3mtu Citations

Structure of the tropomyosin overlap complex from chicken smooth muscle: insight into the diversity of N-terminal recognition.

Frye J, Klenchin VA, Rayment I
Biochemistry 49 4908-20 (2010)
Cited: 55 times
EuropePMC logo PMID: 20465283

Abstract

Tropomyosin is a stereotypical alpha-helical coiled coil that polymerizes to form a filamentous macromolecular assembly that lies on the surface of F-actin. The interaction between the C-terminal and N-terminal segments on adjacent molecules is known as the overlap region. We report here two X-ray structures of the chicken smooth muscle tropomyosin overlap complex. A novel approach was used to stabilize the C-terminal and N-terminal fragments. Globular domains from both the human DNA ligase binding protein XRCC4 and bacteriophage varphi29 scaffolding protein Gp7 were fused to 37 and 28 C-terminal amino acid residues of tropomyosin, respectively, whereas the 29 N-terminal amino acids of tropomyosin were fused to the C-terminal helix bundle of microtubule binding protein EB1. The structures of both the XRCC4 and Gp7 fusion proteins complexed with the N-terminal EB1 fusion contain a very similar helix bundle in the overlap region that encompasses approximately 15 residues. The C-terminal coiled coil opens to allow formation of the helix bundle, which is stabilized by hydrophobic interactions. These structures are similar to that observed in the NMR structure of the rat skeletal overlap complex [Greenfield, N. J., et al. (2006) J. Mol. Biol. 364, 80-96]. The interactions between the N- and C-terminal coiled coils of smooth muscle tropomyosin show significant curvature, which differs somewhat between the two structures and implies flexibility in the overlap complex, at least in solution. This is likely an important attribute that allows tropomyosin to assemble around the actin filaments. These structures provide a molecular explanation for the role of N-acetylation in the assembly of native tropomyosin.

Articles - 3mtu mentioned but not cited (3)

  1. Structure of the tropomyosin overlap complex from chicken smooth muscle: insight into the diversity of N-terminal recognition. Frye J, Klenchin VA, Rayment I. Biochemistry 49 4908-4920 (2010)
  2. Structural attributes for the recognition of weak and anomalous regions in coiled-coils of myosins and other motor proteins. Sunitha MS, Nair AG, Charya A, Jadhav K, Mukhopadhyay S, Sowdhamini R. BMC Res Notes 5 530 (2012)
  3. Structural Variability of EspG Chaperones from Mycobacterial ESX-1, ESX-3, and ESX-5 Type VII Secretion Systems. Tuukkanen AT, Freire D, Chan S, Arbing MA, Reed RW, Evans TJ, Zenkeviciutė G, Kim J, Kahng S, Sawaya MR, Chaton CT, Wilmanns M, Eisenberg D, Parret AHA, Korotkov KV. J. Mol. Biol. 431 289-307 (2019)


Reviews citing this publication (9)

  1. Tropomyosin: double helix from the protein world. Nevzorov IA, Levitsky DI. Biochemistry Mosc. 76 1507-1527 (2011)
  2. Tropomodulins and Leiomodins: Actin Pointed End Caps and Nucleators in Muscles. Fowler VM, Dominguez R. Biophys. J. 112 1742-1760 (2017)
  3. Molecular mechanism of actin-myosin motor in muscle. Koubassova NA, Tsaturyan AK. Biochemistry Mosc. 76 1484-1506 (2011)
  4. Polymorphism in tropomyosin structure and function. Janco M, Suphamungmee W, Li X, Lehman W, Lehrer SS, Geeves MA. J. Muscle Res. Cell. Motil. 34 177-187 (2013)
  5. The role of leiomodin in actin dynamics: a new road or a secret gate. Tolkatchev D, Gregorio CC, Kostyukova AS. FEBS J (2021)
  6. Biophysical Derangements in Genetic Cardiomyopathies. Lynn ML, Lehman SJ, Tardiff JC. Heart Fail Clin 14 147-159 (2018)
  7. Functional outcomes of structural peculiarities of striated muscle tropomyosin. Kopylova GV, Matyushenko AM, Koubassova NA, Shchepkin DV, Bershitsky SY, Levitsky DI, Tsaturyan AK. J Muscle Res Cell Motil 41 55-70 (2020)
  8. Mechanism of the calcium-regulation of muscle contraction--in pursuit of its structural basis. Wakabayashi T. Proc. Jpn. Acad., Ser. B, Phys. Biol. Sci. 91 321-350 (2015)
  9. Modeling Human Cardiac Thin Filament Structures. Rynkiewicz MJ, Pavadai E, Lehman W. Front Physiol 13 932333 (2022)

