Organ-specific distribution of the calcium sensor CaMKII in Locusta migratoria

The Ca(2+)/calmodulin-dependent kinase CaMKII is a key signaling component in Ca(2+)-dependent physiological processes. The expression and function of CaMKII in insect brain is well documented but less investigated for other tissues of insects. The present study demonstrates that in the locust Locusta migratoria CaMKII is widely expressed in various tissues. Relatively high expression levels of CaMKII were found in the brain, upper part of the digestive tract (pharynx, esophagus), and the flight and leg muscles. The different expression patterns of CaMKII in various tissues, as well as different molecular masses of CaMKII between 48 and 60 kDa indicate a tissue-specific expression of CaMKII variants. The expression was monitored with a polyclonal anti-(rat)CaMKII antibody. About 60% of total CaMKII activity in flight muscle cells is associated to the myofibril-rich, particulate fraction suggesting an important role of CaMKII in sarcomeric function.     

Localization of projectin in locust flight muscle

Projectin is a giant filamentous protein of arthropod striated muscle. By using immunofluorescence microscopy, projectin was shown to span between the I band and the A band in locust (Locusta migratoria) flight muscle sarcomeres. The N- and C-terminal regions of projectin molecules were localized in the I band and A band, respectively. This observation explains the controversial reports of previous studies that projectin is localized either in the I band or in the A band of locust flight muscle sarcomeres. It is also observed that the N-terminal region of projectin is located in the I band of locust leg muscle sarcomeres.     

The kinase activity of the giant protein projectin of the flight muscle of Locusta migratoria

Projectin is a member of the functionally and structurally heterogeneous family of myosin light chain kinases associated to myosin of synchronous as well as asynchronous insect muscles. We examined the phosphotransferase activity of projectin from flight muscle of Locusta migratoria. Isolated projectin exhibits an unstimulated autophosphorylation activity in vitro. We observed differences in the formation of synthetic filaments with myosin, and paramyosin depending on if projectin was autophosphorylated in vitro or not. Aggregates of native projectin with myosin and paramyosin (molar ratio 0.08:1:0.5) showed diameters 20-50 nm similar to those of myosin filaments. When in vitro autophosphorylated projectin was used we predominantly obtained, however, subfilament-like structures of only 7-10 nm in diameter. The in vitro autophosphorylation of projectin was suppressed in the presence of either acto-myosin, actin-filaments or myosin, but still seems to exhibit a phosphorylation activity: Projectin added to actomyosin resulted in the phosphorylation of three polypeptides of apparent molecular masses of 200, 165 and 100 kDa, respectively. These data suggest that the autophosphorylation activity of projectin is regulated by its environment. We conclude, therefore, a dual function of its kinase domain: at first, a role of its autophosphorylation in the formation of myosin filaments (association of subfilaments to filaments); secondly, the transphosphorylation activity of projectin modulates the contractile response of the actomyosin system by phosphorylating some of its components. Moreover, we could stimulate in vitro the projectin autophosphorylation 3.4-fold by calmodulin (EC50 = 17.8 nM). However, the transphosphorylations described above were not stimulated by calmodulin.     

Alternative splicing of an amino-terminal PEVK-like region generates multiple isoforms of Drosophila projectin.

Drosophila projectin is an extremely large protein found within the muscle sarcomeric unit, parallel with the actin and myosin filaments. Projectin has been suggested as the elastic component of C-filaments in insect indirect flight muscles, which is consistent with its localization from the Z band to the tip of the A band in these muscles. Here, we describe the completion of the projectin sequence analysis, which defines projectin as a 1 MDa protein, composed of 39 immunoglobulin and 39 fibronectin III domains. This analysis led also to the identification of a domain rich in the amino acids P, E, V and K within the NH(2) terminus of projectin. The length of the projectin PEVK-like region varies from 100 to 624 amino acid residues, following a complex pattern of alternative splicing events. PEVK domains were first identified in vertebrate titin and they have been associated with the elasticity of the protein. The PEVK-like domain of the projectin isoforms in indirect flight muscles may contribute to the elastic function of the C-filaments. The synchronous projectin isoforms contain a PEVK-like region, and the possible non-elastic function(s) of this domain in synchronous muscles are discussed.     

