2y23 Citations

Superhelical architecture of the myosin filament-linking protein myomesin with unusual elastic properties.

Pinotsis N, Chatziefthimiou SD, Berkemeier F, Beuron F, Mavridis IM, Konarev PV, Svergun DI, Morris E, Rief M, Wilmanns M
PLoS Biol 10 e1001261 (2012)
Related entries: 2y25, 3rbs

Cited: 28 times
EuropePMC logo PMID: 22347812

Abstract

Active muscles generate substantial mechanical forces by the contraction/relaxation cycle, and, to maintain an ordered state, they require molecular structures of extraordinary stability. These forces are sensed and buffered by unusually long and elastic filament proteins with highly repetitive domain arrays. Members of the myomesin protein family function as molecular bridges that connect major filament systems in the central M-band of muscle sarcomeres, which is a central locus of passive stress sensing. To unravel the mechanism of molecular elasticity in such filament-connecting proteins, we have determined the overall architecture of the complete C-terminal immunoglobulin domain array of myomesin by X-ray crystallography, electron microscopy, solution X-ray scattering, and atomic force microscopy. Our data reveal a dimeric tail-to-tail filament structure of about 360 Å in length, which is folded into an irregular superhelical coil arrangement of almost identical α-helix/domain modules. The myomesin filament can be stretched to about 2.5-fold its original length by reversible unfolding of these linkers, a mechanism that to our knowledge has not been observed previously. Our data explain how myomesin could act as a highly elastic ribbon to maintain the overall structural organization of the sarcomeric M-band. In general terms, our data demonstrate how repetitive domain modules such as those found in myomesin could generate highly elastic protein structures in highly organized cell systems such as muscle sarcomeres.

Reviews - 2y23 mentioned but not cited (1)

  1. The sarcomeric M-region: a molecular command center for diverse cellular processes. Hu LY, Ackermann MA, Kontrogianni-Konstantopoulos A. Biomed Res Int 2015 714197 (2015)

Articles - 2y23 mentioned but not cited (4)

  1. Superhelical architecture of the myosin filament-linking protein myomesin with unusual elastic properties. Pinotsis N, Chatziefthimiou SD, Berkemeier F, Beuron F, Mavridis IM, Konarev PV, Svergun DI, Morris E, Rief M, Wilmanns M. PLoS Biol 10 e1001261 (2012)
  2. Molecular basis of the mechanical hierarchy in myomesin dimers for sarcomere integrity. Xiao S, Gräter F. Biophys J 107 965-973 (2014)
  3. Myomedin scaffold variants targeted to 10E8 HIV-1 broadly neutralizing antibody mimic gp41 epitope and elicit HIV-1 virus-neutralizing sera in mice. Kuchař M, Kosztyu P, Daniel Lišková V, Černý J, Petroková H, Vróblová E, Malý M, Vaňková L, Křupka M, Rašková Kafková L, Turánek Knotigová P, Dušková J, Dohnálek J, Mašek J, Turánek J, Raška M, Malý P. Virulence 12 1271-1287 (2021)
  4. The dipeptidyl peptidase IV inhibitors vildagliptin and K-579 inhibit a phospholipase C: a case of promiscuous scaffolds in proteins. Chakraborty S, Rendón-Ramírez A, Ásgeirsson B, Dutta M, Ghosh AS, Oda M, Venkatramani R, Rao BJ, Dandekar AM, Goñi FM. F1000Res 2 286 (2013)


Reviews citing this publication (6)

  1. The sarcomeric cytoskeleton: from molecules to motion. Gautel M, Djinović-Carugo K. J Exp Biol 219 135-145 (2016)
  2. Force as a single molecule probe of multidimensional protein energy landscapes. Zoldák G, Rief M. Curr Opin Struct Biol 23 48-57 (2013)
  3. Eccentric contraction: unraveling mechanisms of force enhancement and energy conservation. Nishikawa K. J Exp Biol 219 189-196 (2016)
  4. Thick Filament Protein Network, Functions, and Disease Association. Wang L, Geist J, Grogan A, Hu LR, Kontrogianni-Konstantopoulos A. Compr Physiol 8 631-709 (2018)
  5. Force-induced remodelling of proteins and their complexes. Chen Y, Radford SE, Brockwell DJ. Curr Opin Struct Biol 30 89-99 (2015)
  6. The role of the M-band myomesin proteins in muscle integrity and cardiac disease. Lamber EP, Guicheney P, Pinotsis N. J Biomed Sci 29 18 (2022)

Articles citing this publication (17)

