Role of ATF4 in directing gene expression in the basal state and during the unfolded protein response in liver

• Main Author: Fusakio, Michael Edward
• Other Authors: Wek, Ronald C.
• Language: en_US
• Published: 2016
• Subjects: ATF4; Next generation sequencing; Unfolded protein; Cellular stress; Endoplasmic reticulum; Proteins; Protein folding; Cellular signal transduction; Stress (physiology); Proteins > Synthesis; Fatty liver; Cholesterol; Gene expression
• Online Access: http://hdl.handle.net/1805/11001

Indiana University-Purdue University Indianapolis (IUPUI) === Disturbances in membrane composition and protein folding in the endoplasmic reticulum (ER) trigger the unfolded protein response (UPR). Three UPR sensory proteins, PERK (PEK/EIF2AK3), IRE1, and ATF6 are each activated by ER stress. PERK phosphorylation of the alpha subunit of eIF2 represses global protein synthesis, lowering influx of nascent polypeptides into the stressed ER, coincident with the preferential translation of ATF4 (CREB2). Results from cultured cells demonstrate that ATF4 induces transcriptional expression of genes directed by the PERK arm of the UPR, including genes involved in amino acid metabolism, resistance to oxidative stress, and the proapoptotic transcription factor CHOP (GADD153/DDIT3). In this study, we characterized two ATF4 knockout mouse models and show in liver exposed to ER stress that ATF4 is not required for CHOP expression, but rather ATF6 is a primary inducer. RNA-sequence analysis indicated that ATF4 was responsible for a small portion of the PERK-dependent genes in the UPR. This smaller than expected subset of gene expression lends itself to the relevance of UPR crosstalk, with ATF6, XBP1, and CHOP being capable of upregulating UPR genes in the absence of ATF4. RNA-sequence analysis also revealed a requirement for expression of ATF4 for expression of a comparable number of genes basally, including those involved in oxidative stress response and cholesterol metabolism. Consistent with this pattern of gene expression, loss of ATF4 in our mouse model resulted in enhanced oxidative damage and increased free cholesterol in liver under stress accompanied by lowered cholesterol in sera. Taken together, this study highlights both an expansion of the role of ATF4 in transcriptional regulation of genes involved in metabolism in the basal state and a more specialized role during ER stress. These findings are important for understanding the variances of the UPR signaling between cell culture and in vivo and for a greater understanding of all the roles ATF4 plays within the cell.