Pyridoxamine lowers oxalate excretion and kidney crystals in experimental hyperoxaluria: a potential therapy for primary hyperoxaluria

In order to prevent kidney stones and nephrolithiasis in hyperoxaluria, a new treatment that specifically reduces oxalate production and therefore urinary oxalate excretion would be extremely valuable. Pyridoxamine(PM) could react with the carbonyl intermediates of oxalate biosynthesis, glycolaldehyde and glyoxylate, and prevent their metabolism to oxalate. In PM treated rats, endogenous urinary oxalate levels were consistently lower and became statistically different from controls after 12 days of experiment. In ethylene glycol-induced hyperoxaluria, PM treatment resulted in significantly lower (by ~50%) levels of urinary glycolate and oxalate excretion compared to untreated hyperoxaluric animals, as well as in a significant reduction in calcium oxalate crystal formation in papillary and medullary areas of the kidney. These results, coupled with favorable toxicity profiles of PM in humans, show promise for the therapeutic use of PM in primary hyperoxaluria and other kidney stone diseases.     

Oxalobacter formigenes: a potential tool for the treatment of primary hyperoxaluria type 1

Primary hyperoxaluria is characterized by severe urolithiasis, nephrocalcinosis, and early renal failure. As treatment options are scarce, we aimed for a new therapeutic tool using colonic degradation of endogenous oxalate by Oxalobactor formigenes. Oxalobacter was orally administered for 4 weeks as frozen paste (IxOC-2) or as enteric-coated capsules (IxOC-3). Nine patients (five with normal renal function, one after liver-kidney transplantation, and three with renal failure) completed the IxOC-2 study. Seven patients (six with normal renal function and one after liver-kidney transplantation) completed the IxOC-3 study. Urinary oxalate or plasma oxalate in renal failure was determined at baseline, weekly during treatment and for a 2-week follow-up. The patients who showed >20% reduction both at the end of weeks 3 and 4 were considered as responders. Under IxOC-2, three out of five patients with normal renal function showed a 22-48% reduction of urinary oxalate. In addition, two renal failure patients experienced a significant reduction in plasma oxalate and amelioration of clinical symptoms. Under IxOC-3 treatment, four out of six patients with normal renal function responded with a reduction of urinary oxalate ranging from 38.5 to 92%. Although all subjects under IxOC-2 and 4 patients under IxOC-3 showed detectable levels of O. formigenes in stool during treatment, fecal recovery dropped directly at follow up, indicating only transient gastrointestinal-tract colonization. The preliminary data indicate that O. formigenes is safe, leads to a significant reduction of either urinary or plasma oxalate, and is a potential new treatment option for primary hyperoxaluria.     

Pentoxifylline: a potential therapy for chronic kidney disease

Almost all forms of chronic kidney disease progressing to end-stage kidney failure are characterized by diffuse fibrosis, a final common pathway converging from multiple pathogenetic networks regardless of the initial injury. Four principal interventions including glycaemic and blood pressure control, dietary protein restriction, and angiotensin II blockade have been proven to slow progression of diabetic and/or non-diabetic chronic kidney disease. However, the ultimate solution to halt disease progression in the long term is still pending. Because of the pathogenetic complexity of kidney disease, multidrug intervention with the least side-effects should, without doubt, be the next step to stop kidney disease progression. Animal and cellular studies have demonstrated the rationale for pentoxifylline (i.e. its effects against cell proliferation, inflammation, and extracellular matrix accumulation) in the treatment of chronic kidney disease induced by immune- or non-immune-mediated mechanisms. Limited human studies have proven its efficacy in reducing proteinuria in patients with diabetes receiving angiotensin-converting enzyme inhibitors, and in patients with nephrotic syndrome refractory to conventional immunosuppressive therapy. Moreover, monotherapy with pentoxifylline markedly reduces proteinuria in patients with membranous nephropathy. Further studies are required to examine whether pentoxifylline can improve the renal outcome in patients receiving interventions with proven efficacy.     

