The abundance of calmodulin mRNAs is regulated in phosphorylase kinase-deficient skeletal muscle

In the I/Lyn mouse strain a mutation on the X chromosome results in a deficiency of the major calmodulin-regulated enzyme in skeletal muscle, phosphorylase kinase. Calmodulin has been identified as the delta-subunit of phosphorylase kinase, and it is estimated that approximately 40% of the total calmodulin in rabbit skeletal muscle is associated with the phosphorylase kinase hexadecamer (alpha, beta, gamma, delta)4. The absence of phosphorylase kinase in I/Lyn skeletal muscle results in a reduction in the total amount of calmodulin. The mechanisms affecting this reduction were investigated by comparing the abundance and heterogeneities in calmodulin mRNAs between normal and phosphorylase kinase-deficient skeletal muscles. The results demonstrate that in normal tissue there are four species of calmodulin mRNA distinguished by their molecular weight. All four of these species are present in the deficient tissue, and none of them are preferentially reduced. However, there is a 54% reduction in all four mRNAs as well as in calmodulin in the deficient skeletal muscle relative to normal skeletal muscle. These results indicate that the expression of calmodulin mRNAs is coordinated with the expression of its major enzyme target in skeletal muscle.     

The phosphorylase kinase deficiency (Phk) locus in the mouse: Evidence that the mutant allele codes for an enzyme with an abnormal structure

Female (I/St X C57BL/St) F1 mice heterozygous at the sex-linked phosphorylase kinase deficiency locus (Phk) have phosphorylase kinase activities averaging 86% that of mice homozygous for the wild-type allele (C57BL/St), i.e., 72% greater than the sum of one-half the activities of the parental strains. Approximately one-half the phosphorylase kinase activity in the (I X C57BL) F1 muscle extracts had a stability at 42.5 C similar to that of the activity in C57BL extracts (t1/2 = 13.2 min); the other half of the activity in the F1 extracts was more labile (t1/2 = 3.9 min). Two species of phosphorylase kinase activity in F1 muscle extracts were also differentiated with an antiserum prepared in guinea pigs against purified rabbit skeletal muscle phosphorylase kinase. This anti-serum cross-reacted with phosphorylase kinase in C57BL muscle extracts but did not cross-react with skeletal muscle extracts of mice hemi- or homozygous for the mutant allele (I/LnJ). The guinea pig antiserum precipitated 52% as much protein from (I X C57BL)F1 muscle extracts compared to those of C57BL. However, an antiserum prepared against purified rabbit skeletal muscle phosphorylase kinase in the goat cross-reacted with the mutant phosphorylase kinase. The ratio C57BL:(I X C57BL)F1:I of immunoprecipitated protein from skeletal muscle extracts with this antiserum was 1:0.97:1.08. Polyacrylamide gel electrophoresis of the immunoprecipitates in the presence of 0.1% sodium dodecylsulfate showed three subunits for mouse phosphorylase kinase with molecular weights of 139,000, 118,000, and 41,000; these values are similar to the ones obtained with purified rabbit skeletal muscle phosphorylase kinase. These three subunits were also observed in immunoprecipitates from I/LnJ muscle extracts. These results offer substantial evidence (1) that in skeletal muscle extracts of mice heterozygous at the Phk locus the mutant phosphorylase kinase is active, (2) that the gene product of the mutant allele is an enzyme with an abnormal structure, and (3) that the phosphorylase kinase deficiency in I/LnJ skeletal muscle extracts is not the result of the absence of phosphorylase kinase or one of its subunits.     