Autophosphorylating protein kinase activity in titin-like arthropod projectin.

The function of the high molecular weight structural proteins from muscle, namely vertebrate titin, arthropod projectin and nematode twitchin, remains to be established. Using a simple method for the purification of projectin from crayfish and Drosophila melanogaster, a polyclonal antibody has been raised against crayfish projectin, and shown to immunocrossreact with Drosophila projectin but not with rat titin. In this study, evidence is presented that projectin and twitchin may share functional protein kinase domains, indicating a possible relationship between them. Projectin has a serine/threonine protein kinase activity. This supports the relationship with twitchin since, in sequence analysis of the latter, a protein-kinase-like domain has been found. Moreover, projectin is capable of autophosphorylation in vitro. These kinase activities imply regulatory functions for this group of proteins, extending its previously assumed structural role in the sarcomere. We also show here that projectin is phosphorylated in vivo at serine residues, as described for titin.     

Role of fatty acid-binding protein in lipid metabolism of insect flight muscle

Since insect flight muscles are among the most active muscles in nature, their extremely high rates of fuel supply and oxidation pose interesting physiological problems. Long-distance flights of species like locusts and hawkmoths are fueled through fatty acid oxidation. The lipid substrate is transported as diacylglycerol in the blood, employing a unique and efficient lipoprotein shuttle system. Following diacylglycerol hydrolysis by a flight muscle lipoprotein lipase, the liberated fatty acids are ultimately oxidized in the mitochondria. Locust flight muscle cytoplasm contains an abundant fatty acid-binding protein (FABP). The flight muscle FABP ofLocusta migratoria is a 15 kDa protein with an isoelectric point of 5.8, binding fatty acids in a 1:1 molar stoichiometric ratio. Binding affinity of the FABP for longchain fatty acids (apparent dissociation constant K_d=5.21±0.16 M) is however markedly lower than that of mammalian FABPs. The NH₂-terminal amino acid sequence shares structural homologies with two insect FABPs recently purified from hawkmoth midgut, as well as with mammalian FABPs. In contrast to all other isolated FABPs, the NH₂ terminus of locust flight muscle FABP appeared not to be acetylated. During development of the insect, a marked increase in fatty acid binding capacity of flight muscle homogenate was measured, along with similar increases in both fatty acid oxidation capacity and citrate synthase activity. Although considerable circumstantial evidence would support a function of locust flight muscle FABP in intracellular uptake and transport of fatty acids, the finding of another extremely well-flying migratory insect, the hawkmothAcherontia atropos, which employs the same lipoprotein shuttle system, however contains relatively very low amounts of FABP in its flight muscles, renders the proposed function of FABP in insect flight muscles questionable.     

Drosophila projectin: relatedness to titin and twitchin and correlation with lethal(4) 102 CDa and bent-dominant mutants.

We have investigated projectin, a large protein of insect muscles, in Drosophila melanogaster. The 5.3 kilobases of coding sequence reported here contains Class I and Class II motifs characteristic of titin and twitchin, arranged in a three domain ... [II-I-I] [II-I-I] ... pattern. Two mutants mapped to the location of the projectin gene in the 102C subdivision of chromosome 4, lethal(4) 102 CDa and bent-Dominant, have DNA rearrangements within their projectin gene. The lethal(4) 102 CDa mutant has a 141 nucleotide insertion containing stop codons in all three reading frames within an exon sequence, showing that it cannot synthesize normal projectin. Both bent-Dominant and lethal(4) 102 CDa homozygotes die at the completion of embryogenesis because they are unable to escape the egg vitelline membrane. We propose that this hatching failure is due to muscle weakness caused by projectin defects.     

Localization of connectin-like proteins in leg and flight muscles of insects

In leg muscle sarcomeres of a beetle, approximately 6 mum sarcomere length at rest, projectin ( approximately 1200 kDa) was located on the myosin filament up to 2 mum from the both ends of the filament, using immunofluorescence and immunoelectron microscopy. On the other hand, projectin linked the Z line to the myosin filament and bound on the myosin filament in beetle flight muscle, approximately 3-4 mum sarcomere length at rest. Connectin-like protein ( approximately 3000 kDa) was detected by immunoblot tests in beetle, bumblebee and waterbug leg muscles. Immunofluorescence and immunoelectron microscopic observations revealed that the connectin-like protein linked the myosin filament to the Z line in beetle leg muscle.     

