Navigating the Evolving Landscape of Primary Hyperoxaluria: Traditional Management Defied by the Rise of Novel Molecular Drugs.

Primary hyperoxalurias (PHs) are inherited metabolic disorders marked by enzymatic cascade disruption, leading to excessive oxalate production that is subsequently excreted in the urine. Calcium oxalate deposition in the renal tubules and interstitium triggers renal injury, precipitating systemic oxalate build-up and subsequent secondary organ impairment. Recent explorations of novel therapeutic strategies have challenged and necessitated the reassessment of established management frameworks. The execution of diverse clinical trials across various medication classes has provided new insights and knowledge. With the evolution of PH treatments reaching a new milestone, prompt and accurate diagnosis is increasingly critical. Developing early, effective management and treatment plans is essential to improve the long-term quality of life for PH patients.

A molecular journey on the pathogenesis of primary hyperoxaluria.

PURPOSE OF REVIEW: Primary hyperoxalurias (PHs) are rare disorders caused by the deficit of liver enzymes involved in glyoxylate metabolism. Their main hallmark is the increased excretion of oxalate leading to the deposition of calcium oxalate stones in the urinary tract. This review describes the molecular aspects of PHs and their relevance for the clinical management of patients. RECENT FINDINGS: Recently, the study of PHs pathogenesis has received great attention. The development of novel in vitro and in vivo models has allowed to elucidate how inherited mutations lead to enzyme deficit, as well as to confirm the pathogenicity of newly-identified mutations. In addition, a better knowledge of the metabolic consequences in disorders of liver glyoxylate detoxification has been crucial to identify the key players in liver oxalate production, thus leading to the identification and validation of new drug targets. SUMMARY: The research on PHs at basic, translational and clinical level has improved our knowledge on the critical factors that modulate disease severity and the response to the available treatments, leading to the development of new drugs, either in preclinical stage or, very recently, approved for patient treatment.

Nephrocalcinosis can disappear in infants receiving early lumasiran therapy.

BACKGROUND: Lumasiran is the first RNA interference (RNAi) therapy of primary hyperoxaluria type 1 (PH1). Here, we report on the rapid improvement and even disappearance of nephrocalcinosis after early lumasiran therapy. CASE-DIAGNOSIS/TREATMENT: In patient 1, PH1 was suspected due to incidental discovery of nephrocalcinosis stage 3 in a 4-month-old boy. Bilateral nephrocalcinosis stage 3 was diagnosed in patient 2 at 22 months concomitantly to acute pyelonephritis. Urinary oxalate (UOx) and glycolate (UGly) were increased in both patients allowing to start lumasiran therapy before genetic confirmation. Nephrocalcinosis started to improve and disappeared after 27 months and 1 year of treatment in patients 1 and 2, respectively. CONCLUSION: These cases illustrate the efficacy of early lumasiran therapy in infants to improve and even normalize nephrocalcinosis. As proposed in the 2023 European guidelines, the interest of starting treatment quickly without waiting for genetic confirmation may have an impact on long-term outcomes.

Efficient and safe therapeutic use of paired Cas9-nickases for primary hyperoxaluria type 1.

The therapeutic use of adeno-associated viral vector (AAV)-mediated gene disruption using CRISPR-Cas9 is limited by potential off-target modifications and the risk of uncontrolled integration of vector genomes into CRISPR-mediated double-strand breaks. To address these concerns, we explored the use of AAV-delivered paired Staphylococcus aureus nickases (D10ASaCas9) to target the Hao1 gene for the treatment of primary hyperoxaluria type 1 (PH1). Our study demonstrated effective Hao1 gene disruption, a significant decrease in glycolate oxidase expression, and a therapeutic effect in PH1 mice. The assessment of undesired genetic modifications through CIRCLE-seq and CAST-Seq analyses revealed neither off-target activity nor chromosomal translocations. Importantly, the use of paired-D10ASaCas9 resulted in a significant reduction in AAV integration at the target site compared to SaCas9 nuclease. In addition, our study highlights the limitations of current analytical tools in characterizing modifications introduced by paired D10ASaCas9, necessitating the development of a custom pipeline for more accurate characterization. These results describe a positive advance towards a safe and effective potential long-term treatment for PH1 patients.

In vivo base editing rescues primary hyperoxaluria type 1 in rats.

