神经科学
食欲
生物
机制(生物学)
钠
灵活性(工程)
人口
盐(化学)
适应性反应
适应(眼睛)
细胞生物学
内分泌学
内科学
钠通道
化学
受体
中枢神经系统
基因沉默
刺激
神经元
神经可塑性
胰岛素
生物物理学
吸引力
突触后电位
细胞外
平衡
突触可塑性
神经调节
神经传递
作者
Sonali Puri,Jiun Sang,Prakash Pandey,Youngseok Lee
标识
DOI:10.1073/pnas.2530544123
摘要
Salt intake must be tightly regulated: Too little compromises physiological function, while too much is harmful. Animals therefore display an adaptive salt appetite, dynamically switching between attraction and avoidance depending on internal sodium status. Although this behavioral flexibility is well documented, the central brain mechanisms that link internal salt need to changes in sensory-driven behavior remain poorly understood. Here, we identify a brain-centered neuroendocrine circuit that enables adaptive regulation of salt appetite in Drosophila melanogaster . Using targeted genetic screens, we show that leucokinin ( Lk ), its receptor ( Lkr ), and the insulin-like peptide Ilp2 are essential for shifting salt preference according to sodium deprivation. Under salt-sated conditions, high salt remains aversive. In contrast, salt-deprivation selectively activates Lk neurons in the anterior leucokinin (ALK) region, which in turn recruit Lkr -expressing insulin-producing cells (IPCs), also referred to as medial neurosecretory cells, to promote salt-seeking behavior. Functional imaging and circuit manipulation demonstrate that silencing either neuronal population abolishes this adaptive switch, whereas pathway activation overrides innate salt aversion through PKA-dependent signaling. Notably, both ALK neurons and IPCs directly detect extracellular sodium independent of synaptic input, identifying them as central sodium sensors that couple internal state to behavioral output. Together, our findings define a neuroendocrine mechanism by which the brain adaptively recalibrates salt appetite to maintain internal homeostasis. This work provides a conceptual framework for state-dependent nutrient seeking and suggests conserved principles relevant to salt balance disorders in mammals.
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