Your search keyword '"Levitsky DI"' showing total 96 results

1. Novel Mutation Lys30Glu in the TPM1 Gene Leads to Pediatric Left Ventricular Non-Compaction and Dilated Cardiomyopathy via Impairment of Structural and Functional Properties of Cardiac Tropomyosin.

Author

Zaklyazminskaya EV, Nefedova VV, Koubassova NA, Kotlukova NP, Kopylova GV, Kochurova AM, Shchepkin DV, Ryabkova NS, Katrukha IA, Kleymenov SY, Bershitsky SY, Matyushenko AM, Tsaturyan AK, and Levitsky DI

Subjects

Humans, Child, Preschool, Male, Actins metabolism, Actins genetics, Molecular Dynamics Simulation, Animals, Mutation, Female, Tropomyosin genetics, Tropomyosin chemistry, Tropomyosin metabolism, Cardiomyopathy, Dilated genetics, Cardiomyopathy, Dilated metabolism

Abstract

Pediatric dilated cardiomyopathy (DCM) is a rare heart muscle disorder leading to the enlargement of all chambers and systolic dysfunction. We identified a novel de novo variant, c.88A>G (p.Lys30Glu, K30E), in the TPM1 gene encoding the major cardiac muscle tropomyosin (Tpm) isoform, Tpm1.1. The variant was found in a proband with DCM and left ventricular non-compaction who progressed to terminal heart failure at the age of 3 years and 8 months. To study the properties of the mutant protein, we produced recombinant K30E Tpm and used various biochemical and biophysical methods to compare its properties with those of WT Tpm. The K30E substitution decreased the thermal stability of Tpm and its complex with actin and significantly reduced the sliding velocity of the regulated thin filaments over a surface covered by ovine cardiac myosin in an in vitro motility assay across the entire physiological range of Ca 2+ concentration. Our molecular dynamics simulations suggest that the charge reversal of the 30th residue of Tpm alters the actin monomer to which it is bound. We hypothesize that this rearrangement of the actin-Tpm interaction may hinder the transition of a myosin head attached to a nearby actin from a weakly to a strongly bound, force-generating state, thereby reducing myocardial contractility. The impaired myosin interaction with regulated actin filaments and the decreased thermal stability of the actin-Tpm complex at a near physiological temperature likely contribute to the pathogenicity of the variant and its causative role in progressive DCM.

Published

2024

2. Functional and Structural Properties of Cytoplasmic Tropomyosin Isoforms Tpm1.8 and Tpm1.9.

Author

Lapshina KK, Nefedova VV, Nabiev SR, Roman SG, Shchepkin DV, Kopylova GV, Kochurova AM, Beldiia EA, Kleymenov SY, Levitsky DI, and Matyushenko AM

Subjects

Animals, Cytoplasm metabolism, Humans, Exons, Protein Binding, Protein Stability, Tropomyosin metabolism, Tropomyosin chemistry, Tropomyosin genetics, Protein Isoforms metabolism, Protein Isoforms chemistry, Protein Isoforms genetics, Actin Cytoskeleton metabolism, Actins metabolism, Actins chemistry

Abstract

The actin cytoskeleton is one of the most important players in cell motility, adhesion, division, and functioning. The regulation of specific microfilament formation largely determines cellular functions. The main actin-binding protein in animal cells is tropomyosin (Tpm). The unique structural and functional diversity of microfilaments is achieved through the diversity of Tpm isoforms. In our work, we studied the properties of the cytoplasmic isoforms Tpm1.8 and Tpm1.9. The results showed that these isoforms are highly thermostable and differ in the stability of their central and C -terminal fragments. The properties of these isoforms were largely determined by the 6th exons. Thus, the strength of the end-to-end interactions, as well as the affinity of the Tpm molecule for F-actin, differed between the Tpm1.8 and Tpm1.9 isoforms. They were determined by whether an alternative internal exon, 6a or 6b, was included in the Tpm isoform structure. The strong interactions of the Tpm1.8 and Tpm1.9 isoforms with F-actin led to the formation of rigid actin filaments, the stiffness of which was measured using an optical trap. It is quite possible that the structural and functional features of the Tpm isoforms largely determine the appearance of these isoforms in the rigid actin structures of the cell cortex.

Published

2024

3. Myopathy-causing mutation R91P in the TPM3 gene drastically impairs structural and functional properties of slow skeletal muscle tropomyosin γβ-heterodimer.

Author

Gonchar AD, Koubassova NA, Kopylova GV, Kochurova AM, Nefedova VV, Yampolskaya DS, Shchepkin DV, Bershitsky SY, Tsaturyan AK, Matyushenko AM, and Levitsky DI

Subjects

Humans, Muscle, Skeletal metabolism, Mutation, Muscle Weakness metabolism, Actins genetics, Actins metabolism, Tropomyosin chemistry, Muscular Diseases genetics

Abstract

Tropomyosin (Tpm) is a regulatory actin-binding protein involved in Ca 2+ activation of contraction of striated muscle. In human slow skeletal muscles, two distinct Tpm isoforms, γ and β, are present. They interact to form three types of dimeric Tpm molecules: γγ-homodimers, γβ-heterodimers, or ββ-homodimers, and a majority of the molecules are present as γβ-Tpm heterodimers. Point mutation R91P within the TPM3 gene encoding γ-Tpm is linked to the condition known as congenital fiber-type disproportion (CFTD), which is characterized by severe muscle weakness. Here, we investigated the influence of the R91P mutation in the γ-chain on the properties of the γβ-Tpm heterodimer. We found that the R91P mutation impairs the functional properties of γβ-Tpm heterodimer more severely than those of earlier studied γγ-Tpm homodimer carrying this mutation in both γ-chains. Since a significant part of Tpm molecules in slow skeletal muscle is present as γβ-heterodimers, our results explain why this mutation leads to muscle weakness in CFTD., Competing Interests: Declaration of competing interest The authors declare no conflicts of interest., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

4. Neurofilament Light Protein Rod Domain Exhibits Structural Heterogeneity.

Author

Nefedova VV, Kleymenov SY, Safenkova IV, Levitsky DI, and Matyushenko AM

Subjects

Calorimetry, Differential Scanning, Neurons, Protein Domains, Intermediate Filaments, Tumor Necrosis Factor Ligand Superfamily Member 14

Abstract

Neurofilaments are neuron-specific proteins that belong to the intermediate filament (IFs) protein family, with the neurofilament light chain protein (NFL) being the most abundant. The IFs structure typically includes a central coiled-coil rod domain comprised of coils 1A, 1B, and 2, separated by linker regions. The thermal stability of the IF molecule plays a crucial role in its ability for self-association. In the current study, we investigated the thermal stability of NFL coiled-coil domains by analyzing a set of recombinant domains and their fusions (NFL 1B , NFL 1A+1B , NFL 2 , NFL 1B+2 , and NFL ROD ) via circular dichroism spectroscopy and differential scanning calorimetry. The thermal stability of coiled-coil domains is evident in a wide range of temperatures, and thermal transition values (T m ) correspond well between isolated coiled-coil domains and full-length NFL. NFL 1B has a T m of 39.4 °C, and its' fusions, NFL 1A+1B and NFL 1B+2 , have a T m of 41.9 °C and 41.5 °C, respectively. However, in the case of NFL 2 , thermal denaturation includes at least two thermal transitions at 37.2 °C and 62.7 °C. These data indicate that the continuous α-helical structure of the coil 2 domain has parts with varied thermal stability. Among all the NFL fragments, only NFL 2 underwent irreversible heat-induced denaturation. Together, these results unveil the origin of full-length NFL's thermal transitions, and reveal its domains structure and properties.

