[PDF][PDF] ATF6α optimizes long-term endoplasmic reticulum function to protect cells from chronic stress

J Wu, DT Rutkowski, M Dubois, J Swathirajan… - Developmental cell, 2007 - cell.com
J Wu, DT Rutkowski, M Dubois, J Swathirajan, T Saunders, J Wang, B Song, GDY Yau…
Developmental cell, 2007cell.com
In vertebrates, three proteins—PERK, IRE1α, and ATF6α—sense protein-misfolding stress in
the ER and initiate ER-to-nucleus signaling cascades to improve cellular function. The
mechanism by which this unfolded protein response (UPR) protects ER function during
stress is not clear. To address this issue, we have deleted Atf6α in the mouse. ATF6α is
neither essential for basal expression of ER protein chaperones nor for embryonic or
postnatal development. However, ATF6α is required in both cells and tissues to optimize …
Summary
In vertebrates, three proteins—PERK, IRE1α, and ATF6α—sense protein-misfolding stress in the ER and initiate ER-to-nucleus signaling cascades to improve cellular function. The mechanism by which this unfolded protein response (UPR) protects ER function during stress is not clear. To address this issue, we have deleted Atf6α in the mouse. ATF6α is neither essential for basal expression of ER protein chaperones nor for embryonic or postnatal development. However, ATF6α is required in both cells and tissues to optimize protein folding, secretion, and degradation during ER stress and thus to facilitate recovery from acute stress and tolerance to chronic stress. Challenge of Atf6α null animals in vivo compromises organ function and survival despite functional overlap between UPR sensors. These results suggest that the vertebrate ATF6α pathway evolved to maintain ER function when cells are challenged with chronic stress and provide a rationale for the overlap among the three UPR pathways.
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