Primary Hyperoxaluria Type Research Articles

Primary hyperoxaluria type 3: from infancy to adulthood in a genetically unique cohort.

Primary hyperoxaluria type 3 (PH3) is a rare autosomal recessive disorder caused by bi-allelic genetic variants in the 4 hydroxy-2 oxoglutarate aldolase (HOGA-1) gene. We report the natural history of PH3 in a 16-patient cohort, 15 from a unique genetically isolated population. This retrospective single-center study followed PH3 patients between 2003 and 2023 with demographic, clinical, radiographic, genetic, and biochemical parameters. Genetic population screening was performed in four villages to determine carrier frequency and identify couples at risk in a genetically isolated population. Sixteen patients with biallelic (or homozygous) pathogenic variants (PV) in HOGA-1 (c.944_946 del, c.119C > A, c.208C > T) were included in the study, 15 Druze and one Jewish, aged 0-63years at diagnosis (4 adults and 12 pediatric patients). All symptomatic patients had clinical or imaging signs of nephrolithiasis. One developed chronic kidney disease (CKD) stage 5; biopsy showed focal mesangial sclerosis and chronic tubulo-interstitial changes with few oxalate deposits. Two other patients had CKD stage 2 (eGFR 87 and 74mL/min/1.73m2) upon their last visit. The remaining cohort showed preserved kidney function until the latest follow-up. Of 1167 healthy individuals screened, 90 carriers were found, a rate of 1:13 in the genetically unique cohort screened. A high prevalence of PH3 patients was found among a unique cohort, but probably still underdiagnosed due to relatively mild disease course. The carrier rate is high. There is no specific therapy for PH3, but early diagnosis can prevent redundant diagnostic efforts and provide early treatment for kidney stone disease. Even in our homogeneous cohort, kidney stone disease severity and CKD degree were variable, supporting a suspected contribution of yet unknown genetic or environmental factors.

Genetics in nephrology - any news?

While genetic kidney diseases were long regarded as a rare cause of kidney failure, it has been shown in recent years that they account for a relevant proportion of cases. In cohorts of kidney transplant recipients, a monogenic cause is found in up to 30% of cases. Identifying the genetic cause of kidney disease has become much easier thanks to technological advances in DNA sequencing. The focus has now shifted to understanding the significance of the findings and identifying diagnostic gaps. It is still not possible to clarify all CKD cases of unclear aetiology. Besides very effective generic treatments for monogenic kidney disease (e.g., ACE-inhibitor use in Alport Syndrome), increasing knowledge of the pathophysiology of genetic kidney diseases has led to a growing number of targeted therapies. These include the treatment of ADPKD with Tolvaptan, which has now been in use for 10 years. Recently, exciting, and completely new approaches have been added, such as the first siRNA therapies in nephrology for primary hyperoxaluria type 1, the targeted treatment of hyperphagia in Bardet-Biedl syndrome, the therapy of APOL1-associated kidney disease or the use of the HIF-2 antagonist Belzutifan for renal cell carcinoma associated with Von-Hippel-Lindau syndrome. The new possibilities in the treatment of patients with genetic kidney diseases have also clearly revealed deficits in current patient care. Centers of excellence with extensive experience in this area therefore play an important role in improving care. This also applies to the further training of colleagues in the field. In Germany, the National Action Alliance for People with Rare Diseases (NAMSE) and the nationwide establishment of - to date - 36 centers for rare diseases play an important role in this regard.

Oxygen control in bioreactor drives high yield production of functional hiPSC-like hepatocytes for advanced liver disease modelling

