Expression and distribution of genes encoding for polyamine-metabolizing enzymes in the different zones of male and female mouse kidneys

The role of polyamines in renal physiology is only partially understood. Moreover, most of the data on the enzymes of polyamine metabolism come from studies using whole kidneys. The aim of the present study was to analyze the mRNA abundance of the genes implicated in both the polyamine biosynthetic and catabolic pathways in different renal zones of male and female mice, by means of the quantitative reverse transcription-polymerase chain reaction. Our results indicate that there is an uneven distribution of the different mRNAs studied in the five renal zones: superficial cortex, deep cortex, outer stripe of the outer medulla (OS), inner stripe of the outer medulla (IS), and the inner medulla + papilla (IM). The biosynthetic genes, ornithine decarboxylase (ODC) and spermine synthase, were more expressed in the cortex, whereas the mRNAs of the catabolic genes spermine oxidase (SMO) and diamine oxidase were more abundant in IS and IM. The genes involved in the regulation of polyamine synthesis (AZ1, AZ2 and AZIN1) were expressed in all the renal zones, predominantly in the cortex, while AZIN2 gene was more abundant in the OS. ODC, SMO, spermidine synthase and spermidine/spermine acetyl transferase expression was higher in males than in females. In conclusion, the genes encoding for the polyamine metabolism were specifically and quantitatively distributed along the corticopapillary axis of male and female mouse kidneys, suggesting that their physiological role is essential in defined renal zones and/or nephron segments.

Macrophage plasticity in experimental atherosclerosis

As in human disease, macrophages (MØ) are central players in the development and progression of experimental atherosclerosis. In this study we have evaluated the phenotype of MØ associated with progression of atherosclerosis in the apolipoprotein E (ApoE) knockout (KO) mouse model.

We found that bone marrow-derived MØ submitted to M1 and M2 polarization specifically expressed arginase (Arg) II and Arg I, respectively. This distinct arginase expression was used to evaluate the frequency and distribution of M1 and M2 MØ in cross-sections of atherosclerotic plaques of ApoE KO mice. Early lesions were infiltrated by Arg I⁺ (M2) MØ. This type of MØ favored the proliferation of smooth muscle cells, in vitro. Arg II⁺ (M1) MØ appeared and prevailed in lesions of aged ApoE KO mice and lesion progression was correlated with the dominance of M1 over the M2 MØ phenotype. In order to address whether the M2->M1 switch could be due to a phenotypic switch of the infiltrated cells, we performed in vitro repolarization experiments. We found that fully polarized MØ retained their plasticity since they could revert their phenotype. The analysis of the distribution of Arg I- and Arg II-expressing MØ also argued against a recent recruitment of M1 MØ in the lesion. The combined data therefore suggest that the M2->M1 switch observed in vivo is due to a conversion of cells already present in the lesion. Our study suggests that interventional tools able to revert the MØ infiltrate towards the M2 phenotype may exert an atheroprotective action.

Accumulation of methylguanidine and changes in guanidino compound levels in plasma, urine, and kidneys of furosemide-treated rats

Antidiuresis and renal diseases alter the levels of guanidino compounds (GCs) in various tissues. Therefore, we hypothesized that diuresis could also disturb GC metabolism, storage, and elimination. In this study, rats were made diuretic to analyze GC levels in plasma, urine, and kidneys. Furosemide was chosen because of its wide use in various human pathologies. Rats were injected intraperitoneally 5 or 10 mg furosemide spread over a 24-hour cycle. Urine was collected over a period of 24 hours before and during furosemide treatment. Plasma was obtained from arterial blood. Renal zones were dissected. The GCs were determined by liquid chromatography. Five milligrams of furosemide provoked a significant increase in plasma and urine levels of GCs compared with those of the controls. The renal distribution and content of GCs were weakly modified by furosemide except for methylguanidine (MG). The level of MG was enhanced by 10 to 16 times in all renal zones. The MG level was 60% higher in renal zones of rats treated with 10 rather than 5 mg furosemide. The fractional excretion of MG was decreased by furosemide. Our data suggest that MG accumulation in kidney and plasma was caused by furosemide, which might induce MG synthesis, and that MG washout from tissue cells into urine by furosemide through the kidney may cause an increase in MG in the kidney.

L-arginine metabolism in dog kidney and isolated nephron segments

The renal basic amino acid metabolism often differs in rodents, strict carnivores, and omnivore species. Given the pivotal role of L-arginine and L-ornithine in several metabolic pathways and the fact that the dog is closely related to humans, being also an omnivore, we tested whether L-arginine metabolism and L-ornithine catabolism take place in the dog kidney. We examined the metabolism of L-arginine in dog cortical tubules to integrate local L-arginine metabolism into a general physiological and metabolic framework. To achieve these goals, we first ascertained the protein expression of relevant enzymes by Western blot. L-Arginine catabolism was studied in suspensions of canine cortical proximal tubules, medullary thick ascending limbs, and papillary collecting ducts either incubated without exogenous L-arginine being added (small endogenous quantities) or incubated with L-arginine being added in supraphysiological amounts (2 mmol/L with or without the presence of alternative metabolic substrates, 2 mmol/L L-glutamine, or lactate). The results revealed that dog kidneys consumed L-citrulline and released L-arginine and L-ornithine. Argininosuccinate synthetase and lyase, arginase II, and ornithine aminotransferase were detected in the renal cortex. Arginase II activity was found in a suspension of proximal tubules by measuring the amounts of urea and L-ornithine produced. A fraction of this L-ornithine was further partially metabolized through the intramitochondrial ornithine aminotransferase pathway, leading to changes in L-glutamate, glucose, L-alanine, and ammonia metabolism without L-proline accumulation. Medullary thick ascending limbs expressed a very low arginase activity, whereas papillary collecting ducts did not. In conclusion, the dog kidney produces L-arginine. Part of this L-arginine is further catabolized by arginase II, suggesting that its physiological role was to produce L-ornithine for the body.

