Davis M J, Bertram C D
Department of Medical Pharmacology & Physiology, University of Missouri, Columbia, MO, USA.
School of Mathematics & Statistics, University of Sydney, Sydney, NSW, Australia.
J Physiol. 2025 Jun;603(11):3307-3327. doi: 10.1113/JP288477. Epub 2025 Jun 4.
The spontaneous, phasic contractions of collecting lymphatic vessels are critical for lymph transport and interstitial fluid homeostasis. Phasic contractions are initiated by action potentials in lymphatic muscle and conduct along the vessel to trigger contraction waves. Contractions are regulated by pressure and shear stress (SS), but only limited aspects of that regulation are understood. Numerical models predict that pressure promotes retrograde propagation of contraction waves, whereas nitric oxide (NO) production associated with phasic contractions (pulsatile NO) promotes antegrade conduction and extends the pressure range over which contractions propel lymph. These predictions were tested using 3-4-valve segments of rat mesenteric lymphatic vessels using pressure myography and protocols that imposed forward flow, elevated inflow pressure (P) or elevated outflow pressure (P), each with/without intact NO signalling. NO bioavailability and flow-induced responses were enhanced by l-arginine supplementation. Spatiotemporal maps generated from video images were used to quantify the direction and extent of contraction wave conduction. Our results show that (1) contraction waves are normally biased towards retrograde conduction at equal P/P levels. (2) P elevation promotes antegrade conduction, whereas P elevation promotes retrograde conduction. (3) Imposed flow is inhibitory, reducing contraction amplitude and frequency and limiting the extent of contraction wave conduction without a significant effect on conduction direction. (4) Pulsatile NO does not significantly influence the conduction direction or extend the pressure range over which spontaneous contractions occur. Our findings support the idea that pressure is the dominant regulator of lymphatic pacemaking and pumping, with pulsatile NO having only minimal influence. KEY POINTS: The degree to which spontaneous, phasic contractions of lymphatic collecting vessels are regulated by pressure and shear stress is not fully understood. Numeric models predict that nitric oxide (NO) production associated with phasic contractions (pulsatile NO) promotes antegrade conduction of contraction waves, whereas pressure elevation promotes retrograde conduction; pulsatile NO production is also thought to extend the pressure range over which phasic contractions occur. Ex vivo methods were used to control pressure/flow in 3-4 valve segments of collecting lymphatics from rat mesentery, with preserved or inhibited NO signalling. The relatively long vessel segments limited the absolute levels of imposed flow/SS, so l-arginine supplementation was used to enhance NO bioavailability. Our findings support a scheme whereby pressure is by far the dominant mechanism determining the pacemaking site of lymphatic collectors, and challenge existing dogma about the importance of pulsatile NO production in regulating their behaviour.
集合淋巴管的自发性、阶段性收缩对于淋巴运输和组织液稳态至关重要。阶段性收缩由淋巴管平滑肌中的动作电位引发,并沿血管传导以触发收缩波。收缩受压力和剪切应力(SS)调节,但对该调节的了解仅局限于有限的方面。数值模型预测,压力促进收缩波的逆行传播,而与阶段性收缩相关的一氧化氮(NO)生成(搏动性NO)促进顺行传导并扩展收缩推动淋巴的压力范围。使用大鼠肠系膜淋巴管的3 - 4瓣膜段,采用压力肌动描记法以及施加正向流动、升高流入压力(P)或升高流出压力(P)的实验方案,每种方案均在有/无完整NO信号传导的情况下进行,对这些预测进行了测试。补充L - 精氨酸可增强NO生物利用度和血流诱导反应。从视频图像生成的时空图用于量化收缩波传导的方向和范围。我们的结果表明:(1)在相等的P/P水平下,收缩波通常偏向逆行传导。(2)升高P促进顺行传导,而升高P促进逆行传导。(3)施加的流动具有抑制作用,降低收缩幅度和频率并限制收缩波传导范围,而对传导方向无显著影响。(4)搏动性NO对传导方向无显著影响,也不扩展自发收缩发生的压力范围。我们的研究结果支持这样一种观点,即压力是淋巴管起搏和泵血的主要调节因素,搏动性NO的影响极小。要点:集合淋巴管的自发性、阶段性收缩受压力和剪切应力调节的程度尚未完全了解。数值模型预测,与阶段性收缩相关的一氧化氮(NO)生成(搏动性NO)促进收缩波的顺行传导,而压力升高促进逆行传导;搏动性NO生成还被认为可扩展阶段性收缩发生的压力范围。采用离体方法控制大鼠肠系膜集合淋巴管3 - 4瓣膜段的压力/血流,同时保留或抑制NO信号传导。相对较长的血管段限制了施加的血流/SS的绝对水平,因此使用补充L - 精氨酸来提高NO生物利用度。我们的研究结果支持这样一种机制,即压力是迄今为止决定淋巴管集合器起搏部位的主要机制,并对关于搏动性NO生成在调节其行为中的重要性的现有教条提出了挑战。