Hepatocytes-like cells (HLC) derived from human induced pluripotent stem cells show great promise for cell-based liver therapies and disease modelling. However, their application is currently hindered by the low production yields of existing protocols. We aim to develop a bioprocess able to generate high numbers of HLC. We used stirred-tank bioreactors with a rational control of dissolved oxygen concentration (DO) for the optimization of HLC production as 3D aggregates. We evaluated the impact of controlling DO at physiological levels (4%O2) during hepatic progenitors’ stage on cell proliferation and differentiation efficiency. Whole transcriptome analysis and biochemical assays were performed to provide a detailed characterization of HLC quality attributes. When DO was controlled at 4%O2 during the hepatic progenitors’ stage, cells presented an upregulation of genes associated with hypoxia-inducible factor pathway and a downregulation of oxidative stress genes. This condition promoted higher HLC production (maximum cell concentration: 2 × 106 cell/mL) and improved differentiation efficiencies (80% Albumin-positive cells) when compared to the bioreactor operated under atmospheric oxygen levels (21%O2, 0.6 × 106 cell/mL, 43% Albumin positive cells). These HLC exhibited functional characteristics of hepatocytes: capacity to metabolize drugs, ability to synthesize hepatic metabolites, and inducible cytochrome P450 activity. Bioprocess robustness was confirmed with HLC derived from different donors, including a primary hyperoxaluria type 1 (PH1) patient. The generated PH1.HLC showed metabolic features of PH1 disease with higher secretion of oxalate compared with HLC generated from healthy individuals. This work reports a reproducible bioprocess, that shows the importance of controlling DO at physiological levels to increase HLC production, and the HLC capability to display PH1 disease features.

Lipid nanoparticle-mediated base-editing of the Hao1 gene achieves sustainable primary hyperoxaluria type 1 therapy in rats.

Primary hyperoxaluria type 1 (PH1) is a severe hereditary disease, leading to the accumulation of oxalate in multiple organs, particularly the kidney. Hydroxyacid oxidase 1 (HAO1), a pivotal gene involved in oxalate production, is an approved target for the treatment of PH1. In this study, we demonstrated the discovery of several novel therapeutic sites of the Hao1 gene and the efficient editing of Hao1 c.290-2 A in vivo with lipid nanoparticles (LNP) delivered adenine base editing (ABE) mRNA. A single infusion of LNP-ABE resulted in a near-complete knockout of Hao1 in the liver, leading to the sustainable normalization of urinary oxalate (for at least 6 months) and complete rescue of the patho-physiology in PH1 rats. Additionally, a significant correlation between Hao1 editing efficiency and urinary oxalate levels was observed and over 60% Hao1 editing efficiency was required to achieve the normalization of urinary oxalate in PH1 rats. These findings suggest that the LNP-mediated base-editing of Hao1 c.290-2 A is an efficient and safe approach to PH1 therapy, highlighting its potential utility in clinical settings.

Simultaneous or sequential kidney-liver transplantation in primary hyperoxaluria.

Primary hyperoxaluria type 1 is responsible for pediatric kidney failure in 1 to 2% of cases. Novel therapies based on RNA interference are changing the natural history of the disease. However, for those who do progress to kidney failure, and for patients living in countries that cannot afford these expensive therapies, liver-kidney transplantation may remain the only efficient therapy. The aim of the study was to evaluate the outcome of patients with primary hyperoxaluria type 1 who received simultaneous or sequential liver-kidney transplantation. We retrospectively evaluated 10 patients, five of whom received a simultaneous transplantation, and five underwent sequential transplantation, with a median postponement of the kidney transplantation of 8months (range 4-20). Among the patients, 5 were from medium-lowincome countries. Median follow up was 3.2years (range 1.6-11). Median estimated glomerular filtration rate at 6 and 12months was 81.2 (range: 45.7-108.8) and 79.3ml/min/1.73m2 (range 54.7-112.1) in patients who underwent simultaneous transplantation, and 45.7 (range 34.5-86.7) and 38.3ml/min/1.73m2 (range 29.9-77.5) in those with sequential transplantation (p:NS). Biopsies performed at 6 and 12months showed precipitation of calcium oxalate crystals in 7 patients, demonstrating the recurrence of deposition despite the delay between liver and kidney transplantation. No differences in kidney function or in post-transplant renal oxalate precipitation were observed between patients that underwent bilateral nephrectomy and those who did not. As of their most recent follow up, none of the patients has lost their kidney graft. Our study shows that by adapting the transplant strategy to individual cases, patients with primary hyperoxaluria type 1 can be successfully treated.