Sex-differential expression of ornithine aminotransferase in the mouse kidney

The mouse kidney expresses the gene of ornithine aminotransferase (Oat). Previous works suggest that Oat is differentially expressed in female and male mouse kidney (Alonso E, Rubio V. Biochem J 259: 131-138, 1989; Levillain O, Diaz JJ, Blanchard O, Dechaud H. Endocrinology 146: 950-959, 2005; Manteuffel-Cymborowska M, Chmurzynska W, Peska M, Grzelakowska-Sztabert B. Int J Biochem Cell Biol 27: 287-295, 1995; Natesan S, Reddy SR. Comp Biochem Physiol B Biochem Mol Biol 130: 585-595, 2001; Yu H, Yoo PK, Aguirre CC, Tsoa RW, Kern RM, Grody WW, Cederbaum SD, Iyer RK. J Histochem Cytochem 51: 1151-1160, 2003). This study was designed to provide a detailed description of the sexual dimorphism of Oat expression in the mouse kidney and to test the influence of sex hormones on its regulation. Experiments were performed on male and female Swiss OF1 mice during their postnatal development, at adulthood, and in orchidectomized and ovariectomized mice. Kidneys, dissected renal zones, and mitochondria were used to analyze OAT mRNA and protein levels and measure OAT activity. The results revealed that before puberty, Oat expression was similar between female and male kidneys whereas from puberty until adulthood Oat expression increased in the female kidney, becoming approximately 2.5-fold higher than in the male kidney. This sex-differential expression of Oat was associated with a sex-specific distribution of Oat along the corticopapillary axis and within the nephron. OAT was three- to fourfold more expressed in the female than the male cortex. In males, Oat was highly expressed in the medulla, mainly in the thick ascending limbs. Renal Oat distribution in orchidectomized mice resembled that in the females. Ovariectomy did not influence Oat expression. Sex differences are explained by the physiological increase in plasma testosterone in males. Expression of medium-chain acyl-CoA synthetase protein confirmed this finding. We report sexual dimorphism of Oat expression in the mouse kidney and show that Oat is naturally downregulated in the presence of testosterone.

Mitochondrial expression of arginase II in male and female rat inner medullary collecting ducts

Microdissected rat proximal straight tubules (PST) and inner medullary collecting ducts (IMCD) highly produce urea from l-arginine, supporting the expression of the mitochondrial arginase II. However, IMCD contain a very low density of mitochondria compared with PST. Recently, arginase II has been localized by immunohistochemistry in rat PST but not IMCD. This study was designed to verify whether rat IMCD express arginase II and to identify its subcellular localization. We developed an antibody raised against arginase II that allowed the detection of a band of 38 kDa corresponding to arginase II on immunoblots. In male and female rat kidneys, Western blot analyses revealed that arginase II was highly expressed in the inner medulla (IM), the outer stripe of the outer medulla (osOM), and the deep cortex. Immunocytochemistry demonstrated that arginase II was homogeneously expressed in IMCD. Proteins of the cytosolic and mitochondrial fractions extracted from osOM and IM and analyzed by Western blot showed that 86% of arginase II was associated with mitochondria. The molecular weight of arginase II was similar in the cytosolic and mitochondrial fractions. Immunoelectron microscopy confirmed the presence of arginase II in the mitochondria of IMCD. In conclusion, arginase II is expressed in mitochondria of male and female rat IMCD.

S-adenosyl methionine decarboxylase activity is required for the outcome of herpes simplex virus type 1 infection and represents a new potential therapeutic target

All the available antiherpetic drugs are directed against viral proteins. Their extensive clinical use has led to the emergence of resistant viral strains. There is a need for the treatment of herpes infections due to resistant strains, especially for immunocompromised patients. To design new kinds of drugs, we have developed a strategy to identify cellular targets. Herpes simplex virus type 1 (HSV-1) infection is concomitant to a repression of most host protein synthesis. However, some cellular proteins continue to be efficiently synthesized. We speculated that some of them could determine the outcome of infection. Since two polyamines, spermidine and spermine, are components of the HSV-1 virions, we investigated whether enzymes involved in their synthesis could be required for viral infection. We show that inhibition of S-adenosyl methionine decarboxylase, a key enzyme of the polyamine metabolic pathway, prevents HSV-1 infection. Inhibition of polyamine synthesis prevents infection of culture cells with HSV-1 laboratory strains as well as clinical isolates that are resistant to the conventional antiviral drugs acyclovir and foscarnet. Our data provide the opportunity to develop molecules with a novel mechanism of action for the treatment of herpes infection.

Testosterone down-regulates ornithine aminotransferase gene and up-regulates arginase II and ornithine decarboxylase genes for polyamines synthesis in the murine kidney

The enzymes ornithine aminotransferase (OAT) and ornithine decarboxylase (ODC) share L-ornithine as a common substrate and arginase II produces this amino acid. In the murine kidney, testosterone induced ODC gene expression and polyamine production, but it is unknown how OAT gene is expressed under androgen treatment. These experiments were designed to study the influence of testosterone on the renal expression of OAT gene. Pharmacological and physiological doses of testosterone were injected into female and castrated male mice. Total RNA and soluble proteins extracted from whole kidneys were analyzed by Northern and Western blots, respectively. The results clearly indicate that pharmacological doses of testosterone simultaneously down-regulated the level of OAT protein and up-regulated the expression of arginase II and ODC genes. Variations of the levels of OAT protein and arginase II mRNA and protein were strongly correlated with testosteronemia. Orchidectomy increased the renal level of OAT protein and decreased that of ODC and arginase II. These effects were reversed by injecting a physiological dose of testosterone into castrated male mice. In conclusion, OAT and ODC genes are inversely regulated by testosterone in the mouse kidney. Consequently, in kidneys of testosterone-treated mice, L-arginine-derived ornithine produced by arginase II might be preferentially used by ODC for putrescine production rather than by OAT. This metabolic fate of L-ornithine was facilitated by decreasing OAT gene expression. In contrast, in female and castrated male mice devoided of testosterone, OAT gene is highly expressed and L-ornithine is converted into L-glutamate.

Localization and differential expression of arginase II in the kidney of male and female mice

Arginase II (AII) has been almost exclusively studied in male mammalian kidneys. Our investigations were conducted to localize AII gene expression in the female mouse kidney, and to analyze the differential expression of AII gene at the transcriptional and translational levels in the kidneys of female and male mice. Total RNAs and soluble proteins extracted from renal zones and whole kidneys were analyzed by Northern and Western blots, respectively. Mitochondrial and cytosolic proteins were analyzed by Western blot. L-[guanidino-14C]arginine hydrolysis by AII was detected in microdissected tubules and the 14CO2 released from [14C]urea hydrolysis was quantified. The results of these experiments showed that: (1) both AII mRNA and protein were highly expressed in the deep cortex and the outer stripe of the outer medulla, (2) urea was produced mainly in the proximal straight tubules (PST), (3) the 38-kDa AII protein was more abundant in the mitochondria than the cytosol, and (4) the renal content of AII mRNA and protein was about three-fold higher in female than in male mice. In conclusion, in both genders, AII gene expression is restricted to the PST and localized into mitochondria. AII gene is differentially expressed in the kidney of female and male mice since higher levels of AII mRNA, protein and activity were observed in the kidneys of the former than those of the latter. Renal AII gene expression was gender-dependent in mice but not in rats. Finally, in the PST of females, L-arginine-derived ornithine may be a precursor for the renal production of L -glutamate and L-glutamine because high levels of AII, ornithine aminotransferase and glutamine synthetase are expressed in this nephron segment.

