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Pyruvate kinase deficiency

Pyruvate kinase deficiency (PKD) is a rare, autosomal recessive genetic disorder caused by mutations in the PKLR gene on chromosome 1q21, leading to deficient activity of the pyruvate kinase enzyme essential for glycolysis in red blood cells, resulting in chronic nonspherocytic hemolytic anemia due to premature red blood cell destruction. This condition impairs ATP production in erythrocytes, reducing their deformability and survival, which manifests as variable severity of anemia from mild compensated hemolysis to severe transfusion-dependent states, often presenting in infancy or childhood. Common clinical features include jaundice, fatigue, pallor, splenomegaly, and gallstones, with complications such as iron overload from repeated transfusions, pulmonary hypertension, and increased thrombosis risk in up to 10% of cases post-splenectomy. Epidemiologically, PKD has a global prevalence estimated at 1 in 20,000 to 1 in 300,000 individuals, though it may be underdiagnosed, with higher rates in populations of Northern European descent and specific communities like the ; over 300 PKLR mutations have been identified, mostly missense variants that reduce enzyme activity to less than 25% of normal. Diagnosis typically involves demonstrating reduced pyruvate kinase activity in erythrocytes, elevated count, indirect hyperbilirubinemia, and genetic confirmation via PKLR sequencing, distinguishing it from other congenital hemolytic anemias through a negative direct antiglobulin test. Management is primarily supportive, including folic acid supplementation, blood transfusions for severe , and (total or partial) to reduce transfusion requirements in many responsive cases, though response varies; targeted therapies such as the pyruvate kinase activator (FDA-approved in 2022 for adults with PKD) have shown hemoglobin improvements in up to 50% of non-transfusion-dependent patients in clinical trials, with promising results from pediatric trials as of 2025. varies widely, with mild cases allowing near-normal through vigilant care, but severe untreated forms carrying risks of fatal complications in .

Background

Definition and Overview

Pyruvate kinase deficiency (PKD) is a rare inherited disorder characterized as the second most common cause of congenital non-spherocytic after (G6PD) deficiency. It affects approximately 1 in 20,000 individuals of Northern European descent, though underdiagnosis may influence reported rates. This condition arises from mutations in the PKLR gene, leading to deficient activity of the pyruvate kinase enzyme, which is essential for the final step of in red blood cells. The disorder results in chronic due to premature destruction of erythrocytes stemming from impaired energy production and cellular rigidity. As a glycolytic enzymopathy, PKD disrupts (ATP) generation in erythrocytes, which rely almost exclusively on for energy, rendering red blood cells susceptible to and . catalyzes the conversion of phosphoenolpyruvate to pyruvate, producing ATP; its deficiency thus compromises red cell membrane integrity and deformability. Clinical severity of PKD varies widely, ranging from asymptomatic carriers with compensated hemolysis to severe cases requiring lifelong blood transfusions. is a frequent initial presentation, often appearing within the first days of life due to elevated from hemolysis. Despite this variability, the condition's impact underscores the critical role of glycolytic enzymes in erythrocyte survival.

Biochemical Role of Pyruvate Kinase

Pyruvate kinase (PK) is a critical in the , catalyzing the final, irreversible step that generates adenosine triphosphate (ATP) from phosphoenolpyruvate (PEP) and (ADP). This reaction not only produces pyruvate, which can enter further metabolic processes, but also contributes significantly to the net ATP yield of , making PK a key regulator of glycolytic flux and cellular energy homeostasis. The enzymatic reaction is as follows: \ce{PEP + ADP ->[pyruvate kinase][Mg^{2+}} pyruvate + ATP} Magnesium ions (Mg²⁺) serve as a cofactor, facilitating the phosphate transfer, while potassium ions (K⁺) are required for activity in certain isoforms. In mature erythrocytes, which lack mitochondria and thus cannot perform oxidative phosphorylation, PK plays an indispensable role by enabling ATP production exclusively through anaerobic glycolysis. This ATP is essential for maintaining red blood cell membrane integrity, ion homeostasis, and other energy-dependent functions. Pyruvate kinase exists in multiple isoforms tailored to tissue-specific needs, encoded by two main genes: and PKLR. The PKLR gene specifically produces the L-type isozyme in liver and tissues and the R-type isozyme in erythrocytes, both of which are tetrameric and responsive to metabolic signals. These R-type enzymes in red blood cells ensure efficient glycolytic ATP generation under the unique conditions of these cells. Regulation of pyruvate kinase activity occurs primarily through allosteric mechanisms to fine-tune glycolytic output based on cellular energy status and substrate availability. Fructose-1,6-bisphosphate (FBP), an upstream glycolytic intermediate, acts as a potent allosteric activator, binding to the and stabilizing its active conformation to increase affinity for PEP and enhance catalytic efficiency. Conversely, high levels of ATP and serve as inhibitors; ATP signals energy abundance and reduces activity, while provides feedback from amino acid metabolism to prevent unnecessary glycolytic flux. This regulatory network ensures that ATP production aligns with cellular demands, particularly in energy-reliant tissues like erythrocytes.