Late diagnosis of primary hyperoxaluria after failed kidney transplantation

Primary hyperoxaluria type 1 (PH1) is a rare autosomal recessive inborn error of the glyoxylate metabolism that is based on absence, deficiency or mislocalization of the liver-specific peroxisomal enzyme alanine:glyoxylate aminotransferase. Hyperoxaluria leads to recurrent formation of calculi and/or nephrocalcinosis and often early end-stage renal disease (ESRD) accompanied by systemic calcium oxalate crystal deposition. In this report, we describe an adult female patient with only one stone passage before development of ESRD. With unknown diagnosis of PH, the patient received an isolated kidney graft and developed an early onset of graft failure. Although initially presumed as an acute rejection, the biopsy revealed calcium oxalate crystals, which then raised a suspicion of primary hyperoxaluria. The diagnosis was later confirmed by hyperoxaluria, elevated plasma oxalate levels and mutation of the AGXT gene, showing the patient to be compound heterozygous for the c.33_34InsC and c.508G > A mutations. Plasma oxalate levels did not decrease after high-dose pyridoxine treatment. Based on this case report, we would recommend in all patients even with a minor history of nephrolithiasis but progression to chronic renal failure to exclude primary hyperoxaluria before isolated kidney transplantation is considered.     

Regressive course of oxalate deposition in primary hyperoxaluria after kidney transplantation

Primary hyperoxaluria (PH) is a rare autosomal recessive disease caused by the functional defect of alanine-glyoxylate aminotransferase (AGT) enzyme in the liver and it is characterized by the deposition of diffuse calcium oxalate crystals. A 38-year-old male patient presented with history of recurrent nephrolithiasis and has received chronic hemodialysis treatment for 2 years. Cadaveric renal transplantation was applied to the case. The patient was reoperated on postoperative day 13 because of the collection surrounding the urethra. During this operation, kidney biopsy was made due to late decrease in creatinine levels. Deposition of diffuse oxalate crystal was detected in allograft kidney biopsy, whereas in the 0-hour biopsy there were no oxalate crystals. Oxalate level was found to be high in a 24-hour urine specimen (118 mg/L, normal level: 7–44 mg/L). The patient was identified with primary hyperoxaluria and followed up in terms of systemic oxalate deposition as well as allograft kidney. In the kidney biopsy taken after 18 months, we detected that oxalate crystals almost entirely disappeared. In our case, bilateral preretinal, intraretinal, and intravascular diffuse oxalate crystals were detected, and argon laser photocoagulation treatments were needed for choroidal and retinal neovascularization. Repeated ophthalmic examinations showed the regressive nature of oxalate depositions. In the 18th month, fundus examination and fluorescein angiography revealed that oxalate crystals were significantly regressed. To increase the quality of life and slow down the systemic effects of oxalosis, kidney-only transplantation is beneficial.     

Identification of a novel AGXT gene mutation in primary hyperoxaluria after kidney transplantation failure

Primary hyperoxaluria is a genetic disorder in glyoxylate metabolism that leads to systemic overproduction of oxalate. Functional deficiency of alanine-glyoxylate aminotransferase in this disease leads to recurrent nephrolithiasis, nephrocalcinosis, systemic oxalosis, and kidney failure. The aim of this study was to determine the molecular etiology of kidney transplant loss in a young Tunisian individual. We present a young man with end-stage renal disease who received a kidney allograft and experienced early graft failure. There were no improvement in kidney function; he required hemodialysis and graft biopsy revealed calcium oxalate crystals, which raised suspicion of primary hyperoxaluria. Genetic study in the AGXT gene by PCR direct sequencing identified three missense changes in heterozygote state: the p. Gly190Arg mutation next to two other novels not previously described. The classification of the deleterious effect of the missense changes was developed using the summered results of four different mutation assessment algorithms, SIFT, PolyPhen, Mutation Taster, and Align-GVGD. This system classified the changes as polymorphism in one and as mutation in other. The patient was compound heterozygous mutations. Structural analysis showed that the novel mutation, p.Pro28Ser mutation, affects near the dimerization interface of AGT and positioned on binding site instead of the inhibitor, amino-oxyacetic acid (AOA).With the novel AGXT mutation, the mutational spectrum of this gene continues to broaden in our population. The diagnosis of PH1 was not recognized until after renal transplant with fatal consequences, which led us to confirm the importance of screening before planning for kidney transplantation in population with a relatively high frequency of AGXT mutation carriers.     

