Neal I. Callaghan, Loïck Ducros, J. Craig Bennett, Juan C. Capaz, José Pedro Andrade, Antonio V. Sykes, William R. Driedzic, Simon G. Lamarre, Tyson J. MacCormack
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This is associated with considerable citrate synthase activity (relative to larger cuttlefish) but a lack of glucose metabolism based on zero uptake of glucose by isolated muscle sheets and minimal activity of hexokinase (similar to larger animals). In contrast to glucose metabolism in the heart, glucose metabolism in these muscle sheets was not stimulated by extracellular taurine. Previous research revealed an unusual ion channel complement in mantle myocytes, the most notable feature of which is the lack of a Na<sup>+</sup> current during depolarization. Because this adaptation is not consistent across the coleoid clade, we investigated excitation–contraction coupling. Here, mantle energetics and contractility, including the individual components of the total Ca<sup>2+</sup> flux driving contraction, were studied. Results indicate that the majority of Ca<sup>2+</sup> current underlying contractile stress development capacity in cuttlefish juveniles is not mediated by dihydropyridine-sensitive L-type channels, in contrast to their adult counterparts, and the sarcoplasmic reticulum contributes little to routine contractility. We had previously noted an influence of physiological levels of taurine in limiting cardiac contractility but found no analogous sensitivity in mantle muscle. 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引用次数: 0
摘要
普通墨鱼(Sepia officinalis)的套膜肌肉既负责大运动量的快速运动,也负责持续通气,这需要特定的代谢、电生理和结构组织。幼墨鱼具有高度氧化的表型和快速的生长速度。在这里,我们展示了幼体的高耗氧量和蛋白质合成率,这些速率在生长的最初几周内呈指数衰减。这与相当高的柠檬酸合成酶活性有关(相对于较大的墨鱼),但缺乏葡萄糖代谢,因为离体肌片对葡萄糖的吸收为零,而己糖激酶的活性极低(与较大的动物相似)。与心脏的葡萄糖代谢不同,这些肌片的葡萄糖代谢不受细胞外牛磺酸的刺激。先前的研究发现,套膜肌细胞中存在一种不寻常的离子通道互补,其最显著的特征是在去极化过程中缺乏 Na+ 电流。由于这种适应性在整个蝶形目中并不一致,因此我们对兴奋-收缩耦合进行了研究。在这里,我们研究了套膜能量和收缩能力,包括驱动收缩的总 Ca2+ 通量的各个组成部分。结果表明,墨鱼幼体收缩应激发展能力所依赖的大部分 Ca2+ 电流不是由二氢吡啶敏感的 L 型通道介导的,这与它们的成体不同,而且肌质网对常规收缩力的贡献很小。我们以前曾注意到生理水平的牛磺酸对限制心脏收缩力的影响,但在套膜肌肉中却没有发现类似的敏感性。最后,亚细胞结构的透射电子显微镜检查发现了肌浆管聚集体的存在,这表明肌浆网功能的氧化抑制限制了它在这一生命阶段的作用。
Excitation–contraction coupling reflects the metabolic profile of mantle muscle in young cuttlefish (Sepia officinalis)
The mantle muscle of common cuttlefish, Sepia officinalis, is responsible both for high-magnitude and rapid movements for locomotion, as well as sustained ventilation, which require specific metabolic, electrophysiological, and structural organization. Young cuttlefish have a highly oxidative phenotype and a rapid growth rate. Here, we show high rates of oxygen consumption and protein synthesis in juveniles, and these rates decay exponentially over the first few weeks of growth. This is associated with considerable citrate synthase activity (relative to larger cuttlefish) but a lack of glucose metabolism based on zero uptake of glucose by isolated muscle sheets and minimal activity of hexokinase (similar to larger animals). In contrast to glucose metabolism in the heart, glucose metabolism in these muscle sheets was not stimulated by extracellular taurine. Previous research revealed an unusual ion channel complement in mantle myocytes, the most notable feature of which is the lack of a Na+ current during depolarization. Because this adaptation is not consistent across the coleoid clade, we investigated excitation–contraction coupling. Here, mantle energetics and contractility, including the individual components of the total Ca2+ flux driving contraction, were studied. Results indicate that the majority of Ca2+ current underlying contractile stress development capacity in cuttlefish juveniles is not mediated by dihydropyridine-sensitive L-type channels, in contrast to their adult counterparts, and the sarcoplasmic reticulum contributes little to routine contractility. We had previously noted an influence of physiological levels of taurine in limiting cardiac contractility but found no analogous sensitivity in mantle muscle. Finally, transmission electron microscopy of subcellular architecture revealed the presence of sarcoplasmic tubular aggregates, suggesting that oxidative inhibition of sarcoplasmic reticulum function limits its role in this life stage.
期刊介绍:
Invertebrate Biology presents fundamental advances in our understanding of the structure, function, ecology, and evolution of the invertebrates, which represent the vast majority of animal diversity. Though ultimately organismal in focus, the journal publishes manuscripts addressing phenomena at all levels of biological organization. Invertebrate Biology welcomes manuscripts addressing the biology of invertebrates from diverse perspectives, including those of:
• genetics, cell, and molecular biology
• morphology and biomechanics
• reproduction and development
• physiology and behavior
• ecology
• evolution and phylogenetics