Characterization of components of Z-bands in the fibrillar flight muscle of Drosophila melanogaster

Twelve monoclonal antibodies have been raised against proteins in preparations of Z-disks isolated from Drosophila melanogaster flight muscle. The monoclonal antibodies that recognized Z-band components were identified by immunofluorescence microscopy of flight muscle myofibrils. These antibodies have identified three Z-disk antigens on immunoblots of myofibrillar proteins. Monoclonal antibodies alpha:1-4 recognize a 90-100-kD protein which we identify as alpha-actinin on the basis of cross-reactivity with antibodies raised against honeybee and vertebrate alpha-actinins. Monoclonal antibodies P:1-4 bind to the high molecular mass protein, projectin, a component of connecting filaments that link the ends of thick filaments to the Z-band in insect asynchronous flight muscles. The anti-projectin antibodies also stain synchronous muscle, but, surprisingly, the epitopes here are within the A-bands, not between the A- and Z-bands, as in flight muscle. Monoclonal antibodies Z(210):1-4 recognize a 210-kD protein that has not been previously shown to be a Z-band structural component. A fourth antigen, resolved as a doublet (approximately 400/600 kD) on immunoblots of Drosophila fibrillar proteins, is detected by a cross reacting antibody, Z(400):2, raised against a protein in isolated honeybee Z-disks. On Lowicryl sections of asynchronous flight muscle, indirect immunogold staining has localized alpha-actinin and the 210-kD protein throughout the matrix of the Z-band, projectin between the Z- and A-bands, and the 400/600-kD components at the I-band/Z-band junction. Drosophila alpha-actinin, projectin, and the 400/600-kD components share some antigenic determinants with corresponding honeybee proteins, but no honeybee protein interacts with any of the Z(210) antibodies.     

Both synchronous and asynchronous muscle isoforms of projectin (the Drosophila bent locus product) contain functional kinase domains

In Drosophila, the large muscle protein, projectin, has very different localizations in synchronous and asynchronous muscles, suggesting that projectin has different functions in different muscle types. The multiple projectin isoforms are encoded by a single gene; however they differ significantly in size (as detected by gel mobility) and show differences in some peptide fragments, presumably indicating alternative splicing or termination. We now report additional sequence of the projectin gene, showing a kinase domain and flanking regions highly similar to equivalent regions of twitchin, including a possible autoinhibitory region. In spite of apparent differences in function, all isoforms of projectin have the kinase domain and all are capable of autophosphorylation in vitro. The projectin gene is in polytene region 102C/D where the bentD phenotype maps. The recessive lethality of bentD is associated with a breakpoint that removes sequence of the projectin kinase domain. We find that different alleles of the highly mutable recessive lethal complementation group, l(4)2, also have defects in different parts of the projectin sequence, both NH2-terminal and COOH- terminal to the bentD breakpoint. These alleles are therefore renamed as alleles of the bent locus. Adults heterozygous for projectin mutations show little, if any, effect of one defective gene copy, but homozygosity for any of the defects is lethal. The times of death can vary with allele. Some alleles kill the embryos, others are larval lethal. These molecular studies begin to explain why genetic studies suggested that l(4)2 was a complex (or pseudoallelic) locus.     

CaMKII activity is reduced in skeletal muscle during sepsis

Exercise‐induced muscle hypertrophy is associated with increased calcium/calmodulin‐dependent protein kinase II (CaMKII) expression and activity. In contrast, the influence of muscle atrophy‐related conditions on CaMKII is poorly understood. Here, we tested the hypothesis that sepsis‐induced muscle wasting is associated with reduced CaMKII expression and activity. Sepsis, induced by cecal ligation and puncture in rats, and treatment of rats with TNFα, resulted in reduced total CaMKII activity in skeletal muscle whereas autonomous CaMKII activity was unaffected. The expression of CaMKIIδ, but not β and γ, was reduced in septic muscle. In additional experiments, treatment of cultured myotubes with TNFα resulted in reduced total CaMKII activity and decreased levels of phosphorylated glycogen synthase kinase (GSK)‐3β, a downstream target of CaMKII. The present results suggest that sepsis‐induced muscle wasting is associated with reduced CaMKII activity and that TNFα may be involved in the regulation of CaMKII activity in skeletal muscle. Decreased phosphorylation (consistent with activation) of GSK‐3β may be a consequence of reduced CaMKII activity, indicating that inhibited CaMKII activity may be involved in the catabolic response to sepsis. J. Cell. Biochem. 114: 1294–1305, 2013. © 2012 Wiley Periodicals, Inc.     

