Characterization of liver GSD IX γ2 pathophysiology in a novel Phkg2-/- mouse model.

INTRODUCTION: Liver Glycogen Storage Disease IX is a rare metabolic disorder of glycogen metabolism caused by deficiency of the phosphorylase kinase enzyme (PhK). Variants in the PHKG2 gene, encoding the liver-specific catalytic γ2 subunit of PhK, are associated with a liver GSD IX subtype known as PHKG2 GSD IX or GSD IX γ2. There is emerging evidence that patients with GSD IX γ2 can develop severe and progressive liver disease, yet research regarding the disease has been minimal to date. Here we characterize the first mouse model of liver GSD IX γ2. METHODS: A Phkg2-/- mouse model was generated via targeted removal of the Phkg2 gene. Knockout (Phkg2-/-, KO) and wild type (Phkg2+/+, WT) mice up to 3 months of age were compared for morphology, Phkg2 transcription, PhK enzyme activity, glycogen content, histology, serum liver markers, and urinary glucose tetrasaccharide Glcα1-6Glcα1-4Glcα1-4Glc (Glc4). RESULTS: When compared to WT controls, KO mice demonstrated significantly decreased liver PhK enzyme activity, increased liver: body weight ratio, and increased glycogen in the liver, with no glycogen accumulation observed in the brain, quadricep, kidney, and heart. KO mice demonstrated elevated liver blood markers as well as elevated urine Glc4, a commonly used biomarker for glycogen storage disease. KO mice demonstrated features of liver structural damage. Hematoxylin & Eosin and Masson's Trichrome stained KO mice liver histology slides revealed characteristic GSD hepatocyte architectural changes and early liver fibrosis, as have been reported in liver GSD patients. DISCUSSION: This study provides the first evidence of a mouse model that recapitulates the liver-specific pathology of patients with GSD IX γ2. The model will provide the first platform for further study of disease progression in GSD IX γ2 as well as for the evaluation of novel therapeutics.

Variability of disease spectrum in children with liver phosphorylase kinase deficiency caused by mutations in the PHKG2 gene.

Liver phosphorylase b kinase (PhK) deficiency (glycogen storage disease type IX), one of the most common causes of glycogen storage disease, is caused by mutations in the PHKA2, PHKB, and PHKG2 genes. Presenting symptoms include hepatomegaly, ketotic hypoglycemia, and growth delay. Clinical severity varies widely. Autosomal recessive mutations in the PHKG2 gene, which cause about 10-15% of cases, have been associated with severe symptoms including increased risk of liver cirrhosis in childhood. We have summarized the molecular, biochemical, and clinical findings in five patients, age 5-16 years, diagnosed with liver PhK deficiency caused by PHKG2 gene mutations. We have identified five novel and two previously reported mutations in the PHKG2 gene in these five patients. Clinical severity was variable among these patients. Histopathological studies were performed for four of the patients on liver biopsy samples, all of which showed signs of fibrosis but not cirrhosis. One of the patients (aged 9 years) developed a liver adenoma which later resolved. All patients are currently doing well. Their clinical symptoms have improved with age and treatment. These cases add to the current knowledge of clinical variability in patients with PHKG2 mutations. Long term studies, involving follow-up of these patients into adulthood, are needed.

Phosphorylase kinase deficiency in I-strain mice is associated with a frameshift mutation in the alpha subunit muscle isoform.

Heritable phosphorylase kinase (Phk) deficiency underlies a group of glycogenoses in humans, mice and rats that differ in mode of inheritance and tissue-specificity. It is assumed that this heterogeneity is caused by mutations affecting different subunits and isoforms of Phk. As the first Phk deficiency mutation to be identified, we report a single-nucleotide insertion in the coding sequence of the Phk alpha subunit muscle isoform of the I-strain mouse. This mutation accounts for the virtually complete enzymatic deficiency, the tissue specificity and the X-linked mode of inheritance in this mutant.

Mutations in the testis/liver isoform of the phosphorylase kinase gamma subunit (PHKG2) cause autosomal liver glycogenosis in the gsd rat and in humans.

