Chie Tomida

Prognosis of asymptomatic hematuria and/or proteinuria in men. High prevalence of IgA nephropathy among proteinuric patients found in mass screening.

Aim: To elucidate prognosis and prevalence of chronic renal diseases among proteinuric and/or hematuric subjects found in mass screening, a long-term follow-up study (6.35 years, range 1.03–14.6 years) was conducted on Japanese working men. Methods: A total of 772 subjects selected from 50,501 Japanese men aged 15–62 years were found to have asymptomatic hematuria (n = 404), concomitant hematuria and proteinuria (n = 155), and proteinuria (n = 213) during their annual urine examination and five consecutive urinalyses. Results: Hematuria patients showed significant improvements in urinary abnormalities as compared with both hematuria/proteinuria and proteinuria patients. Both hematuria/proteinuria patients with normotension and hematuria/proteinuria patients aged under 40 years showed significant improvements. During the follow-up period, 9.5% of the hematuria patients became hematuric/proteinuric. Hematuria/proteinuria patients had the highest risk of developing renal insufficiency. The presence of hypertension at detection of urinary abnormalities did not affect the renal function; however, if proteinuria appeared after the age of 40 years, these patients had a higher risk of developing renal insufficiency. The incidence of IgA nephropathy in the present subjects was as high as 143 cases per 1 million per year. Conclusion: Detailed follow-up and definitive diagnosis of asymptomatic urinary abnormalities may raise the prevalence of IgA nephropathy worldwide.

Mitochondrial DNA Mutations in Focal Segmental Glomerulosclerosis Lesions

Glomerular epithelial cells are primary pathogenic sites in focal segmental glomerulosclerosis (FGS) lesions. Glomerular epithelial cells are regarded as terminally differentiated cells that do not proliferate. These characteristics are also noted for neurons and muscular cells, which are major sites of mitochondrial DNA (mtDNA) mutation accumulation. Screening for mtDNA mutations was performed with renal biopsy specimens from patients with primary FGS and patients with IgA nephropathy (as subjects with secondary FGS and as control subjects). mtDNA extracted from kidney biopsy specimens was amplified with appropriate primer pairs for study of the mtDNA point mutations 3243A-->G, 3271T-->C, 8344A-->G, and 8993T-->G/C, as well as the common deletion (a 4977-bp deletion spanning mtDNA nucleotide pairs 8469 to 13447). In situ amplification of both total mtDNA and the common deletion was also performed. Two patients with FGS demonstrated the 3243A-->G point mutation; 12 patients with FGS and seven patients with IgA nephropathy accompanied by glomerulosclerotic lesions exhibited the common deletion in their kidney tissue. No patient demonstrated the mtDNA mutations 3271T-->C, 8344A-->G, or 8993T-->G/C. The degree of heteroplasmy for the 3243A-->G point mutation was >85%; however, the heteroplasmy for the common deletion was <1%. As determined with in situ PCR, normal mtDNA was mainly distributed in the tubular epithelium and mtDNA with the common deletion was mainly distributed among glomerular epithelial cells. In conclusion, it is suggested that mtDNA mutations are distributed in glomerular epithelial cells among some patients with primary FGS or secondary FGS with IgA nephropathy. These mutations may be related to glomerular epithelial cell damage.

Hemodialysis Does Not Influence the Peroxidative State Already Present in Uremia

Hemodialysis (HD) patients are exposed to high oxidative stress, however, the nature of this stress is still unclear. In this study, we employed a specific lipid peroxidative product, phosphatidylcholine hydroperoxide (PCOOH), and evaluated the peroxidative effect of end stage renal disease by measuring thiobarbituric acid reactive substances (TBARS) and PCOOH in both plasma and erythrocyte membrane. We also surveyed plasma TBARS and PCOOH before and after HD sessions thereby assessing oxidative stress by a single HD procedure. The plasma TBARS level of healthy controls was 2.9 ± 0.4 nmol/ml. Those of HD patients before and after HD session were 5.1 ± 1.4 and 3.1 ± 0.5 nmol/ml, respectively, and the pre-HD plasma TBARS levels were significantly higher than those of controls and after HD. The Plasma PCOOH concentration of patients before HD was 119.7 ± 58.4 pmol/ml and was significantly higher than that of controls which was 88.6 ± 14.3 pmol/ml. After HD, the plasma PCOOH level decreased to 103.2 ± 36.0 pmol/ml, which was still significantly higher than that of controls. In erythrocytes, the PCOOH level of patients was 259.3 ± 105.4 nmol/g RBC and was significantly higher than that of controls with 88.6 ± 32.0 nmol/g RBC. Analyzed with respect to the cause of renal disease, the polycystic kidney disease patients showed significantly lower plasma PCOOH levels than the others. These results suggest that there is an increase of lipid peroxidation in both plasma and erythrocytes of HD patients, though this oxidative stress was not brought about by HD.