Ornithine metabolism in male and female rat kidney: mitochondrial expression of ornithine aminotransferase and arginase II

In the kidney, l-ornithine is reabsorbed along the proximal convoluted tubule (PCT), transported by basolateral carriers, and produced by arginase II (AII). Here, the renal metabolic fate of l-ornithine was analyzed in male and female rats. Kidneys and renal zones were dissected and used for Western blot analysis, immunofluorescence, and electron microscopic studies. Ornithine aminotransferase (OAT) and AII were localized using specific antibodies. Ornithine oxidation was determined by incubating microdissected tubules with l-[1-14C] or l-[U-14C]ornithine in the presence or absence of energy-providing substrates. Ornithine decarboxylase (ODC) mRNAs were localized by in situ hybridization. The 48-kDa OAT protein was detected in male and female kidneys, but its level was fourfold higher in the latter. OAT relative distribution increased from the superficial cortex toward the outer medulla to reach its highest level. Almost all OAT protein was localized in cortical and medullary proximal straight tubules (CPST and OSPST, respectively). In proximal straight tubule (PST), AII protein distribution overlapped that of OAT. No gender difference in AII protein level was found. OAT and AII were colocalized within PST mitochondria. l-[1-14C]ornithine decarboxylation occurred in all tubules, but predominantly in proximal tubules. l-[1-14C]ornithine decarboxylation was enhanced when l-[1-14C]ornithine was given to tubules as the sole substrate. The use of l-[U-14C]ornithine demonstrated the complete oxidation of ornithine. In conclusion, the OAT gene was expressed more in female rat proximal tubules than in male. Because OAT and AII proteins overlapped in PST mitochondria, l-arginine-derived ornithine may be preferentially converted to l-glutamate, as proven by ornithine oxidation. However, the coexpression of ODC, glutamate decarboxylase, and glutamine synthetase in PST suggests that l-ornithine can also be metabolized to putrescine, GABA, and l-glutamine. The fate of l-ornithine may depend on the cellular context.

Influence of testosterone on regulation of ODC, antizyme, and N1-SSAT gene expression in mouse kidney

Polyamines are involved in the control of the cell cycle and cell growth. In murine kidney, testosterone enhances gene expression of ornithine decarboxylase (ODC), the first enzyme in polyamine biosynthesis. In this study, we document the time course effect of testosterone on 1) gene expression of ODC, antizyme 1 (AZ1), and spermidine/spermine-N1-acetyltransferase (N1-SSAT); 2) ODC activity in proximal convoluted tubules (PCT) and cortical proximal straight tubules (CPST); and 3) renal polyamine levels. Female mice were treated with testosterone for a period of 1, 2, 3, and 5 consecutive days. ODC gene expression was extremely low in kidneys of untreated female mice compared with that of males. Consequently, the renal putrescine level was sevenfold lower in females than in males, whereas spermidine and spermine levels did not differ between sexes. In female kidneys, testosterone treatment sharply increased ODC mRNA and protein levels as well as ODC activity. Testosterone increased the expression of ODC in PCT and CPST over different time courses, which suggests that ODC activity is differentially regulated in distinct tubules. The expression of AZ1 and N1-SSAT mRNA was similar in male and female mouse kidneys. Testosterone treatment enhanced AZ1 and N1-SSAT mRNA levels in a time-dependent manner by unknown molecular mechanisms. Putrescine and spermidine levels increased after testosterone treatment in female kidneys. Surprisingly, although ODC protein and activity were undetectable in female kidneys, the levels of AZ1 mRNA and protein were similar to those in males. Therefore, one may propose that ODC protein could be continuously degraded by AZ1 in female kidneys.

Dehydration modifies guanidino compound concentrations in the different zones of the rat kidney

Guanidino compounds (GCs) related to arginine (Arg) are unevenly distributed along the cortico-papillary axis of the rat kidney. Inasmuch as the concentration of alpha-keto-delta-guanidinovaleric acid (alpha-keto-delta-GVA), guanidinosuccinic acid (GSA), creatinine (CTN), gamma-guanidinobutyric acid (gamma-GBA) and methylguanidine (MG) increased steeply along the inner medulla in parallel to the urea and osmotic gradients, the question arose as to whether dehydration enhances their renal content and distribution. To examine this possibility, adult male rats were dehydrated by removing the drinking water for 24 or 48 h. The kidneys were sliced and cut in seven sections along the cortico-papillary axis. Twelve GCs were determined by liquid chromatography in each renal zone. Dehydration modified GC concentrations and regional distribution. The renal content of Arg, guanidine and MG was decreased while that of alpha-keto-delta-GVA, gamma-GBA, alpha- N-acetyl-arginine and homoarginine remained unchanged. In contrast, GSA, guanidinoacetic acid (GAA), creatine (CT), CTN and beta-guanidinopropionic acid (beta-GPA) concentrations were enhanced significantly in different renal zones after 24 and 48 h dehydration. In addition, the tissue level of GCs supplying energy, such as CT and beta-GPA, the precursor of CT (GAA) and its metabolite (CTN) were enhanced under dehydration. Arg and CT account for 80-90% of the GCs located in the renal cortex. Variations of some GC levels under dehydration may modify enzyme activities, renal metabolism and cell function.

Influence of 72% injury in one kidney on several organs involved in guanidino compound metabolism: a time course study

Arginine (Arg) produced from citrulline originates mostly from kidneys. Arg is involved in guanidino compound biosynthesis, which requires interorgan co-operation. In renal insufficiency, citrulline accumulates in the plasma in proportion to renal damage. Thus, disturbances in Arg and guanidino compound metabolism are expected in several tissues. An original use of the model of nephrectomy based on ligating branches of the renal artery allowed us to investigate Arg and guanidino compound metabolism simultaneously in injured (left) and healthy (right) kidneys. The left kidney of adult rats was subjected to 72% nephrectomy. Non-operated, sham-operated and nephrectomized rats were studied for a period of 21 days. Constant renal growth was observed only in the healthy kidneys. Guanidino compound levels were modified transiently during the first 48 h. The metabolism and/or tissue content of several guanidino compounds were disturbed throughout the experimental period. Arg synthesis was greatly reduced in the injured kidney, while it increased in the healthy kidney. The renal production of guanidinoacetic acid decreased in the injured kidney and its urinary excretion was reduced. The experimentally proven toxins alpha-keto-delta-guanidinovaleric acid and guanidinosuccinic acid (GSA) accumulated only in the injured kidney. The urinary excretion of GSA and methylguanidine increased in nephrectomized rats. When the injured kidney grew again, the level of some guanidino compounds tended to normalize. Nephrectomy affected the guanidino compound levels and metabolism in muscles and liver. In conclusion, the specific accumulation of toxic guanidino compounds in the injured kidney reflects disturbances in renal metabolism and function. The healthy kidney compensates for the injured kidney's loss of metabolic functions (e.g. Arg: production). This model is excellent for investigating renal metabolism when a disease destroys a limited area in one kidney, as is observed in patients.