Heritable deficiency of phosphorylase kinase (Phk), a regulatory enzyme of glycogen metabolism, is responsible for 25% of all cases of glycogen storage disease and occurs with a frequency of -1 in 100,000 births. It is genetically and clinically heterogeneous, occurring in X-linked and autosomal-recessive forms and exhibiting various patterns of principally affected tissues (liver only, muscle only, liver and muscle, liver and kidney, heart only). This heterogeneity is thought to reflect the enzyme's structural complexity [subunit composition, (alpha beta gamma delta)4] and isoform diversity. Two isoforms encoded by separate genes are known for the subunits alpha (muscle [alpha M] and liver [alpha L isoforms) and gamma (muscle [gamma M] and testis [gamma T] isoforms), whereas only one gene appears to exist for the subunit beta. The subunit delta is calmodulin; identical calmodulins are expressed from three different human genes. Additional isoform diversity arises by differential mRNA splicing of the alpha M, alpha L and beta subunits. Mutations responsible for the various forms of Phk deficiency are sought in those subunit/isoform genes with a matching chromosomal location and tissue-specificity of expression. We report here that autosomal liver-specific Phk deficiency is associated with mutations in the gene encoding the testis/liver isoform of the catalytic gamma subunit (PHKG2). We found homozygous PHKG2 mutations in three human patients of consanguineous parentage and in the gsd (glycogen storage disease) rat strain, which is thus identified as an animal model for the human disorder. One human mutation is a single base-pair insertion in codon 89 that causes a frameshift and premature chain termination. The three other mutations result in non-conservative replacements of amino acid residues (V106E, G189E, D215N) that are highly conserved within the catalytic core regions of all protein kinases. These are the first mutations to be reported for an autosomal form of Phk deficiency. The findings suggest that the PHKG2 gene product is the predominant isoform of the catalytic gamma subunit of Phk not only in testis but also in liver, erythrocytes and, possibly, other non-muscle tissues.

Common mutation in the PHKA2 gene with variable phenotype in patients with liver phosphorylase b kinase deficiency.

We found that the missense mutation p.Pro1205Leu in the PHKA2 gene is a common cause of hepatic phosphorylase-kinase deficiency in Dutch patients, suggesting a founder-effect. Most patients presented with isolated growth delay and diarrhea, prior to the occurrence of hepatomegaly, delaying diagnosis. Tetraglucoside excretion correlated with disease severity and was used to follow compliance. The clinical presentation and therapeutic requirements in the same mutation carriers were variable, and PhK deficiency necessitated tube-feeding in some children.

Liver glycogen storage diseases due to phosphorylase system deficiencies: diagnosis thanks to non invasive blood enzymatic and molecular studies.

Glycogen storage disease (GSD) due to a deficient hepatic phosphorylase system defines a genetically heterogeneous group of disorders that mainly manifests in children. We investigated 45 unrelated children in whom a liver GSD VI or IX was suspected on the basis of clinical symptoms including hepatomegaly, increased serum transaminases, postprandial lactatemia and/or mild fasting hypoglycemia. Liver phosphorylase and phosphorylase b kinase activities studied in peripheral blood cells allowed to suspect diagnosis in 37 cases but was uninformative in 5. Sequencing of liver phosphorylase genes was useful to establish an accurate diagnosis. Causative mutations were found either in the PYGL (11 patients), PHKA2 (26 patients), PHKG2 (three patients) or in the PHKB (three patients) genes. Eleven novel disease causative mutations, five missense (p.N188K, p.D228Y, p.P382L, p.R491H, p.L500R) and six truncating mutations (c.501_502ins361pb, c.528+2T>C, c.856-29_c.1518+614del, c.1620+1G>C, p.E703del and c.2313-1G>T) were identified in the PYGL gene. Seventeen novel disease causative mutations, ten missense (p.A42P, p.Q95R, p.G131D, p.G131V, p.Q134R, p.G187R, p.G300V, p.G300A, p.C326Y, p.W820G) and seven truncating (c.537+5G>A, p.G396DfsX28, p.Q404X, p.N653X, p.L855PfsX87, and two large deletions) were identified in the PHKA2 gene. Four novel truncating mutations (p.R168X, p.Q287X, p.I268PfsX12 and c.272-1G>C) were identified in the PHKG2 gene and three (c.573_577del, p.R364X, c.2427+3A>G) in the PHKB gene. Patients with PHKG2 mutations evolved towards cirrhosis. Molecular analysis of GSD VI or IX genes allows to confirm diagnosis suspected on the basis of enzymatic analysis and to establish diagnosis and avoid liver biopsy when enzymatic studies are not informative in blood cells.

Variability of clinical and biochemical phenotype in liver phosphorylase kinase deficiency with variants in the phosphorylase kinase (PHKG2) gene.

