Clapp Tod R, Medler Kathryn F, Damak Sami, Margolskee Robert F, Kinnamon Sue C
Department of Biomedical Sciences, Colorado State University, Fort Collins, CO 80523, USA.
BMC Biol. 2006 Mar 30;4:7. doi: 10.1186/1741-7007-4-7.
Taste receptor cells are responsible for transducing chemical stimuli from the environment and relaying information to the nervous system. Bitter, sweet and umami stimuli utilize G-protein coupled receptors which activate the phospholipase C (PLC) signaling pathway in Type II taste cells. However, it is not known how these cells communicate with the nervous system. Previous studies have shown that the subset of taste cells that expresses the T2R bitter receptors lack voltage-gated Ca2+ channels, which are normally required for synaptic transmission at conventional synapses. Here we use two lines of transgenic mice expressing green fluorescent protein (GFP) from two taste-specific promoters to examine Ca2+ signaling in subsets of Type II cells: T1R3-GFP mice were used to identify sweet- and umami-sensitive taste cells, while TRPM5-GFP mice were used to identify all cells that utilize the PLC signaling pathway for transduction. Voltage-gated Ca2+ currents were assessed with Ca2+ imaging and whole cell recording, while immunocytochemistry was used to detect expression of SNAP-25, a presynaptic SNARE protein that is associated with conventional synapses in taste cells.
Depolarization with high K+ resulted in an increase in intracellular Ca2+ in a small subset of non-GFP labeled cells of both transgenic mouse lines. In contrast, no depolarization-evoked Ca2+ responses were observed in GFP-expressing taste cells of either genotype, but GFP-labeled cells responded to the PLC activator m-3M3FBS, suggesting that these cells were viable. Whole cell recording indicated that the GFP-labeled cells of both genotypes had small voltage-dependent Na+ and K+ currents, but no evidence of Ca2+ currents. A subset of non-GFP labeled taste cells exhibited large voltage-dependent Na+ and K+ currents and a high threshold voltage-gated Ca2+ current. Immunocytochemistry indicated that SNAP-25 was expressed in a separate population of taste cells from those expressing T1R3 or TRPM5. These data indicate that G protein-coupled taste receptors and conventional synaptic signaling mechanisms are expressed in separate populations of taste cells.
The taste receptor cells responsible for the transduction of bitter, sweet, and umami stimuli are unlikely to communicate with nerve fibers by using conventional chemical synapses.
味觉受体细胞负责转导来自环境的化学刺激,并将信息传递给神经系统。苦味、甜味和鲜味刺激利用G蛋白偶联受体,这些受体在II型味觉细胞中激活磷脂酶C(PLC)信号通路。然而,尚不清楚这些细胞如何与神经系统进行通信。先前的研究表明,表达T2R苦味受体的味觉细胞亚群缺乏电压门控Ca2+通道,而在传统突触处进行突触传递通常需要这些通道。在此,我们使用从两个味觉特异性启动子表达绿色荧光蛋白(GFP)的两系转基因小鼠,来检测II型细胞亚群中的Ca2+信号:T1R3-GFP小鼠用于鉴定对甜味和鲜味敏感的味觉细胞,而TRPM5-GFP小鼠用于鉴定所有利用PLC信号通路进行转导的细胞。通过Ca2+成像和全细胞记录评估电压门控Ca2+电流,同时使用免疫细胞化学检测SNAP-25的表达,SNAP-25是一种突触前SNARE蛋白,与味觉细胞中的传统突触相关。
用高K+进行去极化导致两种转基因小鼠品系的一小部分非GFP标记细胞内的Ca2+增加。相比之下,在任何一种基因型的表达GFP的味觉细胞中均未观察到去极化诱发的Ca2+反应,但GFP标记的细胞对PLC激活剂m-3M3FBS有反应,表明这些细胞是有活力的。全细胞记录表明,两种基因型的GFP标记细胞具有小的电压依赖性Na+和K+电流,但没有Ca2+电流的证据。一部分非GFP标记的味觉细胞表现出大的电压依赖性Na+和K+电流以及高阈值电压门控Ca2+电流。免疫细胞化学表明,SNAP-25在与表达T1R3或TRPM5的细胞不同的另一群味觉细胞中表达。这些数据表明,G蛋白偶联味觉受体和传统突触信号传导机制在不同的味觉细胞群中表达。
负责转导苦味、甜味和鲜味刺激的味觉受体细胞不太可能通过使用传统化学突触与神经纤维进行通信。
Zotero 插件
