Background & Aims: High-fat diets (HFDs) are a major modifiable risk factor for intestinal health. Current research focuses primarily on palmitate (C16:0); however, myristate (C14:0, rich in dairy products) has been minimally investigated. HFDs increase ceramide generation which drives endoplasmic reticulum (ER) stress; with both sphingolipids and ER stress being key contributors to intestinal biology. Whether different fatty acids uniquely impact sphingolipid metabolism and ER stress in intestinal biology has not been well defined. Methods: Human colon epithelial cells were utilized to determine the role of ceramide synthases (CerS) 5 and 6 on myristate-induced ER stress using pharmacologic inhibitors and siRNA. Intestinal epithelial cell specific CerS5 and/or CerS6 knockout mice of both sexes were fed a control, high milk-fat, or high lard-fat diet for 16 weeks. Cells and colon tissues were analyzed for lipids, mRNA, and protein. Results: Myristate treatment increased C14:0-ceramide and induced IRE1-dependent ER stress. Inhibition of CerS suppressed these effects, yet knockdown of CerS5/6, the primary enzymes generating C14:0-ceramide, unexpectedly exacerbated IRE1 activation both in vitro and in vivo, potentially due to depletion of dihydro(dh)sphingosine. Conclusions: CerS are required for myristate-induced IRE1 activation and restoration of the sphingoid base pool provides partial protection from intestinal ER stress.
Human and Robot Assistance for Cognitive Load in Younger and Older Adults: Multimodal Within-Subject Experimental Study
Background: Maintaining cognitive efficiency and independence is a central goal of healthy aging. Socially assistive robots (SARs) are increasingly proposed as scalable digital health solutions