Influence of dehydration on glycerophosphorylcholine and choline distribution along the rat nephron

Glycerophosphorylcholine is one of the four major organic osmolytes in renal medullary cells, changing their intracellular osmolyte concentration in parallel with extracellular tonicity during cellular osmoadaptation. In this study, the tubular content of glycerophosphorylcholine was quantified in untreated and 48-h-dehydrated male rats. A chemiluminescence ultra-micromethod was developed to measure choline at the picomolar level in single tubules microdissected from collagenase-treated kidneys. The glycerophosphorylcholine level was calculated as the difference between total choline after acid hydrolysis and the free tubular choline content. In accordance with the glycerophosphorylcholine distribution pattern in different renal zones of untreated rats, low amounts of glycerophosphorylcholine were found in all cortical and outer medullary structures (< 35 pmol/mm), whereas increasing amounts were detected towards the papillary tip (163 pmol/mm). As a percentage of total choline, the level of free tubular choline varied from 4.2% in outer medullary proximal tubules to 30.3% in the inner medullary collecting ducts adjacent to the outer medulla (IMCD1). Antidiuresis led to a nearly twofold increase in glycerophosphorylcholine content in papillary collecting ducts. The osmolality-dependent regulation of organic osmolytes in single microdissected tubules has been demonstrated for the first time. Furthermore, the high tubular glycerophosphorylcholine concentration compared to sorbitol and myo-inositol emphasizes the predominance of glycerophosphorylcholine in the inner medulla and papilla of the rat kidney.

Gene expression of the taurine transporter and taurine biosynthetic enzymes in rat kidney after antidiuresis and salt loading

Taurine is thought to be an osmolyte in the kidney medulla. We have investigated the gene expression of the taurine transporter (TauT) and the enzymes of taurine biosynthesis, cysteine dioxygenase (CDO) and cysteine sulfinate decarboxylase (CSD). We achieved this by measuring their mRNA levels using reverse transcriptase polymerase chain reaction (RT-PCR) in five kidney regions of rats in various hydration states; namely, normal hydration, after 2 days of antidiuresis following chronic diuresis and finally after acute salt loading. The mRNA levels of the well-established tonicity-sensitive genes coding for the aldose reductase (AR), the sodium myo-inositol transporter (SMIT) and the betaine transporter (BGT1) were also determined for the sake of comparison. In normally hydrated rats, TauT-, CDO-, and CSD-mRNA were enriched in the outer stripe of the outer medulla (OS). Following antidiuresis, the mRNA levels of TauT, CDO, CSD, SMIT, BGT1 and AR were all similarly increased in the papilla when compared with levels in rats submitted to a chronic diuresis. After acute salt loading, the mRNA level of TauT, like that of SMIT and BGT1, was overexpressed in OS whereas the mRNA levels of CDO and CSD remained unchanged. Like SMIT, BGT1 and AR genes, TauT, CDO and CSD genes appear to be tonicity-sensitive genes which can be activated in vivo by hypertonicity in the rat kidney. However, tonicity-induced activation of the TauT gene is more sensitive than that of CDO and CSD genes.

Regional expression and histological localization of cysteine sulfinate decarboxylase mRNA in the rat kidney

Cysteine sulfinate decarboxylase (CSD) is the rate-limiting biosynthetic enzyme of the pathway that forms taurine, a putative osmolyte in the kidney, which was previously localized in various segments of the nephron. Although CSD is known to be expressed in whole kidney extracts, no information on CSD mRNA regional expression and histological localization is yet available. Western blotting and Northern blotting were performed in four dissected regions of the kidney using an antiserum against recombinant CSD and a [(32)P]-dCTP-labeled CSD cDNA probe, respectively. In situ hybridization was carried out using a [(35)S]-CTP-labeled CSD RNA probe. A single protein (53 kD) and a single mRNA (2.5 kb) were detected, both of which appeared to be most enriched in the outer stripe of the outer medulla. In situ hybridization of CSD mRNA showed strong labeling of the thick tubules in the outer stripe of the outer medulla and in cortical medullary rays that corresponded to the proximal straight tubules. The significance of this restricted expression of CSD is discussed in relationship to the data previously reported on the location of taurine and the location of the taurine transporter along the nephron.

Ornithine metabolism along the female mouse nephron: localization of ornithine decarboxylase and ornithine aminotransferase

The fate of ornithine in the nephron of the female OF-1 Swiss mouse remains unknown. The aim of the present study was to identify the nephron segments containing the key enzymes involved in ornithine metabolism: ornithine decarboxylase (ODC) and ornithine aminotransferase (OAT). Viable tubules isolated by microdissection were incubated with [1-14C]ornithine to study the oxidative pathway. Other tubules were permeabilized to measure the ODC activity. Ornithine was decarboxylated in all intact tubules. Gabaculine, a suicide inhibitor of OAT, and rotenone sharply decreased the production of 14CO2 from [1-14C]ornithine. No ODC activity was found in permeabilized tubules isolated from untreated mice. Testosterone increased ODC activity in the proximal tubule substantially and to a minor extent in other nephron segments. In situ hybridization showed ODC messenger ribonucleic acid (mRNA) to be absent in kidneys of untreated females but abundant in the cortex and the outer stripe of the outer medulla of testosterone-treated female mice. The whole proximal tubule contained a great density of silver grains corresponding to ODC mRNA. In conclusion, no basal ODC activity was found in the nephron of female mice. The testosterone-inducible ODC is localized mainly in the proximal tubule, but is also present in distal tubules and collecting ducts. OAT is distributed along the whole nephron, but its activity is higher in proximal tubules than in distal tubules.

