Department of Pharmacology and Physiology, University of Rochester, Rochester, New York, USA.
J Physiol. 2023 Jun;601(12):2391-2405. doi: 10.1113/JP284469. Epub 2023 Mar 25.
The exocrine pancreas secretes fluid and digestive enzymes in response to parasympathetic release of acetylcholine (ACh) via the vagus nerve and the gut hormone cholecystokinin (CCK). Both secretion of fluid and exocytosis of secretory granules containing enzymes and zymogens are dependent on an increase in the cytosolic [Ca ] in acinar cells. It is thought that the specific spatiotemporal characteristics of the Ca signals are fundamental for appropriate secretion and that these properties are disrupted in disease states in the pancreas. While extensive research has been performed to characterize Ca signalling in acinar cells, this has exclusively been achieved in ex vivo preparations of exocrine cells, where it is difficult to mimic physiological conditions. Here we have developed a method to optically observe pancreatic acinar Ca signals in vivo using a genetically expressed Ca indicator and imaged with multi-photon microscopy in live animals. In vivo, acinar cells exhibited baseline activity in fasted animals, which was dependent on CCK1 receptors (CCK1Rs). Both stimulation of intrinsic nervous input and administration of systemic CCK induced oscillatory activity in a proportion of the cells, but the maximum frequencies were vastly different. Upon feeding, oscillatory activity was also observed, which was dependent on CCK1Rs. No evidence of a vago-vagal reflex mediating the effects of CCK was observed. Our in vivo method revealed the spatial and temporal profile of physiologically evoked Ca signals, which will provide new insights into future studies of the mechanisms underlying exocrine physiology and that are disrupted in pathological conditions. KEY POINTS: In the exocrine pancreas, the spatiotemporal properties of Ca signals are fundamentally important for the appropriate stimulation of secretion by the neurotransmitter acetylcholine and gut hormone cholecystokinin. These characteristics were previously defined in ex vivo studies. Here we report the spatiotemporal characteristics of Ca signals in vivo in response to physiological stimulation in a mouse engineered to express a Ca indicator in acinar cells. Specific Ca 'signatures' probably important for stimulating secretion are evoked in vivo in fasted animals, by feeding, neural stimulation and cholecystokinin administration. The Ca signals are probably the result of the direct action of ACh and CCK on acinar cells and not indirectly through a vago-vagal reflex.
外分泌胰腺通过迷走神经和肠道激素胆囊收缩素(CCK)对副交感神经释放的乙酰胆碱(ACh)作出反应,分泌液体和含有酶和酶原的分泌颗粒的外排。液体分泌和分泌颗粒的胞吐均依赖于胰腺腺泡细胞胞浆内[Ca2+]的增加。人们认为,Ca 信号的特定时空特征是适当分泌的基础,并且这些特性在胰腺的疾病状态中被破坏。虽然已经进行了广泛的研究来描述胰腺腺泡细胞中的 Ca 信号,但这仅在胰腺外分泌细胞的离体制备中实现,在离体制备中很难模拟生理条件。在这里,我们开发了一种使用基因表达的 Ca 指示剂在体内观察胰腺腺泡 Ca 信号的方法,并在活动物中使用多光子显微镜对其进行成像。在体内,空腹动物的腺泡细胞表现出基础活动,这依赖于 CCK1 受体(CCK1R)。内在神经输入的刺激和全身 CCK 的给药均诱导一部分细胞中的振荡活动,但最大频率却大不相同。进食后,也观察到依赖于 CCK1R 的振荡活动。没有证据表明迷走神经反射介导 CCK 的作用。我们的体内方法揭示了生理刺激诱发的 Ca 信号的时空特征,这将为未来研究外分泌生理学的机制以及在病理条件下被破坏的机制提供新的见解。 关键点:在外分泌胰腺中,Ca 信号的时空特性对于神经递质乙酰胆碱和肠道激素胆囊收缩素的适当刺激分泌至关重要。这些特性以前是在离体研究中定义的。在这里,我们报告了在一种经过基因工程改造以在腺泡细胞中表达 Ca 指示剂的小鼠中,对生理刺激的体内 Ca 信号的时空特征。在空腹动物中,通过进食、神经刺激和胆囊收缩素给药,会在体内诱发特定的 Ca“特征”,这些特征可能对刺激分泌很重要。Ca 信号可能是 ACh 和 CCK 直接作用于腺泡细胞的结果,而不是通过迷走神经反射间接作用的结果。