Phosphorylase kinase from chicken skeletal muscle. Quaternary structure, regulatory properties and partial proteolysis

Phosphorylase kinase has been purified from white and red chicken skeletal muscle to near homogeneity, as judged by sodium dodecyl sulphate (SDS) gel electrophoresis. The molecular mass of the native enzyme, estimated by chromatography on Sepharose 4B, is similar to that of rabbit skeletal muscle phosphorylase kinase, i.e. 1320 kDa. The purified enzyme both from white and red muscles showed four subunits upon polyacrylamide gel electrophoresis in the presence of SDS, corresponding to alpha', beta, gamma' and delta with molecular masses of 140 kDa, 129 kDa, 44 kDa and 17 kDa respectively. Based on the molecular mass of 1320 kDa for the native enzyme and on the molar ratio of subunits as estimated from densitometric tracings of the polyacrylamide gels, a subunit formula (alpha' beta gamma' delta)4 has been proposed. The antiserum against the mixture of the alpha' and beta subunits of chicken phosphorylase kinase gave a single precipitin line with the chicken enzyme but did not cross-react with the rabbit skeletal muscle phosphorylase kinase. The pH 6.8/8.2 activity ratio of phosphorylase kinase from chicken skeletal muscle varied from 0.3 to 0.5 for different preparations of the enzyme. Chicken phosphorylase kinase could utilize rabbit phosphorylase b as a substrate with an apparent Km value of 0.02 mM at pH 8.2. The apparent V (18 mumol min-1 mg-1) and Km values for ATP at pH 8.2 (0.20 mM) were of the same order of magnitude as that of the purified rabbit phosphorylase kinase b. The activity of chicken phosphorylase kinase was largely dependent on Ca2+. The chicken enzyme was activated 2-4-fold by calmodulin and troponin C, with concentrations for half-maximal activation of 2 nM and 0.1 microM respectively. Phosphorylation with the catalytic subunit of cAMP-dependent protein kinase (up to 2 mol 32P/mol alpha beta gamma delta monomer) and autophosphorylation (up to 8 mol 32P/mol alpha beta gamma delta monomer) increased the activity 1.5-fold and 2-fold respectively. Limited tryptic and chymotryptic hydrolysis of chicken phosphorylase kinase stimulated its activity 2-fold. Electrophoretic analysis of the products of proteolytic attack suggests some differences in the structure of the rabbit and chicken gamma subunits and some similarities in the structure of the rabbit red muscle and chicken alpha'.     

Characterization of the isolated rat flexor digitorum brevis for the study of skeletal muscle phosphorylase kinase phosphorylation

The flexor digitorum brevis skeletal muscle, a nearly homogeneous fast-twitch oxidative glycolytic fiber type, has been examined for its suitability to explore the regulation of phosphorylase kinase by multisite phosphorylation. A characterization of the adrenergic response of glycogenolytic enzymes, together with the previous data on contractile properties (Carlsen, R. C., Larson, D. B., and Walsh, D. A. (1985) Can. J. Physiol. Pharm. 63, 958-965), has demonstrated that this muscle is stably maintained for the several hours necessary for phosphorylation studies. The phosphorylase kinase in this muscle is primarily the alpha' isozyme, suggesting that the alpha versus alpha' isozyme distribution in muscle is related more to oxidative capacity than to fiber contractile characteristics. Using this muscle system, beta-adrenergic activation of phosphorylase kinase was observed to occur with concomitant phosphorylation of both the alpha' and beta subunits, with the total in the alpha' subunit being approximately 3-fold greater. Similarly, deactivation, following initial adrenergic activation, occurred concomitantly with the dephosphorylation of the two subunits. These results are compatible with the conclusions drawn from previous studies of the isolated enzyme and of the enzyme in perfused rat cardiac muscle, that both alpha' (or alpha) and beta subunit phosphorylation regulate phosphorylase kinase activity.     

In vivo developmental modifications of the expression of genes encoding muscle-specific enzymes in rat

cDNA clones for rat muscle-type creatine kinase and glycogen phosphorylase and aldolase A were isolated from a rat muscle cDNA library. An additional clone recognizing an unidentified 2.7-kilobase pair mRNA species was also isolated. These cDNA clones were used as probes to investigate the expression of the corresponding mRNAs during muscle development. Two aldolase A mRNA species were detected, one of 1650 bases expressed in non-muscle tissues, fetal muscle, and adult slow-twitch muscle, the other of 1550 bases was highly specific of adult fast-twitch skeletal muscle differentiation. These aldolase A mRNAs were shown by primer extension to differ by their 5' ends. The accumulation of muscle-type phosphorylase and creatine kinase and muscle-specific aldolase A mRNA accumulation during muscle development seems to be a coordinate process occurring progressively from the 17th day of intrauterine life up to the 30th day after birth. In contrast, the 2.7-kilobase pair RNA species is maximally expressed at the 1st week after birth as is the neonatal form of myosin heavy chain mRNA.     