Polyamines are unevenly distributed within the rat and rabbit kidney

Aliphatic polyamines have generally been measured on the whole kidney. Since the kidney is composed of a variety of cells, whole organ data are of limited value for the interpretation of the functions of the polyamines. The aim of this study was to establish the distribution pattern of putrescine, spermidine and spermine within the kidneys of male and female rats and rabbits. It is shown that the polyamines are unevenly distributed along the cortico-papillary axis. Each amine exhibited its own distinct distribution pattern. The polyamines are predominantly located in the cortex. Putrescine levels increased gradually from the cortex to the papillary tip in rabbits, whereas, in rats, fluctuations in putrescine level were marked. In the six zones of the rabbit kidney studied, spermidine and spermine concentrations were markedly higher in females than in males. This difference was less marked in rats.

NG, NG-dimethylarginine and NG, NG-dimethylarginine in renal insufficiency

Asymmetric NG,NG-dimethylarginine (ADMA) and symmetric NG,NG-dimethylarginine (SDMA) are basic endogenous amino acids with a guanidino group. Our renal distribution study of dimethylarginines clearly indicates that, in mouse and rat, ADMA and SDMA levels are most abundant as protein-incorporated compounds (95%). ADMA represents almost 90% of this protein-incorporated dimethylarginine amount. The four zones studied (cortex, outer and inner stripe of outer medulla, inner medulla) contain more or less the same amount of protein-incorporated dimethylarginine; the concentrations of both free dimethylarginines vary more in the different zones. Plasma and urinary excretion levels in Man, rat and mouse were determined, their changes in renal insufficiency were examined and compared between species. Highly significant negative correlations between both plasma dimethylarginine levels and creatinine clearances were found in Man and rat. The correlation between urinary ADMA excretion levels and creatinine clearances was highly significant and positive in Man and mouse; however, in rat the correlation was negative. In patients with severe renal insufficiency, ADMA clearance was only 9.5% of controls, and that of SDMA only 7.8%. Clearance of ADMA and SDMA in nephrectomized mice was 60.5% and 53.8% of controls, respectively, whereas in nephrectomized rat, ADMA clearance actually increased 5.4 times and that of SDMA did not change significantly. Man, rat and mouse show similarities as well as differences in metabolism.

Identification of two arginase isoenzyme activities along the nephron of Meriones shawi

Conflicting theories on the existence of several renal arginase isoenzymes remain in debate. Because the activity of arginase is high in two embryologically different nephron segments of the Meriones shawi kidney, namely the cortical (CPST) and medullary (OSPST) proximal straight tubule and the outer medullary collecting duct (OMCD), we postulate that these nephron segments may contain different isoforms. Isolated nephron segments were dissected from collagenase-treated kidneys. Tubules were permeabilized with Triton X-100 (0.25%) and incubated with increasing Arg concentrations to characterize the arginase activity. The results were as follows: (1) in OMCD, one arginase isoform (E1), characterized by a high Arg affinity (1.160 mM), was present; (2) in CPST, two arginase isoforms were discovered - one, E1, had a similar Km (1.407 mM) to that found in OMCD whereas the other (E2) had a low affinity for Arg (Km =18.8 mM); and (3) in OSPST, two isoenzymes were present - E1 which had a Km of 1.478 mM and the second isoform that we named E2 which had a Km of 9.07 mM. In addition, arginase located in CPST and OMCD was strongly inhibited by Orn and Lys. The Ki value for Lys varied between 1.635 and 2.288 mM. Therefore, this work demonstrates that two arginase isoforms are present in the kidney of Meriones shawi. Isoform E1 is present in the proximal tubule and the collecting duct whereas isoform E2 is restricted to the proximal tubule.

Ornithine decarboxylase along the mouse and rat nephron

Renal arginase activity is a potent source of ornithine (Orn) for polyamine synthesis. Ornithine decarboxylase (ODC) was localized along the mouse and rat nephron by incubating viable nephron segments isolated by microdissection from collagenase-treated kidneys with or without D,L-2-(difluoromethyl)ornithine (DFMO), a selective inactivator of ODC. Tubules from either control or DFMO-treated animals were incubated with 100 ¿M L-[1-14C]Orn. In control mice, Orn decarboxylation occurred mainly in the proximal convoluted tubule (PCT). In DFMO-treated mice, Orn decarboxylation was dramatically reduced in PCT and in proximal straight tubules (PST). In rats, Orn decarboxylation also occurred predominantly in the proximal tubule. Addition of 10 mM DFMO to isolated tubules dramatically decreased Orn decarboxylation in PCT and in PST. Thereafter, ODC activity was demonstrated in permeabilized tubules. In Triton X-100-treated tubules from control mice, ODC was exclusively found in proximal tubules (PCT > PST). This ODC activity was strongly inhibited in DFMO-treated mice. In conclusion, the highest ODC activity was found in rat and mouse PCT, a segment devoid of arginase. We hypothesize that the filtered Orn, which is reabsorbed along the PCT,is the main source of Orn for ODC.

Biochemical and histopathological changes in nephrectomized mice

Renal failure is characterized by the retention of nitrogenous metabolites such as urea, creatinine (CTN) and other guanidino compounds (GCs), uric acid, and hippuric acid, which could be related to the clinical syndrome associated with renal insufficiency. A model of renal failure has been developed in male C57BL x Swiss-Webster mice using nephrectomy (NX) and/or arterial ligation. A sham group (group A) and two nephrectomized groups, group B (one kidney removed) and group C (one kidney removed and ligation of the contralateral anterior artery branch), were studied. Ten days postsurgery, morphological and functional indices of renal failure were investigated. Nephrectomized mice manifested features of renal failure like polyuria and wasting. CTN clearance (CTN[Cl]) decreased by +/-26% in group B and +/-33% in group C as compared with the control values. Marked increases in the plasma concentration of guanidinosuccinic acid ([GSA] fourfold) and guanidine ([G] twofold) were observed in the experimental animals. CTN and alpha-keto-delta-guanidinovaleric acid (alpha-keto-delta-GVA) reached levels of, respectively, 1.5-fold and twofold those of controls. Urinary GSA excretion increased and guanidinoacetic acid (GAA) excretion decreased about twofold in group C. GSA increases (2.6-fold) were also observed in the brain in group C, in addition to a significant increase of G (2.5-fold) and gamma-guanidinobutyric acid ([GBA] 1.5-fold). Finally, the extent of NX was found to be 45.2% in group B and 71.4% in group C. Light microscopy revealed an expansion and increase in cellularity of the mesangium of the glomeruli, particularly in group C. A significant correlation (r = .574, P < .0001) was found between CTN(Cl) and the degree of NX as calculated from the remaining functional area. These data suggest that the model can be used as a tool for further pathophysiological and/or behavioral investigations of renal failure.