Articles citing this publication (43)

  1. Tropomyosin position on F-actin revealed by EM reconstruction and computational chemistry. Li XE, Tobacman LS, Mun JY, Craig R, Fischer S, Lehman W. Biophys. J. 100 1005-1013 (2011)
  2. Structural conservation of distinctive N-terminal acetylation-dependent interactions across a family of mammalian NEDD8 ligation enzymes. Monda JK, Scott DC, Miller DJ, Lydeard J, King D, Harper JW, Bennett EJ, Schulman BA. Structure 21 42-53 (2013)
  3. Mutations in repeating structural motifs of tropomyosin cause gain of function in skeletal muscle myopathy patients. Marston S, Memo M, Messer A, Papadaki M, Nowak K, McNamara E, Ong R, El-Mezgueldi M, Li X, Lehman W. Hum. Mol. Genet. 22 4978-4987 (2013)
  4. Regulation of nonmuscle myosin II by tropomyosin. Barua B, Nagy A, Sellers JR, Hitchcock-DeGregori SE. Biochemistry 53 4015-4024 (2014)
  5. K7del is a common TPM2 gene mutation associated with nemaline myopathy and raised myofibre calcium sensitivity. Mokbel N, Ilkovski B, Kreissl M, Memo M, Jeffries CM, Marttila M, Lehtokari VL, Lemola E, Grönholm M, Yang N, Menard D, Marcorelles P, Echaniz-Laguna A, Reimann J, Vainzof M, Monnier N, Ravenscroft G, McNamara E, Nowak KJ, Laing NG, Wallgren-Pettersson C, Trewhella J, Marston S, Ottenheijm C, North KN, Clarke NF. Brain 136 494-507 (2013)
  6. Molecular effects of familial hypertrophic cardiomyopathy-related mutations in the TNT1 domain of cTnT. Manning EP, Tardiff JC, Schwartz SD. J. Mol. Biol. 421 54-66 (2012)
  7. An atomic model of the tropomyosin cable on F-actin. Orzechowski M, Li XE, Fischer S, Lehman W. Biophys. J. 107 694-699 (2014)
  8. Structural analysis of smooth muscle tropomyosin α and β isoforms. Rao JN, Rivera-Santiago R, Li XE, Lehman W, Dominguez R. J. Biol. Chem. 287 3165-3174 (2012)
  9. Structure and flexibility of the tropomyosin overlap junction. Li XE, Orzechowski M, Lehman W, Fischer S. Biochem. Biophys. Res. Commun. 446 304-308 (2014)
  10. Structure-function analysis of the C-terminal domain of CNM67, a core component of the Saccharomyces cerevisiae spindle pole body. Klenchin VA, Frye JJ, Jones MH, Winey M, Rayment I. J. Biol. Chem. 286 18240-18250 (2011)
  11. Kinesin-2 KIF3AC and KIF3AB Can Drive Long-Range Transport along Microtubules. Guzik-Lendrum S, Rank KC, Bensel BM, Taylor KC, Rayment I, Gilbert SP. Biophys. J. 109 1472-1482 (2015)
  12. Structural organization of FtsB, a transmembrane protein of the bacterial divisome. LaPointe LM, Taylor KC, Subramaniam S, Khadria A, Rayment I, Senes A. Biochemistry 52 2574-2585 (2013)
  13. Skeletal muscle myopathy mutations at the actin tropomyosin interface that cause gain- or loss-of-function. Memo M, Marston S. J. Muscle Res. Cell. Motil. 34 165-169 (2013)
  14. Skip residues modulate the structural properties of the myosin rod and guide thick filament assembly. Taylor KC, Buvoli M, Korkmaz EN, Buvoli A, Zheng Y, Heinze NT, Cui Q, Leinwand LA, Rayment I. Proc. Natl. Acad. Sci. U.S.A. 112 E3806-15 (2015)