Isozymes of phosphorylase kinase in rabbit skeletal muscle. Functional implications of differences in phosphorylase kinase and phosphorylase activities in individual muscle fibers

Immunological and microanalytical methods were used to investigate the two isozymes of phosphorylase kinase, enzyme w and enzyme r, in psoas major and tibialis anterior muscles. Peptide mapping experiments indicated that the alpha subunit of enzyme w and alpha' subunit of enzyme r were structurally very similar. Both subunits were completely immunoprecipitated from muscle extracts with an antibody specific for the beta subunit of the kinase, indicating that alpha and alpha' subunits are completely assembled with beta subunits in adult muscle fibers. The relative amounts of enzymes w and r in single fibers were determined from amounts of alpha and alpha' subunits, which were detected by immunoblotting. Phosphorylase kinase and phosphorylase activities were measured in the same fibers, as well as in individual fibers from diaphragm and soleus muscles. Slow oxidative fibers were found to contain low levels of enzyme r, but almost no enzyme w. Considerably more enzyme r was present in fast oxidative-glycolytic fibers. Fast glycolytic fibers contained the most enzyme w, and the highest levels of enzyme r were found in a subgroup of such fibers. Interestingly, more than half of the fast glycolytic fibers analyzed contained both isozymes. In these fibers phosphorylase was positively correlated with enzyme w, but negatively correlated with enzyme r. Total kinase activity ranged 30-fold from the highest in one of the psoas fibers to the lowest in one of the soleus fibers and was closely correlated with the phosphorylase levels. In psoas and soleus fibers, calculated absolute maximal rates for phosphorylase b to a conversion varied almost 2,500-fold.     

Limited proteolysis and phosphorylation of phosphorylase kinase from chicken skeletal muscles

The changes in the quaternary structure of chicken skeletal muscle phosphorylase kinase during limited proteolysis by trypsin and chymotrypsin were studied. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate of the products of phosphorylase kinase limited proteolysis revealed a similarity in the structure of the alpha'- and beta-subunits and some differences in the structure of the gamma-subunits of the chicken and rabbit enzymes. Phosphorylation with the catalytic subunit of cAMP-dependent protein kinase (up to 2 mol of 32P/mol of alpha' beta gamma' sigma monomer) and autophosphorylation (up to 8 mol of 32P/mol alpha' beta gamma' delta monomer) increased the activity of chicken phosphorylase kinase 1.5-fold and 2.0-fold, respectively. The incorporation of phosphate into the alpha' and beta-subunits in the course of the protein kinase-catalyzed reaction was demonstrated.     

Purification, quaternary structure and immunological properties of phosphorylase kinase from chicken skeletal muscle

Phosphorylase kinase was isolated from red and white chicken skeletal muscle in a nearly homogeneous state as judged by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. The molecular weight of the native enzyme as determined by gel filtration on Sepharose 4B is close to that of rabbit skeletal muscle phosphorylase kinase (i. e., approximately 1300 000). The molecular weights of the subunits determined by SDS gel electrophoresis are: alpha', 140 000 beta, 129 000; gamma', 44 000; delta, 17 000 (cf. the Mr values of the alpha- and gamma-subunits of the rabbit muscle isoenzyme are 146 000 and 42 000). The four subunits, alpha', beta, gamma' and delta, were found to exist in equimolar amounts as shown by a densitometric analysis of acrylamide gels; hence, the subunit formula of the chicken skeletal muscle isoenzyme is (alpha' beta gamma' delta)4. Rabbit antisera against a mixture of alpha'- and beta-subunits of chicken phosphorylase kinase yield a single precipitin line with this enzyme, do not show cross reactions of identity with the rabbit muscle enzyme but strongly inhibit the activity of the chicken enzyme and partially inhibit the activity of the rabbit muscle isoenzyme.     

