Bioenergetics of Axon Integrity and Its Regulation by Oligodendrocytes and Schwann Cells.

Axons are long slender portions of neurons that transmit electrical impulses to maintain proper physiological functioning. Axons in the central nervous system (CNS) and peripheral nervous system (PNS) do not exist in isolation but are found to form a complex association with their surrounding glial cells, oligodendrocytes and Schwann cells. These cells not only myelinate them for faster nerve impulse conduction but are also known to provide metabolic support. Due to their incredible length, continuous growth, and distance from the cell body (where major energy synthesis takes place), axons are in high energetic demand. The stability and integrity of axons have long been associated with axonal energy levels. The current mini-review is thus focused on how axons accomplish their high energetic requirement in a cell-autonomous manner and how the surrounding glial cells help them in maintaining their integrity by fulfilling their energy demands (non-cell autonomous trophic support). The concept that adjacent glial cells (oligodendrocytes and Schwann cells) provide trophic support to axons and assist them in maintaining their integrity comes from the conditional knockout research and the studies in which the metabolic pathways controlling metabolism in these glial cells are modulated and its effect on axonal integrity is evaluated. In the later part of the mini-review, the current knowledge of axon-glial metabolic coupling during various neurodegenerative conditions was discussed, along with the potential lacunae in our current understanding of axon-glial metabolic coupling.

Design and Characterization of Silver Nanoparticles of Different Species of Curcuma in the Treatment of Cancer Using Human Colon Cancer Cell Line (HT-29).

BACKGROUND: Cancer is a deadly disease responsible for worldwide mortality; usually, middle- and low-income countries have been more affected by cancer and are responsible for 70% of deaths. The present study was performed with the aim to design silver nanoparticles using three species of Curcuma, i.e., Curcuma longa, Curcuma aromatica, and Curcuma caesia. METHODS: The rhizomes of different plants were extracted with ethanol. The rhizome extracts were used to prepare silver nanoparticles. It was optimized at different pH, silver ion concentrations, and concentrations of plant extracts. The anticancer activity of prepared nanoparticles of C. longa, C. aromatica, and C. caesia was evaluated on a human colon cancer cell line (HT-29) using sulforhodamine B (SRB) assay. RESULTS: The percentage yield of C. longa, C. aromatica, and C. caesia was 11.34 g, 15.45 g, and 12.67 g, respectively. The results exhibited that the prepared nanoparticles were smooth and spherical. All the nanoparticles of rhizome extracts rescued the viability of HT-29 cells in a different extent. HT-29 cells were sensitive to prepared nanoparticles that induce more cytotoxicity towards cancer cells. CONCLUSION: Thus, the prepared silver nanoparticle of Curcuma species through green synthesis may help treat cancer with low toxicity.