A randomised Phase II/III study to evaluate the efficacy and safety of orally administered Oxalobacter formigenes to treat primary hyperoxaluria.

Primary hyperoxaluria (PH) patients overproduce oxalate because of rare genetic errors in glyoxylate metabolism. Recurrent urolithiasis and/or progressive nephrocalcinosis are PH hallmarks and can lead to kidney damage, systemic oxalosis and death. Based on previous studies, we hypothesised that treatment with the oxalate-metabolizing bacterium Oxalobacter formigenes would mediate active elimination of oxalate from the plasma to the intestine of PH patients, thereby reducing urinary oxalate excretion (Uox). The efficacy and safety of O. formigenes (Oxabact™ OC3) were evaluated for 24 weeks in a randomised, placebo-controlled, double-blind study. The primary endpoint was reduction in Uox. Secondary endpoints included change in plasma oxalate (Pox) concentration, frequency of stone events, number of responders, and Uox in several subgroups. Additional post hoc analyses were conducted. Thirty-six patients were randomised; two patients withdrew from placebo treatment. Both OC3 and placebo groups demonstrated a decrease in Uox/urinary creatinine ratio, but the difference was not statistically significant. No differences were observed with respect to change in Pox concentration, stone events, responders' number or safety measures. In patients with estimated glomerular filtration rate (eGFR) < 90 mL/min/1.73 m2, Pox increased by 3.25 µmol/L in the placebo group and decreased by -1.7 µmol/L in the OC3 group (p = 0.13). After 24 weeks, eGFR had declined to a greater degree in the placebo than in the OC3 group: -8.00 ± 2.16 versus -2.71 ± 2.50; p = 0.01. OC3 treatment did not reduce urinary oxalate over 24 weeks of treatment compared with placebo in patients with PH. The treatment was well tolerated.

Role of gut microbiota against calcium oxalate.

Nephrolithiasis is a condition marked by the presence or formation of stones in kidneys. Several factors contribute to kidney stones development such as environmental conditions, type of dietary intake, gender and gastrointestinal flora. Most of the kidney stones are composed of calcium phosphate and calcium oxalate, which enter in to the body through diet. Both sources of oxalates become dangerous when normal flora of gastrointestinal tract is disturbed. Oxalobacter and Lactobacillus species exist symbiotically in the human gut and prevent stone formation by altering some biochemical pathways through production of specific enzymes which help in the degradation of oxalate salts. Both Oxalobacter and Lactobacillus have potential probiotic characteristics for the prevention of kidney stone formation and this avenue should be further explored.

Effect of Dietary Oxalate on the Gut Microbiota of the Mammalian Herbivore Neotoma albigula.

Diet is one of the primary drivers that sculpts the form and function of the mammalian gut microbiota. However, the enormous taxonomic and metabolic diversity held within the gut microbiota makes it difficult to isolate specific diet-microbe interactions. The objective of the current study was to elucidate interactions between the gut microbiota of the mammalian herbivore Neotoma albigula and dietary oxalate, a plant secondary compound (PSC) degraded exclusively by the gut microbiota. We quantified oxalate degradation in N. albigula fed increasing amounts of oxalate over time and tracked the response of the fecal microbiota using high-throughput sequencing. The amount of oxalate degraded in vivo was linearly correlated with the amount of oxalate consumed. The addition of dietary oxalate was found to impact microbial species diversity by increasing the representation of certain taxa, some of which are known to be capable of degrading oxalate (e.g., Oxalobacter spp.). Furthermore, the relative abundances of 117 operational taxonomic units (OTU) exhibited a significant correlation with oxalate consumption. The results of this study indicate that dietary oxalate induces complex interactions within the gut microbiota that include an increase in the relative abundance of a community of bacteria that may contribute either directly or indirectly to oxalate degradation in mammalian herbivores.

Analysis of commercial kidney stone probiotic supplements.

OBJECTIVE: To examine the levels of Oxalobacter formigenes in probiotic supplements marketed by PRO-LAB, Ltd, Toronto, Canada, and capsules of Oxalo purchased from Sanzyme Ltd, Hyderabad, India, and to measure the ability of these preparations to degrade oxalate in vitro. METHODS: Probiotic supplements and pure cultures of O. formigenes were cultured in a number of media containing oxalate. Optical density at 595 nm (OD595) was used to measure bacterial growth, and ion chromatography was used to measure loss of oxalate in culture media. O. formigenes-specific and degenerate Lactobacillus primers to the oxalate decarboxylase gene (oxc) were used in polymerase chain reaction (PCR). RESULTS: Incubating probiotic supplements in different media did not result in the growth of oxalate-degrading organisms. PCR indicated the absence of organisms harboring the oxc gene. Culture and 16S ribosomal ribonucleic acid gene sequencing indicated the PRO-LAB supplement contained viable Lactococcus lactis subsp. lactis (GenBank accession no. KJ095656.1), whereas Oxalo contained several Bacillus species and Lactobacillus plantarum. CONCLUSION: The probiotic supplement sold over the Internet by PRO-LAB Ltd and Sanzyme Ltd did not contain identifiable O. formigenes or viable oxalate-degrading organisms, and they are unlikely to be of benefit to calcium oxalate kidney stone patients.