The phosphorylation of troponin B by phosphorylase b kinase in skeletal muscle of mice carrying the phosphorylase b kinase deficiency gene

In skeletal muscle of animals with the phosphorylase $\text{b}$ kinase deficiency gene there is < 1% of the normal activity to convert phosphorylase $\text{b}$ to $\text{a}$ in the presence of Ca⁺⁺, Mg⁺⁺, and ATP (1). Correspondingly, there is < 1% of the normal activity to phosphorylate phosphorylase $\text{b}$. Nevertheless, under the same conditions, these extracts catalyze the phosphorylation of troponin at a rate 57% of normal. Phosphorylase $\text{b}$ converting activity can be sedimented from skeletal muscle of control mice by centrifugation. This fraction isolated from I strain skeletal muscle extracts phosphorylates troponin at a rate 29–39% of the control. EGTA¹ (15 mM) inhibits troponin phosphorylation by 50–60% in this fraction from both strains. The EGTA inhibition is reversed by 15 mM Ca⁺⁺. Thus the phosphorylase $\text{b}$ kinase in skeletal muscle of animals with the phosphorylase $\text{b}$ kinase deficiency gene can phosphorylate troponin B, although it shows little or no activity with phosphorylase as a substrate. This observation is consistent with the normal muscle contractility of I strain animals.     

Mapping of the phosphorylase kinase alpha subunit gene on the mouse X chromosome

Phosphorylase kinase is a glycogenolytic enzyme in several animal tissues. Within the last few years all four subunits of the enzyme have been cloned. The beta, gamma, and delta subunits are known to be autosomal. We have mapped the alpha subunit of phosphorylase kinase, recently cloned by Zander et al. (1988), in an interspecific mouse pedigree and localized it on the X chromosome, where it maps between the X-linked zinc finger protein and phosphoglycerate kinase genes, close to the latter. In man and mouse several X-linked disorders of this enzyme have been described. Although the X-linked phosphorylase kinase deficiency in mice may be caused by a mutation in the structural gene for the alpha subunit, mapped here, the existence of a separate regulatory locus, important in the normal expression or function of the enzyme in muscle, still remains a possibility.     

Isoform diversity of phosphorylase kinase alpha and beta subunits generated by alternative RNA splicing

We have sequenced rabbit cDNAs that encode one isoform of the alpha subunit and two isoforms of the beta subunit of phosphorylase kinase, in addition to the single isoform from fast skeletal muscle that has been characterized to date for each subunit. All these isoforms are generated by alternative RNA splicing. The alpha subunit sequence obtained from slow skeletal muscle (soleus) is characterized by an internal deletion of 59 amino acids. This deletion is predominant in mRNA from slow muscle, heart, and uterus and accounts for the smaller alpha subunit variant (alpha') characteristic of phosphorylase kinase purified from slow muscle and heart. The beta subunit mRNA can be differentially spliced at two sites. In all tissues (except skeletal muscle) that were analyzed, an internal segment encoding 28 amino acids of the muscle sequence is replaced by a homologous sequence of identical length, presumably through the use of mutually exclusive exons. In brain and some other tissues, the deduced N-terminal sequence of the beta subunit is also changed. This is achieved by an insertion into the mRNA sequence that interrupts the initial reading frame after 25 codons and starts a new reading frame, encoding a different N terminus of 18 amino acids. This modification probably affects the major regulatory phosphorylation site of the beta subunit.     

