PT  - JOURNAL ARTICLE
AU  - Bugarski, Milica
AU  - Ghazi, Susan
AU  - Polesel, Marcello
AU  - Martins, Joana R.
AU  - Hall, Andrew M.
TI  - Changes in NAD and Lipid Metabolism Drive Acidosis-Induced Acute Kidney Injury
AID  - 10.1681/ASN.2020071003
DP  - 2021 Feb 01
TA  - Journal of the American Society of Nephrology
PG  - 342--356
VI  - 32
IP  - 2
4099  - http://jasn.asnjournals.org/content/32/2/342.short
4100  - http://jasn.asnjournals.org/content/32/2/342.full
SO  - J. Am. Soc. Nephrol.2021 Feb 01; 32
AB  - Clinical studies have suggested that metabolic acidosis (MA) aggravates tubular damage in patients with both AKI and CKD, but the mechanisms were unknown. Intravital live cell imaging and other complementary techniques demonstrated in the mouse kidney that MA induces acute changes in the mitochondrial NAD redox state, respiratory chain function, and lipid metabolism, which collectively lead to tubular cell damage. Intravenous injection of bicarbonate increases blood pH and improves tubular function, whereas pretreatment with an NAD precursor is highly protective. Thus, changes in cell metabolism explain the harmful effects of MA on kidney tubules, which therapeutic strategies that are viable in humans can substantially ameliorate.Background The kidney plays an important role in maintaining normal blood pH. Metabolic acidosis (MA) upregulates the pathway that mitochondria in the proximal tubule (PT) use to produce ammonia and bicarbonate from glutamine, and is associated with AKI. However, the extent to which MA causes AKI, and thus whether treating MA would be beneficial, is unclear.Methods Gavage with ammonium chloride induced acute MA. Multiphoton imaging of mitochondria (NADH/membrane potential) and transport function (dextran/albumin uptake), oxygen consumption rate (OCR) measurements in isolated tubules, histologic analysis, and electron microscopy in fixed tissue, and urinary biomarkers (KIM-1/clara cell 16) assessed tubular cell structure and function in mouse kidney cortex.Results MA induces an acute change in NAD redox state (toward oxidation) in PT mitochondria, without changing the mitochondrial energization state. This change is associated with a switch toward complex I activity and decreased maximal OCR, and a major alteration in normal lipid metabolism, resulting in marked lipid accumulation in PTs and the formation of large multilamellar bodies. These changes, in turn, lead to acute tubular damage and a severe defect in solute uptake. Increasing blood pH with intravenous bicarbonate substantially improves tubular function, whereas preinjection with the NAD precursor nicotinamide (NAM) is highly protective.Conclusions MA induces AKI via changes in PT NAD and lipid metabolism, which can be reversed or prevented by treatment strategies that are viable in humans. These findings might also help to explain why MA accelerates decline in function in CKD.