Published

2024

5. Novel Mutation Glu98Lys in Cardiac Tropomyosin Alters Its Structure and Impairs Myocardial Relaxation.

Author

Matyushenko AM, Nefedova VV, Kochurova AM, Kopylova GV, Koubassova NA, Shestak AG, Yampolskaya DS, Shchepkin DV, Kleymenov SY, Ryabkova NS, Katrukha IA, Bershitsky SY, Zaklyazminskaya EV, Tsaturyan AK, and Levitsky DI

Subjects

Humans, Myocardium metabolism, Actin Cytoskeleton metabolism, Actins metabolism, Mutation, Calcium metabolism, Tropomyosin metabolism, Cardiomyopathies genetics, Cardiomyopathies metabolism

Abstract

We characterized a novel genetic variant c.292G > A (p.E98K) in the TPM1 gene encoding cardiac tropomyosin 1.1 isoform (Tpm1.1), found in a proband with a phenotype of complex cardiomyopathy with conduction dysfunction and slow progressive neuromuscular involvement. To understand the molecular mechanism by which this mutation impairs cardiac function, we produced recombinant Tpm1.1 carrying an E98K substitution and studied how this substitution affects the structure of the Tpm1.1 molecule and its functional properties. The results showed that the E98K substitution in the N-terminal part of the Tpm molecule significantly destabilizes the C-terminal part of Tpm, thus indicating a long-distance destabilizing effect of the substitution on the Tpm coiled-coil structure. The E98K substitution did not noticeably affect Tpm's affinity for F-actin but significantly impaired Tpm's regulatory properties. It increased the Ca 2+ sensitivity of the sliding velocity of regulated thin filaments over cardiac myosin in an in vitro motility assay and caused an incomplete block of the thin filament sliding at low Ca 2+ concentrations. The incomplete motility block in the absence of Ca 2+ can be explained by the loosening of the Tpm interaction with troponin I (TnI), thus increasing Tpm mobility on the surface of an actin filament that partially unlocks the myosin binding sites. This hypothesis is supported by the molecular dynamics (MD) simulation that showed that the E98 Tpm residue is involved in hydrogen bonding with the C-terminal part of TnI. Thus, the results allowed us to explain the mechanism by which the E98K Tpm mutation impairs sarcomeric function and myocardial relaxation.

Published

2023

6. Structural and Functional Properties of Tropomyosin Isoforms Tpm4.1 and Tpm2.1.

Author

Logvinov AS, Nefedova VV, Yampolskaya DS, Kleymenov SY, Levitsky DI, and Matyushenko AM

Subjects

Animals, Cytoskeletal Proteins, Protein Isoforms, Amino Acid Sequence, Actins, Tropomyosin

Abstract

Tropomyosin (Tpm) is one of the most important partners of actin filament that largely determines its properties. In animal organisms, there are different isoforms of Tpm, which are believed to be involved in the regulation of various cellular functions. However, molecular mechanisms by which various Tpm cytoplasmic regulate of the functioning of actin filaments are still poorly understood. Here, we investigated the properties of Tpm2.1 and Tpm4.1 isoforms and compared them to each other and to more extensively studied Tpm isoforms. Tpm2.1 and Tpm4.1 were very similar in their affinity to F-actin, thermal stability, and resistance to limited proteolysis by trypsin, but differed markedly in the viscosity of their solutions and thermal stability of their complexes with F-actin. The main difference of Tpm2.1 and Tpm4.1 from other Tpm isoforms (e.g., Tpm1.6 and Tpm1.7) was their extremely low thermal stability as measured by the CD and DSC methods. We suggested the possible causes of this instability based on comparing the amino acid sequences of Tpm4.1 and Tpm2.1 with the sequences of Tpm1.6 and Tpm1.7 isoforms, respectively, that have similar exon structure.

Published

2023

7. Structural and Functional Properties of Kappa Tropomyosin.

Author

Kopylova GV, Kochurova AM, Yampolskaya DS, Nefedova VV, Tsaturyan AK, Koubassova NA, Kleymenov SY, Levitsky DI, Bershitsky SY, Matyushenko AM, and Shchepkin DV

Subjects

Animals, Rats, Swine, Tropomyosin genetics, Tropomyosin chemistry, Actin Cytoskeleton chemistry, Myosins analysis, Actins chemistry, Calcium analysis

Abstract

In the myocardium, the TPM1 gene expresses two isoforms of tropomyosin (Tpm), alpha (αTpm; Tpm 1.1) and kappa (κTpm; Tpm 1.2). κTpm is the result of alternative splicing of the TPM1 gene. We studied the structural features of κTpm and its regulatory function in the atrial and ventricular myocardium using an in vitro motility assay. We tested the possibility of Tpm heterodimer formation from α- and κ-chains. Our result shows that the formation of ακTpm heterodimer is thermodynamically favorable, and in the myocardium, κTpm most likely exists as ακTpm heterodimer. Using circular dichroism, we compared the thermal unfolding of ααTpm, ακTpm, and κκTpm. κκTpm had the lowest stability, while the ακTpm was more stable than ααTpm. The differential scanning calorimetry results indicated that the thermal stability of the N-terminal part of κκTpm is much lower than that of ααTpm. The affinity of ααTpm and κκTpm to F-actin did not differ, and ακTpm interacted with F-actin significantly worse. The troponin T1 fragment enhanced the κκTpm and ακTpm affinity to F-actin. κκTpm differently affected the calcium regulation of the interaction of pig and rat ventricular myosin with the thin filament. With rat myosin, calcium sensitivity of thin filaments containing κκTpm was significantly lower than that with ααTpm and with pig myosin, and the sensitivity did not differ. Thin filaments containing κκTpm and ακTpm were better activated by pig atrial myosin than those containing ααTpm.

Published

2023

8. Effect of Neurodegenerative Mutations in the NEFL Gene on Thermal Denaturation of the Neurofilament Light Chain Protein.

Author

Nefedova VV, Yampolskaya DS, Kleymenov SY, Chebotareva NA, Matyushenko AM, and Levitsky DI

Subjects

Mutation, Protein Denaturation, Calorimetry, Differential Scanning, Circular Dichroism, Intermediate Filaments metabolism, Proteins metabolism

Abstract

Effects of E90K, N98S, and A149V mutations in the light chain of neurofilaments (NFL) on the structure and thermal denaturation of the NFL molecule were investigated. By using circular dichroism spectroscopy, it was shown that these mutations did not lead to the changes in α-helical structure of NFL, but they caused noticeable effects on the stability of the molecule. We also identified calorimetric domains in the NFL structure by using differential scanning calorimetry. It was shown that the E90K replacement leads to the disappearance of the low-temperature thermal transition (domain 1). The mutations cause changes in the enthalpy of NFL domains melting, as well as lead to the significant changes in the melting temperatures (T m ) of some calorimetric domains. Thus, despite the fact that all these mutations are associated with the development of Charcot-Marie-Tooth neuropathy, and two of them are even located very close to each other in the coil 1A, they affect differently structure and stability of the NFL molecule.

