Guan Chenyang, Ryu Seungjin, Dong Mingze, Youm Yun-Hee, Mohanty Subhasis, Maeda Rae, Orliaguet Lucie, Kim Hee-Hoon, Dlugos Tamara, Smith Steven R, Ravussin Eric, Onyuru Janset, Wang Andrew, Shaw Albert C, Hoffman Hal M, Kluger Yuval, Sugiura Yuki, Dixit Vishwa Deep
Department of Pathology, Yale School of Medicine.
Department of Immunobiology Yale School of Medicine.
bioRxiv. 2025 May 31:2025.05.27.656381. doi: 10.1101/2025.05.27.656381.
Taurine, the most abundant sulfonic amino acid in humans is largely obtained from diets rich in animal proteins. However, taurine is dietary non-essential because it can be synthesized from cysteine by activation of transsulfuration pathway (TSP) when food consumption is low or if the diet is predominantly plant based. The decline of taurine was proposed as the driver of aging through an undefined mechanism. Here, we found that mild food restriction in humans for one year that resulted in 14% reduction of calorie intake elevated the hypotaurine and taurine concentration in adipose tissue. Therefore, we investigated whether elevated taurine mimics caloric-restriction's beneficial effects on inflammation, a key mechanism of aging. Interestingly, aging increased the circulating and tissue concentrations of taurine suggesting that elevated taurine may serve as a hormetic stress response metabolite that regulates mechanism of age-related inflammation. The elevated taurine protected mice against mortality from sepsis and inhibited inflammasome-driven inflammation and gasdermin-D (GSDMD) mediated pyroptosis. Mechanistically, 'danger signals' including hypotonicity that activate NLRP3-inflammasome, caused upstream taurine efflux from macrophages, which triggered potassium (K) release and downstream canonical NLRP3 inflammasome assembly, caspase-1 activation, GSDMD cleavage and IL-1β and IL-18 secretion that was reversed by taurine restoration. Notably, taurine does not efflux from GSDMD pore and inhibited IL-1β from macrophages independently of known transporters SLC6A6 and SLC36A1. Increased taurine in old mice promotes healthspan by inducing anti-inflammatory pathways previously linked to youthfulness. These findings demonstrate that taurine is an upstream metabolic sensor of cellular perturbations that control NLRP3 inflammasome and lowers age-related inflammation.
牛磺酸是人体内含量最丰富的磺酸氨基酸,主要从富含动物蛋白的饮食中获取。然而,牛磺酸并非饮食必需氨基酸,因为当食物摄入量低或饮食以植物性为主时,它可通过转硫途径(TSP)的激活由半胱氨酸合成。有人提出牛磺酸水平下降是衰老的驱动因素,但其机制尚不明确。在此,我们发现人类进行为期一年的轻度食物限制,导致卡路里摄入量减少14%,这使脂肪组织中的次牛磺酸和牛磺酸浓度升高。因此,我们研究了牛磺酸水平升高是否能模拟热量限制对炎症的有益作用,炎症是衰老的关键机制。有趣的是,衰老会增加牛磺酸的循环和组织浓度,这表明升高的牛磺酸可能作为一种适应性应激反应代谢产物,调节与年龄相关的炎症机制。升高的牛磺酸可保护小鼠免受败血症致死,并抑制炎性小体驱动的炎症以及gasdermin-D(GSDMD)介导的细胞焦亡。从机制上讲,包括低渗在内的“危险信号”激活NLRP3炎性小体,导致巨噬细胞上游牛磺酸外流,进而引发钾离子(K)释放以及下游经典NLRP3炎性小体组装、半胱天冬酶-1激活、GSDMD裂解以及白细胞介素-1β和白细胞介素-18分泌,而牛磺酸恢复可逆转这一过程。值得注意的是,牛磺酸不会从GSDMD孔道外流,并且独立于已知转运体SLC6A6和SLC36A1抑制巨噬细胞分泌白细胞介素-1β。老年小鼠体内牛磺酸增加,通过诱导先前与年轻化相关的抗炎途径来促进健康寿命。这些发现表明,牛磺酸是细胞扰动的上游代谢传感器,可控制NLRP3炎性小体并减轻与年龄相关的炎症。