  15. Direct observation of tropomyosin binding to actin filaments. Schmidt WM, Lehman W, Moore JR. Cytoskeleton (Hoboken) 72 292-303 (2015)
  16. A small molecule inhibitor of tropomyosin dissociates actin binding from tropomyosin-directed regulation of actin dynamics. Bonello TT, Janco M, Hook J, Byun A, Appaduray M, Dedova I, Hitchcock-DeGregori S, Hardeman EC, Stehn JR, Böcking T, Gunning PW. Sci Rep 6 19816 (2016)
  17. Altering the stability of the Cdc8 overlap region modulates the ability of this tropomyosin to bind co-operatively to actin and regulate myosin. East DA, Sousa D, Martin SR, Edwards TA, Lehman W, Mulvihill DP. Biochem. J. 438 265-273 (2011)
  18. Heterodimerization of Kinesin-2 KIF3AB Modulates Entry into the Processive Run. Albracht CD, Guzik-Lendrum S, Rayment I, Gilbert SP. J. Biol. Chem. 291 23248-23256 (2016)
  19. High-throughput NMR assessment of the tertiary structure of food allergens. Alessandri S, Sancho A, Vieths S, Mills CE, Wal JM, Shewry PR, Rigby N, Hoffmann-Sommergruber K. PLoS ONE 7 e39785 (2012)
  20. Three mammalian tropomyosin isoforms have different regulatory effects on nonmuscle myosin-2B and filamentous β-actin in vitro. Pathan-Chhatbar S, Taft MH, Reindl T, Hundt N, Latham SL, Manstein DJ. J. Biol. Chem. 293 863-875 (2018)
  21. Docking Troponin T onto the Tropomyosin Overlapping Domain of Thin Filaments. Pavadai E, Rynkiewicz MJ, Ghosh A, Lehman W. Biophys J 118 325-336 (2020)
  22. A composite approach towards a complete model of the myosin rod. Korkmaz EN, Taylor KC, Andreas MP, Ajay G, Heinze NT, Cui Q, Rayment I. Proteins 84 172-189 (2016)
  23. Actin-tropomyosin distribution in non-muscle cells. Manstein DJ, Meiring JCM, Hardeman EC, Gunning PW. J Muscle Res Cell Motil 41 11-22 (2020)
  24. Clinically Divergent Mutation Effects on the Structure and Function of the Human Cardiac Tropomyosin Overlap. McConnell M, Tal Grinspan L, Williams MR, Lynn ML, Schwartz BA, Fass OZ, Schwartz SD, Tardiff JC. Biochemistry 56 3403-3413 (2017)
  25. Different positions of tropomyosin isoforms on actin filament are determined by specific sequences of end-to-end overlaps. Sliwińska M, Zukowska M, Borys D, Moraczewska J. Cytoskeleton (Hoboken) 68 300-312 (2011)
  26. The structural dynamics of α-tropomyosin on F-actin shape the overlap complex between adjacent tropomyosin molecules. Lehman W, Li XE, Orzechowski M, Fischer S. Arch. Biochem. Biophys. 552-553 68-73 (2014)
  27. CM1-driven assembly and activation of yeast γ-tubulin small complex underlies microtubule nucleation. Brilot AF, Lyon AS, Zelter A, Viswanath S, Maxwell A, MacCoss MJ, Muller EG, Sali A, Davis TN, Agard DA. Elife 10 e65168 (2021)
  28. Family-specific Kinesin Structures Reveal Neck-linker Length Based on Initiation of the Coiled-coil. Phillips RK, Peter LG, Gilbert SP, Rayment I. J. Biol. Chem. 291 20372-20386 (2016)
  29. Conformational Dynamics of Asparagine at Coiled-Coil Interfaces. Thomas F, Niitsu A, Oregioni A, Bartlett GJ, Woolfson DN. Biochemistry 56 6544-6554 (2017)
