Stanniocalcin 1a is a Ca2+-regulated switch controlling epithelial cell quiescence-proliferation balance and Ca2+ uptake

The mechanisms governing cell quiescence-proliferation balance are poorly defined. Using a zebrafish model, here we report that Stc1a, a glycoprotein known as a hypocalcemic hormone, not only inhibits epithelial calcium uptake but also functions as a Ca2+-regulated switch controlling epithelial cell quiescence-proliferation balance. Among the 4 stc genes, only the stc1a expression is [Ca2+]-dependent. Genetic deletion of stc1a, but not stc2b, resulted in elevated body Ca2+ contents, ectopic Ca2+ deposit, body swelling, and premature death. Reducing epithelial calcium channel Trpv6-mediated Ca2+ uptake alleviated these phenotypes. Loss of Stc1a also promoted quiescent epithelial cells to re-enter the cell cycle. This action was accompanied by local IGF signaling activation and increased expression in papp-aa, a zinc metalloproteinase degrading Igfbp5a. Genetic deletion of papp-aa or igfbp5a abolished the elevated epithelial cell reactivation in stc1a-/- mutants. Likewise, inhibition of IGF1 receptor, PI3 kinase, Akt, and Tor signaling abolished epithelial cell reactivation. These results reveal that Stc1a plays dual roles in regulating epithelial calcium uptake and cell quiescence-proliferation balance and implicate Trpv6 and Papp-aa-Igfbp5a-IGF signaling in these functions.

Tissue-resident memory T cell reactivation by diverse antigen-presenting cells imparts distinct functional responses

CD8+ tissue-resident memory T cells (TRM cells) are poised at the portals of infection and provide long-term protective immunity. Despite their critical roles, the precise mechanics governing TRM cell reactivation in situ are unknown. Using a TCR-transgenic Nur77-GFP reporter to distinguish “antigen-specific” from “bystander” reactivation, we demonstrate that lung CD8+ TRM cells are reactivated more quickly, yet less efficiently, than their counterparts in the draining LNs (TLN cells). Global profiling of reactivated memory T cells revealed tissue-defined and temporally regulated recall response programs. Unlike the reactivation of CD8+ TLN cells, which is strictly dependent on CD11c+XCR1+ APCs, numerous antigen-presenting partners, both hematopoietic and non-hematopoietic, were sufficient to reactivate lung CD8+ TRM cells, but the quality of TRM cell functional responses depended on the identity of the APCs. Together, this work uncovers fundamental differences in the activation kinetics, mechanics, and effector responses between CD8+ memory T cells in peripheral vs. lymphoid organs, revealing a novel tissue-specific paradigm for the reactivation of memory CD8+ T cells.