Characterization of a Ca2+ -dependent protein kinase in skeletal muscle membranes of I-strain and wild-type mice

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.

The association of phosphorylase kinase with membranes of rat liver smooth endoplasmic reticulum

Upon fractionation of a post mitochondrial supernatant from rat liver, phosphorylase kinase activity was largely recovered in the cytosol and the smooth endoplasmic reticulum (SER) fraction. The presence of phosphorylase kinase in SER vesicles was not due to an interaction of the enzyme with glycogen particles, since previous elimination of SER glycogen either by 48 h animal starvation or by treatment of the membrane fraction with alpha-amylase did not significantly alter phosphorylase kinase activity content. Washing of the initial pellet of SER fraction (crude SER) by dilution and recentrifugation, released in the supernatant an amount of phosphorylase kinase activity, which is dependent on: i) the degree of dilution, ii) the number of washes, iii) the ionic strength of the washing solution and iii) the presence or absence of Ca2+. Crude SER-associated phosphorylase kinase was marginally affected by increased concentrations of antibody against rabbit skeletal muscle holoenzyme which nevertheless drastically inhibited cytosolic enzyme activity, while it showed a higher resistance to partial proteolysis and a different Western blotting profile with anti-phosphorylase kinase when compared with the soluble kinase. A small but significant fraction of SER phosphorylase kinase was strongly associated with the microsomal fraction being partly extractable only in presence of detergents. This membrane-bound enzyme form exhibited an alkaline pH optimum, in contrast to the neutral pH optima of both soluble and weakly associated phosphorylase kinase.

Subcellular distribution of phosphorylase kinase in rat brain. Association of the enzyme with mitochondria and membranes

The evaluation of glycogen phosphorylase kinase in rat brain subcellular fractions was undertaken in order to get further insight into the association of this kinase with specific neuronal cell compartments. The enzyme was found to be primarily soluble, but considerable latent specific activities were observed in particulate fractions, especially in microsomes, mitochondria and synaptosomes, which could be unmasked by treatment with Triton-X-100. The submitochondrial and subsynaptic distribution patterns of phosphorylase kinase revealed high overt activity in the mitochondrial intermembrane space and high latent activities in mitochondrial membranes, and synaptic vesicles, membranes and mitochondria. The Ca(2+)-dependency of soluble phosphorylase kinase was similar to that of microsomal enzyme but higher than that of other particulate enzyme forms. Mitochondrial phosphorylase kinase showed a higher pH 6.8:8.2 activity ratio than the soluble and the microsomal enzyme. The rate of inactivation of cytosolic phosphorylase kinase by proteinase K was higher than that of microsomal and mitochondrial enzymes. Antibodies against rabbit skeletal muscle phosphorylase kinase effectively inhibited both cytosolic and microsomal enzyme but failed to significantly affect the kinase activity present in intact mitochondria and intermembrane space. Western blotting with anti-phosphorylase kinase showed that rat brain mitochondria exhibited a significantly lower immunoreactivity compared to soluble cytosol. In conclusion, the presence of phosphorylase kinase activity in a variety of particulate fractions of rat brain suggests a multiplicity of actions of this kinase in neuronal tissues.

Phosphorylase kinase from bovine stomach smooth muscle: a Ca2(+)-dependent protein kinase associated with an actin-like molecule

Phosphorylase kinase was purified (110-fold) from bovine stomach smooth muscle by a procedure involving DEAE-cellulose chromatography, ammonium sulfate fractionation and glycerol density ultracentrifugation. On sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) the final enzyme preparation shows a single protein band of 43 kDa. The purified protein exhibits a close similarity with bovine aortic actin, as revealed by amino acid analysis and sequencing of a tryptic decapeptide fragment, although it differs widely from actin in several respects. In our effort to separate phosphorylase kinase activity from the 43 kDa protein we used a variety of chromatographic procedures, but in all cases the catalytic activity (when eluted) was accompanied by the 43 kDa protein band. Bovine stomach phosphorylase kinase exhibits an apparent molecular mass of 950 kDa, it shows a low Vmax value for phosphorylase b (85 nmol.min-1.mg-1), a pH 6.8/8.2 activity ratio of 0.23, it has an absolute requirement for Ca2+ and it is activated 1.8-fold by Ca2+/calmodulin. Furthermore, the protein kinase activity is neither inhibited by antibodies against rabbit skeletal muscle phosphorylase kinase nor activated by protein phosphorylation. These results suggest that bovine stomach phosphorylase kinase is tightly bound to an aggregate of actin-like molecules.

