Amino acid abundance and composition in cell culture medium affects trace metal tolerance and cholesterol synthesis.

Amino acid compositions of cell culture media are empirically designed to enhance cell growth and productivity and vary both across media formulations and over the course of culture due to imbalance in supply and consumption. The interconnected nature of the amino acid transporters and metabolism suggests that changes in amino acid composition can affect cell physiology. In this study, we explore the effect of a step change in amino acid composition from a DMEM: F12-based medium to a formulation varying in relative abundances of all amino acids, evaluated at two amino acid concentrations (lean LAA vs. rich HAA). Cell growth was inhibited in LAA but not HAA. In addition to the expected effects on expression of the cell cycle, amino acid response and mTOR pathway genes in LAA, we observed an unanticipated effect on zinc uptake and efflux genes. This was accompanied by a lower tolerance to zinc supplementation in LAA but not in the other formulations. Histidine was sufficient but not necessary to prevent such zinc toxicity. Additionally, an unanticipated downregulation of genes in the cholesterol synthesis pathway was observed in HAA, accompanied by an increase in cellular cholesterol content, which may depend on the relative abundances of glutamine and other amino acids. This study shows that changes in the amino acid composition without any evident effect on growth may have profound effects on metabolism. Such analyses can help rationalize the designing of medium and feed formulations for bioprocess applications beyond replenishment of consumed components.

Brain region specific methylation and Sirt1 binding changes in MAOA promoter is associated with sexual dimorphism in early life stress induced aggressive behavior.

The maladaptive form of aggressive behavior confers risk for violence and criminal incidences with profound impact on society. Although considerable research has been devoted to elucidate the etiology of aggression, molecular correlates of sex differences remains largely unexplored. Also, little attention has been given to whether males and females respond differently to similar causal factor of aggression. Here, we show the possible association of brain region specific neural activity (c-Fos expression) and monoamine oxidase A (MAOA) epigenetic state with sexual dimorphism in peripubertal stress (PPS) induced adulthood aggression. While PPS adult males exhibited escalated aggression, females spent maximal time in social exploration. c-Fos expression was brain region and sex specific. In the PPS adult cohort, only males showed elevated c-Fos expression in the prefrontal cortex, indicative of their hyper-responsive behavior. MAOA expression and enzyme activity was reduced in hypothalamus and increased in prefrontal cortex of hyper-aggressive male mice. Investigation into the underlying mechanisms revealed hypomethylation in prefrontal cortex and hypermethylation in hypothalamus of MAOA promoter negatively correlating with the expression pattern. On the other hand, binding of Sirt1 to MAOA promoter was diametrically opposite being increased in prefrontal cortex and reduced in hypothalamus. In females, neither expression nor epigenetic state of MAOA gene was significantly altered between control and PPS adult mice. Our study revealed novel epigenetic correlates of sexual dimorphism in stress induced aggressive psychopathology. However, given the multi-factorial nature with environmental influences, further studies are warranted to uncover the biological hub.