Bilateral renal denervation does not prevent the kidney damage caused by a high fat diet in rats

Abstract

One of the hallmarks of the metabolic syndrome (MS) is the increase of renal sympathetic nerve activity (RSNA), which leads to the upregulation of the renin‐angiotensin system (RAS). Interestingly, the sympathetic hyperactivity in the kidney of obese humans often occurs in absence of overt systemic hypertension. The stimulation of RSNA contributes to the glomerular lesions and the progressive loss of nephron functionality, resulting in acute renal injury (AKI) and, in the long term, chronic kidney disease (CKD), which represent the most common complication of MS. Clinical evidence and animal models of MS have shown that renal sympathetic denervation (RSDN) induces a transient attenuation of the hypertensive symptoms, while the markers of kidney damage continue worsening. Therefore, it is likely that the renal derangement in MS might also depend on the metabolic impairment, such as the upregulation of plasma leptin and insulin, independently from the RSNA. To investigate this issue, we explored the effect of MS over blood pressure and kidney functionality, in intact and renal denervated rats. For that, animals were either fed with a standard diet (SD) or a high‐fat diet for 12 weeks (HFD), with or without bilateral renal denervation performed at the beginning of protocol (n = 6). Results indicate that, as expected, HFD in intact animals promotes fat accumulation, glucose intolerance and hypertension, but also decreases water consumption and induces marked proteinuria from week 7, slight hematuria from week 9, with respect to SD rats. Remarkably, the renal denervation prevents the changes that HFD triggered in blood pressure and renal parameters only in the short and medium term, but it is ineffective in the long term. On the bases of these results, we suggest that the hypertension associated to MS is not only due to hyperactivation of RSNA, but it could involve hormonal/hemodynamic factors, typical of metabolic impairment, which could contribute to renal injury.Support or Funding InformationCONACYT‐CB‐243298This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.