Efficient and safe in vivo treatment of primary hyperoxaluria type 1 via LNP-CRISPR-Cas9-mediated disruption of glycolate oxidase

Primary hyperoxaluria type 1 (PH1) is a severe genetic metabolic disorder caused by mutations in the AGXT gene, leading to defects in enzymes crucial for glyoxylate metabolism. PH1 is characterized by severe, potentially life-threatening manifestations due to excessive oxalate accumulation, which leads to calcium oxalate crystal deposits in the kidneys and, ultimately, renal failure and systemic oxalosis. Existing substrate reduction therapies, such as inhibition of liver-specific glycolate oxidase (GO) encoded by HAO1 using siRNA or CRISPR/Cas9 delivered by adeno-associated virus (AAV), either require repeated dosing or have raised safety concerns. To address these limitations, our study employed lipid nanoparticles (LNPs) for CRISPR/Cas9 delivery to rapidly generate a PH1 mouse model and validate the therapeutic efficacy of LNP-CRISPR/Cas9 targeting the Hao1 gene. The LNP-CRISPR/Cas9 system exhibited efficient editing of the Hao1 gene, significantly reducing GO expression and lowering urinary oxalate levels in treated PH1 mice. Notably, these effects persisted for 12 months with no significant off-target effects, liver-induced toxicity, or substantial immune responses, highlighting the approach's safety and specificity. Furthermore, the developed humanized mouse model validated the efficacy of our therapeutic strategy. These findings support LNP-CRISPR/Cas9 targeting HAO1 as a promising and safer alternative for PH1 treatment with a single administration.

Effective Newborn Screening for Type 1 and 3 Primary Hyperoxaluria

IntroductionNewborn Screening programs for a defined set of eligible diseases have been enormously successful, but genomic newborn screening allowing for detection of additional treatable disorders has not been broadly implemented. All three types of primary hyperoxaluria (PH1-3) are rare autosomal recessive diseases caused by distinct defects of glyoxylate metabolism that are diagnosed genetically with certainty. Early diagnosis and treatment are mandatory to avoid renal failure or sequalae associated with persistent hyperoxaluria. MethodsThe prospective pilot study was undertaken within the framework of the German Newborn Screening. DNA samples extracted from dried blood spot cards were screened by multiplex PCR for the two most prevalent mutations: AGXT c.508G>A (PH1) and HOGA1 c.700+5G>T (PH3). Heterozygous AGXT/HOGA1 carriers received repeated spot urine analyses and, in case of persistent hyperoxaluria, complete Sanger sequencing of AGXT and HOGA1 gene, respectively. ResultsBetween March 15th 2022 and June 30th 2023 additional screening for PH1 and PH3 was performed in 77199 out of 222638 newborns included in the regular newborn screening program. No homozygous individuals, but 274 potential carriers for the AGXT mistargeting and 287 potential carriers for the HOGA1 splice variant were identified. Further work up revealed two already symptomatic compound heterozygous infants, one with PH1 (genotype c.508G>A; c.33delC) and one with PH3 (genotype: c.700+5G>T;c.134C>G). A second symptomatic PH1 patient (father of an identified carrier; genotype: c.508G>A;c.508G>A) was uncovered via family history. ConclusionThis pilot study demonstrated the efficacy of a genomic neonatal screening program for primary hyperoxaluria even in relatively small cohorts.

Long-Term Efficacy and Safety of Lumasiran in Patients with Primary Hyperoxaluria Type 1: Final Analysis of the ILLUMINATE-A Trial

Long-Term Efficacy and Safety of Lumasiran in Patients with Primary Hyperoxaluria Type 1: Final Analysis of the ILLUMINATE-A Trial

Less Is More: A Case of Isolated Kidney Transplantation with Lumasiran in Primary Hyperoxaluria Type 1

Less Is More: A Case of Isolated Kidney Transplantation with Lumasiran in Primary Hyperoxaluria Type 1

PHYOX3: Long-Term Safety and Efficacy of Nedosiran in Patients with Primary Hyperoxaluria Type 1

PHYOX3: Long-Term Safety and Efficacy of Nedosiran in Patients with Primary Hyperoxaluria Type 1

Kidney Function and Isolated Kidney Transplant Outcomes in Primary Hyperoxaluria Type 1 Treated with Long-Term Lumasiran

Kidney Function and Isolated Kidney Transplant Outcomes in Primary Hyperoxaluria Type 1 Treated with Long-Term Lumasiran

Development of ABO-101, a Novel Gene Editing Therapy for Primary Hyperoxaluria Type 1

Development of ABO-101, a Novel Gene Editing Therapy for Primary Hyperoxaluria Type 1