  1. Loss of muscleblind-like 1 results in cardiac pathology and persistence of embryonic splice isoforms. Dixon DM, Choi J, El-Ghazali A, Park SY, Roos KP, Jordan MC, Fishbein MC, Comai L, Reddy S. Sci Rep 5 9042 (2015)
  2. Binding of Myomesin to Obscurin-Like-1 at the Muscle M-Band Provides a Strategy for Isoform-Specific Mechanical Protection. Pernigo S, Fukuzawa A, Beedle AEM, Holt M, Round A, Pandini A, Garcia-Manyes S, Gautel M, Steiner RA. Structure 25 107-120 (2017)
  3. Effective population size, extended linkage disequilibrium and signatures of selection in the rare dog breed lundehund. Pfahler S, Distl O. PLoS One 10 e0122680 (2015)
  4. The crystal structure of the human titin:obscurin complex reveals a conserved yet specific muscle M-band zipper module. Pernigo S, Fukuzawa A, Pandini A, Holt M, Kleinjung J, Gautel M, Steiner RA. J Mol Biol 427 718-736 (2015)
  5. Liprin-α-1 is a novel component of the murine neuromuscular junction and is involved in the organization of the postsynaptic machinery. Bernadzki KM, Gawor M, Pęziński M, Mazurek P, Niewiadomski P, Rędowicz MJ, Prószyński TJ. Sci Rep 7 9116 (2017)
  6. Dissection of Z-disc myopalladin gene network involved in the development of restrictive cardiomyopathy using system genetics approach. Gu Q, Mendsaikhan U, Khuchua Z, Jones BC, Lu L, Towbin JA, Xu B, Purevjav E. World J Cardiol 9 320-331 (2017)
  7. Titin and obscurin: giants holding hands and discovery of a new Ig domain subset. Benian GM, Mayans O. J Mol Biol 427 707-714 (2015)
  8. Knockout of MYOM1 in human cardiomyocytes leads to myocardial atrophy via impairing calcium homeostasis. Hang C, Song Y, Li Y, Zhang S, Chang Y, Bai R, Saleem A, Jiang M, Lu W, Lan F, Cui M. J Cell Mol Med 25 1661-1676 (2021)
  9. Conformational plasticity and evolutionary analysis of the myotilin tandem Ig domains. Puž V, Pavšič M, Lenarčič B, Djinović-Carugo K. Sci Rep 7 3993 (2017)
  10. IGFN1_v1 is required for myoblast fusion and differentiation. Li X, Baker J, Cracknell T, Haynes AR, Blanco G. PLoS One 12 e0180217 (2017)
  11. Nanosurgical Manipulation of Titin and Its M-Complex. Sziklai D, Sallai J, Papp Z, Kellermayer D, Mártonfalvi Z, Pires RH, Kellermayer MSZ. Nanomaterials (Basel) 12 178 (2022)
  12. Structural consequences of mutations associated with idiopathic restrictive cardiomyopathy. Tarnovskaya S, Kiselev A, Kostareva A, Frishman D. Amino Acids 49 1815-1829 (2017)
  13. Skelemin association with αIIbβ3 integrin: a structural model. Gorbatyuk V, Nguyen K, Podolnikova NP, Deshmukh L, Lin X, Ugarova TP, Vinogradova O. Biochemistry 53 6766-6775 (2014)
  14. Exosome Liberation by Human Neutrophils under L-Amino Acid Oxidase of Calloselasma rhodostoma Venom Action. Serrath SN, Pontes AS, Paloschi MV, Silva MDS, Lopes JA, Boeno CN, Silva CP, Santana HM, Cardozo DG, Ugarte AVE, Magalhães JGS, Cruz LF, Setubal SS, Soares AM, Cavecci-Mendonça B, Santos LD, Zuliani JP. Toxins (Basel) 15 625 (2023)
  15. Myomedin replicas of gp120 V3 loop glycan epitopes recognized by PGT121 and PGT126 antibodies as non-cognate antigens for stimulation of HIV-1 broadly neutralizing antibodies. Daniel Lišková V, Kosztyu P, Kuchař M, Černý J, Bharadwaj S, Petroková H, Vroblová E, Křupka M, Malý M, Zosinčuková T, Šulc J, Rašková Kafková L, Raška M, Malý P. Front Immunol 13 1066361 (2022)
  16. Proteomic Analysis of Decellularized Extracellular Matrix: Achieving a Competent Biomaterial for Osteogenesis. Monteiro-Lobato GM, Russo PST, Winck FV, Catalani LH. Biomed Res Int 2022 6884370 (2022)
  17. The role of single protein elasticity in mechanobiology. Beedle AE, Garcia-Manyes S. Nat Rev Mater 8 10-24 (2023)


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