repair and protein production. This newly identified specialisation could have crucial implications for how cells adapt to injury and respond to resource limitations.

Traditionally, mitochondria are known as the powerhouses of the cell, responsible for generating adenosine triphosphate (ATP), which fuels many cellular activities. However, they also play a role in synthesising essential molecules like amino acids, which are crucial for protein production and cell function. When cells are deprived of nutrients—such as during blood loss after an injury—mitochondria may struggle to simultaneously support both energy production and molecular synthesis. Dr. Thompson’s team sought to understand how mitochondria manage this balance under stress, revealing a surprising adaptation mechanism.

In experiments involving mouse cells, the researchers imposed conditions that forced the cells to rely exclusively on mitochondrial ATP production, limiting the use of other energy sources. Surprisingly, despite these constraints, the mitochondria continued to synthesise amino acids, a task usually considered secondary to energy production. Further investigation pinpointed a key enzyme, P5CS, which was found to be crucial for this process. The enzyme was located only in specific mitochondria, which clustered together in a way that enabled amino acid synthesis. When the scientists genetically modified the cells to prevent this clustering, amino acid production ceased, highlighting the critical role of P5CS in enabling mitochondria to perform multiple functions under low-nutrient stress.

This research adds a new layer of understanding to mitochondrial function, showing that these organelles are not just energy producers but also dynamic responders to environmental challenges. The discovery could have significant implications for understanding how cells repair themselves after injury or cope with diseases like cancer, where nutrient availability is often compromised. By uncovering the specialised roles of mitochondria under nutrient stress, this study opens up potential avenues for therapeutic interventions that could harness the adaptability of mitochondria to improve cell survival and function.