Primary hyperoxaluria type 1 (PH1) is a childhood-onset autosomal recessive disease, characterized by nephrocalcinosis, multiple recurrent urinary calcium oxalate stones, and a high risk of progressive kidney damage. PH1 is caused by inherent genetic defects of the alanine glyoxylate aminotransferase (AGXT) gene. The in vivo repair of disease-causing genes was exceedingly inefficient before the invention of base editors which can efficiently introduce precisely targeted base alterations without double-strand DNA breaks. Adenine base editor (ABE) can precisely convert A·T to G·C with the assistance of specific guide RNA. Here, we demonstrated that systemic delivery of dual adeno-associated virus encoding a split-ABE8e could artificially repair 13% of the pathogenic allele in AgxtQ84X rats, a model of PH1, alleviating the disease phenotype. Specifically, ABE treatment partially restored the expression of alanine-glyoxylate-aminotransferase (AGT), reduced endogenous oxalate synthesis and alleviated calcium oxalate crystal deposition. Western blot and immunohistochemistry confirmed that ABE8e treatment restored AGT protein expression in hepatocytes. Moreover, the precise editing efficiency in the liver remained stable six months after treatment. Thus, our findings provided a prospect of in vivo base editing as a personalized and precise medicine for PH1 by directly correcting the mutant Agxt gene.

Multiplex gene editing reduces oxalate production in primary hyperoxaluria type 1.

Targeting key enzymes that generate oxalate precursors or substrates is an alternative strategy to eliminate primary hyperoxaluria type I (PH1), the most common and life-threatening type of primary hyperoxaluria. The compact Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) from the Prevotella and Francisella 1 (Cpf1) protein simplifies multiplex gene editing and allows for all-in-one adeno-associated virus (AAV) delivery. We hypothesized that the multiplex capabilities of the Cpf1 system could help minimize oxalate formation in PH1 by simultaneously targeting the hepatic hydroxyacid oxidase 1 ( Hao1) and lactate dehydrogenase A ( Ldha) genes. Study cohorts included treated PH1 rats ( Agxt Q84X rats injected with AAV-AsCpf1 at 7 days of age), phosphate-buffered saline (PBS)-injected PH1 rats, untreated PH1 rats, and age-matched wild-type (WT) rats. The most efficient and specific CRISPR RNA (crRNA) pairs targeting the rat Hao1 and Ldha genes were initially screened ex vivo. In vivo experiments demonstrated efficient genome editing of the Hao1 and Ldha genes, primarily resulting in small deletions. This resulted in decreased transcription and translational expression of Hao1 and Ldha. Treatment significantly reduced urine oxalate levels, reduced kidney damage, and alleviated nephrocalcinosis in rats with PH1. No liver toxicity, ex-liver genome editing, or obvious off-target effects were detected. We demonstrated the AAV-AsCpf1 system can target multiple genes and rescue the pathogenic phenotype in PH1, serving as a proof-of-concept for the development of multiplex genome editing-based gene therapy.

Is withdrawal of nocturnal hyperhydration possible in children with primary hyperoxaluria treated with RNAi?

Primary hyperoxaluria type 1 is a rare genetic disorder caused by bi-allelic pathogenic variants in the AGXT gene leading to an overproduction of oxalate which accumulates in the kidneys in the form of calcium oxalate crystals. Thus, patients may present with recurrent nephrocalcinosis and lithiasis, with progressive impairment of the  renal function and eventually kidney failure.  There is no specific treatment besides liver-kidney transplantation, and pre-transplantation management by 24 h-hyperhydration, crystallisation inhibitors and high-dose pyridoxine has a high negative impact on quality of life, especially because of the discomfort due to nocturnal hyperhydration. Since 2020, lumasiran, an RNA-interfering therapy, has been approved for the treatment of primary hyperoxaluria type 1 in adults and children. However, to date, there are no recommendations regarding the discontinuation of other supportive measures during RNAi therapy. In this report, we present two patients with primary hyperoxaluria type 1 who were treated with lumasiran and stopped nocturnal hyperhydration with positive outcomes, i.e. normal urinary oxalate, absence of crystalluria, stable kidney function and improved well-being. These data suggest that discontinuing nocturnal hydration may be safe in children responding to lumasiran, and may have a positive impact on their quality of life. Additional data are needed to update treatment recommendations.

Simple, fast and inexpensive quantification of glycolate in the urine of patients with primary hyperoxaluria type 1.