Comparative electron microscopic study on projectin and titin binding to F-actin

Using the system of F-actin paracrystals, we have obtained electron microscopic evidence that projectin from synchronous flight muscles of Locusta migratoria binds to actin filaments in the same fashion as skeletal titin. Control actin paracrystals formed in the presence of Mg(2+) ions have great width and length and blunted ends. The addition of either projectin or titin results in disruption of compact ordered packing of F-actin in paracrystals and leads to the formation of loose filament bundles with smaller diameters and tapered ends. It is also accompanied with the appearance of individual actin filaments in considerable amounts. The effect becomes more pronounced with the increase in concentrations of added projectin or titin. Possible physiological implications of projectin-actin interactions are discussed.     

Dual mechanism of a natural CaMKII inhibitor

Ca(2+)/calmodulin (CaM)-dependent protein kinase II (CaMKII) is a major mediator of cellular Ca(2+) signaling. Several inhibitors are commonly used to study CaMKII function, but these inhibitors all lack specificity. CaM-KIIN is a natural, specific CaMKII inhibitor protein. CN21 (derived from CaM-KIIN amino acids 43-63) showed full specificity and potency of CaMKII inhibition. CNs completely blocked Ca(2+)-stimulated and autonomous substrate phosphorylation by CaMKII and autophosphorylation at T305. However, T286 autophosphorylation (the autophosphorylation generating autonomous activity) was only mildly affected. Two mechanisms can explain this unusual differential inhibitor effect. First, CNs inhibited activity by interacting with the CaMKII T-site (and thereby also interfered with NMDA-type glutamate receptor binding to the T-site). Because of this, the CaMKII region surrounding T286 competed with CNs for T-site interaction, whereas other substrates did not. Second, the intersubunit T286 autophosphorylation requires CaM binding both to the "kinase" and the "substrate" subunit. CNs dramatically decreased CaM dissociation, thus facilitating the ability of CaM to make T286 accessible for phosphorylation. Tat-fusion made CN21 cell penetrating, as demonstrated by a strong inhibition of filopodia motility in neurons and insulin secrection from isolated Langerhans' islets. These results reveal the inhibitory mechanism of CaM-KIIN and establish a powerful new tool for dissecting CaMKII function.     

Calcium/calmodulin-dependent protein kinase II (CaMKII) localization acts in concert with substrate targeting to create spatial restriction for phosphorylation

Ca2+/calmodulin-dependent protein kinase II (CaMKII) acts in diverse cell types by phosphorylating proteins with key calcium-dependent functions such as synaptic plasticity, electrical excitability, and neurotransmitter synthesis. CaMKII displays calcium-dependent binding to proteins in vitro and translocation to synaptic sites after glutamatergic activity in neurons. We therefore hypothesized that subcellular targeting of CaMKII can direct its substrate specificity in an activity-dependent fashion. Here, we examined whether activity-dependent colocalization of CaMKII and its substrates could result in regulation of substrate phosphorylation in cells. We find that substrates localized at cellular membranes required CaMKII translocation to these compartments to achieve effective phosphorylation. Spatial barriers to phosphorylation could be overcome by translocation and anchoring to the substrate itself or to nearby target proteins within the membrane compartment. In contrast, phosphorylation of a cytoplasmic counterpart of the substrate does not require CaMKII translocation or stable protein-protein binding. Cytosolic phosphorylation is more permissive, exhibiting partial calcium-independence. Localization-dependent substrate specificity can also show more graded levels of regulation within signaling microdomains. We find that colocalization of translocated CaMKII and its substrate to lipid rafts in the plasma membrane can modulate the magnitude of phosphorylation. Thus, dynamic regulation of both substrate and kinase localization provides a powerful and nuanced way to regulate CaMKII signal specificity.     

