Metabolic Rewiring and Communication: An Integrative View of Kidney Proximal Tubule Function
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Metabolic Rewiring and Communication: An Integrative View of Kidney Proximal Tubule Function. / Chrysopoulou, Maria; Rinschen, Markus M.
In: ANNU REV PHYSIOL, Vol. 86, 12.02.2024, p. 405-427.Research output: SCORING: Contribution to journal › SCORING: Review article › Research
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TY - JOUR
T1 - Metabolic Rewiring and Communication: An Integrative View of Kidney Proximal Tubule Function
AU - Chrysopoulou, Maria
AU - Rinschen, Markus M
PY - 2024/2/12
Y1 - 2024/2/12
N2 - The kidney proximal tubule is a key organ for human metabolism. The kidney responds to stress with altered metabolite transformation and perturbed metabolic pathways, an ultimate cause for kidney disease. Here, we review the proximal tubule's metabolic function through an integrative view of transport, metabolism, and function, and embed it in the context of metabolome-wide data-driven research. Function (filtration, transport, secretion, and reabsorption), metabolite transformation, and metabolite signaling determine kidney metabolic rewiring in disease. Energy metabolism and substrates for key metabolic pathways are orchestrated by metabolite sensors. Given the importance of renal function for the inner milieu, we also review metabolic communication routes with other organs. Exciting research opportunities exist to understand metabolic perturbation of kidney and proximal tubule function, for example, in hypertension-associated kidney disease. We argue that, based on the integrative view outlined here, kidney diseases without genetic cause should be approached scientifically as metabolic diseases.
AB - The kidney proximal tubule is a key organ for human metabolism. The kidney responds to stress with altered metabolite transformation and perturbed metabolic pathways, an ultimate cause for kidney disease. Here, we review the proximal tubule's metabolic function through an integrative view of transport, metabolism, and function, and embed it in the context of metabolome-wide data-driven research. Function (filtration, transport, secretion, and reabsorption), metabolite transformation, and metabolite signaling determine kidney metabolic rewiring in disease. Energy metabolism and substrates for key metabolic pathways are orchestrated by metabolite sensors. Given the importance of renal function for the inner milieu, we also review metabolic communication routes with other organs. Exciting research opportunities exist to understand metabolic perturbation of kidney and proximal tubule function, for example, in hypertension-associated kidney disease. We argue that, based on the integrative view outlined here, kidney diseases without genetic cause should be approached scientifically as metabolic diseases.
U2 - 10.1146/annurev-physiol-042222-024724
DO - 10.1146/annurev-physiol-042222-024724
M3 - SCORING: Review article
C2 - 38012048
VL - 86
SP - 405
EP - 427
JO - ANNU REV PHYSIOL
JF - ANNU REV PHYSIOL
SN - 0066-4278
ER -