Effects of altered thyroid status on beta-adrenergic actions on skeletal muscle glycogen metabolism

The effects of hypothyroidism on glycogen metabolism in rat skeletal muscle were studied using the perfused rat hindlimb preparation. Three weeks after propylthiouracil treatment, serum thyroxine was undetectable and muscle glycogen and Glc-6-P were decreased. Basal and epinephrine-stimulated phosphorylase a and phosphorylase b kinase activities were also significantly reduced, as were epinephrine-stimulated cAMP accumulation and cAMP-dependent protein kinase activity. Conversely, basal and epinephrine-stimulated glycogen synthase I activities were significantly higher while the Ka of the enzyme for Glc-6-P was lower in hypothyroid animals. Propylthiouracil-treated rats also had increased phosphoprotein phosphatase activities towards phosphorylase and glycogen synthase and decreased activity of phosphatase inhibitor 1. beta-Adrenergic receptor binding and basal and epinephrine-stimulated adenylate cyclase activities were reduced in muscle particulate fractions from hypothyroid rats. Administration of triiodothyronine to rats for 3 days after 3 weeks of propylthiouracil treatment restored the altered metabolic parameters to normal. It is proposed that the decreased beta-adrenergic responsiveness of the enzymes of glycogen metabolism in hypothyroid rat skeletal muscle is due to increased activity of phosphoprotein phosphatases and to reduced beta-adrenergic receptors and adenylate cyclase activity.     

Dephosphorylation and inactivation of phosphorylase kinase: subunit specificity of rabbit skeletal muscle protein phosphatases

The dephosphorylation of phosphorylase kinase by four rabbit skeletal muscle protein phosphatases was studied. The four enzymes used were preparations of protein phosphatases C-I, C-II, H-I, and H-II. Phosphatases C-I, C-II, and H-II were obtained as homogeneous preparations using procedures previously developed. Phosphatase H-I was purified 644-fold from rabbit skeletal muscle for the purposes of this study, and was the major phosphorylase phosphatase activity in the tissue extract. Phosphatases C-I and H-I were relatively specific for removal of the beta subunit phosphate of phosphorylase kinase, this occurring at rates approximately 100 times more rapidly than the removal of the alpha subunit phosphate. In contrast, phosphatases C-II and H-II readily dephosphorylated both the alpha and beta subunits, although the alpha subunit phosphate release occurred at rates about twice that of the beta subunit phosphate. These studies show that skeletal muscle contains two phosphatases capable of acting on phosphorylase kinase, and that these have different specificities as represented by phosphatases H-I and C-I on the one hand, and phosphatases C-II and H-II on the other hand. These studies also provided unequivocal evidence that dephosphorylation of the beta subunit of phosphorylase kinase is solely involved in the inactivation of the cAMP-dependent protein kinase-activated enzyme. When autophosphorylated phosphorylase kinase was used as the substrate, the four phosphatases displayed similar general specificities as they did toward the cAMP-dependent protein kinase-activated enzyme. With none of the phosphatases examined was there any evidence that alpha subunit phosphorylation affected the rate of beta subunit dephosphorylation.     

Monoclonal antibodies to rabbit skeletal muscle phosphorylase kinase. Probes for studies of subunit function

Monoclonal antibodies to rabbit skeletal muscle phosphorylase kinase were produced by the conventional hybridoma cell technique. 90 out of 600 hybridomas were found to produce phosphorylase kinase binding antibodies from which only five secreted also phosphorylase kinase activity affecting antibodies. Three of them were cloned; two hybridomas resisted all cloning efforts. Employing immunoblot technique all monoclonal antibodies show cross-reactivity with the alpha, beta, and gamma subunits of phosphorylase kinase indicating that similar, if not identical, epitopes are present on these three subunits. No cross-reactivity with delta is observed. Monoclonal antibodies secreted by two clones which bind to the alpha subunit stimulate the Ca2+-independent A0 activity of phosphorylase kinase more than 30-fold, whereas all other monoclonal antibodies obtained are ineffective in this respect. Monoclonal antibodies binding to the beta subunit inhibit the Ca2+-dependent activities significantly. Antibody produced by one hybridoma binds to the alpha, beta, and gamma subunits with approximately the same affinity. Based on the dual function of calmodulin in phosphorylase kinase (Hessová, Z., Varsányi, M., and Heilmeyer, L.M.G., Jr. (1985) Eur. J. Biochem. 146, 107-115) we conclude that binding of anti-alpha monoclonal antibodies to a regulatory domain in the alpha subunit results in an uncoupling of the inhibitory function of the Ca2+-free delta from the holoenzyme which leads to a concomitant increase in A0 activity. Furthermore, binding of anti-beta monoclonal antibodies to the beta subunit prevents a signal transfer from the Ca2+-saturated delta to the catalytic site of the holoenzyme which inhibits the Ca2+-dependent activities.     