Genetics and Pathophysiology

Genetic Causes and Inheritance

Pyruvate kinase deficiency (PKD) is primarily caused by biallelic mutations in the PKLR gene, located on chromosome 1q22, which encodes the liver and isoform of (PK-R), a key enzyme in . Over 300 pathogenic variants have been identified in the PKLR gene, with the majority (70-80%) being missense mutations that impair enzyme stability, catalytic activity, or tetramer formation, leading to reduced PK-R function in erythrocytes. These mutations disrupt the enzyme's ability to catalyze the conversion of phosphoenolpyruvate to pyruvate, resulting in diminished ATP production essential for membrane integrity. The disorder follows an autosomal recessive inheritance pattern, requiring inheritance of two mutated alleles (homozygous or compound heterozygous) for disease manifestation, while heterozygous carriers typically exhibit 40-60% residual enzyme activity and remain under normal conditions. Rare cases of apparent autosomal dominant inheritance have been reported, such as in a single family where affected individuals showed approximately 20% residual PK activity and variable severity, though the underlying mechanism remains unclear. Common mutations include the missense variants p.R479H (prevalent in populations) and p.R510Q (common in Northern European and U.S. cohorts), which reduce enzyme activity to less than 25% of normal levels in homozygous states, contributing to chronic . Another example is p.R486W, frequent in Southern European populations, similarly associated with low residual activity. Genotype-phenotype correlations in PKD reveal that the severity of is influenced by the nature of the : null alleles (e.g., , frameshift, or large deletions leading to absent protein) result in more severe , characterized by earlier onset, greater transfusion dependence, and higher rates of complications compared to missense , which often allow for some residual enzyme function and milder phenotypes. For instance, patients with two non-missense exhibit lower levels and increased rates than those with at least one missense variant. These correlations underscore the heterogeneity in clinical presentation and inform prognostic assessments.

Cellular and Molecular Effects

Pyruvate kinase deficiency (PKD) impairs the final step of in erythrocytes, where catalyzes the conversion of phosphoenolpyruvate to pyruvate, generating ATP. This defect results in reduced ATP production, which constitutes approximately 50% of the total ATP generated in s under normal conditions. The diminished ATP levels compromise the activity of ATP-dependent pumps, particularly the Na⁺/K⁺-ATPase, leading to intracellular accumulation of sodium, efflux of , and subsequent loss of , which causes erythrocyte dehydration and increased cellular rigidity. These changes reduce red blood cell deformability, making them more susceptible to mechanical stress and sequestration in the microvasculature. The enzymatic block also causes accumulation of upstream glycolytic intermediates, notably 2,3-bisphosphoglycerate (2,3-BPG), which can increase up to threefold in affected cells. This buildup shifts the oxygen-hemoglobin dissociation curve to the right, facilitating enhanced oxygen unloading to tissues and partially compensating for the anemia. However, the metabolic imbalance exacerbates oxidative stress due to altered redox homeostasis and increased levels of reactive oxygen species precursors like hypoxanthine and xanthine. Consequently, oxidative damage to membrane lipids and proteins occurs, promoting membrane fragility and leading to extravascular hemolysis predominantly in the spleen, where rigid and damaged erythrocytes are phagocytosed by macrophages. In response to chronic , the exhibits , with counts often elevated to 20-40% as a compensatory mechanism to replenish mass. In severe cases, however, ineffective predominates, characterized by accelerated intramedullary destruction of erythroid precursors due to metabolic stress. Residual activity in affected individuals typically ranges from 5-25% of normal levels, with lower activity strongly correlating to the degree of and clinical severity. in the PKLR underlie this variability in function, though the precise molecular impacts are detailed in genetic analyses.