Efficacy and safety of lumasiran for infants and young children with primary hyperoxaluria type 1: 30-month analysis of the phase 3 ILLUMINATE-B trial

BackgroundPrimary hyperoxaluria type 1 (PH1) is a genetic disorder resulting in overproduction of hepatic oxalate, potentially leading to recurrent kidney stones, nephrocalcinosis, chronic kidney disease, and kidney failure. Lumasiran, the first RNA interference therapeutic approved for infants and young children, is a liver-directed treatment that reduces hepatic oxalate production. Lumasiran demonstrated sustained efficacy with an acceptable safety profile over 12 months in infants and young children (age <6 years) with PH1 in ILLUMINATE-B (clinicaltrials.gov: NCT03905694), an ongoing, Phase 3, multinational, open-label, single-arm study.MethodsHere, we report interim efficacy and safety findings from ILLUMINATE-B following 30 months of lumasiran treatment. Eligible patients had an estimated glomerular filtration rate (eGFR) >45 ml/min/1.73 m2 if ≥12 months old or normal serum creatinine if <12 months old, and a urinary oxalate to creatinine ratio (UOx:Cr) greater than the upper limit of normal. All 18 patients enrolled in ILLUMINATE-B completed the 6-month primary analysis period, entered an extension period of up to 54 months, and continue to participate in the study.ResultsAt Month 30, mean percent change from baseline in spot UOx:Cr was −76%, and mean percent change in plasma oxalate was −42%. eGFR remained stable through Month 30. In 14 patients (86%) with nephrocalcinosis at baseline, nephrocalcinosis grade improved at Month 24 in 12; no patient worsened. In the 4 patients without baseline nephrocalcinosis, nephrocalcinosis was absent at Month 24. Kidney stone event rates were ≤0.25 per person-year through Month 30. Mild, transient injection site reactions were the most common lumasiran-related adverse events (17% of patients).ConclusionIn infants and young children with PH1, long-term lumasiran treatment resulted in sustained reductions in urinary and plasma oxalate that were sustained for 30 months, with an acceptable safety profile. Kidney function remained stable, low kidney stone event rates were observed through Month 30, and nephrocalcinosis grade improvements were observed through Month 24. Clinical Trial Registrationhttps://clinicaltrials.gov, identifier NCT03905694.

A case report on primary hyperoxaluria type 1 in an infant

An alanine-glyoxylate aminotransferase (AGT) deficiency causes elevated oxalate levels in primary hyperoxaluria type 1 (PH1), a rare genetic disorder that can cause renal complications. We report the case of a 3-month-old male infant with respiratory distress, decreased urine output, and metabolic acidosis who was born to consanguineous parents. Bilateral nephrocalcinosis and severe metabolic disturbances were found during further examinations. Prompt identification and genetic validation for therapeutic interventions guided by PH1, such as peritoneal dialysis. The severity of PH1 was highlighted by difficulties maintaining renal function even after an initial improvement. To lessen the severe effects of PH1, this case highlights the significance of early diagnosis, genetic evaluation, and multidisciplinary management.

Nedosiran population pharmacokinetic and pharmacodynamic modelling and simulation to guide clinical development and dose selection in patients with primary hyperoxaluria type 1.

To characterize pharmacokinetic and pharmacodynamic profiles of nedosiran in patients with primary hyperoxaluria type 1 (PH1), identify influential covariates and confirm therapeutic doses. A population pharmacokinetic (PK)/pharmacodynamic (PD) (POP-PKPD) model was developed to characterize the concentration-time course of nedosiran and the corresponding effect on 24-h urinary oxalate (Uox). Simulations of dosing to achieve clinically meaningful reduction in Uox in children, adolescents and adults with PH1 were performed. Analyses included PK data from 143 healthy participants and PH1/PH2 patients, and PD data from 46 PH1 patients. Nedosiran PK was described by a two-compartment model with dual n-transit absorption and parallel linear and nonlinear elimination. The relationship between nedosiran exposure and Uox was described by an indirect response model. Body weight, estimated glomerular filtration rate (eGFR) and disease status were identified as influential covariates for the POP-PK model. The simulation results supported a weight-banded dosing regimen of nedosiran sodium in adolescents and adults (≥12 years) with PH1 of 170 mg (weight ≥50 kg) and 136 mg (weight <50 kg), in children (6-11 years) with PH1 of 3.5mg/kg, and no dose adjustments for PH1 patients with relatively preserved kidney function (eGFR ≥ 30 mL/min/1.73m2). Following the proposed dosing regimens, the simulated median fold-changes in PK AUC0-τ,ss were acceptable (≤1.51 fold-change) and ~71% of PH1 patients across all age groups achieved near-normal Uox (<0.6mmol) by week 52. The final POP-PKPD model characterizes observed nedosiran PK and Uox data. Simulations support nedosiran dosing regimens in PH1 patients aged ≥6years with relatively preserved kidney function.