[Oxalate: a poorly soluble organic waste with consequences]. / L'oxalate: un déchet organique peu soluble, avec conséquences.

Oxalate is a highly insoluble metabolic waste excreted by the kidneys. Disturbances of oxalate metabolism are encountered in enteric hyperoxaluria (secondary to malabsorption, gastric bypass or in case of insufficient Oxalobacter colonization), in hereditary hyperoxaluria and in intoxication (ethylene glycol, vitamin C). Hyperoxaluria causes a large spectrum of diseases, from isolated hyperoxaluria to kidney stones and nephrocalcinosis formation, eventually leading to kidney failure and systemic oxalosis with life-threatening deposits in vital organs. New causes of hyperoxaluria are arising recently, in particular after gastric bypass surgery, which requires regular and preemptive monitoring. The treatment of hyperoxaluria involves reduction in oxalate intake and increase in calcium intake. Optimal urine dilution and supplementation with inhibitors of kidney stone formation (citrate) are required. Some conditions may need vitamin B6 supplementation, and the addition of probiotics might be useful in the future. Primary care physicians should identify cases of recurrent calcium oxalate stones and severe hyperoxaluria. Further management of hyperoxaluria requires specialized care.

L'oxalate est un déchet métabolique peu soluble excrété par les reins, et les hyperoxaluries peuvent être distinguées en hyperoxaluries entériques, hyperoxaluries héréditaires et les intoxications (éthylène glycol, vitamine C). L'hyperoxalurie induit un large spectre de maladies allant de l'hyperoxalurie isolée, formation de calculs rénaux, voire d'une néphrocalcinose, à l'insuffisance rénale et l'oxalose systémique avec des dépôts s'accumulant dans de nombreux organes. De nouvelles causes d'hyperoxalurie sont apparues ces dernières années, en particulier les hyperoxaluries survenant à la suite d'un bypass gastrique. Le traitement des hyperoxaluries fait intervenir, d'une part, une diminution contrôlée des apports en oxalate et une augmentation des apports en calcium et, d'autre part, une dilution des urines et l'ajout d'inhibiteurs de la lithogenèse (citrate). Dans certaines conditions particulières, une supplémentation en vitamine B6 ou l'utilisation de probiotiques peuvent être envisagées. Le praticien doit rester attentif aux cas de calculs d'oxalate de calcium récidivants ou d'hyperoxalurie sévère et les adresser pour une prise en charge spécialisée et multidisciplinaire.

Bifidobacterium animalis subsp. lactis decreases urinary oxalate excretion in a mouse model of primary hyperoxaluria.

Hyperoxaluria significantly increases the risk of calcium oxalate kidney stone formation. Since several bacteria have been shown to metabolize oxalate in vitro, including probiotic bifidobacteria, we focused on the efficiency and possible mechanisms by which bifidobacteria can influence oxalate handling in vivo, especially in the intestines, and compared these results with the reported effects of Oxalobacter formigenes. Bifidobacterium animalis subsp. lactis DSM 10140 and B. adolescentis ATCC 15703 were administered to wild-type (WT) mice and to mice deficient in the hepatic enzyme alanine-glyoxylate aminotransferase (Agxt(-/-), a mouse model of Primary Hyperoxaluria) that were fed an oxalate-supplemented diet. The administration of B. animalis subsp. lactis led to a significant decrease in urinary oxalate excretion in WT and Agxt(-/-) mice when compared to treatment with B. adolescentis. Detection of B. animalis subsp. lactis in feces revealed that 3 weeks after oral gavage with the bacteria 64% of WT mice, but only 37% of Agxt(-/-) mice were colonized. Examining intestinal oxalate fluxes showed there were no significant changes to net oxalate secretion in colonized animals and were therefore not associated with the changes in urinary oxalate excretion. These results indicate that colonization with B. animalis subsp. lactis decreased urinary oxalate excretion by degrading dietary oxalate thus limiting its absorption across the intestine but it did not promote enteric oxalate excretion as reported for O. formigenes. Preventive or therapeutic administration of B. animalis subsp. lactis appears to have some potential to beneficially influence dietary hyperoxaluria in mice.