Clinical Features

Signs and Symptoms

Pyruvate kinase deficiency (PKD) presents with a wide spectrum of clinical manifestations, ranging from severe neonatal disease to mild or even forms in adulthood, primarily due to chronic non-spherocytic resulting from impaired energy metabolism and ATP depletion. In neonates, the condition often manifests as severe hyperbilirubinemia and , affecting 59–90% of cases and frequently requiring phototherapy in 93% and exchange transfusions in approximately half. Severe cases may include , characterized by fetal edema and potential , along with , , poor feeding, , and indicative of . Chronically, patients experience with hemoglobin levels typically ranging from 6 to 10 g/dL, leading to symptoms such as , , , and in 40–70% of individuals. is common, occurring in 80–85% of cases, and contributes to ongoing and reduced exercise tolerance. Symptoms often exacerbate during periods of , such as infections, , or other physiological stressors, precipitating acute hemolytic crises that may necessitate transfusions. Additionally, chronic overload from hemolysis leads to pigment gallstones in 30–45% of patients by adulthood, with a median onset around age 15 years. Milder or cases, which may represent up to a significant portion of the spectrum, are often identified incidentally through family screening or during evaluation for unrelated conditions in adulthood.

Complications and Prognosis

Pyruvate kinase deficiency (PKD) is associated with several long-term complications arising from chronic and its management. One of the most prevalent issues is , which occurs in up to 82% of non-regularly transfused patients and nearly all regularly transfused individuals, often leading to hepatic damage such as or and cardiac complications including . is common and can progress to hypersplenism, exacerbating through increased red blood cell sequestration and destruction. Gallstones, resulting from chronic elevation due to , affect a significant proportion of patients and may cause or require surgical intervention. In severe, transfusion-dependent cases, rarer complications include (reported in approximately 3-5% of cases) and chronic leg ulcers (approximately 2-4%), as observed in natural history cohorts. Prognosis in PKD has improved substantially with modern supportive care, with median survival from birth estimated at 76.9 years in recent real-world studies, though patients face a 4-5 times higher compared to the general population, primarily due to complications like cardiac and biliary events. Approximately 50% of adults achieve transfusion independence, particularly those with milder genotypes, while the remainder require ongoing transfusions, influencing overall health outcomes. Early can reduce transfusion requirements in many cases but carries risks of postoperative infections and , necessitating careful patient selection. is recommended for affected families to assess risks and inform reproductive planning, given the autosomal recessive nature of the disorder.

Diagnosis

Initial Clinical Assessment

The initial clinical assessment of suspected pyruvate kinase deficiency begins with a thorough patient history, focusing on familial patterns of or , as the condition follows an autosomal recessive inheritance pattern. in the family is a notable that heightens suspicion, particularly in populations with higher rates of related marriages. Clinicians should inquire about episodes of that worsen during infections, acute illnesses, or other stressors such as , which can precipitate hemolytic crises. Additionally, a history of chronic fatigue or may raise early suspicion, though these are not unique to the . Physical examination typically reveals signs of ongoing , including due to , manifesting as yellowing of the skin and sclerae, and from the spleen's role in sequestering damaged red blood cells. In pediatric patients, may also be present, and chronic cases can lead to growth delays or , reflecting the systemic impact of persistent . These findings, combined with a lack of obvious external causes for , prompt consideration of pyruvate kinase deficiency in individuals presenting with chronic non-spherocytic . Differential diagnosis during this assessment should encompass other causes of hemolytic anemia, such as or , which may present with similar historical and physical features but differ in triggers or inheritance patterns. Suspicion for pyruvate kinase deficiency is particularly warranted when no spherocytes are evident on initial evaluation and the persists without an identifiable extrinsic cause.