Background PHKG2-related liver phosphorylase kinase deficiency is inherited in autosomal recessive pattern and is a rare type of liver glycogenosis. We demonstrated the clinical presentation and genetic determinants involved in children with PHKG2- related liver phosphorylase kinase deficiency. Methodology Ten Pakistani children with liver phosphorylase kinase from seven different families, were enrolled over a period of 18 months. All regions of the PHKG2 gene spanning exons and splicing sites were evaluated through targeted exome sequencing. Variants were analyzed using different bioinformatics tools. Novel variants were reconfirmed by direct sequencing. Results Seven different variants were identified in PHKG2 gene including five novel variants: three stop codons (c.226C>T [p.R76*], c.454C>T [p.R152*] and c.958C>T [p.R320*]), one missense variant c.107C>T (p.S36F) and one splice site variant (c.557-3C>G). All five novel variants were predicted to be damaging by in Silico analysis. The variants are being transmitted through recessive pattern of inheritance except one family (two siblings) has compound heterozygotes. Laboratory data revealed elevated transaminases and triglycerides, normal creatinine phosphokinase and uric acid levels but with glycogen loaded hepatocytes on liver histology. Conclusion PHKG2 related liver phosphorylase kinase deficiency can mimic both liver glycogenosis type I (glucose-6-phosphatase deficiency) & III(amylo-1,6 glucosidase) and characterized by early childhood onset of hepatomegaly, growth restriction, elevated liver enzymes and triglycerides. Molecular analysis would be helpful in accurate diagnosis and proper treatment. The symptoms and biochemical abnormalities in liver glycogenosis due phosphorylase kinase deficiency tend to improve with proper dietary restrictions but need to be monitored for long-term complications such as liver fibrosis and cirrhosis.

Nutritional therapy for glycogen storage diseases.

Glycogen storage diseases (GSDs) are a group of inherited disorders characterized by enzyme defects that affect the glycogen synthesis and degradation cycle, classified according to the enzyme deficiency and the affected tissue. The understanding of GSD has increased in recent decades, and nutritional management of some GSDs has allowed better control of hypoglycemia and metabolic complications. However, growth failure and liver, renal, and other complications are frequent problems in the long-term outcome. Hypoglycemia is the main biochemical consequence of GSD type I and some of the other GSDs. The basis of dietary therapy is nutritional manipulation to prevent hypoglycemia and improve metabolic dysfunction, with the use of continuous nocturnal intragastric feeding or cornstarch therapy at night and foods rich in starches with low concentrations of galactose and fructose during the day and to prevent hypoglycemia during the night.

PHKG2 mutation spectrum in glycogen storage disease type IXc: a case report and review of the literature.

BACKGROUND: PHKG2 gene mutation can lead to liver phosphorylase kinase (PhK) deficiency, which is related to glycogen storage disease type IX (GSD IX). GSD IXc due to PHKG2 mutation is the second most common GSD IX. METHODS: We identified a novel mutation (c.553C>T, p.Arg185X) in PHKG2 in a Chinese family and verified it by next-generation and Sanger sequencing. The mutation spectrum of the PHKG2 gene was summarized based on 25 GSD IXc patients with PHKG2 mutations. RESULTS: We found that missense mutation (39%) was the most common type of mutation, followed by nonsense mutation (23%). Mutations were more prevalent in Asian (12/25) and European (9/25) populations than in populations from elsewhere. The exons had more sites of mutation than the introns, and exons 3 and 6 were the most frequent sites of mutations. CONCLUSIONS: This study expands our knowledge of the PHKG2 gene mutation spectrum, providing a molecular basis for GSD IXc.

Calmodulin ligands. The interaction of muscle phosphorylase kinase with phosphodiesterase. Comparison of calmodulin ligands in muscle extracts from normal and phosphorylase kinase-deficient mice.

Interactions between phosphorylase kinase (ATP:phosphorylase-b phosphotransferase, EC 2.7.1.38) and calmodulin were studied with pure preparations of muscle phosphorylase kinase, and with crude extracts from muscles of control (C57 Black) and deficient (ICR/IAn) mice, which lack muscle phosphorylase kinase activity. Calmodulin was determined by its ability to stimulate a calmodulin-dependent phosphodiesterase. The amount of calmodulin bound to phosphorylase kinase in muscle extract was estimated to a maximum of 30% of the total amount of calmodulin. In the muscle of the deficient strain a decrease of 35% in the total amount of calmodulin was observed. This correlates with the absence of the calmodulin fraction specifically bound to phosphorylase kinase. From sucrose gradient studies we demonstrated that in the presence of Ca2+ the amount of calmodulin bound to phosphorylase kinase was enhanced, compared to the control in the presence of EGTA. This observation was made both in crude extracts and in pure phosphorylase kinase preparations. Sucrose gradient also showed that muscle phosphorylase kinase can be dissociated to low molecular species when extracts are made in the presence of Ca+; this dissociation was found to be related to a Ca2+-dependent proteolytic effect.