Amino acid handling in uremic rats: citrulline, a reliable marker of renal insufficiency and proximal tubular dysfunction

The kidney is involved in amino acid reabsorption and metabolism; consequently, in renal insufficiency, these important functions are disturbed, as has been reported in animals and patients. In a first experimental series, rats were subjected to degrees of nephrectomy (NX) varying between 10% and 90%. Three weeks later, amino acid levels were measured in plasma to correlate the levels with the degree of NX. The results indicate that in the range of 33% to 74% NX, the plasma concentration of only three to four amino acids was modified, whereas in rats with 84% NX, the concentration of 11 amino acids was disturbed, compared with sham-operated rats. Citrullinemia was enhanced in uremic rats and correlated with the degree of NX. More interestingly, citrullinemia was increased in the range of 10% to 33% NX without any changes in uremia and creatininemia, two well-known markers of uremic states. A second experimental series was designed to study the time course of changes in aminoacidemia to find a marker for the onset of renal failure. Rats were subjected to 36% NX for a period of 1 to 21 days. Uremia and creatininemia peaked 24 to 48 hours after NX, and creatinine clearance (Clcreat) concomitantly diminished. Unfortunately, these three markers of uremic states returned to control values during the next few days before increasing during the last 2 weeks. In contrast, citrullinemia increased twofold 48 hours after NX and plateaued over the next 20 days. We conclude that in rats, citrullinemia could be used (1) to detect acute and chronic renal failure, (2) as a specific marker of normal function of the proximal tubule, and (3) to estimate the degree of renal damage. From this study, renal insufficiency might be easily detected by measuring citrullinemia.

Renal handling of guanidino compounds in rat and rabbit

1. Guanidino compounds (GCs) have been quantified in different mammalian tissues such as brain, liver, muscle and kidney. The high anatomical heterogeneity of the kidney suggests that GCs could be unevenly distributed along the corticopapillary axis of the kidney in different species. 2. This study was designed to quantify twelve GCs in the different zones of rat and rabbit kidney. The kidneys were sliced and pieces of seven definite zones were weighed and homogenized for further GC extraction. GCs were determined by liquid chromatography. 3. The results indicate that: (1) GCs were unevenly distributed along rat and rabbit kidney; (2) qualitative and quantitative studies proved that each GC shows a particular distribution pattern along the corticopapillary axis for a given species; (3) in rats, alpha-keto-delta-guanidinovaleric acid, guanidinosuccinic acid, creatinine (CTN), methylguanidine and to a lesser extent gamma-guanidinobutyric acid increased steeply along the inner medulla in parallel to urea, whereas in rabbits, most of the GCs reached a plateau in the inner medulla and remained constant at this level; (4) gamma-guanidinobutyric acid was specifically found in the rat kidney; (5) argininic acid was higher in rabbit compared with rat kidney; (6) significantly higher levels of homoarginine were found in all zones of the rat kidney compared with the rabbit kidney. 4. The results suggest that: (1) GCs are mostly localized within the nephron segments; (2) an accumulation of GCs in the inner medulla might be explained either by a recycling process or by an intracellular storage as has been reported for urea, amino acids and organic osmolytes; (3) some GCs might be synthesized in nephron segments as reported for arginine (Arg) and guanidinoacetic acid (GAA); (4) several metabolic pathways of the GCs seemed to differ between rat and rabbit; (5) except for creatine, CTN, Arg and GAA, it seems unlikely that GCs might significantly increase the intracellular osmolality.

Biochemical heterogeneity of arginine metabolism along kidney proximal tubules

By using an in vitro single tubule micromethod of high specificity, in four different species of mammals it has been observed that (a) arginine synthesis from citrulline (arginine synthase activity, E.C. 6.3.4.5 and E.C. 4.3.2.1) is restricted to the early portions of proximal convoluted tubules, whereas (b) urea production from arginine (arginase activity, E.C. 3.5.3.1.) is present mainly in the cortical (CPST) and even more in the outer medullary (OSPST) portions of straight proximal tubules. The data suggest that (a) in early PCT cells, the citrulline reabsorbed from glomerular filtrate is converted into arginine, which in turn crosses peritubular cell membranes together with reabsorbed arginine, and (b) the urea formed in CPST and OSPST cells might passively diffuse into the luminal fluid entering Henle's loops. Such urea secretion might contribute to sustain the process of urea recycling in kidney medulla and thereby participate in the mechanism of urine concentration.

Arginine metabolism in cat kidney

1. Arginine is essential for growth in the kitten and, because of the resulting hyperammonaemia, in the adult cat an arginine-free diet is life threatening. 2. The kidney is the main site of arginine synthesis. 3. This study was performed to determine whether the cat kidney synthesizes arginine and to establish which factors, such as low citrullinaemia, defects of argininosuccinate synthase and lyase activities or high renal arginase activity, might limit renal arginine production. 4. Identified nephron segments were isolated by microdissection from collagenase-treated cat kidney. 5. Arginine metabolism was studied by incubating the nephron segments with either physiological concentrations of L-[ureido-14C]citrulline (anabolism) or L-[guanido-14C]-arginine (catabolism). Arginine and urea were measured by a micro-enzymatic method. Amino acids were measured by HPLC. 6. In cat blood, the citrulline, but not the arginine, concentration was very low by comparison with other species. 7. Arginine synthesis occurred almost entirely in the proximal tubule, the highest rate occurring in the proximal convoluted tubule and the lowest in the medullary straight proximal tubule. 8. Arginase activity was restricted to the proximal tubule. Urea production increased from the convoluted towards the medullary straight tubule. 9. The limited capacity of the cat kidney to produce arginine in vivo may result from the low blood concentration of citrulline and from the high arginase activity in the various proximal cells with the ability to synthesize arginine.

Guanidino compound metabolism in rats subjected to 20% to 90% nephrectomy

In mammalian kidney, the proximal convoluted tubule (PCT) is the main site of arginine (Arg) production. Arginine can be used in the biosynthesis of guanidino compounds (GC). Since uremic rats have a lower functional mass of PCT, GC synthesis might be modified, especially that of guanidinoacetic acid (GAA) which occurs in PCT. In order to study GC metabolism at different steps of uremia, rats were subjected to either 42% or 80% nephrectomy (NX); the experiment lasted for three weeks. Results show that: (1) in plasma, the pattern of GC levels in 42% NX rats was similar to that of controls except for a clear increase of beta-guanidinopropionic acid (beta-GPA), whereas in 80% NX rats, all GC levels sharply increased except that of creatine which decreased. (2) Urinary excretion of GC in control and 42% NX rats is quite similar except for GAA which strongly decreased, and for homoarginine (HArg) and argininic acid (ArgA) which increased. In rats with 80% NX, the principal modification in GC excretion was a four- to five-fold reduction in GAA output. (3) After induction of renal failure, Arg, creatine and guanidinosuccinic acid reabsorption remained unchanged, and that of HArg decreased. For guanidine and methylguanidine the negative renal balance remained unchanged, and that of gamma-guanidinobutyric acid, GAA and alpha-keto-delta-guanidinovaleric acid became smaller, suggesting a better reabsorption. In conclusion, uremia strongly modified GC metabolism involving mainly those synthesized from Arg; both GAA and creatine synthesis were strongly decreased probably because of the loss of renal tissue, mainly PCT.