Confirmatory Testing

Confirmatory testing for pyruvate kinase deficiency (PKD) primarily involves laboratory evaluations to detect reduced enzyme activity, characteristic morphological changes in red blood cells, and genetic alterations, distinguishing it from other causes of hemolytic anemia. A peripheral blood smear typically reveals echinocytes (burr cells) and acanthocytes, with notable absence of spherocytes, reflecting the non-spherocytic nature of the hemolytic anemia in PKD. These poikilocytes arise due to impaired ATP production affecting red cell membrane integrity, though their presence is neither highly sensitive nor specific and should be interpreted in context with other findings. The cornerstone of confirmation is the pyruvate kinase enzyme assay, which measures red blood cell pyruvate kinase activity and typically shows levels reduced to less than 25% of normal (often 5-25%), even after adjustment for reticulocytosis, as reticulocytes contain higher enzyme activity than mature erythrocytes. False-normal results can occur with recent transfusions or marked reticulocytosis, so assays may include ratios like pyruvate kinase to to enhance specificity. Supporting laboratory findings consistent with extravascular include elevated reticulocyte counts (typically 10-30%), increased indirect , elevated (LDH), and decreased levels. A negative direct antiglobulin test () is essential to rule out . These markers help corroborate the but are not specific to PKD. Genetic testing provides definitive confirmation by sequencing the PKLR gene for biallelic pathogenic variants, as PKD follows autosomal recessive inheritance with compound heterozygous or homozygous mutations in over 300 identified variants. Next-generation sequencing panels targeting hemolytic anemias or full PKLR gene analysis are recommended, particularly when enzyme assays are inconclusive or for carrier screening in families. For at-risk pregnancies, prenatal diagnosis can be achieved through amniocentesis to analyze fetal DNA for PKLR mutations, enabling early intervention planning.

Treatment and Management

Supportive Care

Supportive care for pyruvate kinase deficiency focuses on alleviating symptoms of chronic , preventing complications such as , and improving quality of life through non-curative measures. These interventions are tailored to disease severity, with milder cases often requiring only monitoring and supplementation, while severe, transfusion-dependent necessitates more intensive management. Folic acid supplementation is recommended for all patients to support increased driven by ongoing . Daily doses of 1 mg are typically sufficient, with higher or intermittent dosing during periods of accelerated turnover, such as hemolytic crises or . This prevents secondary to depletion from elevated production. Blood transfusions are indicated for severe , particularly when levels fall below 7 g/dL or symptoms like , , or cardiopulmonary compromise arise. Transfusions alleviate acute symptoms and reduce the risk of complications from profound , though chronic use can lead to even in non-transfused patients due to increased intestinal absorption. , such as with , is initiated in patients aged 2 years or older with evidence of hepatic (liver iron concentration exceeding 5 mg/g dry weight), monitored via serum or . Splenectomy is considered for transfusion-dependent patients older than 5 years to reduce and transfusion requirements, often improving levels by 2-3 g/dL and decreasing by 50-70% in responsive cases. The procedure is generally performed between ages 5 and 18 to balance benefits against risks, with approximately 60% of patients undergoing it at some point. Partial splenectomy is not recommended due to lack of efficacy in this condition. Following splenectomy, patients require vaccinations against encapsulated bacteria, including pneumococcal, meningococcal, and type b vaccines, administered at least 14 days prior if possible. Prophylactic antibiotics, such as penicillin, are advised lifelong or until age 5 in young children to mitigate risk, which is elevated due to impaired immune clearance. Ongoing monitoring includes annual echocardiograms for adults aged 18 years and older to screen for , a potential complication linked to chronic and reported in up to 10% of cases. Early detection allows for timely intervention to manage this rare but serious risk. Iron overload from transfusions or ineffective is briefly referenced here as a key complication warranting vigilant surveillance, with details covered elsewhere.