Published

2023

9. Pseudo-phosphorylation of essential light chains affects the functioning of skeletal muscle myosin.

Author

Yampolskaya DS, Kopylova GV, Shchepkin DV, Nabiev SR, Nikitina LV, Walklate J, Ziganshin RH, Bershitsky SY, Geeves MA, Matyushenko AM, and Levitsky DI

Subjects

Phosphorylation, Myosins, Muscle, Skeletal, Actins, Skeletal Muscle Myosins

Abstract

The work aimed to investigate how the phosphorylation of the myosin essential light chain of fast skeletal myosin (LC1) affects the functional properties of the myosin molecule. Using mass-spectrometry, we revealed phosphorylated peptides of LC1 in myosin from different fast skeletal muscles. Mutations S193D and T65D that mimic natural phosphorylation of LC1 were produced, and their effects on functional properties of the entire myosin molecule and isolated myosin head (S1) were studied. We have shown that T65D mutation drastically decreased the sliding velocity of thin filaments in an in vitro motility assay and strongly increased the duration of actin-myosin interaction in optical trap experiments. These effects of T65D mutation in LC1 observed only with the whole myosin but not with S1 were prevented by double T65D/S193D mutation. The T65D and T65D/S193D mutations increased actin-activated ATPase activity of S1 and decreased ADP affinity for the actin-S1 complex. The results indicate that pseudo-phosphorylation of LC1 differently affects the properties of the whole myosin molecule and its isolated head. Also, the results show that phosphorylation of LC1 of skeletal myosin could be one more mechanism of regulation of actin-myosin interaction that needs further investigation., Competing Interests: Declaration of Competing Interest The authors declare no conflict of interest., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2023

10. De Novo Asp219Val Mutation in Cardiac Tropomyosin Associated with Hypertrophic Cardiomyopathy.

Author

Tsaturyan AK, Zaklyazminskaya EV, Polyak ME, Kopylova GV, Shchepkin DV, Kochurova AM, Gonchar AD, Kleymenov SY, Koubasova NA, Bershitsky SY, Matyushenko AM, and Levitsky DI

Subjects

Humans, Tropomyosin metabolism, Actin Cytoskeleton metabolism, Mutation, Death, Sudden, Cardiac, Calcium metabolism, Actins metabolism, Cardiomyopathy, Hypertrophic genetics, Cardiomyopathy, Hypertrophic metabolism

Abstract

Hypertrophic cardiomyopathy (HCM), caused by mutations in thin filament proteins, manifests as moderate cardiac hypertrophy and is associated with sudden cardiac death (SCD). We identified a new de novo variant, c.656A>T (p.D219V), in the TPM1 gene encoding cardiac tropomyosin 1.1 (Tpm) in a young SCD victim with post-mortem-diagnosed HCM. We produced recombinant D219V Tpm1.1 and studied its structural and functional properties using various biochemical and biophysical methods. The D219V mutation did not affect the Tpm affinity for F-actin but increased the thermal stability of the Tpm molecule and Tpm-F-actin complex. The D219V mutation significantly increased the Ca2+ sensitivity of the sliding velocity of thin filaments over cardiac myosin in an in vitro motility assay and impaired the inhibition of the filament sliding at low Ca2+ concentration. The molecular dynamics (MD) simulation provided insight into a possible molecular mechanism of the effect of the mutation that is most likely a cause of the weakening of the Tpm interaction with actin in the "closed" state and so makes it an easier transition to the “open” state. The changes in the Ca2+ regulation of the actin-myosin interaction characteristic of genetic HCM suggest that the mutation is likely pathogenic.

Published

2022

11. Impact of Troponin in Cardiomyopathy Development Caused by Mutations in Tropomyosin.

Author

Nefedova VV, Kopylova GV, Shchepkin DV, Kochurova AM, Kechko OI, Borzova VA, Ryabkova NS, Katrukha IA, Mitkevich VA, Bershitsky SY, Levitsky DI, and Matyushenko AM

Subjects

Humans, Actins metabolism, Calcium metabolism, Mutation, Troponin T metabolism, Cardiomyopathies genetics, Cardiomyopathies metabolism, Tropomyosin genetics, Troponin genetics

Abstract

Tropomyosin (Tpm) mutations cause inherited cardiac diseases such as hypertrophic and dilated cardiomyopathies. We applied various approaches to investigate the role of cardiac troponin (Tn) and especially the troponin T (TnT) in the pathogenic effects of Tpm cardiomyopathy-associated mutations M8R, K15N, A277V, M281T, and I284V located in the overlap junction of neighboring Tpm dimers. Using co-sedimentation assay and viscosity measurements, we showed that TnT1 (fragment of TnT) stabilizes the overlap junction of Tpm WT and all Tpm mutants studied except Tpm M8R. However, isothermal titration calorimetry (ITC) indicated that TnT1 binds Tpm WT and all Tpm mutants similarly. By using ITC, we measured the direct K D of the Tpm overlap region, N-end, and C-end binding to TnT1. The ITC data revealed that the Tpm C-end binds to TnT1 independently from the N-end, while N-end does not bind. Therefore, we suppose that Tpm M8R binds to TnT1 without forming the overlap junction. We also demonstrated the possible role of Tn isoform composition in the cardiomyopathy development caused by M8R mutation. TnT1 dose-dependently reduced the velocity of F-actin-Tpm filaments containing Tpm WT, Tpm A277V, and Tpm M281T mutants in an in vitro motility assay. All mutations impaired the calcium regulation of the actin-myosin interaction. The M281T and I284V mutations increased the calcium sensitivity, while the K15N and A277V mutations reduced it. The Tpm M8R, M281T, and I284V mutations under-inhibited the velocity at low calcium concentrations. Our results demonstrate that Tpm mutations likely implement their pathogenic effects through Tpm interaction with Tn, cardiac myosin, or other protein partners.

Published

2022

12. Properties of Cardiac Myosin with Cardiomyopathic Mutations in Essential Light Chains.

Author

Yampolskaya DS, Kopylova GV, Shchepkin DV, Bershitsky SY, Matyushenko AM, and Levitsky DI

Subjects

Humans, Actins genetics, Actins metabolism, Actin Cytoskeleton metabolism, Mutation, Myosin Light Chains genetics, Myosin Light Chains metabolism, Cardiac Myosins genetics, Cardiac Myosins metabolism, Myosins genetics, Myosins metabolism

Abstract

The effects of cardiomyopathic mutations E56G, M149V, and E177G in the MYL3 gene encoding essential light chain of human ventricular myosin (ELCv), on the functional properties of cardiac myosin and its isolated head (myosin subfragment 1, S1) were investigated. Only the M149V mutation upregulated the actin-activated ATPase activity of S1. All mutations significantly increased the Ca2+-sensitivity of the sliding velocity of thin filaments on the surface with immobilized myosin in the in vitro motility assay, while mutations E56G and M149V (but not E177G) reduced the sliding velocity of regulated thin filaments and F-actin filaments almost twice. Therefore, despite the fact that all studied mutations in ELCv are involved in the development of hypertrophic cardiomyopathy, the mechanisms of their influence on the actin-myosin interaction are different.