In primary hyperoxaluria type 1 excessive endogenous production of oxalate and glycolate leads to increased urinary excretion of these metabolites. Although genetic testing is the most definitive and preferred diagnostic method, quantification of these metabolites is important for the diagnosis and evaluation of potential therapeutic interventions. Current metabolite quantification methods use laborious, technically highly complex and expensive liquid, gas or ion chromatography tandem mass spectrometry, which are available only in selected laboratories worldwide. Incubation of ortho-aminobenzaldehyde (oABA) with glyoxylate generated from glycolate using recombinant mouse glycolate oxidase (GO) and glycine leads to the formation of a stable dihydroquinazoline double aromatic ring chromophore with specific peak absorption at 440 nm. The urinary limit of detection and estimated limit of quantification derived from eight standard curves were 14.3 and 28.7 µmol glycolate per mmol creatinine, respectively. High concentrations of oxalate, lactate and L-glycerate do not interfere in this assay format. The correlation coefficient between the absorption and an ion chromatography tandem mass spectrometry method is 93% with a p value < 0.00001. The Bland-Altmann plot indicates acceptable agreement between the two methods. The glycolate quantification method using conversion of glycolate via recombinant mouse GO and fusion of oABA and glycine with glyoxylate is fast, simple, robust and inexpensive. Furthermore this method might be readily implemented into routine clinical diagnostic laboratories for glycolate measurements in primary hyperoxaluria type 1.

Clinical practice recommendations for primary hyperoxaluria: an expert consensus statement from ERKNet and OxalEurope.

Primary hyperoxaluria (PH) is an inherited disorder that results from the overproduction of endogenous oxalate, leading to recurrent kidney stones, nephrocalcinosis and eventually kidney failure; the subsequent storage of oxalate can cause life-threatening systemic disease. Diagnosis of PH is often delayed or missed owing to its rarity, variable clinical expression and other diagnostic challenges. Management of patients with PH and kidney failure is also extremely challenging. However, in the past few years, several new developments, including new outcome data from patients with infantile oxalosis, from transplanted patients with type 1 PH (PH1) and from patients with the rarer PH types 2 and 3, have emerged. In addition, two promising therapies based on RNA interference have been introduced. These developments warrant an update of existing guidelines on PH, based on new evidence and on a broad consensus. In response to this need, a consensus development core group, comprising (paediatric) nephrologists, (paediatric) urologists, biochemists and geneticists from OxalEurope and the European Rare Kidney Disease Reference Network (ERKNet), formulated and graded statements relating to the management of PH on the basis of existing evidence. Consensus was reached following review of the recommendations by representatives of OxalEurope, ESPN, ERKNet and ERA, resulting in 48 practical statements relating to the diagnosis and management of PH, including consideration of conventional therapy (conservative therapy, dialysis and transplantation), new therapies and recommendations for patient follow-up.

ePHex: a phase 3, double-blind, placebo-controlled, randomized study to evaluate long-term efficacy and safety of Oxalobacter formigenes in patients with primary hyperoxaluria.

BACKGROUND: Primary hyperoxalurias (PHs) are rare genetic diseases that increase the endogenous level of oxalate, a waste metabolite excreted predominantly by the kidneys and also the gut. Treatments aim to improve oxalate excretion, or reduce oxalate generation, to prevent kidney function deterioration. Oxalobacter formigenes is an oxalate metabolizing bacterium. This Phase III, double-blind, placebo-controlled randomized trial investigated the effectiveness of orally administered Oxabact™, a lyophilized O. formigenes formulation, at reducing plasma oxalate levels in patients suffering from PH. METHODS: Subjects (≥ 2 years of age) with a diagnosis of PH and maintained but suboptimal kidney function (mean estimated glomerular filtration rate at baseline < 90 mL/min/1.73 m2) were eligible to participate. Subjects were randomized to receive Oxabact or placebo twice daily for 52 weeks. Change from baseline in plasma oxalate concentration at Week 52 was the primary study endpoint. RESULTS: Forty-three subjects were screened, 25 were recruited and one was discontinued. At Week 52, O. formigenes was established in the gut of subjects receiving Oxabact. Despite decreasing plasma oxalate level in subjects treated with Oxabact, and stable/increased levels with placebo, there was no significant difference between groups in the primary outcome (Least Squares mean estimate of treatment difference was - 3.80 µmol/L; 95% CI: - 7.83, 0.23; p-value = 0.064). Kidney function remained stable in both treatments. CONCLUSIONS: Oxabact treatment may have stabilized/reduced plasma oxalate versus a rise with placebo, but the difference over 12 months was not statistically significant (p = 0.06). A subtle effect observed with Oxabact suggests that O. formigenes may aid in preventing kidney stones. A higher resolution version of the Graphical abstract is available as Supplementary information.

Cutaneous Oxalosis Due to Primary Hyperoxaluria.

