Project description:LC-MS/MS analysis of peptide digests of myofibrils from wild type and Dmlc2(Delta 2-46; S66A, S67A) mutant Drosophila flies. Myofibrils and thick filament samples were solubilized in 150 ul 0.1% RapiGest SF Surfactant (Waters Corporation; 50 C, 1 hour). Proteins were reduced by addition of 0.75 ul of 1M dithiothreitol and heating (100 C, 10 min). Cysteines were alkylated by addition of 22.5 ul of 100 mM iodoacetamide in 50 mM ammonium bicarbonate and incubation in the dark (22C, 30 min). Proteins were digested to peptides by addition of 25 ul of 50 mM ammonium bicarbonate containing 5 ug of trypsin (Promega) and incubating (37 C, 18 hours). The samples were dried down in speed vacuum device. Trypsin was deactivated and RapiGest was cleaved by addition of 100 ul of 7% formic acid in 50 mM ammonium bicarbonate and heating (37 C, 1 hour). The resultant peptides were dried down. RapiGest was cleaved again by addition of 100 ul of 0.1% trifluoroacetic acid and heating (37 C, 1 hour). The resultant peptides were dried down and reconstituted a final time in 60 ul of 0.1% trifluoroacetic acid. The samples were centrifuged at 18,800 RCF for 5 minutes (Thermo, Sorvall Legend Micro 21R) to pellet the surfactant. The top 57 ul of solution was transferred into a mass spectrometry (MS) analysis vial. A 20 ul aliquot of each sample was injected onto an Acquity UPLC HSS T3 column (100 A, 1.8 um, 1 x 150 mm) (Waters Corporation) attached to a UltiMate 3000 ultra-high pressure liquid chromatography (UHPLC) system (Dionex). The peptides were separated and the UHPLC effluent was directly infused into a Q Exactive Hybrid Quadrupole-Orbitrap mass spectrometer (MS) through an electrospray ionization source (Thermo Fisher Scientific). Data were collected in data-dependent MS/MS mode with the top five most abundant ions being selected for fragmentation.

Project description:Projectin and kettin are titin-like proteins mainly responsible for the high passive stiffness of insect indirect flight muscles, which is needed to generate oscillatory work during flight. Here we report the mechanical properties of kettin and projectin by single-molecule force spectroscopy. Force-extension and force-clamp curves obtained from Lethocerus projectin and Drosophila recombinant projectin or kettin fragments revealed that fibronectin type III domains in projectin are mechanically weaker (unfolding force, F(u) approximately 50-150 pN) than Ig-domains (F(u) approximately 150-250 pN). Among Ig domains in Sls/kettin, the domains near the N terminus are less stable than those near the C terminus. Projectin domains refolded very fast [85% at 15 s(-1) (25 degrees C)] and even under high forces (15-30 pN). Temperature affected the unfolding forces with a Q(10) of 1.3, whereas the refolding speed had a Q(10) of 2-3, probably reflecting the cooperative nature of the folding mechanism. High bending rigidities of projectin and kettin indicated that straightening the proteins requires low forces. Our results suggest that titin-like proteins in indirect flight muscles could function according to a folding-based-spring mechanism.

Project description:Structural interactions between the myosin converter and relay domains have been proposed to be critical for the myosin power stroke and muscle power generation. We tested this hypothesis by mutating converter residue 759, which interacts with relay residues I508, N509, and D511, to glutamate (R759E) and determined the effect on Drosophila indirect flight muscle mechanical performance. Work loop analysis of mutant R759E indirect flight muscle fibers revealed a 58% and 31% reduction in maximum power generation (P(WL)) and the frequency at which maximum power (f(WL)) is generated, respectively, compared to control fibers at 15 °C. Small amplitude sinusoidal analysis revealed a 30%, 36%, and 32% reduction in mutant elastic modulus, viscous modulus, and mechanical rate constant 2?b, respectively. From these results, we infer that the mutation reduces rates of transitions through work-producing cross-bridge states and/or force generation during strongly bound states. The reductions in muscle power output, stiffness, and kinetics were physiologically relevant, as mutant wing beat frequency and flight index decreased about 10% and 45% compared to control flies at both 15 °C and 25 °C. Thus, interactions between the relay loop and converter domain are critical for lever-arm and catalytic domain coordination, high muscle power generation, and optimal Drosophila flight performance.

Project description:Kettin is a giant muscle protein originally identified in insect flight muscle Z-discs. Here, we determined the entire nucleotide sequence of Drosophila melanogaster kettin, deduced the amino acid sequence of its protein product (540 kD) along with that of the Caenorhabditis elegans counterpart, and found that the overall primary structure of Kettin has been highly conserved in evolution. The main body of Drosophila Kettin consists of 35 immunoglobulin C2 domains separated by spacers. The central two thirds of spacers are constant in length and share in common two conserved motifs, putative actin binding sites. Neither fibronectin type III nor kinase domains were found. Kettin is present at the Z-disc in several muscle types. Genetic analysis showed that kettin is essential for the formation and maintenance of normal sarcomere structure of muscles and muscle tendons. Accordingly, embryos lacking kettin activity cannot hatch nor can adult flies heterozygous for the kettin mutation fly.

