Resumen:
One of the hallmarks of metabolic syndrome is the increased renal sympathetic nerve
activity, which contributes to hypertension and leads to chronic kidney disease. Clinical
evidence and animal models of this condition have shown that renal sympathetic
denervation transiently attenuates hypertension while renal injury worsens. Leptin and
insulin resistance and other alterations of energy homeostasis play a role in metabolic
syndrome's cardiovascular and renal complications. To investigate this issue, we
compared the metabolic, cardiovascular, and renal health of male rats that underwent
bilateral renal denervation and were fed either with a standard or a high-fat diet for 8 and
12 weeks. The results indicate that the animals fed with hypercaloric diet does not affect
the amount of noradrenaline in the kidneys but display increased blood pressure and
plasma levels of angiotensin II, proteinuria, decreased glomerular filtration rate, urinary
flow, and potassium excretion independently from the surgery. Nevertheless, bilateral
renal denervation attenuates the ketonuria observed in intact, high-fat diet-fed rats. The
comparison of intracellular proteins in the kidney, downstream of angiotensin II, leptin,
and insulin signaling (AKT, PI3K, and ERK1/2) in the kidney showed a combined effect
of the renal sympathetic input, the energy content of the diet and time, especially in the
long term. Based on of these results, we suggest that renal sympathetic nerve activity
plays a role in the early-intermediate stages of the metabolic syndrome. At the same
time, the effects of chronic, long-term exposure to the hypercaloric diet prevails on the
autonomic regulation of kidney homeostasis.