FORMATION OF GUANIDINOSUCCINIC ACID, A STABLE NITRIC OXIDE MIMIC, FROM ARGININOSUCCINIC ACID AND NITRIC OXIDE-DERIVED FREE RADICALS

Guanidinosuccinic acid (GSA) is noted for its nitric oxide (NO) mimicking actions such as vasodilatation and activation of the N-methyl-D-aspartate (NMDA) receptor. We have reported that GSA is the product of argininosuccinate (ASA) and some reactive oxygen species, mainly the hydroxyl radical. We tested for GSA synthesis in the presence of NO donors. ASA (1 mM) was incubated with NOR-2, NOC-7 or 3-morpholinosydomine hydrochloride (SIN-1) at 37 degrees C. GSA was determined by HPLC using a cationic resin for separation and phenanthrenequinone as an indicator. Neither NOR-2 or NOC-7 formed GSA. SIN-1, on the other hand, generates NO and the superoxide anion which, in turn, generated peroxynitrite which was then converted to the hydroxyl radical. Incubation of ASA with SIN-1 leads, via this route, to GSA. When ASA was incubated with 1 mM SIN-1, the amount of GSA produced depended on the incubation time and the concentration of ASA. Among the tested SIN-1 concentrations, from 0.5 to 5 mM, GSA synthesis was maximum at 0.5 mM and decreased with increasing concentrations of SIN-1. Carboxy-PTIO, a NO scavenger, completely inhibited GSA synthesis. SOD, a superoxide scavenger, decreased GSA synthesis by 20%, and catalase inhibited GSA synthesis only by 12%; DMSO, a hydroxyl radical scavenger completely inhibited GSA synthesis in the presence of SIN-1. These data suggest that the hydroxyl radical derived from a combination of NO and the superoxide anion generates GSA, a stable NO mimic. Meanwhile, synthesis of GSA by NO produces reactive oxygen and activates the NMDA receptor that generates NO from GSA, suggesting a positive feed back mechanism.

Synthesis of Guanidinosuccinate from Argininosuccinate and Reactive Oxygen in vitro

Synthesis of guanidinosuccinic acid (GSA), a uremic toxin, has been suggested to relate to the urea concentration and synthetic rate. Among the urea cycle enzymes, inhibition of argininosuccinate (ASA) lyase by urea has been reported. Argininosuccinate which contains a GSA structure is a candidate of a GSA precursor. We found that another uremic toxin, methylguanidine, is formed from creatinine with reactive oxygen species. Therefore, we investigated in vitro whether GSA is formed from ASA with reactive oxygen species. GSA was measured by HPLC by a post-column-labeling method using 9,10-phenathrequinone. When 1 mmol/l ASA was reacted with the hydroxyl radical-generating system for 5 min at pH 7.4, 9 mumol/l GSA was formed. Dimethylsulfoxide, a hydroxyl radical scavenger, markedly inhibited GSA synthesis. The superoxide radical generated by xanthine and xanthine oxidase reaction also formed 1 mumol/l GSA from 1 mumol/l ASA and the GSA formation was inhibited by superoxide dismutase or catalase almost completely. Addition of FeCl2 to the xanthine/xanthine oxidase reaction further increased GSA synthesis. These results indicate that GSA is formed from ASA by reaction with the hydroxyl radical and the superoxide radical.

Creatol, an oxidative product of creatinine in hemodialysis patients

Creatol (CTL) is a product resulting from the reaction of creatinine (Cr) with the hydroxyl radical and is identified as a precursor of methylguanidine (MG), a uremic toxin. In this study, we investigated serum CTL levels together with those of Cr and MG in 66 patients who were on maintenance hemodialysis (HD). Prior to dialysis, the mean serum levels of Cr, CTL and MG were 967 (=11.1 mg/dl) ±267 μM, 11.1 ± 4.8μM and 5.8±2.9 μM, respectively. The mean CTL level was about 1.1% that of Cr, and the CTL plus MG level was about 1.4% that of the Cr level. The reduction rates of Cr, CTL and MG by a single HD were 62.6±6.1%, 71.0±10.3% and 51.9±11.6%, respectively. The CTL level at 0.5, 1 and 6h after HD increased rapidly by 20.7±8.7%, 31.7±14.7% and 80.1±27.3%, respectively. There was a significant correlation between CTL or CTL/Cr and parathyroid hormone in patients who had just undergone parathyroidectomy. No significant correlation was found between CTL or CTL/Cr and those factors which seems to be related to the predialysis levels of reactive oxygen. Therefore, because of the good clearance of CTL and its rapid conversion to MG, its usefulness for the estimation of hydroxyl radical generation in HD patients is limited.