International registry for primary hyperoxaluria

BACKGROUND/AIMS: Primary hyperoxaluria (PH) is an inherited disorder that causes calcium urolithiasis and renal failure. Due to its rarity, experience at most centers with this disease is limited. METHODS: A secure, web-based, institutional review board/ethics committee and American Health Insurance Portability and Accountability Act (HIPAA)-compliant registry was developed to facilitate international contributions to a data base. To date 95 PH patients have been entered. RESULTS: PH type was confirmed in 84/95 (PH1 79%, PH2 9%). Mean age +/- SD at symptom onset was 9.5 +/- 10.2 (median 5.5) years whereas age at diagnosis was 15.0 +/- 15.2 (median 10.0) years. Urolithiasis was present at diagnosis in 90% (mean 7, median 1, stones prior to diagnosis) and nephrocalcinosis in 48%. Surprisingly 15% of the patients were asymptomatic at the time of diagnosis. Nineteen of the 95 patients were first recognized to have PH after they had reached end-stage renal disease, with the diagnosis made only after kidney transplantation in 7 patients. Patients were followed for 12.1 +/- 10.6 (median 9.4) years. Thirty-four of 95 progressed to end-stage renal failure, before (19 patients) or after (15 patients) diagnosis. In the PH1 cohort actuarial renal survival was 64% at 30 years of age, 47% at 40 years, and 29% at 50 years. CONCLUSION: We have developed a PH registry, and demonstrated the feasibility of this secure, web-based approach for data entry. By facilitating accumulation of an increasing cohort of patients, this registry should allow more complete characterization of clinical expression of PH, an appreciation of geographic variability, and identification of treatment outcomes.     

Genetic analysis: a diagnostic tool for primary hyperoxaluria type 1

Pediatric Nephrology -     

Mitochondrial hydroxyproline metabolism: implications for primary hyperoxaluria

BACKGROUND/AIMS: Primary hyperoxaluria results from an alteration in enzymes that metabolize glyoxylate. The metabolism that leads to glyoxylate synthesis is not well defined. The aim of this study was to investigate the production of glyoxylate in liver mitochondria when they metabolize hydroxyproline. METHODS: Mitochondria were isolated from mouse liver using Percoll gradient centrifugation. The metabolism of hydroxyproline was examined by a combination of HPLC and ion chromatography/mass spectrometry techniques. RESULTS: Glyoxylate production was substantially greater when mitochondria were incubated with hydroxyproline in comparison with proline. Inclusion of malate and glutamate with hydroxyproline resulted in a drop in glyoxylate and an increase in glycolate in the incubation mixture. This suggests an increased NAD(P)+ reduction which occurred with the inclusion of glutamate/malate and that the NAD(P)H production was required to stimulate the glyoxylate reductase-catalyzed conversion of glyoxylate to glycolate. The presence of glyoxylate reductase in these mitochondria was confirmed by measuring enzymatic activity and by Western blotting. CONCLUSION: These results indicate that studies on isolated mitochondria have the potential to help unravel the metabolism associated with glyoxylate and oxalate production and understand the metabolic function of glyoxylate reductase.     