Evidence that phosphorylase kinase exhibits phosphatidylinositol kinase activity

Phosphorylase kinase phosphorylates the pure phospholipid phosphatidylinositol. Furthermore, it catalyzed phosphatidylinositol 4-phosphate formation using as substrate phosphatidylinositol that is associated with an isolated trypsin-treated Ca2+-transport adenosinetriphosphatase (ATPase) preparation from skeletal muscle sarcoplasmic reticulum. On this basis a fast and easy assay was developed that allows one to follow the phosphatidylinositol kinase activity during a standard phosphorylase kinase preparation. Both activities are enriched in parallel approximately to the same degree. Neither chromatography on DEAE-cellulose nor that on hydroxyapatite in the presence of 1 M KCl separates phosphatidylinositol kinase from phosphorylase kinase. The presence of a lipid kinase, phosphatidylinositol kinase, in phosphorylase kinase is not a general phenomenon; diacylglycerol kinase can be easily separated from phosphorylase kinase. Polyclonal anti-phosphorylase kinase antibodies as well as a monoclonal antibody directed specifically against the alpha subunit of phosphorylase kinase immunoprecipitate both phosphorylase kinase and phosphatidylinositol kinase.

The association of phosphorylase kinase with rabbit muscle T-tubules

Evidence is presented for the association of a phosphorylase kinase activity with transverse tubules as well as terminal cisternae in triads isolated from rabbit skeletal muscle. This activity remained associated with T-tubules throughout the purification of triad junctions by one cycle of dissociation and reassociation. The possibility that the presence of phosphorylase kinase in these highly purified membrane vesicle preparations was due to its association with glycogen was eliminated by digestion of the latter with alpha-amylase. The phosphorylase kinase activity associated with the T-tubule membranes was similar to that reported for other membrane-bound phosphorylase kinases. The enzyme had a high pH 6.8/pH 8.2 activity ratio (0.4-0.7) and a high level of Ca2+ independent activity (EGTA/Ca2+ = 0.3-0.5). The kinase activated and phosphorylated exogenous phosphorylase b with identical time courses. When mechanically disrupted triads were centrifuged on continuous sucrose gradients, the distribution of phosphorylase kinase activity was correlated with the distribution of a Mr 128,000 polypeptide in the gradients. This polypeptide and a Mr 143,000 polypeptide were labeled with 32P by endogenous and exogenous protein kinases. These findings suggest that the membrane-associated phosphorylase kinase may be similar to the cytosolic enzyme. Markers employed for the isolated organelles included a Mr 102,000 membrane polypeptide which followed the distribution of Ca2+-stimulated 3-O-methylfluorescein phosphatase activity, which is specific for the sarcoplasmic reticulum. A Mr 72,000 polypeptide was confirmed to be a T-tubule-specific protein. Several proteins of the triad component organelle were phosphorylated by the endogenous kinase in a Ca2+/calmodulin-stimulated manner, including a Mr ca. 72,000 polypeptide found only in the transverse tubule.

Biochemistry and pharmacology of the myometrium and labor: regulation at the cellular and molecular levels

This review presents the essentials of cell biology, biochemistry, and pharmacology of the myometrium and labor, especially as they relate to premature labor. The aim is to explore the neuroendocrine and pharmacologic regulation of myometrial muscle cells in the context of cell membrane function and contractile processes. In the first section, smooth muscle protein structure and interactions are described, the central roles of myosin light-chain kinase, calcium, and cyclic adenosine monophosphate (cAMP) are reviewed. Subsequently, events relating to hormone/drug receptor function and implications for pharmacologic applications are discussed. Finally, the processes of information transfer via hormones and drugs are incorporated into a model which explains how the hormones and drugs used in clinical practice may mediate myometrial contractility. The reader is introduced to current concepts of the cellular, molecular, and pharmacologic aspects of labor in order to facilitate the understanding of medical augmentation of labor and tocolytic therapy.