Published

2022

13. Comparative structural and functional studies of low molecular weight tropomyosin isoforms, the TPM3 gene products.

Author

Marchenko MA, Nefedova VV, Yampolskaya DS, Borzova VA, Kleymenov SY, Nabiev SR, Nikitina LV, Matyushenko AM, and Levitsky DI

Subjects

Actins chemistry, Actins metabolism, Animals, Humans, In Vitro Techniques, Molecular Weight, Protein Folding, Protein Interaction Domains and Motifs, Protein Isoforms chemistry, Protein Isoforms genetics, Protein Isoforms metabolism, Protein Stability, Rabbits, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Thermodynamics, Tropomyosin metabolism, Viscosity, Tropomyosin chemistry, Tropomyosin genetics

Abstract

Tropomyosin (Tpm) is an actin-associated protein and key regulator of actin filament structure and dynamics in muscle and non-muscle cells where it participates in many vital processes. Human non-muscle cells produce many Tpm isoforms; however, little is known yet about their structural and functional properties. In the present work, we have applied various methods to investigate the properties of five low molecular weight Tpm isoforms (Tpm3.1, Tpm3.2, Tpm3.4, Tpm3.5, and Tpm3.7), the products of TPM3 gene, which significantly differ by alternatively spliced internal exon 6 (6a or 6b) and C-terminal exon 9 (9a, 9c or 9d). Our results clearly demonstrate that the properties of these Tpm isoforms are quite different depending on sequence variations in alternatively spliced regions of their molecules. These differences can be important in further studies to explain why these Tpm isoforms play a key role in organization and dynamics of the cytoskeleton., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

14. Acidosis modifies effects of phosphorylated tropomyosin on the actin-myosin interaction in the myocardium.

Author

Kopylova GV, Matyushenko AM, Berg VY, Levitsky DI, Bershitsky SY, and Shchepkin DV

Subjects

Actins, Humans, Myocardium, Myosins, Acidosis, Tropomyosin

Abstract

Phosphorylation of α-tropomyosin (Tpm1.1), a predominant Tpm isoform in the myocardium, is one of the regulatory mechanisms of the heart contractility. The Tpm 1.1 molecule has one site of phosphorylation, Ser283. The degree of the Tpm phosphorylation decreases with age and also changes in heart pathologies. Myocardial pathologies, in particular ischemia, are usually accompanied by pH lowering in the cardiomyocyte cytosol. We studied the effects of acidosis on the structural and functional properties of the pseudo-phosphorylated form of Tpm1.1 with the S283D substitution. We found that in acidosis, the interaction of the N- and C-ends of the S283D Tpm molecules decreases, whereas that of WT Tpm does not change. The pH lowering increased thermostability of the complex of F-actin with S283D Tpm to a greater extent than with WT Tpm. Using an in vitro motility assay with NEM- modified myosin as a load, we assessed the effect of the Tpm pseudo-phosphorylation on the force of the actin-myosin interaction. In acidosis, the force generated by myosin in the interaction with thin filaments containing S283D Tpm was higher than with those containing WT Tpm. Also, the pseudo-phosphorylation increased the myosin ability to resist a load. We conclude that ischemia changes the effect of the phosphorylated Tpm on the contractile function of the myocardium., (© 2021. The Author(s), under exclusive licence to Springer Nature Switzerland AG part of Springer Nature.)

Published

2021

15. Tropomyosin pseudo-phosphorylation can rescue the effects of cardiomyopathy-associated mutations.

Author

Nefedova VV, Koubassova NA, Borzova VA, Kleymenov SY, Tsaturyan AK, Matyushenko AM, and Levitsky DI

Subjects

Humans, Phosphorylation, Protein Conformation, Serine genetics, Tropomyosin genetics, Tropomyosin metabolism, Cardiomyopathy, Dilated genetics, Molecular Dynamics Simulation, Mutation, Missense, Tropomyosin chemistry

Abstract

We applied various methods to investigate how mutations S283D and S61D that mimic phosphorylation of tropomyosin (Tpm) affect structural and functional properties of cardiac Tpm carrying cardiomyopathy-associated mutations in different parts of its molecule. Using differential scanning calorimetry and molecular dynamics, we have shown that the S61D mutation (but not the S283 mutation) causes significant destabilization of the N-terminal part of the Tpm molecule independently of the absence or presence of cardiomyopathy-associated mutations. Our results obtained by cosedimentation of Tpm with F-actin demonstrated that both S283D and S61D mutations can reduce or even eliminate undesirable changes in Tpm affinity for F-actin caused by some cardiomyopathy-associated mutations. The results indicate that Tpm pseudo-phosphorylation by mutations S283D or S61D can rescue the effects of mutations in the TPM1 gene encoding a cardiac isoform of Tpm that lead to the development of such severe inherited heart diseases as hypertrophic or dilated cardiomyopathies., Competing Interests: Declaration of competing interest The authors declare no conflict of interests., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2021

16. Effects of myopathy-causing mutations R91P and R245G in the TPM3 gene on structural and functional properties of slow skeletal muscle tropomyosin.

Author

Gonchar AD, Kopylova GV, Kochurova AM, Berg VY, Shchepkin DV, Koubasova NA, Tsaturyan AK, Kleymenov SY, Matyushenko AM, and Levitsky DI

Subjects

Actins metabolism, Humans, Molecular Dynamics Simulation, Protein Multimerization, Tropomyosin chemistry, Troponin metabolism, Viscosity, Muscle, Skeletal physiopathology, Myopathies, Structural, Congenital genetics, Point Mutation, Tropomyosin genetics, Tropomyosin metabolism

Abstract

Tropomyosin (Tpm) is an actin-binding protein that plays a crucial role in the regulation of muscle contraction. Numerous point mutations in the TPM3 gene encoding Tpm of slow skeletal muscles (Tpm 3.12 or γ-Tpm) are associated with the genesis of various congenital myopathies. Two of these mutations, R91P and R245G, are associated with congenital fiber-type disproportion (CFTD) characterized by hypotonia and generalized muscle weakness. We applied various methods to investigate how these mutations affect the structural and functional properties of γγ-Tpm homodimers. The results show that both these mutations lead to strong structural changes in the γγ-Tpm molecule and significantly impaired its functional properties. These changes in the Tpm properties caused by R91P and R245G mutations give insight into the molecular mechanism of the CFTD development and the weakness of slow skeletal muscles observed in this inherited disease., Competing Interests: Declaration of competing interest The authors declare no conflicts of interest., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

17. Impact of A134 and E218 Amino Acid Residues of Tropomyosin on Its Flexibility and Function.

Author

Marchenko MA, Nefedova VV, Yampolskaya DS, Kopylova GV, Shchepkin DV, Bershitsky SY, Koubassova NA, Tsaturyan AK, Levitsky DI, and Matyushenko AM

Subjects

Actin Cytoskeleton chemistry, Actin Cytoskeleton metabolism, Actins chemistry, Actins metabolism, Animals, Calcium chemistry, Calcium metabolism, Calorimetry, Differential Scanning, Humans, Myosins chemistry, Myosins metabolism, Protein Conformation, Protein Stability, Temperature, Tropomyosin chemistry, Tropomyosin metabolism, Trypsin metabolism, Amino Acid Substitution, Molecular Dynamics Simulation, Mutation, Missense, Tropomyosin genetics

Abstract

Tropomyosin (Tpm) is one of the major actin-binding proteins that play a crucial role in the regulation of muscle contraction. The flexibility of the Tpm molecule is believed to be vital for its functioning, although its role and significance are under discussion. We choose two sites of the Tpm molecule that presumably have high flexibility and stabilized them with the A134L or E218L substitutions. Applying differential scanning calorimetry (DSC), molecular dynamics (MD), co-sedimentation, trypsin digestion, and in vitro motility assay, we characterized the properties of Tpm molecules with these substitutions. The A134L mutation prevented proteolysis of Tpm molecule by trypsin, and both substitutions increased the thermal stability of Tpm and its bending stiffness estimated from MD simulation. None of these mutations affected the primary binding of Tpm to F-actin; still, both of them increased the thermal stability of the actin-Tpm complex and maximal sliding velocity of regulated thin filaments in vitro at a saturating Ca 2+ concentration. However, the mutations differently affected the Ca 2+ sensitivity of the sliding velocity and pulling force produced by myosin heads. The data suggest that both regions of instability are essential for correct regulation and fine-tuning of Ca 2+ -dependent interaction of myosin heads with F-actin.

Published

2020

18. Mechanisms of disturbance of the contractile function of slow skeletal muscles induced by myopathic mutations in the tropomyosin TPM3 gene.