One hundred percent patient and kidney allograft survival with simultaneous liver and kidney transplantation in infants with primary hyperoxaluria: a single-center experience

BACKGROUND: Combined liver-kidney transplantation is the definitive treatment for end-stage renal disease caused by primary hyperoxaluria type I (PH1). The infantile form is characterized by renal failure early in life, advanced systemic oxalosis, and a formidable mortality rate. Although others have reported on overall results of transplantation for PH1 covering a wide age spectrum, none has specifically addressed the high-risk infantile form of the disease. METHODS: Six infants with PH1 underwent simultaneous liver-kidney transplantation at our center between May 1994 and August 1998. Diagnosis was made at 5.2+/-3.3 months of age, they were on dialysis for 11.8+/-2.3 months, and they underwent transplantation at 14.8+/-3.0 months of age when they weighed 10.6+/-1.7 kg. RESULTS: At a mean follow-up of 6.4+/-1.7 years (range, 3.9-8.1 years), we report 100% patient and kidney allograft survival. There were no cases of acute tubular necrosis. Long-term kidney allograft function remained stable in all patients, with serum creatinine values of less than 1.1 mg/dL and a mean creatinine clearance of 99 mL/min/1.73 m2 at follow-up. Those who received combined hemodialysis and peritoneal dialysis pretransplant had lower posttransplant urinary oxalate values than those receiving peritoneal dialysis alone. There was improvement in growth and psychomotor and mental developmental scores after transplantation. CONCLUSIONS: Combined liver-kidney transplantation for the infantile presentation of PH1 is associated with excellent outcome when the approach includes early diagnosis and early combined transplantation, aggressive pretransplant dialysis, and avoidance of posttransplant renal dysfunction.     

Reversal of pancytopenia following kidney transplantation in a patient of primary hyperoxaluria with bone marrow involvement

Combined liver and kidney transplantation is the ideal treatment for patients with end-stage renal failure secondary to primary hyperoxaluria and systemic oxalosis, with a functioning liver providing replacement of the deficient enzyme and a functioning kidney providing the route of excretion for the oxalate crystals. Pancytopenia from bone marrow infiltration of oxalate crystals is a rare complication of primary hyperoxaluria, and its reversal following transplant has not been described. We report the first case of pancytopenia from marrow infiltration by oxalate crystals reversing following a successful kidney transplant alone. Although kidney alone transplants do not provide the best chance of survival or quality of life as compared to a combined kidney and liver transplant, a well functioning kidney transplant is able to take care of the systemic oxalate load and ameliorate, at least for a period of time, the systemic complications of oxalosis.     

Cadaveric orthotopic auxiliary split liver transplantation and kidney transplantation: an alternative for type 1 primary hyperoxaluria

Liver transplantation (LTX) corrects the enzymatic defect responsible for type 1 primary hyperoxaluria (PH1). It has been advocated in combination with kidney transplantation (KTX) in patients with renal failure from PH1 because KTX alone can result in early graft loss. A 58-year-old male patient with PH1 on hemodialysis underwent resection of the left lateral segment of the liver followed by orthotopic auxiliary left lateral segment liver transplantation and kidney transplantation from a deceased donor. The serum oxalate dropped from 34.8 micromol/L before transplant to 3.6-8.3 in the first months posttransplant to <1 micromol/L (normal range 0.4-3.0). One year after posttransplant, the patient has an iothalamate glomerular filtration rate of 58 ml/min. Orthotopic auxiliary LTX is an alternative to whole LTX in PH1. By using a split deceased donor liver, it does not deprive the donor pool and protects the recipient from liver failure in case of graft loss.     

Combined liver-kidney transplantation in a child with primary hyperoxaluria

A 3.5-year-old boy presented with end-stage renal disease and bilateral nephrocalcinosis. Renal biopsy demonstrated marked parenchymal calcium oxalate deposition and a diagnosis of primary hyperoxaluria (PH) was made. Following 2 years of hemodialysis he received two renal allografts which were lost at 7 and 11 months, respectively, due to biopsy-proven recurrent oxalosis. Combined liver-kidney transplantation was then performed, after which renal and hepatic function initially stabilized. The patient died on the 28th postoperative day, of in fectious complications and progressive respiratory insufficiency. However, comparisons between the patterns of urinary oxalate excretion noted after the isolated renal and liver-kidney transplants indicated that, following the latter, successful biochemical correction of the enzyme defect responsible for type 1 PH had occurred.