Fig. 1

Osmotic Shock Contributes a Second Signal Required for Ca²⁺-Dependent cPla₂ Activation in Live Zebrafish

(A) Left: scheme of experimental setup. Right: working hypothesis for cell swelling-induced pathway of cPLA₂ activation.

(B) Ratiometric imaging of Ca²⁺ transients evoked by laser-induced tail fin injury of zebrafish larvae as a function of environmental fluid osmolarity (see also Figure S1 and Movie S1). Larvae are either immersed in hypotonic solution that mimics the osmolarity of their natural habitat (“hypo,” top), or isotonic solution that mimics the osmolarity of their interstitial fluid (“iso,” bottom) to prevent cell swelling after injury. Nuclear GCaMP6s signals are normalized by nuclear mKate2 (mK2) fluorescence using the transgenic Ca²⁺ reporter larvae Tg(hsp70l:GCaMP6s-NLS-P2A-mK2-NLS). UV-laser wounding was performed at ~1 min. Scale bars, 50 µm.

(C) Averaged spatiotemporal profile of Ca²⁺ signal oscillation frequency of the indicated number of transgenic Ca²⁺ ratio-reporter larvae, wounded at the indicated times (red arrows) under hypotonic (top) or isotonic conditions (bottom).

(D) Spatiotemporal plot of permanent and transient cPla₂-mK2 INM-translocation events induced by wounding under hypotonic (top) and isotonic conditions (bottom) in the indicated number of Tg(hsp70l:cPla₂-mK2) larvae.

(E) Average spatial distribution of cPla₂-mK2 translocation events (blue, transient; gray, permanent) and Ca²⁺ oscillation frequency (orange) as a function of distance from the wound margin, induced by wounding larvae under hypotonic (top) or isotonic (bottom) conditions. Data from experiments shown in (C) and (D).

See also Figure S2.