Targeted and Emerging Therapies

Mitapivat (PYRUKYND), the first oral allosteric activator of approved for the treatment of in adults with deficiency (PKD), received U.S. (FDA) approval in February 2022. By binding to in place of fructose-1,6-bisphosphate, enhances enzyme activity, thereby increasing (ATP) production and reducing . In the phase 3 ACTIVATE for non-regularly transfused adults, led to a mean hemoglobin increase of 1.8 g/dL from baseline, with 37% of patients achieving reduced transfusion requirements compared to 10% on . Phase 3 for pediatric patients completed in 2025, with the ACTIVATE-Kids demonstrating a statistically significant hemoglobin response in children aged 1 to less than 18 years who are not regularly transfused, and the ACTIVATE-KidsT confirming in regularly transfused children. Pediatric approval is under as of 2025. Hematopoietic stem cell transplantation (HSCT) offers a potentially curative option for severe, transfusion-dependent PKD, particularly in pediatric cases where the disease manifests early and aggressively. In a series of 16 patients across and , allogeneic HSCT achieved a 74% cumulative survival rate, though outcomes were complicated by a high incidence of and other transplant-related morbidities. Despite these risks, successful engraftment has restored normal in select cases, underscoring HSCT's role as a high-stakes intervention reserved for young patients with compatible donors. Gene therapy approaches using lentiviral vectors to deliver a codon-optimized PKLR (RP-L301) aim to restore expression in hematopoietic cells. Early phase 1/2 trial results from 2023–2024 demonstrate sustained improvements, with three of four patients reaching normal-range levels and all remaining transfusion-independent up to three years post-treatment, without serious vector-related adverse events. However, as of 2025, the sponsor has paused further development of RP-L301, including the phase 2 trial (NCT06422351), due to strategic priorities. Preclinical studies employing /Cas9 combined with single-stranded oligodeoxynucleotides have shown promise in correcting specific PKLR mutations underlying PKD. In 2023 experiments using patient-derived hematopoietic stem/progenitor cells, editing achieved efficiencies up to 10% for certain mutations (e.g., c.1003 G>A), resulting in improved ATP levels in differentiated erythroid cells and no off-target effects for most variants. In October 2025, researchers reported optimizations in tracking systems that enhanced editing protocols for PKLR mutations, achieving higher correction efficiencies in patient-derived cells. These advancements highlight the potential for personalized therapies, though clinical translation remains in early stages as of 2025. The Pyruvate Kinase Deficiency Global Longitudinal (Peak) Registry, an initiated in 2018 and sponsored by Agios Pharmaceuticals, tracks long-term outcomes in up to 500 patients across multiple countries to inform emerging therapies. As of April 2025, enrolment was completed with approximately 251 participants, and the registry continues to monitor disease progression and treatment responses, including , with follow-up through 2027.

Epidemiology and History

Global Prevalence and Demographics

Pyruvate kinase deficiency (PKD) is a rare autosomal recessive disorder with an estimated prevalence ranging from 1 in 20,000 to 1 in 300,000 individuals, though the condition is significantly underdiagnosed, particularly in non-Caucasian populations. The diagnosed prevalence in Western populations is lower, at approximately 3.2 to 8.5 cases per million, reflecting challenges in recognition and testing that lead to many cases remaining undetected. This underdiagnosis is especially pronounced in and Asian communities outside of , where reporting is limited due to lower awareness, limited access to specialized diagnostics, and overlapping symptoms with other hemolytic anemias. Demographic patterns show a higher incidence in certain ethnic groups, with estimated at 1 in 20,000 among individuals of Northern European descent. Higher rates have also been observed in specific communities, such as the Old Order Amish, due to founder effects. Cases are documented in populations, though reporting remains limited in other Asian groups due to underdiagnosis. The disorder affects males and females equally, consistent with its autosomal recessive inheritance pattern. The global burden of PKD, based on the estimated prevalence range and a world population of approximately 8 billion (as of 2023), implies roughly 27,000 to 400,000 affected individuals, though this likely underrepresents the true number due to undiagnosed cases, with diagnosed cases estimated at around 25,000 to 68,000 primarily in Western populations. The Pyruvate Kinase Deficiency Global Longitudinal (Peak) Registry, an ongoing international , has enrolled over 240 genetically confirmed patients as of 2022, providing valuable insights into and aiding in improved tracking of the disease's distribution. Risk factors include , which increases the likelihood of homozygous mutations in regions with high rates of related marriages, such as parts of the and .

Historical Discovery and Milestones

Pyruvate kinase deficiency (PKD) was first described in by and colleagues, who identified a specific defect in the glycolytic pyruvate kinase in erythrocytes from three patients with congenital non-spherocytic . This seminal report established PKD as a distinct cause of hereditary , characterized by reduced activity leading to impaired energy production and premature . In the , following the initial discovery, researchers developed standardized enzyme assays to measure activity in red blood cells, enabling more reliable of the deficiency. During this period, early genetic studies began to link the disorder to autosomal recessive inheritance, with initial explorations into the chromosomal location of the responsible gene, later identified as PKLR on chromosome 1q21. The 1990s marked significant advances in molecular understanding, as the PKLR gene was cloned and the first disease-causing mutations were identified through sequencing efforts, revealing over 100 variants associated with varying degrees of dysfunction. Concurrently, emerged as a standard supportive intervention, with clinical reports demonstrating its ability to ameliorate in many patients by reducing red blood cell sequestration, though outcomes varied by disease severity. In the 2010s, large-scale natural history studies, including the international Pyruvate Kinase Deficiency Natural History Study initiated in 2014, provided comprehensive data on disease phenotypes, revealing a wide spectrum from mild compensated hemolysis to transfusion-dependent anemia and highlighting factors influencing clinical variability. These insights spurred the exploration of gene therapy concepts, with preclinical models using lentiviral vectors to restore PKLR expression showing promise in correcting the metabolic defect in murine and human cells. A major milestone occurred in 2022 with the U.S. Food and Drug Administration approval of , the first disease-modifying therapy for PKD, an allosteric activator of residual that improves metabolism and reduces in adults. In 2024, an international expert panel published updated management guidelines in Haematology, incorporating evidence from recent trials and registries to standardize , , and therapeutic approaches for improved patient outcomes.