Decreased Serum Antioxidant Activity of Hemodialysis Patients Demonstrated by Methylguanidine Synthesis and Microsomal Lipid Peroxidation

This study aims to raise the possibility of methylguanidine, a peroxidative product of creatinine, as a measure of the peroxidative state. As a known standard, we measured the inhibitory effect of uremic serum on the NADPH-dependent microsomal lipid peroxidation. This is an established method for evaluating the peroxidative state and is compared to the effect of uremic serum on methylguanidine synthesis. The study shows decreased serum antioxidant activity in hemodialysis patients by both methods, though there is no correlation between them. These results support the use of methylguanidine as a peroxidative marker and suggest a difference in the reactive oxygen species involved in the reactions of methylguanidine synthesis and microsomal lipid peroxidation.

Biosynthesis of methylguanidine in the hepatic peroxisomes and the effect of the induction of peroxisomal enzymes by clofibrate

A state of peroxidation is one of the factors contributing to uremia. For example, we have reported that certain species of reactive oxygen, particularly the hydroxyl radical, play an important role in the biosynthesis of methylguanidine which contributes to toxicity in patients with uremia. However, it is uncertain which enzymes are involved in the synthesis of methylguanidine from creatinine. In this study, we attempt to show methylguanidine synthesis in the presence of peroxisomal enzymes that catalyze the β-oxidation of fatty acids. In addition, we investigate the effect of clofibrate, which induces peroxisomal enzymes or glutathione peroxidase activity, on methylguanidine synthesis in the peroxisomal fraction. Male Wistar rats were fed with the chow containing 0.5% clofibrate to induce peroxisomal enzymes and control rats were fed with ordinary laboratory chow. Peroxisomal fractions were obtained from liver homogenates by centrifugation, and incubated with creatinine in 0.1 M potassium phosphate buffer pH 7.4 at 37°C. Results show that methylguanidine is synthesized from creatinine concomitant with the synthesis of hydrogen peroxide from endogenous substrates in the peroxisomal fraction. This methylguanidine synthesis is inhibited by the addition of dimethylsulfoxide, glutathione, or sodium azide (p < 0.01). The rate of methylguanidine synthesis in clofibrate-treated rats was significantly less than that in control rats (p < 0.02). These results suggest that methylguanidine is synthesized in the peroxisomal fraction, and reactive oxygen species which are generated through this enzymatic reaction, participate in methylguanidine synthesis. Moreover, the induction of a scavenger system, especially glutathione peroxidase takes precedent over the generation of reactive oxygen species in peroxisomes treated with clofibrate.

Increased Lipid Peroxidation by Rat Liver Microsomes in Experimental Renal Failure

This study investigated the peroxidative state of renal failure by measuring lipid peroxidation. The generation of lipid peroxides by rat hepatic microsomes was compared between experimental renal failure caused by 7/8 nephrectomy and healthy control animals. The concentrations of BUN at the point of sacrifice were 84.2 +/- 18.4 (mean +/- SD) in nephrectomized and 19.8 +/- 4.3 mg/dl in the control group (p < 0.01, n = 5). Microsomal generation of thiobarbituric acid reactive substance was 31.2 +/- 2.8 in the nephrectomized group and 20.9 +/- 4.9 nmol/incubation/min in the control group. There was a significant difference between the groups (p < 0.01, n = 5). In summary, the generation rate of lipid peroxides in the microsomes obtained from the rats with experimental renal failure was significantly higher than the control. This study confirms an increased peroxidative state, and specifies one of the sites of increased lipid peroxide generation in renal failure.

Chronic Renal Failure with Severe Mesangiolysis in a Hematopoietic Stem Cell Transplant Recipient

Chronic progressive renal failure is a well-recognized complication in hematopoietic stem cell transplantation (HSCT) recipients. Although thrombotic microangiopathy or chemotherapeutic agents are frequently associated, total body irradiation might also be one of the suspected etiologic factors. This study describes a 38-year-old female patient with acute lymphoblastic leukemia treated with HSCT who developed chronic renal dysfunction after transplantation. Renal biopsy revealed focal and diffuse glomerulosclerosis with extensive mesangiolytic lesions. Her clinical course implied that pretransplant irradiation might have the most impact on the expression of this glomerular lesion.