Author

Matyushenko AM, Nefedova VV, Shchepkin DV, Kopylova GV, Berg VY, Pivovarova AV, Kleymenov SY, Bershitsky SY, and Levitsky DI

Subjects

Humans, Models, Molecular, Mutation, Protein Isoforms, Protein Multimerization, Muscle Contraction, Myopathies, Nemaline genetics, Myopathies, Nemaline pathology, Tropomyosin chemistry, Tropomyosin genetics

Abstract

Several congenital myopathies of slow skeletal muscles are associated with mutations in the tropomyosin (Tpm) TPM3 gene. Tropomyosin is an actin-binding protein that plays a crucial role in the regulation of muscle contraction. Two Tpm isoforms, γ (Tpm3.12) and β (Tpm2.2) are expressed in human slow skeletal muscles forming γγ-homodimers and γβ-heterodimers of Tpm molecules. We applied various methods to investigate how myopathy-causing mutations M9R, E151A, and K169E in the Tpm γ-chain modify the structure-functional properties of Tpm dimers, and how this affects the muscle functioning. The results show that the features of γγ-Tpm and γβ-Tpm with substitutions in the Tpm γ-chain vary significantly. The characteristics of the γγ-Tpm depend on whether these mutations located in only one or both γ-chains. The mechanism of the development of nemaline myopathy associated with the M9R mutation was revealed. At the molecular level, a cause-and-effect relationship has been established for the development of myopathy by the K169E mutation. Also, we described the structure-functional properties of the Tpm dimers with the E151A mutation, which explain muscle weakness linked to this substitution. The results demonstrate a diversity of the molecular mechanisms of myopathy pathogenesis induced by studied Tpm mutations., (© 2020 Federation of American Societies for Experimental Biology.)

Published

2020

19. Unique functional properties of slow skeletal muscle tropomyosin.

Author

Matyushenko AM, Shchepkin DV, Kopylova GV, Bershitsky SY, and Levitsky DI

Subjects

Calcium physiology, Humans, Muscle Contraction, Protein Binding, Protein Isoforms chemistry, Protein Isoforms physiology, Protein Multimerization, Muscle, Skeletal metabolism, Tropomyosin chemistry, Tropomyosin physiology

Abstract

Tropomyosin (Tpm) is an α-helical coiled-coil actin-binding protein playing an essential role in the regulation of muscle contraction. The α- (Tpm 1.1) and γ- (Tpm 3.12) Tpm isoforms are expressed in fast and slow human skeletal muscles, respectively, while β-Tpm (Tpm 2.2) is expressed in both muscle types. This results in the formation of Tpm αα- and γγ-homodimers as well as αβ- and γβ-heterodimers. The properties of αα-homodimer are well studied, whereas very little is known about the functional properties of γγ-homodimer and γβ-heterodimer. We investigated interaction characteristics of Tpm γγ-homodimer and γβ-heterodimer with actin filaments and Ca 2+ -regulation of actin-myosin interaction on myosin from fast and slow skeletal muscles. The results showed that complexes formed by γγ-Tpm and γβ-Tpm with F-actin are more stable than those with αα-Tpm and αβ-Tpm. The maximum sliding speed of regulated thin filaments with either γγ-Tpm or γβ-Tpm moving over skeletal myosin was significantly less than that of the filaments with αα-Tpm or αβ-Tpm. The results indicate that isoforms of Tpm along with isoforms of myosin determine of functional properties of skeletal muscles and support an idea on the combined expression of myosin and Tpm isoforms., Competing Interests: Declaration of competing interest None., (Copyright © 2020 Elsevier B.V. and Société Française de Biochimie et Biologie Moléculaire (SFBBM). All rights reserved.)

Published

2020

20. Functional outcomes of structural peculiarities of striated muscle tropomyosin.

Author

Kopylova GV, Matyushenko AM, Koubassova NA, Shchepkin DV, Bershitsky SY, Levitsky DI, and Tsaturyan AK

Subjects

Humans, Muscle Contraction physiology, Muscle, Striated metabolism, Tropomyosin metabolism

Abstract

Tropomyosin is a dimer coiled-coil actin-binding protein. Adjacent tropomyosin molecules connect each other 'head-to-tail' via an overlap junction and form a continuous strand that winds around an actin filament and controls the actin-myosin interaction. High cooperativity of muscle contraction largely depends on tropomyosin characteristics. Here we summarise experimental evidence that local peculiarities of tropomyosin structure have long-range effects and determine functional properties of the strand, including changes in its bending stiffness and interaction with actin and myosin. Point mutations and posttranslational modifications help to probe the roles of the conserved 'non-canonical' residues, clusters of stabilising and destabilising core residues, and core gap in tropomyosin function. The data suggest that tropomyosin structural lability including a diversity of homo- and heterodimers of different isoforms provide a balance of stiffness, flexibility, and strength of interaction with partner sarcomere proteins necessary for fine-tuning of Ca 2+ regulation in various types of striated muscles.

Published

2020

21. Molecular Mechanisms of Pathologies of Skeletal and Cardiac Muscles Caused by Point Mutations in the Tropomyosin Genes.

Author

Matyushenko AM and Levitsky DI

Subjects

Actins metabolism, Animals, Dimerization, Heterozygote, Humans, Models, Molecular, Muscle Contraction genetics, Protein Binding, Protein Isoforms, Tropomyosin chemistry, Cardiomyopathies genetics, Muscle, Skeletal pathology, Muscular Diseases genetics, Myocardium pathology, Point Mutation, Tropomyosin genetics, Tropomyosin metabolism

Abstract

The review is devoted to tropomyosin (Tpm) - actin-binding protein, which plays a crucial role in the regulation of contraction of skeletal and cardiac muscles. Special attention is paid to myopathies and cardiomyopathies - severe hereditary diseases of skeletal and cardiac muscles associated with point mutations in Tpm genes. The current views on the molecular mechanisms of these diseases and the effects of such mutations on the Tpm structure and functions are considered in detail. Besides, some part of the review is devoted to analysis of the properties of Tpm homodimers and heterodimers with myopathic substitutions of amino acid residues in only one of the two chains of the Tpm dimeric molecule.

Published

2020

22. Cardiomyopathy-associated mutations in tropomyosin differently affect actin-myosin interaction at single-molecule and ensemble levels.

Author

Kopylova GV, Shchepkin DV, Nabiev SR, Matyushenko AM, Koubassova NA, Levitsky DI, and Bershitsky SY

Subjects

Animals, Humans, Mutation, Rabbits, Actins metabolism, Cardiomyopathies genetics, Myosins metabolism, Tropomyosin metabolism

Abstract

In the heart, mutations in the TPM1 gene encoding the α-isoform of tropomyosin lead, in particular, to the development of hypertrophic and dilated cardiomyopathies. We compared the effects of hypertrophic, D175N and E180G, and dilated, E40K and E54K, cardiomyopathy mutations in TPM1 gene on the properties of single actin-myosin interactions and the characteristics of the calcium regulation in an ensemble of myosin molecules immobilised on a glass surface and interacting with regulated thin filaments. Previously, we showed that at saturating Ca 2+ concentration the presence of Tpm on the actin filament increases the duration of the interaction. Here, we found that the studied Tpm mutations differently affected the duration: the D175N mutation reduced it compared to WT Tpm, while the E180G mutation increased it. Both dilated mutations made the duration of the interaction even shorter than with F-actin. The duration of the attached state of myosin to the thin filament in the optical trap did not correlate to the sliding velocity of thin filaments and its calcium sensitivity in the in vitro motility assay. We suppose that at the level of the molecular ensemble, the cooperative mechanisms prevail in the manifestation of the effects of cardiomyopathy-associated mutations in Tpm.