Isolation and some properties of troponin T kinase from rabbit skeletal muscle

A method for isolation of troponin T kinase (ATP-protein phosphotransferase, EC 2.7.1.37) from rabbit skeletal muscles in proposed. The method gives a 7000-10 000-fold purification and results in an enzyme with specific activity of 400-800-nmol x min-1 x mg-1 of protein. The molecular weight of tropin T kinase as determined by gel filtration exceeds 500 000. Electrophoresis in polyacrylamide gel in the presence of sodium dodecyl sulphate revealed that isolated preparations of the enzyme consisted of at least three distinct proteins with apparent mol.wt. of 50 000, 46 000 and 31 000. The enzyme phosphorylates isolated troponin T at a rate which exceeds the phosphorylation rates of casein, phosvitin, histones, phosphorylase b and protamine 5-30-fold. Within the whole troponin complex, only troponin T is phosphorylated by the enzyme. The enzyme phosphorylates only the N-terminal serine residue of troponin T, i.e. the site that is normally phosphorylated in the whole troponin complex isolated from rabbit skeletal muscles.

X-linked dominant inheritance of partial phosphorylase kinase deficiency in mice

A new mouse strain, the V strain, with a partial deficiency of phosphorylase kinase has been established. The deficiency is caused by an X-linked dominant gene (PhKc). Muscle extracts of homozygous and heterozygous females and hemizygous males have about 25% of the activity found in extracts of normal (C3H/HeHan) mice. This dominant phosphorylase kinase deficiency of the new V strain is different from that of the I-strain mice with the X-linked recessive deficiency of skeletal muscle phosphorylase kinase. The muscle extracts of V-strain and normal mice contain the same phosphorylase phosphatase activity of about 1 U/mg. Heart and liver extracts from V mice contained about 50% and 66%, respectively, of the phosphorylase kinase activity compared to that found in the same organs from the normal mice. The glycogen content of the skeletal muscle of the V strain was normal, i.e., 0.9 mg/g. Phosphorylase kinase was purified from the skeletal muscle of the V strain by (a) hydrophobic chromatography on methylamine Sepharose, (b) ammonium sulfate precipitation, and (c) gel filtration of Sepharose 4B. The enzyme has a similar structure to the normal murine and rabbit skeletal muscle enzyme, except that the proportion of the subunits differs. The molar ratio of the subunits of the V strain mice is (alpha + alpha'):beta:gamma=0.54:1:1.169, in comparison with that of the rabbit (alpha + alpha'):beta:gamma=1.1:1.0:1.0 and that of normal murine enzyme 0.9:1.0:0.7.

Metabolic adaptation in phosphorylase kinase deficiency. Changes in metabolite concentrations during tetanic stimulation of mouse leg muscles

1. Glycogen, nucleotides and glycolytic intermediates and products were measured before and during tetanus in the hamstrings-muscle groups of normal (C3H) and phosphorylase kinase-deficient (ICR/IAn) mice. 2. Phosphorylase kinase-deficient muscles contained 3-4-fold more glycogen and sustained a larger (approx. 2-fold), more rapid (11 +/- 2 ng/s faster) and more prolonged glycogenolysis during 120s tetanus despite their lack of phosphorylase a. 3. No significant change in total adenine nucleotide contents occurred during tetanus in either strain, but there was a 60-100-fold rise in IMP concentration to approx. 2mM in both strains. The initial rate of IMP formation was 6-fold more rapid (112 nmol/s per g) in phosphorylase kinase-deficient muscle. 4. Adenylosuccinate content rose to 36 nmol/g in phosphorylase kinase-deficient muscle and to 9 nmol/g in normal muscle at 45s tetanus, but then fell. 5. In phosphorylase kinase-deficient muscle, glucose 6-phosphate, a powerful phosphorylase inhibitor, was 56% of that in normal muscle. 6. The mass-action ratio of the phosphoglucomutase-catalysed reaction [glucose 6-phosphate]/[glucose 1-phosphate] was markedly lower than Keq. (approx. 17) in relaxed muscle of both strains (approx. 5-7), but rose significantly during tetanus to the value for Keq. 7. The data for IMP satisfy the criteria put forward by Rahim, Perrett & Griffiths [(1976) FEBS Lett. 69, 203-206] for a nucleotide activator of phosphorylase b: it should be present at a higher concentration in phosphorylase kinase-deficient muscle, its concentration should rise during muscle work, and it should attain a concentration comparable with its activation constant for phosphorylase b.