Calcium and electrical dynamics in lymphatic endothelium.

KEY POINTS

Endothelial cell function in resistance arteries integrates Ca signalling with hyperpolarization to promote relaxation of smooth muscle cells and increase tissue blood flow. Whether complementary signalling occurs in lymphatic endothelium is unknown. Intracellular calcium and membrane potential were evaluated in endothelial cell tubes freshly isolated from mouse collecting lymphatic vessels of the popliteal fossa. Resting membrane potential measured using intracellular microelectrodes averaged ∼-70 mV. Stimulation of lymphatic endothelium by acetylcholine or a TRPV4 channel agonist increased intracellular Ca with robust depolarization. Findings from Trpv4 mice and with computational modelling suggest that the initial mobilization of intracellular Ca leads to influx of Ca and Na through TRPV4 channels to evoke depolarization. Lymphatic endothelial cells lack the Ca -activated K channels present in arterial endothelium to generate endothelium-derived hyperpolarization. Absence of this signalling pathway with effective depolarization may promote rapid conduction of contraction along lymphatic muscle during lymph propulsion.

ABSTRACT

Subsequent to a rise in intracellular Ca ([Ca ] ), hyperpolarization of the endothelium coordinates vascular smooth muscle relaxation along resistance arteries during blood flow control. In the lymphatic vasculature, collecting vessels generate rapid contractions coordinated along lymphangions to propel lymph, but the underlying signalling pathways are unknown. We tested the hypothesis that lymphatic endothelial cells (LECs) exhibit Ca and electrical signalling properties that facilitate lymph propulsion. To study electrical and intracellular Ca signalling dynamics in lymphatic endothelium, we excised collecting lymphatic vessels from the popliteal fossa of mice and removed their muscle cells to isolate intact LEC tubes (LECTs). Intracellular recording revealed a resting membrane potential of ∼-70 mV. Acetylcholine (ACh) increased [Ca ] with a time course similar to that observed in endothelium of resistance arteries (i.e. rapid initial peak with a sustained 'plateau'). In striking contrast to the endothelium-derived hyperpolarization (EDH) characteristic of arteries, LECs depolarized (>15 mV) to either ACh or TRPV4 channel activation. This depolarization was facilitated by the absence of Ca -activated K (K ) channels as confirmed with PCR, persisted in the absence of extracellular Ca , was abolished by LaCl and was attenuated ∼70% in LECTs from Trpv4 mice. Computational modelling of ion fluxes in LECs indicated that omitting K channels supports our experimental results. These findings reveal novel signalling events in LECs, which are devoid of the K activity abundant in arterial endothelium. Absence of EDH with effective depolarization of LECs may promote the rapid conduction of contraction waves along lymphatic muscle during lymph propulsion.