Hiroshi Nonoguchi

Polymerase chain reaction localization of constitutive nitric oxide synthase and soluble guanylate cyclase messenger RNAs in microdissected rat nephron segments.

Stimulation of the release of nitric oxide (NO) in the kidney has been shown to result in renal hemodynamic changes and natriuresis. NO is a potent stimulator of soluble guanylate cyclase, leading to an increase of cyclic GMP. The precise localization of NO synthase and soluble guanylate cyclase in the renal structure is not known. In this study, the microlocalization of mRNAs coding for constitutive NO synthase and soluble guanylate cyclase was carried out in the rat kidney, using an assay of reverse transcription and polymerase chain reaction in individual microdissected renal tubule segments along the nephron, glomeruli, vasa recta bundle, and arcuate arteries. A large signal for constitutive NO synthase was detected in inner medullary collecting duct. Small signals were detected in inner medullary thin limb, cortical collecting duct, outer medullary collecting duct, glomerulus, vasa recta, and arcuate artery. Soluble guanylate cyclase mRNA is expressed largely in glomerulus, proximal convoluted tubule, proximal straight tubule, and cortical collecting duct, and in small amounts in medullary thick ascending limb, inner medullary thin limb, outer medullary collecting duct, inner medullary collecting duct, and the vascular system. Our data demonstrate that NO can be produced locally in the kidney, and that soluble guanylate cyclase is widely distributed in glomerulus, renal tubules, and the vascular system.

Different localization of two types of endothelin receptor mRNA in microdissected rat nephron segments using reverse transcription and polymerase chain reaction assay.

Recent studies have revealed that endothelins (ETs) have at least two types of receptors. One receptor has high affinity to ET-1 and ET-2 and low affinity to ET-3 (A type). The other receptor binds almost equally to ET-1, ET-2, and ET-3 (B type). In this study, microlocalization of mRNA coding for the A-type and B-type ET receptors was carried out in the rat kidney using a reverse transcription and polymerase chain reaction assay of individual microdissected renal tubule segments along the nephron, glomeruli, vasa recta bundle, and arcuate arteries. Large signals for the B-type receptor polymerase chain reaction product were detected in the initial and terminal inner medullary collecting duct and the glomerulus, while small signals were found in the cortical collecting duct and outer medullary collecting duct, vasa recta bundle, and arcuate artery. In contrast, A-type receptor mRNA was detected only in the glomerulus, vasa recta bundle, and arcuate artery. Thus, the two ET receptor subtypes are distributed differently along the nephron. This suggests that the two types of receptors and ET families may affect kidney functioning in different ways.

Different localization and regulation of two types of vasopressin receptor messenger RNA in microdissected rat nephron segments using reverse transcription polymerase chain reaction.

Recent studies have revealed that arginine vasopressin (AVP) has at least two types of receptors in the kidney: V1a receptor and V2 receptor. In this study, microlocalization of mRNA coding for V1a and V2 receptors was carried out in the rat kidney using a reverse transcription and polymerase chain reaction. Large signals for V1a receptor PCR product were detected in the glomerulus, initial cortical collecting duct, cortical collecting duct, outer medullary collecting duct, inner medullary collecting duct, and arcuate artery. Small but detectable signals were found in proximal convoluted and straight tubules, inner medullary thin limbs, and medullary thick ascending limbs. Large signals for V2 receptor mRNA were detected in the cortical collecting duct, outer medullary collecting duct, and inner medullary collecting duct. Small signals for V2 receptor were found in the inner medullary thick limbs, medullary thick ascending limbs, and initial cortical collecting duct. Next, we investigated V1a and V2 receptor mRNA regulation in the dehydrated state. During a 72-h water restriction state, the plasma AVP level increased and V2 receptor mRNA decreased in collecting ducts. In contrast, V1a receptor mRNA did not change significantly. Thus, the two AVP receptor subtypes are distributed differently along the nephron, and these mRNAs are regulated differently in the dehydrated state.

Messenger RNA expression and synthesis of endothelin-1 along rat nephron segments.

The kidney both produces and responds to endothelin. We examined the production and the expression of mRNA of endothelin-1 (ET-1) in tubule suspensions and microdissected nephron segments. ET-1 production was measured by RIA using an ET-1-specific antibody. We applied the reverse transcription and polymerase chain reaction (PCR) technique to detect ET-1 mRNA along the nephron segments. Stimulation of ET-1 production was observed in the presence of FCS and transforming growth factor-beta (TGF-beta) in inner medullary tubules but not in cortical or outer medullary tubule suspensions. Among dissected nephron segments, ET-1 production was observed in glomeruli and inner medullary collecting ducts (IMCD), whereas it was negligible in proximal convoluted tubules (PCT) and medullary thick ascending limbs (MAL). In addition, the PCR product of ET-1 mRNA was also higher in glomeruli and IMCD, whereas it was undetectable in PCT and MAL. Furthermore, FCS and TGF-beta increased ET-1 mRNA in microdissected glomeruli and IMCD. These data clearly demonstrated that the production sites of ET-1 are glomeruli and IMCD among the nephron segments. ET-1 is an autocrine factor in these sites.

Effects of atrial natriuretic peptide and vasopressin on chloride transport in long- and short-looped medullary thick ascending limbs.

Recent studies have suggested a selective effect of atrial natriuretic peptide (ANP) in regulating NaCl reabsorption in juxtamedullary nephrons. We examined (a) functional differences between medullary thick ascending limbs from long and short loops of Henle (lMAL and sMAL, respectively) and (b) the interaction of ANP and arginine vasopressin (AVP) on Cl- transport (JCl) in these two segments. AVP-, glucagon-, and calcitonin-stimulated cAMP accumulation was higher in lMAL than in sMAL. 10(-10) M AVP increased JCl in lMAL but not in sMAL. ANP-stimulated cGMP production was higher in lMAL than in sMAL. 10(-10) and 10(-8) M ANP inhibited AVP-stimulated JCl in lMAL by 26-30% (from 70.3 +/- 11.4 to 51.7 +/- 13.6 pmol/mm per min and from 88.1 +/- 10.1 to 61.8 +/- 11.7 pmol/mm per min, respectively), and this effect was mimicked by 10(-5) to 10(-4) M cGMP. This effect of ANP in lMAL could account for a large part of the ANP-induced natriuresis and diuresis in vivo, in that the rate of NaCl reabsorption in MAL is the largest among distal nephron segments, providing the chemical potential energy for the renal countercurrent multiplication system.

Renal effects of alacepril in essential hypertension.

Summary: Short-term effects of alacepril, an angiotensin-converting enzyme inhibitor (ACEI), on renal function and hemodynamics were investigated in 10 hypertensive subjects (aged 55.7 ± 9.5 years, mean ± SD). Renal plasma flow (RPF) and glomerular filtration rate (GFR) were examined before and after 12-week administration of alacepril, by [131I]hippuran and [99mTc]DTPA, respectively. Alacepril (50 mg/day) caused a significant decrease in both systolic and diastolic blood pressure (SBP and DBP, from 161 ± 8 to 140 ± 10 mm Hg and from 100 ± 3 to 90 ± 5 mm Hg, respectively). Alacepril increased GFR (from 63.4 ± 22.2 to 69.1 ± 22.1 ml/min/1.73 m2, p < 0.05) without changing RPF (from 438 ± 194 to 432 ± 148 ml/ min/1.73 m2, p > 0.05). Serum creatinine and electrolytes were not changed by alacepril administration. These data show that short-term alacepril administration improves renal function, probably owing to relaxation of renal vasoconstriction