In addition to its function in excitation-contraction coupling, the ability of the T-system of skeletal muscle fibres to undergo reversible vacuolation indicates that it may play a role in volume regulation. The mechanism of reversible vacuolation has been investigated by confocal microscopy using fluorescein dextran to probe the accessibility of T-tubules to the extracellular environment. Vacuolation was induced by loading the fibres with 60-100 nM glycerol for 30 minutes and then returning them to glycerol-free medium. Devacuolation was subsequently induced by the reentry of glycerol. During their formation from T-tubules, the vacuoles filled with fluorescent dextran from the extracellular medium. The inaccessibility of the vacuoles to extracellular ferritin observed in a previous study raised the possibility that the vacuoles may be detached from the surface membrane after their formation. However, it is apparent from the present work that, although the tubules of the treated fibres are constricted, the vacuoles maintain a open connection with the external medium for smaller macromolecules. In the light of these experiments, it is proposed that vacuolation is caused by water moving into T-tubules from the cytoplasm faster than it can exit to the extracellular space during a decrease in fibre volume. Since T-tubules have been implicated in the transfection of skeletal muscle by direct injection, the accessibility of plasmid DNA to T-tubules has also been investigated. DNA penetrated into the vacuoles from the extracellular medium less well than dextran, but many vacuoles containing fluorescent DNA were observed in the superficial layers of vacuolated fibres, and it is suggested that T-tubule vacuolation might be used to improve the efficiency of the transfection of skeletal muscle by direct injection.