  30. Protein-Protein Docking Reveals Dynamic Interactions of Tropomyosin on Actin Filaments. Pavadai E, Lehman W, Rynkiewicz MJ. Biophys J 119 75-86 (2020)
  31. The propensity for tropomyosin twisting in the presence and absence of F-actin. Rynkiewicz MJ, Fischer S, Lehman W. Arch. Biochem. Biophys. 609 51-58 (2016)
  32. Addressing the Molecular Mechanism of Longitudinal Lamin Assembly Using Chimeric Fusions. Stalmans G, Lilina AV, Vermeire PJ, Fiala J, Novák P, Strelkov SV. Cells 9 (2020)
  33. Novel human cell expression method reveals the role and prevalence of posttranslational modification in nonmuscle tropomyosins. Carman PJ, Barrie KR, Dominguez R. J Biol Chem 297 101154 (2021)
  34. Structural and Functional Peculiarities of Cytoplasmic Tropomyosin Isoforms, the Products of TPM1 and TPM4 Genes. Marchenko M, Nefedova V, Artemova N, Kleymenov S, Levitsky D, Matyushenko A. Int J Mol Sci 22 5141 (2021)
  35. Structural insights into the tropomodulin assembly at the pointed ends of actin filaments. Tolkatchev D, Kuruba B, Smith GE, Swain KD, Smith KA, Moroz N, Williams TJ, Kostyukova AS. Protein Sci 30 423-437 (2021)
  36. Acetylation of fission yeast tropomyosin does not promote differential association with cognate formins. Tang Q, Pollard LW, Homa KE, Kovar DR, Trybus KM. Cytoskeleton (Hoboken) 80 77-92 (2023)
  37. Design considerations in coiled-coil fusion constructs for the structural determination of a problematic region of the human cardiac myosin rod. Andreas MP, Ajay G, Gellings JA, Rayment I. J. Struct. Biol. 200 219-228 (2017)
  38. Distinct sites in tropomyosin specify shared and isoform-specific regulation of myosins II and V. Barua B, Sckolnick M, White HD, Trybus KM, Hitchcock-DeGregori SE. Cytoskeleton (Hoboken) 75 150-163 (2018)
  39. Effects of cardiomyopathy-linked mutations K15N and R21H in tropomyosin on thin-filament regulation and pointed-end dynamics. Ly T, Pappas CT, Johnson D, Schlecht W, Colpan M, Galkin VE, Gregorio CC, Dong WJ, Kostyukova AS. Mol. Biol. Cell 30 268-281 (2019)
  40. Structural differences between C-terminal regions of tropomyosin isoforms. Sliwińska M, Moraczewska J. PeerJ 1 e181 (2013)
  41. Structure and function of Spc42 coiled-coils in yeast centrosome assembly and duplication. Drennan AC, Krishna S, Seeger MA, Andreas MP, Gardner JM, Sether EKR, Jaspersen SL, Rayment I. Mol. Biol. Cell 30 1505-1522 (2019)
  42. Temperature sensitive point mutations in fission yeast tropomyosin have long range effects on the stability and function of the actin-tropomyosin copolymer. Johnson CA, Brooker HR, Gyamfi I, O'Brien J, Ashley B, Brazier JE, Dean A, Embling J, Grimsey E, Tomlinson AC, Wilson EG, Geeves MA, Mulvihill DP. Biochem. Biophys. Res. Commun. 506 339-346 (2018)
  43. Troponin-I-induced tropomyosin pivoting defines thin-filament function in relaxed and active muscle. Lehman W, Rynkiewicz MJ. J Gen Physiol 155 e202313387 (2023)


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