ABSTRACT: A 19-year-old girl presented to the emergency department with a progressively painful purpuric lesion on the left dorsal foot, which had initially appeared 2 days prior. Three months earlier, she had been diagnosed with end-stage renal disease. Her medical history also included recurrent urolithiasis for the past 5 years and liver failure. Biopsy revealed oxalate crystals occluding vessels with secondary epidermal and dermal ischemia. Oxalate crystals were also visualized in the vessel walls and free in the subcutis. Genetic testing confirmed the diagnosis of primary hyperoxaluria type 1. She was treated with sodium thiosulfate, apixaban, pentoxifylline, wound care, and palliative care. At 4-month follow-up, the cutaneous manifestations of oxalosis were confined to only her feet, and she was undergoing evaluation for combined liver and kidney transplant. Cutaneous oxalosis because of primary hyperoxaluria should be considered in young patients presenting with purpuric lesions, recurrent urolithiasis, and early-onset renal failure.

[Bilateral nephrocalcinosis: primary hyperoxaluria involved]. / Néphrocalcinose bilatérale : l'hyperoxalurie primitive en cause.

Primary hyperoxaluria type 1 is a rare autosomal recessive disorder leading to oxalate overproduction by deficiency in the liver-specific enzyme alanine-glyoxylate transaminase (AGT). Oxalate is a poorly soluble molecule that binds calcium and deposits in the entire organism leading to oxalosis. Its elimination is mainly carried out by kidneys. Hence the first manifestations are frequently of urinary concern and whitout any early care, progression of the disease to end-stage renal failure cannot be avoided. The only etiological treatment has long been combined liver-kidney transplantation because it restaures enzymatic function and replaces pathological kidneys. However, for a few years now, numerous studies are carried out on this subject and promising results have already been published with a new drug, lumasiran. From a clinical case, we describe the different options for the therapeutic management of primary hyperoxaluria type 1.

L'hyperoxalurie primitive de type 1 (HP1) est une maladie autosomale récessive rare entraînant une hyperproduction d'oxalate par déficit d'une enzyme hépatique : l'alanine-glyoxylate aminotransférase. L'oxalate est une petite molécule peu soluble qui se lie au calcium et forme des dépôts d'oxalate calcique dans l'ensemble de l'organisme : c'est l'oxalose. Son élimination est principalement rénale. Dès lors, les premières manifestations sont souvent d'ordre urinaire et, en l'absence de traitement précoce, la maladie évolue inévitablement vers l'insuffisance rénale terminale. Le seul traitement étiologique a longtemps été la transplantation combinée hépatique et rénale qui restaure une activité enzymatique et remplace les reins défaillants. Cependant, depuis quelques années, de nombreuses recherches sont réalisées à ce sujet et des résultats prometteurs ont déjà vu le jour avec le lumasiran. à partir d'un cas clinique, nous décrivons les différentes options de la prise en charge thérapeutique de l'HP1.

Progress with RNA Interference for the Treatment of Primary Hyperoxaluria.

Over the last few years, US Food and Drug Administration-approved drugs using RNA interference have come to the market. Many have treated liver-specific diseases utilizing N-acetyl galactosamine conjugation because of its effective delivery and limited off-target effects. The autosomal recessive disorder primary hyperoxaluria, specifically type 1, has benefited from these developments. Primary hyperoxaluria arises from mutations in the enzymes involved in endogenous oxalate synthesis. The severity of disease varies but can result in kidney failure and systemic oxalosis. Until recently, the treatment options were limited and focused primarily on supportive treatments, pyridoxine use in a subset of patients with primary hyperoxaluria type 1, and liver-kidney transplants in those who progressed to kidney failure. Two genes have been targeted with RNA interference; lumasiran targets glycolate oxidase and nedosiran targets lactate dehydrogenase A. Lumasiran was recently approved in the treatment of primary hyperoxaluria type 1 and nedosiran is in the approval process. Unfortunately, despite initial hopes that nedosiran may also be a treatment option for primary hyperoxaluria types 2 and 3, initial data suggest otherwise. The use of RNA interference liver-specific targeting for the treatment of primary hyperoxaluria type 1 will likely transform the natural history of the disease.

New salicylic acid derivatives, double inhibitors of glycolate oxidase and lactate dehydrogenase, as effective agents decreasing oxalate production.

The synthesis and biological evaluation of double glycolate oxidase/lactate dehydrogenase inhibitors containing a salicylic acid moiety is described. The target compounds are obtained in an easily scalable two-step synthetic procedure. These compounds showed low micromolar IC50 values against the two key enzymes in the metabolism of glyoxylate. Mechanistically they behave as noncompetitive inhibitors against both enzymes and this fact is supported by docking studies. The biological evaluation also includes in vitro and in vivo assays in hyperoxaluric mice. The compounds are active against the three types of primary hyperoxalurias. Also, possible causes of adverse effects, such as cyclooxygenase inhibition or renal toxicity, have been studied and discarded. Altogether, this makes this chemotype with drug-like structure a good candidate for the treatment of primary hyperoxalurias.