Muscle glycogenosis with low phosphorylase kinase activity: mutations in PHKA1, PHKG1 or six other candidate genes explain only a minority of cases.

Muscle-specific deficiency of phosphorylase kinase (Phk) causes glycogen storage disease, clinically manifesting in exercise intolerance with early fatiguability, pain, cramps and occasionally myoglobinuria. In two patients and in a mouse mutant with muscle Phk deficiency, mutations were previously found in the muscle isoform of the Phk alpha subunit, encoded by the X-chromosomal PHKA1 gene (MIM # 311870). No mutations have been identified in the muscle isoform of the Phk gamma subunit (PHKG1). In the present study, we determined Q1the structure of the PHKG1 gene and characterized its relationship to several pseudogenes. In six patients with adult- or juvenile-onset muscle glycogenosis and low Phk activity, we then searched for mutations in eight candidate genes. The coding sequences of all six genes that contribute to Phk in muscle were analysed: PHKA1, PHKB, PHKG1, CALM1, CALM2 and CALM3. We also analysed the genes of the muscle isoform of glycogen phosphorylase (PYGM), of a muscle-specific regulatory subunit of the AMP-dependent protein kinase (PRKAG3), and the promoter regions of PHKA1, PHKB and PHKG1. Only in one male patient did we find a PHKA1 missense mutation (D299V) that explains the enzyme deficiency. Two patients were heterozygous for single amino-acid replacements in PHKB that are of unclear significance (Q657K and Y770C). No sequence abnormalities were found in the other three patients. If these results can be generalized, only a fraction of cases with muscle glycogenosis and a biochemical diagnosis of low Phk activity are caused by coding, splice-site or promoter mutations in PHKA1, PHKG1 or other Phk subunit genes. Most patients with this diagnosis probably are affected either by elusive mutations of Phk subunit genes or by defects in other, unidentified genes.

Detection of glycogen in a glycogen storage disease by 13C nuclear magnetic resonance.

The livers of gsd/gsd rats homozygous for the glycogen storage disease phosphorylase b kinase deficiency were observed by 13C NMR using a surface coil. Clear signals were detected from glycogen. The concentration of glycogen as determined by NMR was approximately 3-times that found in normal strains agreeing well with chemical determinations. Starvation did not significantly reduce the glycogen content of the livers with glycogen storage disease whereas it reduced the signal below detectability in normal rats. Difference spectra of starved normal rats from fed gsd/gsd rats gave spectra similar in appearance to that of purified glycogen. Glycogen both in vivo and in vitro is fully visible using 13C NMR.

Clinical and biochemical features of 10 adult patients with muscle phosphorylase kinase deficiency.

Ten adult patients complained of exercise intolerance; five of them had cramps and three had recurrent myoglobinuria. Resting serum CK was increased in five. Muscle biopsies showed phosphorylase b kinase (PbK) deficiency, whereas the activities of other enzymes of carbohydrate metabolism were normal. None of the patients exhibited symptoms indicative of liver PbK deficiency. Thus, these patients are new additions to a class of PbK glycogen storage disease characterized by enzyme deficiency in muscle but not liver. Family histories were consistent with autosomal recessive transmission. Monoclonal antibodies specific for the beta and gamma subunits of PbK cross-reacted differentially with muscle biopsies from three of these patients, suggesting that this phenotype of PbK deficiency is biochemically heterogeneous.

Fatal infantile glycogen storage disease: deficiency of phosphofructokinase and phosphorylase b kinase.

A girl with congenital limb weakness, mental retardation, and corneal ulceration died with respiratory insufficiency at age 4 years. Histochemistry of muscle biopsy showed only nonspecific myopathy, but electronmicroscopy revealed subsarcolemmal and intramyofibrillar accumulation of glycogen. Biochemical studies showed increased glycogen content of muscle with lack of phosphofructokinase. Phosphorylase b kinase activity was about 30% of normal. The relationship of the double enzyme deficiency to this unusual clinical picture is unclear.

Infantile glycogen storage myopathy in a girl with phosphorylase kinase deficiency.