Sites of arginine synthesis and urea production along the nephron of a desert rodent species, Meriones shawi

The distribution of arginine synthase and arginase activities along the successive nephron segments of Meriones kidney was measured in vitro with single tubule enzymatic microtechniques making use of either L-[ureido-14C] Citrulline (0.108 mM) or L-[guanidino-14C]arginine (0.2 mM) as the respective substrates. Arginase activity (fmol urea formed per min per mm of tubule) was very low (5-25 fmol.min-1.mm-1) in most nephron segments including the early portions of proximal convoluted tubules (early PCT). It increased progressively after 3 mm of the PCT to reach a value of 200 fmol.min-1.mm-1 in the cortical portion of the straight proximal tubule (CPST), with a further increase, along the pars recta, of up to 250 fmol.min-1.mm-1 in the outer medullary portion (OSPST). In addition, arginase activity in OSPST and the adjacent descending thin limb (DTL) was higher in juxtamedullary nephrons (JN) than in the corresponding portions of superficial nephrons (SN). Arginine synthase activity (fmol arginine formed per mm of tubule per min) was present in proximal tubules exclusively, with a gradient decreasing along the PCT (about 600 fmol.min-1.mm-1 in the 1st mm, 65 fmol.min-1.mm-1 in CPST and 30 fmol.min-1.mm-1 in OSPST). It has been checked that CPST and OSPST (where the two enzyme systems are present) are able to convert citrulline directly into urea with a yield of 65%.(ABSTRACT TRUNCATED AT 250 WORDS)

Urea production by kidney collecting ducts in vitro: effect of amino acid addition

Urea production by cortical (CCD) and medullary (OMCD) collecting ducts of the rat kidney was measured in vitro by incubating single microdissected pieces of tubule in the presence of L-[guanido-14C]arginine (0.2 mM). The [14C]urea released from the cells was hydrolysed in presence of urease added to the incubation medium and the 14CO2 formed was trapped in KOH and counted. The effect of various amino acids (AA) on urea production was investigated by adding unlabelled AA (either in combination or singly) at concentrations close to those present in blood plasma. A mixture of 17 AA decreased urea production from [14C]arginine by 46% in CCD and by 58% in OMCD. When lysine and proline were omitted from the mixture, the inhibition was less marked (19% in CCD and 43% in OMCD, respectively). When AA were tested singly, lysine induced the larger inhibition (40% in CCD and 45% in OMCD), than ornithine and glutamine (about 15% each, in CCD and OMCD), whereas proline inhibition (7% in CCD, 10% in OMCD) was not statistically significant. Branched-chain amino acids (BCAA) in combination (leucine, isoleucine and valine) also markedly reduced urea production by CCD and OMCD. Their effect was dose dependent. Solubilization of CCD and OMCD cell membranes with Triton X-100 resulted in a twofold increase in urea production by control samples; the relative inhibition (per cent) induced by BCAA was enhanced, whereas that induced by lysine was decreased. The data suggest that, in living tubules, the inhibition obtained with lysine resulted, for a large part, from competition between lysine and arginine for cell uptake via a common membrane carrier, whereas the inhibition induced by BCAA corresponded to an effect on arginase activity itself.

Valine oxidation in the rat medullary thick ascending limb

In the kidney, a branched-chain amino acid transferase (BCAAT) activity has been localized mainly in the medullary thick ascending limb (MTAL) of the rat nephron. BCAAT is the first enzyme involved in the metabolic pathway of the three branched-chain amino acids (BCAA): leucine, isoleucine and valine. The present work has been designed to study valine catabolism. Valine and leucine oxidation in MTAL were compared by measuring the rate of 14CO2 produced when these substrates were incubated as sole substrates at a final concentration of 1 mM. Since glucose is also metabolized in MTAL, valine and leucine oxidation were quantified also in the presence of glucose (1 mM). The results show that: (1) valine oxidation was greater than that of leucine (63.0 +/- 4.7 vs 39.7 +/- 5.2 pmol.h-1 x micrograms-1 protein, respectively; P < 0.001). As previously shown, leucine oxidation was found to be increased in the presence of glucose whereas glucose oxidation decreased. In contrast, the presence of glucose strongly diminished valine oxidation (19.2 +/- 1.9 vs 63.1 +/- 4.7 pmol.h-1 x micrograms-1 protein; P < 0.001) whereas glucose oxidation was increased in the presence of valine (268.2 +/- 14.9 vs 229.6 +/- 16.2 pmol.h-1 x micrograms-1 protein; P < 0.05). We conclude that in rat MTAL, under near physiological conditions (in the presence of glucose, as in vivo), leucine is a preferential respiratory fuel as compared to valine. However, valine supports energetic salt transport and facilitates glucose oxidation.

Arginine synthesis in mouse and rabbit nephron: localization and functional significance

In the rat kidney, arginine (Arg) synthesis is restricted to the proximal tubule with a decreasing intensity from its convoluted (PCT) to its straight part (PST). The present study was designed to investigate the pattern of Arg synthesis along the nephron in other mammals, the mouse and rabbit. Microdissected representative nephron segments were incubated with 0.1 mM L-[ureido-14C]citrulline in a sealed chamber. Addition of arginase and urease to the incubation medium led to the hydrolysis of Arg into ornithine, NH3, and 14CO2. The latter was trapped in KOH and counted (results are in fmol Arg.min-1.mm tubular length-1). As in the rat, the main site of Arg synthesis in both species was found to be the PCT (mouse, 191; and rabbit, 57). A lower production was observed in rabbit and mouse PST and in rabbit distal segments. Along the PCT (from 1st to 4th mm after the glomerulus), a steep decrease is observed in mouse (595 and 37, respectively) but not in rabbit (57 and 23). The fate of the newly synthesized Arg probably depends on its site of production. Intracellular arginase activity is known to be present in the cortical (C) and medullary (OS) PST, in both mouse and rabbit. In rabbit only, arginase activity is also found in the PCT. We observed that a large part of Arg was further hydrolyzed into urea and ornithine in CPST and OSPST of mouse (66 and 80%, respectively) and rabbit (40 and 70%) but not in rabbit PCT (8%). Thus Arg produced by PCT in both species is probably released in the cortical blood, whereas Arg produced in PST may serve locally to produce urea and ornithine, and the latter could be used for polyamine synthesis.

