In vivo investigation of homocysteine metabolism to polyamines by high-resolution accurate mass spectrometry and stable isotope labeling.

Polyamines are essential polycations, playing important roles in mammalian physiology. Theoretically, the involvement of homocysteine in polyamine synthesis via S-adenosylmethionine is possible; however, to our knowledge, it has not been established experimentally. Here, we propose an original approach for investigation of homocysteine metabolites in an animal model. The method is based on the combination of isotope-labeled homocysteine supplementation and high-resolution accurate mass spectrometry analysis. Structural identity of the isotope-labeled metabolites was confirmed by accurate mass measurements of molecular and fragment ions and comparison of the retention times and tandem mass spectrometry fragmentation patterns. Isotope-labeled methionine, spermidine, and spermine were detected in all investigated plasma and tissue samples. The induction of moderate hyperhomocysteinemia leads to an alteration in polyamine levels in a different manner. The involvement of homocysteine in polyamine synthesis and modulation of polyamine levels could contribute to a better understanding of the mechanisms connected with homocysteine toxicity.

Interaction of endothelin with renal nerves modulates kidney function in spontaneously hypertensive rats.

BACKGROUND AND METHODS: We investigated kidney function, renal endothelin-1 concentration, prepro-endothelin-1 mRNA as well as endothelin receptor A and B mRNA expression and receptor properties in normotensive Wistar-Kyoto (WKY) rats and spontaneously hypertensive rats (SHR) with intact renal nerves and 7 days after renal denervation. In addition, responses of renal function to the non-selective ETA/ETB receptor blocker bosentan (10 mg/kg i.v. bolus injection) were studied. RESULTS: In SHR, renal papillary prepro-endothelin-1 mRNA expression, endothelin-1 tissue concentrations and endothelin receptor density were significantly lower than in normotensive rats. Renal denervation was associated with a decrease in papillary tissue prepro-endothelin-1 mRNA and in WKY rats also with a significant reduction in papillary endothelin-1 content without affecting ET receptor density. Bosentan did not alter renal blood flow or glomerular filtration rate but decreased urine flow rate in both intact normotensive and hypertensive rats, whereas it decreased urine sodium and potassium excretion only in intact WKY. Bosentan had no effects on renal function in renal denervated rats. CONCLUSION: Since renal papillary endothelin-1 appears to counteract the fluid and sodium retaining effects of renal nerve activity, an impaired renal endothelin-1 synthesis in SHR may contribute to excessive sodium retention and thus to the pathogenesis of hypertension in SHR.

Impaired response of the denervated kidney to endothelin receptor blockade in normotensive and spontaneously hypertensive rats.

BACKGROUND: As yet, there are only limited data available on the exact role of endothelin (ET) acting through endothelin-A (ETA) receptors in renal sodium and water regulation and the potential functional implications of an interaction of the renal ET system with renal nerves in normotensive and spontaneously hypertensive rats. METHODS: Experiments were carried out in 64 male conscious spontaneously hypertensive rats and in 56 normotensive Wistar-Kyoto (WKY) rats. Bilateral renal denervation (BRD) was performed in 32 spontaneously hypertensive rats and 28 WKY rats 7 days before the experiments. The ETA receptor antagonist, BQ-123 (16.4 nmol/kg x min intravenously) or the endothelin-B (ETB) receptor antagonist, BQ-788 (25 nmol/kg x min intravenously) were infused at a rate of 25 microL/min for 50 minutes. RESULTS: Renal papillary ET-1 concentration in intact spontaneously hypertensive rats was 67.8% lower than in intact WKY rats (154 +/- 40 fmol/mg protein vs. 478 +/- 62 fmol/mg protein, P < 0.01). BRD decreased papillary ET-1 by 73.5% in WKY rats to 127 +/- 19 fmol/mg protein (P < 0.001), but had no effect in spontaneously hypertensive rats (122 +/- 37 fmol/mg protein). BRD, BQ-123, or BQ-788 did not affect glomerular filtration rate (GFR) or renal blood flow (RBF) in any of the groups. In intact WKY, BQ-123 decreased urine flow rate (V) from 4.65 +/- 0.44 microL/min.100 g body weight to 2.44 +/- 0.35 microL/min.100 g body weight (P < 0.01), urinary excretion of sodium (UNaV) from 238.2 +/- 27.4 to 100.2 +/- 17.0 (P < 0.01) and potassium (UKV) from 532.1 +/- 62.6 nmol/min.100 g body weight to 243.0 +/- 34.2 nmol/min.100 g body weight (P < 0.001), whereas BQ-788 decreased only V and UNaV. In renal denervated WKY, BQ-123 or BQ-788 did not alter V, UNaV, or UKV. In intact spontaneously hypertensive rats BQ-123 but not BQ-788 decreased V from 3.94 +/- 0.48 microL/min.100 g body weight to 2.55 +/- 0.44 microL/min.100 g body weight (P < 0.05). In renal denervated spontaneously hypertensive rats neither BQ-123 nor BQ-788 affected V, UNaV, or UKV. CONCLUSION: An interaction between ET and renal nerves is involved in the control of renal function. Moreover, renal nerves participate in the regulation of ET-1 production within the kidney. Finally, decreased synthesis of ET-1 in the renal papilla of spontaneously hypertensive rats may contribute to development and/or maintenance of hypertension due to modulation of renal excretory function.

Renal and cardiovascular effects of renal denervation in conscious rats after adenosine administration and nitric oxide synthase inhibition.

The role of renal nerves on renal and cardiovascular responses to adenosine administration and/or acute NO synthase inhibition was investigated. Conscious male Wistar rats with implanted catheters in femoral artery for blood pressure registration, femoral vein for drug infusion and bladder for urine collection were used. Adenosine was applied i.v. (1.0 mg/kg BW bolus) followed by infusion of 0.1 mg/kg.min, and/or nitric oxide synthase inhibition (NOSI) was performed by i.v. administration of 10 mg/kg BW N-Omega-nitro-L-arginine methyl ester (L-NAME) before and 1 week after bilateral renal denervation (BRD). NOSI decreased HR and increased SAP, MAP and DAP both in intact and BRD rats. Baroreflex sensitivity increased in intact and BRD rats. Adenosine did not change HR, blood pressure or baroreflex sensitivity in intact as well as BRD rats. NOSI increased V, VU(Na) and VU(CI) in intact rats but decreased V and did not alter VU(Na) and VU(CI) in BRD rats. Adenosine increased V, VU(CI) and C(cr) in intact rats but did not change renal excretory function in BRD rats. Combined application of adenosine and L-NAME led to a dramatic increase of V, VU(Na), VU(Cl) and C(cr) in intact rats. However, VU(Na) and VU(CI) in BRD rats were lower as compared to intact rats. Therefore, changes in renal excretory function seen after NOSI are not exclusively the result of pressure diuresis and natriuresis but in some way are dependent on renal nerves. Renal denervation attenuates the renal excretory response to adenosine. Sympathetic nervous system is important in mediating the effects of adenosine and/or NO on renal excretory function. Renal denervation did not change the pattern of baroreflex sensitivity after adenosine and/or L-NAME administration.