Transport and Utilization of Lipids in Insect Flight Muscles*

In migrating lepidopteran and orthopteran insects, lipid is the preferred fuel for sustained flight activity. Diacylglycerol is delivered by lipophorin to the flight muscle and hydrolyzed to free fatty acid and glycerol. After penetrating the plasma membrane by an unknown mechanism, fatty acids are bound by the intracellular fatty acid binding protein (FABP) and transported through the cytosol. After their conversion to acyl-CoA esters, the fatty acids enter the mitochondrial matrix via the carnitine shuttle for subsequent β-oxidation. This article reviews the current knowledge of lipid metabolism in insect flight muscle, with particular emphasis on the structure and function of FABP and its expression during locust development and flight.     

Binding of brain spectrin to the 70-kDa neurofilament subunit protein

Brain spectrin, or fodrin, a major protein of the subaxolemmal cytoskeleton, associates specifically in in vitro assays with the 70-kDa neurofilament subunit (NF-L) and with glial filaments from pig spinal cord. As an initial approach to the identification of the fodrin-binding proteins, a crude preparation of neurofilaments was resolved by electrophoresis on SDS/polyacrylamide gels and then transferred to nitrocellulose paper, which was 'blotted' with 125I-fodrin. A significant binding of fodrin was observed on polypeptides of 70 kDa, 52 kDa and 20 kDa. These polypeptides were further purified and identified respectively as the NF-L subunit of neurofilaments, the glial fibrillary acidic protein (GFP) and the myelin basic protein. The binding of fodrin to NF-L was reversible and concentration-dependent. The ability of the pure NF-L and GFP to form filaments was used to quantify their association with fodrin. a) The binding of fodrin to reassembled NF-L was saturable with a stoichiometry of 1 mol fodrin bound/50 +/- 10 mol NF-L and an apparent dissociation constant Kd = 4.3 x 10(-7) M. b) The binding involved the N-terminal domain of the polypeptide chain derived from the [2-(2-nitrophenylsulfenyl)-3-methyl-3'-bromoindolenine] cleavage of NF-L. c) Binding occurred optimally at physiological pH (6.8-7.2) and salt concentrations (50 mM). d) Interestingly, calmodulin, a Ca2+-binding protein, which has been shown to bind to fodrin, was found to reinforce the binding of fodrin to the NF-L, at Ca2+ physiological concentrations. The binding of fodrin to pure neurofilaments was not affected by the presence of the 200-kDa (NF-H) and the 160-kDa (NF-M) subunits. The apparent dissociation constant for the binding of fodrin to NF-L in the pure NF was 1.0 x 10(-6) M with 1 mol fodrin bound/80 +/- 10 mol NF-L. Moreover, the binding of fodrin to GFP, demonstrated in blot assays, was confirmed by cosedimentation experiments. The apparent dissociation constant Kd for the fodrin binding was 2.8 x 10(-7) M and the maximum binding was 1 mol fodrin/55 +/- 10 mol GFP.     

Glycogen synthase binds to sarcoplasmic reticulum and is phosphorylated by CaMKII in fast-twitch skeletal muscle

We investigated the subcellular localization of glycogen synthase (GS) in the adductor muscle of anesthetized rabbits injected intravenously with propranolol. Under these experimental conditions, glycogen content was about 10 mmol/kg of fresh tissue. Immunofluorescent and fractionation studies showed that GS associated with sarcoplasmic reticulum (SR) membranes. Glycogen and GS always co-sedimented, suggesting a predominant role of glycogen in targeting of GS to SR. SR-associated GS was phosphorylated in vitro by SR-bound Ca2+-calmodulin dependent protein kinase (CaMKII) and dephosphorylated by endogenous protein phosphatase 1 (PP1c). Based on measurements of GS activity ratio, in vitro phosphorylation of GS by CaMKII did not significantly affect GS activity per se. However, GS activity ratio was slightly reduced, when SR membranes were further incubated with ATP after prior phosphorylation by CaMKII, suggesting that CaMKII might act sinergistically with other protein kinases. We propose that SR-bound CaMKII plays a role in regulation of glycogen metabolism in skeletal muscle, when intracellular Ca2+ is raised.     