Project description:Biophysical and structural studies on muscle myosin rely upon milligram quantities of extremely pure material. However, many biologically interesting myosin isoforms are expressed at levels that are too low for direct purification from primary tissues. Efforts aimed at recombinant expression of functional striated muscle myosin isoforms in bacterial or insect cell culture have largely met with failure, although high level expression in muscle cell culture has recently been achieved at significant expense. We report a novel method for the use of strains of the fruit fly Drosophila melanogaster genetically engineered to produce histidine-tagged recombinant muscle myosin isoforms. This method takes advantage of the single muscle myosin heavy chain gene within the Drosophila genome, the high level of expression of accessible myosin in the thoracic indirect flight muscles, the ability to knock out endogenous expression of myosin in this tissue and the relatively low cost of fruit fly colony production and maintenance. We illustrate this method by expressing and purifying a recombinant histidine-tagged variant of embryonic body wall skeletal muscle myosin II from an engineered fly strain. The recombinant protein shows the expected ATPase activity and is of sufficient purity and homogeneity for crystallization. This system may prove useful for the expression and isolation of mutant myosins associated with skeletal muscle diseases and cardiomyopathies for their biochemical and structural characterization.

Project description:Expression profiling of IFMs from 1-2 day old adult male flies of 3 genotypes: Canton-S, IFM-specific actin null (Act88FKM88) and IFM-specific myosin null (Mhc7). Results provide insight into how muscles respond to the absence of major scaffold proteins, and whether these transcriptional responses are filament-specific or generic to the tissue. RNA was extracted from the IFMs of 1-2 day old adult male flies of 3 genotypes (Canton-S, Act88FKM88, Mhc7), labeled, and hybridized on Affymetrix GeneChip Drosophila Genome 2.0 microarrays. 9 microarray experiments from 3 independent biological replicates of each genotype. Data was analyzed using RMA method, and significance was tested using SAM version 3.02, with cut-off parameters of 10% FDR and minimum 2-fold change in expression levels.

Project description:Expression profiling of IFMs from 1-2 day old adult male flies of 3 genotypes: Canton-S, IFM-specific actin null (Act88FKM88) and IFM-specific myosin null (Mhc7). Results provide insight into how muscles respond to the absence of major scaffold proteins, and whether these transcriptional responses are filament-specific or generic to the tissue.

Project description:In striated muscle tropomyosin (Tm) extends along the length of F-actin-containing thin filaments. Its location governs access of myosin binding sites on actin and, hence, force production. Intermolecular electrostatic associations are believed to mediate critical interactions between the proteins. For example, actin residues K326, K328, and R147 were predicted to establish contacts with E181 of Tm. Moreover, K328 also potentially forms direct interactions with E286 of myosin when the motor is strongly bound. Recently, LC-MS/MS analysis of the cardiac acetyl-lysine proteome revealed K326 and K328 of actin were acetylated, a post-translational modification (PTM) that masks the residues' inherent positive charges. Here, we tested the hypothesis that by removing the vital actin charges at residues 326 and 328, the PTM would perturb Tm positioning and/or strong myosin binding as manifested by altered skeletal muscle function and structure in the Drosophila melanogaster model system. Transgenic flies were created that permit tissue-specific expression of K326Q, K328Q, or K326Q/K328Q acetyl-mimetic actin and of wild-type actin via the UAS-GAL4 bipartite expression system. Compared to wild-type actin, muscle-restricted expression of mutant actin had a dose-dependent effect on flight ability. Moreover, excessive K328Q and K326Q/K328Q actin overexpression induced indirect flight muscle degeneration, a phenotype consistent with hypercontraction observed in other Drosophila myofibrillar mutants. Based on F-actin-Tm and F-actin-Tm-myosin models and on our physiological data, we conclude that acetylating K326 and K328 of actin alters electrostatic associations with Tm and/or myosin and thereby augments contractile properties. Our findings highlight the utility of Drosophila as a model that permits efficient targeted design and assessment of molecular and tissue-specific responses to muscle protein modifications, in vivo.

Project description:We are investigating the influence of the converter and relay domains on elementary rate constants of the actomyosin cross-bridge cycle. The converter and relay domains vary between Drosophila myosin heavy chain isoforms due to alternative mRNA splicing. Previously, we found that separate insertions of embryonic myosin isoform (EMB) versions of these domains into the indirect flight muscle (IFM) myosin isoform (IFI) both decreased Drosophila IFM power and slowed muscle kinetics. To determine cross-bridge mechanisms behind the changes, we employed sinusoidal analysis while varying phosphate and MgATP concentrations in skinned Drosophila IFM fibers. Based on a six-state cross-bridge model, the EMB converter decreased myosin rate constants associated with actin attachment and work production, k(4), but increased rates related to cross-bridge detachment and work absorption, k(2). In contrast, the EMB relay domain had little influence on kinetics, because only k(4) decreased. The main alteration was mechanical, in that work production amplitude decreased. That both domains decreased k(4) supports the hypothesis that these domains are critical to lever-arm-mediated force generation. Neither domain significantly influenced MgATP affinity. Our modeling suggests the converter domain is responsible for the difference in rate-limiting cross-bridge steps between EMB and IFI myosin--i.e., a myosin isomerization associated with MgADP release for EMB and Pi release for IFI.

Project description:The goal of the study was to investigate the mechanistic basis for Time-restricted feeding (TRF) improvement in skeletal muscle by assessing transcriptomic data of wild type (WT), WT under High-fat diet (HFD), and genetic obesity linked mutant sphingosine kinase 2 (Sk2) under ad libitum feeding (ALF) and time-restricted feeding (TRF) conditions. Next generation sequencing was used to assess the changes along a diurnal cycle in the transcriptome of Drosophila indirect flight muscle (IFM) tissue at 3-week of age under ad libitum feeding (ALF) or time-restricted feeding (TRF).