Key points Increased plasma osmolarity induces intracellular water depletion and cell shrinkage (CS) followed by activation of a regulatory volume increase (RVI). In skeletal muscle, the hyperosmotic shock‐induced CS is accompanied by a small membrane depolarization responsible for a release of Ca2+ from intracellular pools. Hyperosmotic shock also induces phosphorylation of STE20/SPS1‐related proline/alanine‐rich kinase (SPAK). TRPV2 dominant negative expressing fibres challenged with hyperosmotic shock present a slower membrane depolarization, a diminished Ca2+ response, a smaller RVI response, a decrease in SPAK phosphorylation and defective muscle function. We suggest that hyperosmotic shock induces TRPV2 activation, which accelerates muscle cell depolarization and allows the subsequent Ca2+ release from the sarcoplasmic reticulum, activation of the Na+–K+–Cl− cotransporter by SPAK, and the RVI response. Increased plasma osmolarity induces intracellular water depletion and cell shrinkage followed by activation of a regulatory volume increase (RVI). In skeletal muscle, this is accompanied by transverse tubule (TT) dilatation and by a membrane depolarization responsible for a release of Ca2+ from intracellular pools. We observed that both hyperosmotic shock‐induced Ca2+ transients and RVI were inhibited by Gd3+, ruthenium red and GsMTx4 toxin, three inhibitors of mechanosensitive ion channels. The response was also completely absent in muscle fibres overexpressing a non‐permeant, dominant negative (DN) mutant of the transient receptor potential, V2 isoform (TRPV2) ion channel, suggesting the involvement of TRPV2 or of a TRP isoform susceptible to heterotetramerization with TRPV2. The release of Ca2+ induced by hyperosmotic shock was increased by cannabidiol, an activator of TRPV2, and decreased by tranilast, an inhibitor of TRPV2, suggesting a role for the TRPV2 channel itself. Hyperosmotic shock‐induced membrane depolarization was impaired in TRPV2‐DN fibres, suggesting that TRPV2 activation triggers the release of Ca2+ from the sarcoplasmic reticulum by depolarizing TTs. RVI requires the sequential activation of STE20/SPS1‐related proline/alanine‐rich kinase (SPAK) and NKCC1, a Na+–K+–Cl− cotransporter, allowing ion entry and driving osmotic water flow. In fibres overexpressing TRPV2‐DN as well as in fibres in which Ca2+ transients were abolished by the Ca2+ chelator BAPTA, the level of P‐SPAKSer373 in response to hyperosmotic shock was reduced, suggesting a modulation of SPAK phosphorylation by intracellular Ca2+. We conclude that TRPV2 is involved in osmosensation in skeletal muscle fibres, acting in concert with P‐SPAK‐activated NKCC1.