CaMKII Binding to GluN2B Is Differentially Affected by Macromolecular Crowding Reagents

Binding of the Ca²⁺/calmodulin(CaM)-dependent protein kinase II (CaMKII) to the NMDA-type glutamate receptor (NMDAR) subunit GluN2B controls long-term potentiation (LTP), a form of synaptic plasticity thought to underlie learning and memory. Regulation of this interaction is well-studied biochemically, but not under conditions that mimic the macromolecular crowding found within cells. Notably, previous molecular crowding experiments with lysozyme indicated an effect on the CaMKII holoenzyme conformation. Here, we found that the effect of molecular crowding on Ca²⁺/CaM-induced CaMKII binding to immobilized GluN2B in vitro depended on the specific crowding reagent. While binding was reduced by lysozyme, it was enhanced by BSA. The ATP content in the BSA preparation caused CaMKII autophosphorylation at T286 during the binding reaction; however, enhanced binding was also observed when autophosphorylation was blocked. Importantly, the positive regulation by nucleotide and BSA (as well as other macromolecular crowding reagents) did not alleviate the requirement for CaMKII stimulation to induce GluN2B binding. The differential effect of lysozyme (14 kDa) and BSA (66 kDa) was not due to size difference, as both dextran-10 and dextran-70 enhanced binding. By contrast, crowding with immunoglobulin G (IgG) reduced binding. Notably, lysozyme and IgG but not BSA directly bound to Ca²⁺/CaM in an overlay assay, suggesting a competition of lysozyme and IgG with the Ca²⁺/CaM-stimulus that induces CaMKII/GluN2B binding. However, lysozyme negatively regulated binding even when it was instead induced by CaMKII T286 phosphorylation. Alternative modes of competition would be with CaMKII or GluN2B, and the negative effects of lysozyme and IgG indeed also correlated with specific or non-specific binding to the immobilized GluN2B. Thus, the effect of any specific crowding reagent can differ, depending on its additional direct effects on CaMKII/GluN2B binding. However, the results of this study also indicate that, in principle, macromolecular crowding enhances CaMKII binding to GluN2B.     

Fructose 2,6-bisphosphate as a signal for changing from sugar to lipid oxidation during flight in locusts

Flight in locusts is initially powered mainly by carbohydrate but if flight is to be sustained, as in migration, the animals have to utilize fat as the predominant fuel. The molecular basis of this metabolic switch has not been identified. Fructose 2,6-bisphosphate is a potent activator of 6-phosphofructokinase (EC 2.7.1.11) purified from locust flight muscle. After the first few minutes of flight in the locust the concentration of fructose 2,6-bisphosphate in the flight muscle falls dramatically, which should lead to a decrease in the activity of 6-phosphofructokinase as part of the mechanism to conserve carbohydrate during prolonged flight.     

Kettin, a major source of myofibrillar stiffness in Drosophila indirect flight muscle

Kettin is a high molecular mass protein of insect muscle that in the sarcomeres binds to actin and alpha-actinin. To investigate kettin's functional role, we combined immunolabeling experiments with mechanical and biochemical studies on indirect flight muscle (IFM) myofibrils of Drosophila melanogaster. Micrographs of stretched IFM sarcomeres labeled with kettin antibodies revealed staining of the Z-disc periphery. After extraction of the kettin-associated actin, the A-band edges were also stained. In contrast, the staining pattern of projectin, another IFM-I-band protein, was not altered by actin removal. Force measurements were performed on single IFM myofibrils to establish the passive length-tension relationship and record passive stiffness. Stiffness decreased within seconds during gelsolin incubation and to a similar degree upon kettin digestion with mu-calpain. Immunoblotting demonstrated the presence of kettin isoforms in normal Drosophila IFM myofibrils and in myofibrils from an actin-null mutant. Dotblot analysis revealed binding of COOH-terminal kettin domains to myosin. We conclude that kettin is attached not only to actin but also to the end of the thick filament. Kettin along with projectin may constitute the elastic filament system of insect IFM and determine the muscle's high stiffness necessary for stretch activation. Possibly, the two proteins modulate myofibrillar stiffness by expressing different size isoforms.