Acute irreversible oxalate nephropathy in a lung transplant recipient treated successfully with a renal transplant.

We report a 29 year old male cystic fibrosis patient with end stage lung disease and normal renal function who underwent a sequential double lung transplant. Medical history included: an ileal resection and pancreatic exocrine dysfunction. The postoperative period was complicated with haemorrhage and repeat surgery, requiring multiple blood transfusions and extensive antibiotic cover. Pancreatic supplements were interrupted. Acute renal failure attributed to haemodynamically-mediated acute tubular necrosis was managed expectantly. He remained dialysis dependent 8 weeks post surgery and was maintained on triple immunosuppression with tacrolimus, mycophenolate and prednisolone. A DTPA study was consistent with ATN. Renal biopsy revealed features consistent with tubular injury due to acute oxalate nephropathy (AON). Further biochemical characterization excluded primary hyperoxaluria but confirmed increased 24 hour urinary oxalate. He was maintained on enhanced frequency HDF and subsequently received an uncomplicated live related renal transplant 10 months post lung transplant with only additional basiliximab. Calcium carbonate was continued to manage post transplant hyperoxaluria and an early renal biopsy excluded recurrent oxalate injury. Enteric hyperoxaluria due to malabsorption in patients with CF especially with ileal resection, in addition to loss of gut Oxalobacter formigenes due to prolonged antimicrobials, increases the risk of AON. Increased awareness of this condition and screening prior to lung transplant is recommended.

Impact of dietary calcium and oxalate, and Oxalobacter formigenes colonization on urinary oxalate excretion.

PURPOSE: Enteric colonization with Oxalobacter formigenes, a bacterium whose main energy source is oxalate, has been demonstrated to decrease the risk of recurrent calcium oxalate kidney stone formation. We assessed the impact of diets controlled in calcium and oxalate contents on urinary and fecal analytes in healthy subjects who were naturally colonized with O. formigenes or not colonized with O. formigenes. MATERIALS AND METHODS: A total of 11 O. formigenes colonized and 11 noncolonized subjects were administered diets controlled in calcium and oxalate contents. We assayed 24-hour urine collections and stool samples obtained on the last 4 days of each 1-week diet for stone risk parameters and O. formigenes levels. Mixed model analysis was used to determine the effects of colonization status on these variables. RESULTS: Urinary calcium and oxalate excretion were significantly altered by the dietary changes in O. formigenes colonized and noncolonized individuals. Mixed model analysis showed significant interaction between colonization status and oxalate excretion on a low calcium (400 mg daily)/moderate oxalate (250 mg daily) diet (p = 0.026). Urinary oxalate excretion was 19.5% lower in O. formigenes colonized subjects than in noncolonized subjects on the low calcium/moderate oxalate diet (mean ± SE 34.9 ± 2.6 vs 43.6 ± 2.6 mg, p = 0.031). CONCLUSIONS: Results suggest that O. formigenes colonization decreases oxalate excretion during periods of low calcium and moderate oxalate intake.

Rapid reversal of hyperoxaluria in a rat model after probiotic administration of Oxalobacter formigenes.

PURPOSE: The gut inhabiting bacterium Oxalobacter formigenes may be a negative risk factor in recurrent calcium oxalate kidney stone disease that apparently maintains oxalic acid homeostasis in its host via the degradation of dietary oxalate. The possibility of using this bacterium as probiotic treatment to reduce urinary oxalate was investigated in a rat model. MATERIALS AND METHODS: Male Sprague-Dawley rats were placed on a diet supplemented with ammonium oxalate to induce a state of severe hyperoxaluria. Subgroups of these rats received an esophageal gavage of 1 x 10(3), 10(5), 10(7) or 10(9) O. formigenes per feeding for a 2-week period. Each rat was followed for general health and changes in urinary oxalate. RESULTS: Rats with chronic hyperoxaluria resulting from high dietary oxalate that were treated with O. formigenes showed decreased urinary oxalate within 2 days of initiating probiotic supplementation. The amount of the decrease in a 2-week period proved directly proportional to the dose of bacteria. Urinary oxalate in rats receiving higher amounts of O. formigenes returned to almost normal. Throughout the study the rats remained healthy with no signs of toxicity, antibody development or a histopathological condition. CONCLUSIONS: Probiotic treatment of hyperoxaluric rats with O. formigenes may significantly and rapidly reduce the level of oxalate in the urine. This probiotic treatment appears to be safe and well tolerated. The approach may be feasible for treating calcium oxalate kidney stone disease.