A 19-month-old girl with moderate hypotonia was studied. Histochemical and electronmicroscopic findings revealed that many skeletal muscle fibers contained an excess amount of glycogen. The phosphorylase reaction was normalized only after activation with 5' AMP. Biochemical studies showed an increased glycogen content and decreased activities of phosphorylase "a" and an active form of phosphorylase kinase, whereas activities of total phosphorylase, total phosphorylase kinase, and cyclic AMP-dependent protein kinase were all in the normal range. Thus, phosphorylase kinase in the patient's muscle seemed to be a variant form, which was activated partially under the physiologic condition. This condition may be inherited as an X-linked recessive trait.

Glycogen storage diseases. Phenotypic, genetic, and biochemical characteristics, and therapy.

The glycogen storage diseases are caused by inherited deficiencies of enzymes that regulate the synthesis or degradation of glycogen. In the past decade, considerable progress has been made in identifying the precise genetic abnormalities that cause the specific impairments of enzyme function. Likewise, improved understanding of the pathophysiologic derangements resulting from individual enzyme defects has led to the development of effective nutritional therapies for each of these disorders. Meticulous adherence to dietary therapy prevents hypoglycemia, ameliorates the biochemical abnormalities, decreases the size of the liver, and results in normal or nearly normal physical growth and development. Nevertheless, serious long-term complications, including nephropathy that can cause renal failure and hepatic adenomata that can become malignant, are a major concern in GSD-I. In GSD-III, the risk for hypoglycemia diminishes with age, and the liver decreases in size during puberty. Cirrhosis develops in some adult patients, and progressive myopathy and cardiomyopathy occur in patients with absent GDE activity in muscle. It remains unclear whether these complications of glycogen storage disease can be prevented by dietary therapy. Glycogen storage diseases caused by lack of phosphorylase activity are milder disorders with a good prognosis. The liver decreases in size, and biochemical abnormalities disappear by puberty.

Liver glycogenosis caused by a defective phosphorylase system: hemolysate analysis.

Investigated were 24 cases of glycogenosis caused by a reduction in liver phosphorylase activity. The intravenous glucagon tolerance test could not discriminate between phosphorylase kinase deficiency [glycogen storage disease (GSD) IX] and phosphorylase deficiency (GSD VI). These two subgroups were distinguished by hemolysate enzyme assays: (1) GSD IX was characterized by a residual phosphorylase kinase activity, a low activation curve for endogenous phosphorylase b and increased amylo-1,6-glucosidase activity. (2) GSD VI was characterized by a normal or increased phosphorylase kinase activity, a slight activation of endogenous phosphorylase b and a normal amylo-1,6-glucosidase activity.

Glycogen storage disease confined to the heart with deficient activity of cardiac phosphorylase kinase: a new type of glycogen storage disease.

The case of a male infant with marked deposition of glycogen, confined to the heart, is presented. Clinically, prominent cardiomegaly had been evident from immediately after birth until the infant's death due to heart failure. There were no significant clinical manifestations in other organs, including liver and skeletal muscle, during the clinical course. Autopsy revealed abnormal deposition of normally structured glycogen in the heart, but no deposition in the liver, skeletal muscle, or other systemic organs. This unusual pattern of glycogen deposition was also confirmed by measurement of the glycogen content of each organ. This is the first report of glycogen storage disease confined to the heart. Enzymatic analysis revealed no decrease in the activities of acid maltase, amylo-1,6-glucosidase, and phosphorylase in the heart or in the liver or skeletal muscle. However, phosphorylase kinase activity was not detectable in the heart, although high activity levels were observed in the liver and skeletal muscle. In this case the inborn error of metabolism responsible for the isolated deposition of glycogen in heart muscle may have been due to a deficiency of cardiac phosphorylase kinase.

Clinical and laboratory observations in a child with hepatic phosphorylase kinase deficiency.

A 3-year-old child with glycogenosis due to hepatic phosphorylase kinase deficiency is described. His clinical presentation was unusually severe. Biochemical studies revealed a lack of hypoglycemia, the presence of marked ketosis and hyperlipidemia, and a normal glycemic response to glucagon and to loading with galactose, fructose, and alanine. The ketosis was reversed by glucagon administration. Changes in plasma concentrations of lactate, pyruvate, beta-OH butyrate, and alanine in response to glucagon, galactose, fructose, and alanine administration are reported. The child responded poorly to a high protein diet. His condition improved markedly with a high carbohydrate diet. The significance of the findings is discussed.