The Evolving Role of Genetic Testing in Monogenic Kidney Stone Disease: Spotlight on Primary Hyperoxaluria.

Multiple factors are thought to give rise to common, recurrent kidney stone disease, but for monogenic stone disorders a firm diagnosis is possible through genetic testing. The autosomal recessive primary hyperoxalurias (PH) are rare forms of monogenic kidney stone disease. All 3 types of PH are caused by inborn errors of glyoxylate metabolism in the liver, leading to hepatic oxalate overproduction and excessive renal urinary oxalate excretion. These conditions are characterized by kidney stones, nephrocalcinosis, progressive chronic kidney disease, and kidney failure. Systemic oxalosis, the extra-renal deposition of oxalate resulting in severe morbidity and mortality, occurs in chronic kidney disease when oxalate clearance by the kidneys declines. Novel small interfering RNA-based therapeutics targeting the liver to reduce urinary oxalate excretion have been approved, introducing precision medicine to treat primary hyperoxaluria type 1. The goal of this narrative review is to address the benefits and practicalities of genetic testing for suspected monogenic kidney stone disease and the critical roles of a multidisciplinary team. We collated our procedures, education, training, and workflows to help other clinicians integrate genetic assessment into their diagnostic routines. In our experience, increased access to genetic testing facilitates early detection of PH and other monogenic causes of kidney stone disease so that individualized care can be instituted promptly. Alongside biochemical assessments, more widespread genetic testing may ensure more timely diagnoses so that patients with suspected monogenic kidney stone disease gain access to an expanded range of services and enrollment in clinical trials and registries.

Clinical analysis of seven cases of primary hyperoxaluria type 1

We retrospectively analyzed the clinical data of seven patients (four men and three women) with primary hyperoxaluria (PH) type 1 (PH1) in the Department of Nephrology of Zhongda Hospital, Southeast University from January 2018 to October 2023. The mean age at disease onset was 32.1 (range: 26-42) years. The mean age at diagnosis was 40.6 (range: 28-51) years. All patients initially had kidney stones, and three patients were found to have renal insufficiency at the time of disease onset. Among them, two patients underwent hemodialysis immediately. Symptoms at the first visit included bone pain (n=7), joint pain or deformity (n=5), fatigue (n=5), hypotension (n=3), and subcutaneous nodules (n=2). Four patients had a family history of PH. All patients had varying degrees of anemia (60-114 g/L), significant hypoalbuminemia (16.5-32.1 g/L), and hypercoagulable state (D-dimer: 2 230-12 781 μg/L). Seven patients received maintenance hemodialysis; their mean age was 37.7 (range: 26-50) years. The mean duration from disease onset to hemodialysis was 5.6 (range: 0-20) years. Five patients repeatedly experienced dialysis access dysfunction. Three patients underwent kidney transplantation before a diagnosis was made, and all transplanted kidneys lost function due to oxalate deposition. The mean follow-up duration was 14.43 (range: 4-38) months. Unfortunately, one patient died. All seven patients underwent computed tomography of the abdomen. All patients suffered skeletal abnormalities, bilateral nephrolithiasis, and nephrocalcinosis. Six patients carried AGXT gene mutations, including four compound heterozygous mutations and two pure homozygous mutations.The mutation sites included: c.823-824dup.AG (p.S275Rfs*38)(exon 8), c.815-816ins.GA (p.S275Rfs*38)(exon 8), c.595G>A (p.G199S) (exon 5), c.32C>G (p.P11R) (exon 1), and c.638C>T (p.A213V)(exon 6). According to the American College of Medical Genetics and Genomics guidelines, two loci were identified as likely pathogenic variants, seven were identified as pathogenic variants, and one locus was identified as having uncertain significance. In addition, patients 1 and 4 underwent skin biopsy, patient 2 underwent renal transplant biopsy, and patient 3 underwent bone marrow biopsy. Interestingly, significant oxalate deposition was found in the tissues. Therefore, PH1 is a rare autosomal recessive inherited disease. This study not only enhanced the understanding of the clinical characteristics of PH1 patients but also had great significance in early diagnosis and treatment of the disease.