Published

2019

23. Thermal unfolding of various human non-muscle isoforms of tropomyosin.

Author

Nefedova VV, Marchenko MA, Kleymenov SY, Datskevich PN, Levitsky DI, and Matyushenko AM

Subjects

Calorimetry, Calorimetry, Differential Scanning, Humans, Molecular Weight, Neurons metabolism, Protein Domains, Protein Isoforms chemistry, Protein Isoforms metabolism, Protein Stability, Protein Structure, Secondary, Muscle, Skeletal metabolism, Protein Unfolding, Temperature, Tropomyosin chemistry, Tropomyosin metabolism

Abstract

Tropomyosin (Tpm) is an α-helical coiled-coil protein dimer, which forms a continuous head-to-tail polymer along the actin filament. In striated muscles, Tpm plays an important role in the Ca 2+ -dependent regulation of muscle contraction. However, little is known about functional and especially structural properties of the numerous non-muscle Tpm isoforms. In the present work, we have applied circular dichroism (CD) and differential scanning calorimetry (DSC) to investigate thermal unfolding and domain structure of various non-muscle human Tpm isoforms. These isoforms, the products of two different genes, TPM1 and TPM3, also significantly differ by alternatively spliced exons: N-terminal exons 1a2b or 1b, internal exons 6a or 6b, and C-terminal exons 9a, 9c or 9d. Our results clearly demonstrate that structural properties of various non-muscle Tpm isoforms can be quite different depending on the presence of different alternatively spliced exons in their genes. These data show for the first time a significant difference in the thermal unfolding between muscle and non-muscle Tpm isoforms and indicate that replacement of alternatively spliced exons alters the stability of certain domains in the Tpm molecule., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

24. The effects of cardiomyopathy-associated mutations in the head-to-tail overlap junction of α-tropomyosin on its properties and interaction with actin.

Author

Matyushenko AM, Koubassova NA, Shchepkin DV, Kopylova GV, Nabiev SR, Nikitina LV, Bershitsky SY, Levitsky DI, and Tsaturyan AK

Subjects

Acetylation, Actins chemistry, Animals, Humans, Molecular Conformation, Molecular Dynamics Simulation, Myocardium, Protein Binding, Protein Domains, Protein Stability, Protein Unfolding, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Spectrum Analysis, Tropomyosin chemistry, Viscosity, Actins metabolism, Cardiomyopathies genetics, Cardiomyopathies metabolism, Mutation, Tropomyosin genetics, Tropomyosin metabolism

Abstract

Tropomyosin (Tpm) plays a crucial role in the regulation of muscle contraction by controlling actin-myosin interaction. Tpm coiled-coil molecules bind each other via overlap junctions of their N- and C-termini and form a semi-rigid strand that binds the helical surface of an actin filament. The high bending stiffness of the strand is essential for high cooperativity of muscle regulation. Point mutations M8R and K15N in the N-terminal part of the junction and the A277V one in the C-terminal part are associated with dilated cardiomyopathy, while the M281T and I284V mutations are related to hypertrophic cardiomyopathy. To reveal molecular mechanism(s) underlying these pathologies, we studied the properties of recombinant Tpm carrying these mutations using several experimental approaches and molecular dynamic simulation of the junction. The M8R and K15N mutations weakened the interaction between the N- and C-termini of Tpm in the overlap junction and reduced the Tpm affinity for actin. These changes possibly led to a reduction in the regulation cooperativity. The C-terminal mutations caused only small and controversial changes in properties of Tpm and its complex with actin. Their involvement in disease phenotype is possibly caused by interaction with other sarcomere proteins., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2019

25. Structural and functional properties of αβ-heterodimers of tropomyosin with myopathic mutations Q147P and K49del in the β-chain.

Author

Matyushenko AM, Shchepkin DV, Susorov DS, Nefedova VV, Kopylova GV, Berg VY, Kleymenov SY, and Levitsky DI

Subjects

Actins metabolism, Animals, Humans, Muscular Diseases genetics, Protein Multimerization, Protein Unfolding, Rabbits, Tropomyosin chemistry, Tropomyosin metabolism, Mutation, Tropomyosin genetics

Abstract

Tropomyosin (Tpm) is an α-helical coiled-coil actin-binding protein that plays a key role in the Ca 2+ -regulated contraction of striated muscles. Two Tpm isoforms, α (Tpm 1.1) and β (Tpm 2.2), are expressed in fast skeletal muscles. These Tpm isoforms can form either αα and ββ homodimers, or αβ heterodimers. However, only αα-Tpm and αβ-Tpm dimers are usually present in most of fast skeletal muscles, because ββ-homodimers are relatively unstable and cannot exist under physiologic conditions. Nevertheless, the most of previous studies of myopathy-causing mutations in the Tpm β-chains were performed on the ββ-homodimers. In the present work, we applied different methods to investigate the effects of two myopathic mutations in the β-chain, Q147P and K49del (i.e. deletion of Lys49), on structural and functional properties of Tpm αβ-heterodimers and to compare them with the properties of ββ-homodimers carrying these mutations in both β-chains. The results show that the properties of αβ-Tpm heterodimers with these mutations in the β-chain differ significantly from the properties of ββ-homodimers with the same substitutions in both β-chains. This indicates that the αβ-heterodimer is a more appropriate model for studying the effects of myopathic mutations in the β-chain of Tpm than the ββ-homodimer which virtually does not exist in human skeletal muscles., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2019

26. Thermal unfolding of homodimers and heterodimers of different skeletal-muscle isoforms of tropomyosin.

Author

Matyushenko AM, Kleymenov SY, Susorov DS, and Levitsky DI

Subjects

Calorimetry, Differential Scanning, Dimerization, Humans, Mutagenesis, Site-Directed, Protein Isoforms chemistry, Protein Isoforms genetics, Protein Isoforms metabolism, Protein Stability, Protein Unfolding, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Temperature, Tropomyosin chemistry, Tropomyosin genetics, Muscle, Skeletal metabolism, Tropomyosin metabolism

Abstract

We applied differential scanning calorimetry (DSC) to investigate the structural properties of three isoforms of tropomyosin (Tpm), α, β, and γ, expressed from different genes in human skeletal muscles. We compared specific features of the thermal unfolding of αα, ββ, and γγ Tpm homodimers, as well as of αβ and γβ Tpm heterodimers. The results show that the thermal stability of γγ homodimer is much higher than that of αα homodimer which, in turn, is much more thermostable than the ββ homodimer. The stability of the γβ Tpm heterodimer is much lower than that of the γγ homodimer, and its thermal unfolding is quite different from that for γγ and ββ homodimers, whereas the unfolding of the αβ heterodimer is roughly similar to that of the αα homodimer., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

27. Essential Light Chains of Myosin and Their Role in Functioning of the Myosin Motor.

Author

Logvinova DS and Levitsky DI

Subjects

Amino Acid Sequence, Animals, Humans, Protein Isoforms chemistry, Protein Isoforms metabolism, Structure-Activity Relationship, Myosin Light Chains chemistry, Myosin Light Chains metabolism

Abstract

This review summarizes current data on the structure and functions of myosin essential light chains (ELCs) and on their role in functioning of the myosin head as a molecular motor. The data on structural and functional features of the N-terminal extension of myosin ELC from skeletal and cardiac muscles are analyzed; the role of this extension in the ATP-dependent interaction of myosin heads with actin in the molecular mechanism of muscle contraction is discussed. The data on possible interactions of the ELC N-terminal extension with the myosin head motor domain in the myosin ATPase cycle are presented, including the results of the authors' studies that are in favor of such interactions.