Adaptation of the medullary thick ascending limb to dietary protein intake

Since the renal growth response to a high-protein diet is characterized by prominent hypertrophy of the medullary thick ascending limb of Henle's loop (MTAL), the functional and metabolic adaptations of this nephron segment to dietary protein were investigated. MTAL suspensions were obtained from rats fed equal amounts of isocaloric food containing either 10% (LP) or 32% (HP) casein for 4-6 weeks. The results show that intact MTAL of HP rats exhibit a blunted respiration rate, sodium pump activity, hormone-sensitive cAMP production and leucine oxidation rate in comparison with those of LP rats. On the other hand, adenylate cyclase and leucine transaminase activities, measured on permeabilized or homogenized MTAL, are enhanced by a HP diet. We conclude that the MTAL adapts to high dietary protein by increasing its maximal enzyme activities, but certain factors, present in intact cells, limit transport and metabolism in HP- more than in LP-fed rats. This reduced function per unit MTAL protein in HP rats is more than compensated for by hypertrophy of the MTAL tissue mass.

Localization of urea and ornithine production along mouse and rabbit nephrons: functional significance

Hydrolysis of arginine into urea and ornithine (Orn) was observed to take place in several segments of the rat nephron including cortical and medullary pars recta of the proximal tubule (PST) and collecting duct (CD). This work was now extended to the adult mouse and rabbit. Representative nephron segments, obtained by microdissection of collagenase-treated kidneys, were incubated with L-[guanido-14C]arginine (216 microM). Addition of urease produced 14CO2 + 2 NH3 from the newly formed urea released in the incubate. 14CO2 was trapped in KOH and counted. In both species, as well as in the rat, the PST was the site of the highest urea + Orn production, with an intensity increasing from cortex to medulla. For other nephron segments, the pattern was not similar in all species. Significant production of urea + Orn was observed in the proximal convoluted tubule and the medullary thick ascending limb in the rabbit, but not in the CD of either the rabbit or the mouse. The functional significance of this urea + Orn production remains unclear. The total amount of urea generated intrarenally by this reaction does not seem sufficient to play a significant role in the urinary concentrating mechanism. It may be assumed that Orn could be further metabolized to polyamines and play a role in maintaining cell integrity and function in the PST, especially in its medullary part, exposed to hypertonicity and poor oxygen supply.

Localization of arginine synthesis along rat nephron

Arginine production was measured in isolated rat nephron segments. Segments were incubated with 0.3 mM aspartate and 0.1 mM L-[ureido-14C]-citrulline in a sealed chamber. Arginase and urease were added to the medium to hydrolyze arginine and to release 14CO2, which was trapped in KOH and counted. Arginine synthesis was found only in the proximal tubule, with decreasing intensity from proximal convoluted (PCT) to proximal straight tubule (PST). Results were as follows (in fmol.min-1.mm tubule length-1): PCT, 122 +/- 15; cortical PST, 71 +/- 6; outer medullary PST, 41 +/- 4; all other segments, less than 6. Arginine synthesis changed almost proportionally with precursor concentration of less than or equal to 0.4 mM. We had shown previously that PST but not PCT was able to hydrolyze arginine into urea and ornithine. In this study arginine was further hydrolyzed in cortical (40%) and medullary (64%) PST but not in PCT. These observations suggest that the arginine formed in PCT contributes to the maintenance of the whole body arginine pool, whereas most of the arginine formed in PST might contribute, by its conversion to urea, to the process of urine concentration.

Production of urea from arginine in pars recta and collecting duct of the rat kidney

Urea production from arginine was studied in vitro in the kidney of normal rats in tubule suspensions of the four different renal zones (cortex, outer and inner stripe of outer medulla, and inner medulla), and in individual microdissected nephron segments. Tissue was incubated with L-[guanido-14C]-arginine to measure cellular arginase activity. Addition of urease to the incubate freed 14CO2 from the 14C-urea formed by arginase and released from the cells. CO2 was trapped in KOH and counted. These experiments revealed that significant amounts of urea are produced in the outer stripe and in the inner medulla. This intrarenal urea generation takes place mainly in the proximal straight tubule and in the collecting duct, with increasing activity in these two structures from superficial to deep regions of the kidney. Urea is known to play a critical role in the urinary concentrating process. The fact that some urea can be produced in the mammalian kidney, and that the two structures showing this capacity are straight portions of the renal tubular system descending along the corticopapillary axis suggest that this urea production might play a role in the formation and/or maintenance of the medullary urea concentration gradient.

Contribution of leucine to oxidative metabolism of the rat medullary thick ascending limb

It has recently been reported that branched-chain amino acid aminotransferase (BCAATase) is inhomogeneously distributed in the kidney. BCAATase activity is several-fold higher in the medullary thick ascending limb (MTAL) than in other nephron segments. The present work was designed to determine whether leucine, a branched-chain amino acid (AA), is used as metabolic fuel by this nephron segment. MTAL were isolated from the inner stripe of the outer medulla of adult Sprague Dawley rats by mild enzymatic digestion and appropriate sieving. Leucine aminotransferase activity measured in homogenates of MTAL was 653 +/- 52 pmol alpha-ketoglutarate formed/micrograms protein per hour, a value threefold higher than that observed in the renal cortex or muscle in the same rats. Substrate oxidation was assessed by measuring 14CO2 production from tracer amounts of uniformly labeled 14C-amino acids or glucose in isolated MTAL incubated in modified Earle balanced salt solution. When each substrate was offered at a concentration of 1 mM, leucine oxidation was much higher than that of unbranched AA, but fivefold lower than that of glucose. With 1 mM glucose and 1 mM leucine in the medium, leucine oxidation was close to that of glucose (123 +/- 8 versus 177 +/- 15 pmol CO2/micrograms protein per hour), probably because glucose contributed to the formation of alpha-ketoglutarate, a cosubstrate for leucine transamination. Inhibition of salt transport by furosemide (0.1 mM) decreased oxidation of both substrates by 60-70%. Inhibition of salt transport by ouabain (1 mM) decreased glucose oxidation markedly.(ABSTRACT TRUNCATED AT 250 WORDS)