Veterinary Aspects

Occurrence in Animals

Pyruvate kinase deficiency, an inherited caused by in the , is well-documented in , particularly in breeds such as the , , , and . Affected dogs typically present with severe regenerative in the neonatal or juvenile period, often leading to fatal outcomes due to , , and organ failure from ineffective . In breeds like the , screening studies have identified carrier rates as high as 35% in sampled populations, with affected individuals showing markedly reduced erythrocyte survival times of 2.5–3 days compared to approximately 110 days in unaffected . Overall prevalence remains low in the general population, with frequencies around 0.01% in mixed-breed , underscoring the importance of breed-specific genetic screening to prevent . In , pyruvate kinase deficiency is rare and generally manifests as a milder form of compared to dogs, with affected individuals often surviving into adulthood despite chronic red blood cell destruction. The condition has been reported primarily in , , , and domestic shorthair breeds, where a in the PKLR gene reduces activity. frequencies can reach 0.19 in certain populations, such as Australian Abyssinians and Somalis, resulting in approximately 5% affected Somalis in surveyed groups. may occur, but clinical signs are often less severe, with regenerative responses mitigating . Diagnosis in mirrors approaches, relying on activity assays in erythrocytes and confirmatory for PKLR mutations, which is crucial for identifying carriers in programs. Supportive care, including blood transfusions and iron chelation for secondary hemochromatosis, is the mainstay of management, though has been successful in correcting the disease in affected dogs, leading to long-term survival; prognosis is guarded in severely affected cases. Veterinary genetic screening initiatives in high-risk breeds help mitigate zoonotic concerns—though none exist—and support ethical practices to reduce incidence.

Comparative Pathophysiology

Pyruvate kinase deficiency (PKD) arises from mutations in the PKLR gene or its orthologs across species, leading to impaired glycolysis and hemolytic anemia due to reduced ATP production in erythrocytes. In dogs, breed-specific mutations in the PKLR ortholog, such as nonsense mutations in Labradors (c.799C>T) and Basenjis (single base pair deletion in exon 5), mirror human PKLR variants and cause autosomal recessive inheritance with chronic hemolytic anemia. However, canine PKD often manifests with more severe neonatal hemolysis compared to humans, attributed to the inherently shorter erythrocyte lifespan in dogs (approximately 100-120 days normally, reduced to 2.5-3 days in affected Basenjis), exacerbating energy depletion and cell fragility from birth. Mouse knockout models of PKD, such as the AcB61 with a Pklr (isoleucine to asparagine at position 90), effectively replicate human-like ATP depletion in erythrocytes due to blocked , resulting in elevated glycolytic intermediates and shortened survival. These models exhibit constitutive with and , similar to human . Nonetheless, the chronic in mice is generally less severe than in humans or dogs, presenting as moderate without the same degree of life-threatening complications, partly due to differences in response and overall metabolic demands. Species-specific differences highlight variations in disease expression. In cats, particularly and Somalis, compensatory mechanisms such as pronounced (up to 936 × 10⁹/L) enable many affected individuals to maintain non-anemic states or milder symptoms despite reduced PK activity, reducing overall disease severity compared to dogs. These animal models provide valuable insights for human PKD research, with canine models demonstrating utility in preclinical testing of therapies, including approaches that correct PKLR mutations and inform human applications. For instance, PK-deficient dogs have been used to validate strategies that restore enzyme function, offering translational benefits for emerging human therapies. The evolutionary conservation of the pathway, including the PKLR , across mammals facilitates these cross-species studies, as the core enzymatic role in ATP generation remains identical, enabling reliable modeling of metabolic perturbations.

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