Published

2018

28. Functional role of the core gap in the middle part of tropomyosin.

Author

Matyushenko AM, Shchepkin DV, Kopylova GV, Bershitsky SY, Koubassova NA, Tsaturyan AK, and Levitsky DI

Subjects

Actin Cytoskeleton physiology, Actins metabolism, Calcium pharmacology, Humans, Molecular Dynamics Simulation, Motion, Mutation, Missense, Point Mutation, Protein Binding, Protein Domains, Protein Folding, Protein Stability, Protein Structure, Secondary, Recombinant Proteins chemistry, Temperature, Tropomyosin genetics, Tropomyosin physiology, Amino Acid Substitution, Tropomyosin chemistry

Abstract

Tropomyosin (Tpm) is an α-helical coiled-coil actin-binding protein playing an essential role in the regulation of muscle contraction. The middle part of the Tpm molecule has some specific features, such as the presence of noncanonical residues as well as a substantial gap at the interhelical interface, which are believed to destabilize a coiled-coil and impart structural flexibility to this part of the molecule. To study how the gap affects structural and functional properties of α-striated Tpm (the Tpm1.1 isoform that is expressed in cardiac and skeletal muscles) we replaced large conserved apolar core residues located at both sides of the gap with smaller ones by mutations M127A/I130A and M141A/Q144A. We found that in contrast with the stabilizing substitutions D137L and G126R studied earlier, these substitutions have no appreciable influence on thermal unfolding and domain structure of the Tpm molecule. They also do not affect actin-binding properties of Tpm. However, they strongly increase sliding velocity of regulated actin filaments in an in vitro motility assay and cause an oversensitivity of the velocity to Ca 2+ similar to the stabilizing substitutions D137L and G126R. Molecular dynamics shows that the substitutions studied here increase bending stiffness of the coiled-coil structure of Tpm, like that of G126R/D137L, probably due to closure of the interhelical gap in the area of the substitutions. Our results clearly indicate that the conserved middle part of Tpm is important for the fine tuning of the Ca 2+ regulation of actin-myosin interaction in muscle., (© 2017 Federation of European Biochemical Societies.)

Published

2018

29. Transient interaction between the N-terminal extension of the essential light chain-1 and motor domain of the myosin head during the ATPase cycle.

Author

Logvinova DS, Matyushenko AM, Nikolaeva OP, and Levitsky DI

Subjects

Adenosine Triphosphate metabolism, Catalytic Domain, Fluorescence Resonance Energy Transfer, Humans, Models, Molecular, Myosin Light Chains chemistry, Myosin Subfragments chemistry, Myosins metabolism, Protein Conformation, Protein Domains, Adenosine Triphosphatases metabolism, Myosin Light Chains metabolism, Myosin Subfragments metabolism

Abstract

The molecular mechanism of muscle contraction is based on the ATP-dependent cyclic interaction of myosin heads with actin filaments. Myosin head (myosin subfragment-1, S1) consists of two major domains, the motor domain responsible for ATP hydrolysis and actin binding, and the regulatory domain stabilized by light chains. Essential light chain-1 (LC1) is of particular interest since it comprises a unique N-terminal extension (NTE) which can bind to actin thus forming an additional actin-binding site on the myosin head and modulating its motor activity. However, it remains unknown what happens to the NTE of LC1 when the head binds ATP during ATPase cycle and dissociates from actin. We assume that in this state of the head, when it undergoes global ATP-induced conformational changes, the NTE of LC1 can interact with the motor domain. To test this hypothesis, we applied fluorescence resonance energy transfer (FRET) to measure the distances from various sites on the NTE of LC1 to S1 active site in the motor domain and changes in these distances upon formation of S1-ADP-BeF x complex (stable analog of S1 ∗ -AТP state). For this, we produced recombinant LC1 cysteine mutants, which were first fluorescently labeled with 1,5-IAEDANS (donor) at different positions in their NTE and then introduced into S1; the ADP analog (TNP-ADP) bound to the S1 active site was used as an acceptor. The results show that formation of S1-ADP-BeF x complex significantly decreases the distances from Cys residues in the NTE of LC1 to TNP-ADP in the S1 active site; this effect was the most pronounced for Cys residues located near the LC1 N-terminus. These results support the concept of the ATP-induced transient interaction of the LC1 N-terminus with the S1 motor domain., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2018

30. Cooperativity of myosin interaction with thin filaments is enhanced by stabilizing substitutions in tropomyosin.

Author

Shchepkin DV, Nabiev SR, Kopylova GV, Matyushenko AM, Levitsky DI, Bershitsky SY, and Tsaturyan AK

Subjects

Humans, Muscle Contraction, Actin Cytoskeleton metabolism, Muscle, Skeletal metabolism, Myosins metabolism, Tropomyosin metabolism

Abstract

Muscle contraction is powered by myosin interaction with actin-based thin filaments containing Ca 2+ -regulatory proteins, tropomyosin and troponin. Coiled-coil tropomyosin molecules form a long helical strand that winds around actin filament and either shields actin from myosin binding or opens it. Non-canonical residues G126 and D137 in the central part of tropomyosin destabilize its coiled-coil structure. Their substitutions for canonical ones, G126R and D137L, increase structural stability and the velocity of sliding of reconstructed thin filaments along myosin coated surface. The effect of these stabilizing mutations on force of the actin-myosin interaction is unknown. It also remains unclear whether the stabilization affects single actin-myosin interactions or it modifies the cooperativity of the binding of myosin molecules to actin. We used an optical trap to measure the effects of the stabilization on step size, unitary force and duration of the interactions at low and high load and compared the results with those obtained in an in vitro motility assay. We found that significant prolongation of lifetime of the actin-myosin complex under high load observed at high extent of tropomyosin stabilization, i.e. with double mutant, G126R/D137L, correlates with higher force in the motility assay. Also, the higher the extent of stabilization of tropomyosin, the fewer myosin molecules are needed to propel the thin filaments. The data suggest that the effects of the stabilizing mutations in tropomyosin on the myosin interaction with regulated thin filaments are mainly realized via cooperative mechanisms by increasing the size of cooperative unit.

Published

2017

31. Intermolecular Interactions of Myosin Subfragment 1 Induced by the N-Terminal Extension of Essential Light Chain 1.

Author

Logvinova DS, Nikolaeva OP, and Levitsky DI

Subjects

Animals, Protein Isoforms chemistry, Rabbits, Myosin Light Chains chemistry

Abstract

We applied dynamic light scattering (DLS) to compare aggregation properties of two isoforms of myosin subfragment 1 (S1) containing different "essential" (or "alkali") light chains, A1 or A2, which differ by the presence of an N-terminal extension in A1. Upon mild heating (up to 40°C), which was not accompanied by thermal denaturation of the protein, we observed a significant growth in the hydrodynamic radius of the particles for S1(A1), from ~18 to ~600-700 nm, whereas the radius of S1(A2) remained unchanged and equal to ~18 nm. Similar difference between S1(A1) and S1(A2) was observed in the presence of ADP. In contrast, no differences were observed by DLS between these two S1 isoforms in their complexes S1-ADP-BeF x and S1-ADP-AlF 4 - which mimic the S1 ATPase intermediate states S1*-ATP and S1**-ADP-P i . We propose that during the ATPase cycle the A1 N-terminal extension can interact with the motor domain of the same S1 molecule, and this can explain why S1(A1) and S1(A2) in S1-ADP-BeF x and S1-ADP-AlF 4 - complexes do not differ in their aggregation properties. In the absence of nucleotides (or in the presence of ADP), the A1 N-terminal extension can interact with actin, thus forming an additional actin-binding site on the myosin head. However, in the absence of actin, this extension seems to be unable to undergo intramolecular interaction, but it probably can interact with the motor domain of another S1 molecule. These intermolecular interactions of the A1 N-terminus can explain unusual aggregation properties of S1(A1).