Precise control of fasciclin II expression is required for adult mushroom body development in Drosophila

Fasciclin II (FASII) is a cell adhesion molecule that participates in axonal pathfinding, fasciculation and divergence in the Drosophila nervous system. Here, we examined spatio-temporal control of fasII expression during the development of adult mushroom body (MB) and found that suppression of fasII in alpha'/beta' neurons is essential for the formation of adult alpha'/beta' and alpha/beta lobes. Of gamma, alpha'/beta' and alpha/beta neurons, which are derived sequentially from the same four MB neuroblasts, only gamma and alpha/beta neurons expressed fasII. When fasII was misexpressed in developing MB neurons, defects resulted, including loss or misdirection of adult alpha'/beta' lobes and concurrent misdirection of alpha/beta lobes. Although no gross anatomical defects were apparent in the larval MB lobes, alpha'/beta' lobes collapsed at the pupal stage when the larval lobe of gamma neurons degenerated. In addition, alpha/beta lobes, which developed at this time, were misdirected in close relationship with the collapse of alpha'/beta' lobes. These defects did not occur when fasII was overexpressed in only gamma and alpha/beta neurons, indicating that ectopic expression of fasII in alpha'/beta' neurons is required for the defects. Our findings also suggest that the alpha'/beta' lobe play a role in guiding the pathfinding by alpha/beta axons.     

Pest sequences present in the subunits of phosphorylase kinase

We report that the amino acid sequences of all four subunits of rabbit skeletal muscle phosphorylase kinase possess one or more regions rich in proline (P), glutamic acid (E), serine (S) and threonine (T). alpha and beta subunits contain strong PEST sequences, showing PEST scores greater than 0 (Rogers et al. (1986) Science 234, 364-368), while gamma and delta subunits contain weak PEST regions (negative PEST scores greater than -5.3). In addition to PEST sequences, alpha, beta and gamma subunits contain clusters of arginine pairs. The above sequence characteristics may serve to signal rapid turnover of phosphorylase kinase.     

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 (Phk ^c ). 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 (+)::=0.54:1:1.169, in comparison with that of the rabbit (+)::=1.1:1.0:1.0 and that of normal murine enzyme 0.9:1.0:0.7.This work was supported by the Minister für Wissenschaft und Forschung des Landes Nordrhein-Westfalen, West Germany and of the Fonds der Chemie, West Germany, and forms part of the md thesis of A. Vrbica.     

Thiophosphate-activated phosphorylase kinase as a probe in the regulation of phosphorylase phosphatase.

Rabbit muscle nonactivated phosphorylase kinase (EC 2.7.1.38) is converted to thiophosphate-activated phosphorylase kinase by cyclic AMP dependent protein kinase, Mg2+ and ATP-gamma-S/adenosine-5'-O-(s-thiotriphosphate)/. The formation of thiophosphate-activated phosphorylase kinase wal also observed in the protein-glycogen complex from skeletal muscle. This new form of kinase is resistant to the action of phosphatase and behaves as a competitive inhibitor in the dephosphorylation of phosphorylase alpha by phosphorylase phosphatase (Ki = 0.04 mg per ml). The fact that the inhibitory effect of thiophosphate-activated phosphorylase kinase is 3 times higher than in the case of nonactivated kinase, may explain the transient inhibition of phosphorylase phosphatase in the protein-glycogen complex. The use of activated (phosphorylated) phosphorylase kinase supports this assumption since it causes a delay in the dephosphorylation of phosphorylase alpha, i.e. the conversion of phosphorylase alpha into beta could start only after the dephosphorylation of activated phosphorylase kinase.