Modified by the Innovative Drugs and Strategies-Pattern of Selected Indications for Pediatric Liver Transplantation.

Liver transplantation (LTx) constitutes a major life-saving routine treatment for children with end-stage liver disease. However, the analysis of LTx registries in children provides much information about changes in the indication profiles in the recent years. The article provides a comprehensive review about the successes, hopes, and challenges related to changing indications for LTx in children based on the literature review and our own experience. Retrospective review of the indications for LTx at a tertiary referral pediatric hospital was also presented. In the context of the new therapies that have emerged, the need for LTx has decreased in patients with chronic hepatitis B and C infection and tyrosinemia type 1. In primary hyperoxaluria type 1, new RNAi-based therapy has eliminated the requirement for LTx (both isolated or combined). There is a hope that introduction of ileal bile acid transporter (IBAT) blockers reduces the need for LTx in patients with Alagille syndrome or progressive familial intrahepatic cholestasis. The number of children qualified for LTx with urea cycle disorders (UCDs) as a prophylaxis of neurodevelopmental impairment is increasing.

Intrafamilial Disease Heterogeneity in Primary Hyperoxaluria Type 1

Primary hyperoxaluria type 1 (PH1) is known for its variable clinical course, even within families. However, the extent of this heterogeneity has not been well-studied. We aimed to analyze intrafamilial clinical heterogeneity and disease course among siblings in a large cohort of familial PH1 cases. A retrospective registry study was performed using data from OxalEurope. All PH1 families with 2 or more affected siblings were included. A 6-point PH1 clinical outcome scoring system was developed to grade heterogeneity within a family. Intrafamilial clinical heterogeneity was defined as a score≥2. Kaplan-Meier analyses were used to analyze differences in kidney survival between index cases and siblings. We included 88 families, encompassing 193 patients with PH1. The median interquartile range (IQR) follow-up time was 7.8 (1.9-17) years. Intrafamilial clinical heterogeneity, as defined by our score, was found in 38 (43%) PH1 families. In 54% of the families, affected siblings had a better outcome than the index case. Clinically asymptomatic siblings at the time of their diagnosis had a significantly more favorable clinical outcome based on the authors' scoring system than siblings with clinical signs and index cases (P< 0.001). Kaplan-Meier analyses revealed that index cases reached kidney failure at an earlier age and earlier in follow-up compared to siblings (P< 0.001). Intrafamilial clinical heterogeneity was found in a substantial number of familial PH1 cases. Compared to index cases, siblings had significantly better clinical outcomes and kidney survival; thereby supporting the policy of family screening to diagnose affected siblings early to improve their prognosis.

Histopathologic Perspective of Combined Liver–kidney Transplant: In Primary Hyperoxaluria Type 1 Patient

Abstract Primary hyperoxaluria (PH) type 1 is a rare autosomal recessive disorder of glyoxylate metabolism. Its prevalence is 1–3 cases/million people. Glyoxylate is the precursor of oxalate which is believed to be produced by oxidation in liver peroxisomes. Serine-pyruvate aminotransferase/alanine-glyoxylate aminotransferase is an enzyme involved in the metabolism of glyoxylate. In the absence of this enzyme, oxalate and glycolate are overproduced leading to hyperoxaluria. This causes urolithiasis or nephrocalcinosis, which are conditions caused by the deposition of calcium oxalate. Due to its rarity and heterogeneous phenotype, it remains unrecognized due to which diagnosis is delayed, ending up in end-stage renal disease (ESRD) and ultimately death. Hence, early diagnosis and simultaneous hepatorenal transplant remain the mainstay to avoid systemic oxalosis. Here, we discuss a case of a 43-year-old female who underwent combined liver–kidney transplant with a history of multiple episodes of renal calculi since childhood ultimately landing into ESRD in view of PH type 1.