T13F2.2 of C. elegans is Critical for Chromatin Organization, Autophagy, and Longevity

Intricately modulated by a spectrum of proteins, Chromatin structure governs gene expression and cellular homeostasis. In Caenorhabditis elegans , critical components like the TATA-binding protein tbp-1 play pivotal roles in orchestrating chromatin dynamics. While the function of many of the interacting partners of tbp-1 is well-understood, our study brings into focus a lesser-known entity, T13F2.2, an unexplored tbp-1 interacting protein and a putative RNA polymerase II transcriptional coactivator. Employing reverse genetics, we found that RNAi-induced depletion of T13F2.2 resulted in pronounced disruptions to nuclear architecture, evidenced by nuclear staining and transmission electron microscopy. Accompanying these structural anomalies, we observed increased autophagy, pointing to cellular stress and a hyperacetylation of the core histones, suggesting potential chromatin decompaction. Notably, multifaceted functional alterations, upon the partial knockdown of the T13F2.2, culminated in a substantial reduction in the worm’s lifespan. Intriguingly, interventions such as administering ROS scavengers and autophagy modulators offered a reprieve from this life-shortening effect. Transcriptomic analysis upon T13F2.2 knockdown revealed upregulation of genes related to autophagy and chromatin remodelling, alongside downregulation of genes involved in longevity pathways and oxidative stress response. This study, thus, not only puts forward the functional implication of an uncharacterized gene in C. elegans biology, but also further emphasizes the role of chromatin organization in aging at the organismal level.