Published

2017

32. The Relaxation Properties of Myofibrils Are Compromised by Amino Acids that Stabilize α-Tropomyosin.

Author

Scellini B, Piroddi N, Matyushenko AM, Levitsky DI, Poggesi C, Lehrer SS, and Tesi C

Subjects

Animals, Calcium metabolism, Humans, Myofibrils drug effects, Myofibrils metabolism, Protein Stability, Psoas Muscles cytology, Psoas Muscles physiology, Rabbits, Sequence Deletion, Tropomyosin genetics, Tropomyosin pharmacology, Troponin I genetics, Troponin I metabolism, Amino Acid Substitution, Muscle Relaxation drug effects, Myofibrils physiology, Tropomyosin chemistry, Tropomyosin metabolism

Abstract

We investigated the functional impact of α-tropomyosin (Tm) substituted with one (D137L) or two (D137L/G126R) stabilizing amino acid substitutions on the mechanical behavior of rabbit psoas skeletal myofibrils by replacing endogenous Tm and troponin (Tn) with recombinant Tm mutants and purified skeletal Tn. Force recordings from myofibrils (15°C) at saturating [Ca 2+ ] showed that Tm-stabilizing substitutions did not significantly affect the maximal isometric tension and the rates of force activation (k ACT ) and redevelopment (k TR ). However, a clear effect was observed on force relaxation: myofibrils with D137L/G126R or D137L Tm showed prolonged durations of the slow phase of relaxation and decreased rates of the fast phase. Both Tm-stabilizing substitutions strongly decreased the slack sarcomere length (SL) at submaximal activating [Ca 2+ ] and increased the steepness of the SL-passive tension relation. These effects were reversed by addition of 10 mM 2,3-butanedione 2-monoxime. Myofibrils also showed an apparent increase in Ca 2+ sensitivity. Measurements of myofibrillar ATPase activity in the absence of Ca 2+ showed a significant increase in the presence of these Tms, indicating that single and double stabilizing substitutions compromise the full inhibition of contraction in the relaxed state. These data can be understood with the three-state (blocked-closed-open) theory of muscle regulation, according to which the mutations increase the contribution of the active open state in the absence of Ca 2+ (M - ). Force measurements on myofibrils substituted with C-terminal truncated TnI showed similar compromised relaxation effects, indicating the importance of TnI-Tm interactions in maintaining the blocked state. It appears that reducing the flexibility of native Tm coiled-coil structure decreases the optimum interactions of the central part of Tm with the C-terminal region of TnI. This results in a shift away from the blocked state, allowing myosin binding and activity in the absence of Ca 2+ . This work provides a basis for understanding the effects of disease-producing mutations in muscle proteins., (Copyright © 2017. Published by Elsevier Inc.)

Published

2017

33. Structural and Functional Effects of Cardiomyopathy-Causing Mutations in the Troponin T-Binding Region of Cardiac Tropomyosin.

Author

Matyushenko AM, Shchepkin DV, Kopylova GV, Popruga KE, Artemova NV, Pivovarova AV, Bershitsky SY, and Levitsky DI

Subjects

Actin Cytoskeleton metabolism, Actins chemistry, Actins metabolism, Binding Sites genetics, Calcium metabolism, Calorimetry methods, Cardiomyopathy, Hypertrophic metabolism, Circular Dichroism, Humans, Myocardium metabolism, Protein Binding, Protein Domains, Protein Stability, Protein Unfolding, Temperature, Tropomyosin chemistry, Tropomyosin metabolism, Troponin T metabolism, Cardiomyopathy, Hypertrophic genetics, Genetic Predisposition to Disease genetics, Mutation, Missense, Tropomyosin genetics

Abstract

Hypertrophic cardiomyopathy (HCM) is a severe heart disease caused by missense mutations in genes encoding sarcomeric proteins of cardiac muscle. Many of these mutations are identified in the gene encoding the cardiac isoform of tropomyosin (Tpm), an α-helical coiled-coil actin-binding protein that plays a key role in Ca 2+ -regulated contraction of cardiac muscle. We employed various methods to characterize structural and functional features of recombinant human Tpm species carrying HCM mutations that lie either within the troponin T-binding region in the C-terminal part of Tpm (E180G, E180V, and L185R) or near this region (I172T). The results of our structural studies show that all these mutations affect, although differently, the thermal stability of the C-terminal part of the Tpm molecule: mutations E180G and I172T destabilize this part of the molecule, whereas mutation E180V strongly stabilizes it. Moreover, various HCM-causing mutations have different and even opposite effects on the stability of the Tpm-actin complexes. Studies of reconstituted thin filaments in the in vitro motility assay have shown that those HCM-associated mutations that lie within the troponin T-binding region of Tpm similarly increase the Ca 2+ sensitivity of the sliding velocity of the filaments and impair their relaxation properties, causing a marked increase in the sliding velocity in the absence of Ca 2+ , while mutation I172T decreases the Ca 2+ sensitivity and has no influence on the sliding velocity under relaxing conditions. Finally, our data demonstrate that various HCM mutations can differently affect the structural and functional properties of Tpm and cause HCM by different molecular mechanisms.

Published

2017

34. The interchain disulfide cross-linking of tropomyosin alters its regulatory properties and interaction with actin filament.

Author

Matyushenko AM, Artemova NV, Shchepkin DV, Kopylova GV, Nabiev SR, Nikitina LV, Levitsky DI, and Bershitsky SY

Subjects

Animals, Binding Sites, Cross-Linking Reagents, Elastic Modulus, Motion, Protein Binding, Protein Domains, Rabbits, Actin Cytoskeleton chemistry, Calcium chemistry, Disulfides chemistry, Molecular Motor Proteins chemistry, Tropomyosin chemistry

Abstract

Tropomyosin (Tpm) is an α-helical coiled-coil actin-binding protein that plays a key role in the Ca 2+ -regulated contraction of striated muscles. Two chains of Tpm can be cross-linked by formation of a disulfide bond between Cys-190 residues. Normally, the SH-groups of these residues in cardiac muscle are in reduced state but in heart pathologies the interchain cross-linking of Tpm was shown to occur. Previous studies have shown that this cross-linking increases the thermal stability of the C-terminal part of the Tpm molecule. However it was unclear how this affects its functional properties. In the current work, we studied functional features of cross-linked Tpm at the level of isolated proteins. The results have shown that the cross-linking greatly decreases affinity of Tpm for F-actin and stability of the Tpm-F-actin complex. It also increases sliding velocity of regulated thin filaments in an in vitro motility assay. This last effect was mostly pronounced when cardiac isoforms of myosin and troponin were used instead of skeletal ones. The results indicate that cross-linking significantly affects properties of Tpm and actin-myosin interaction and can explain, at least partly, the role of the interchain disulfide cross-linking of cardiac Tpm in human heart diseases., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2017

35. High-yield soluble expression, purification and characterization of human steroidogenic acute regulatory protein (StAR) fused to a cleavable Maltose-Binding Protein (MBP).

Author

Sluchanko NN, Tugaeva KV, Faletrov YV, and Levitsky DI

Subjects

Amino Acid Sequence, Cholesterol chemistry, Chromatography, Affinity, Cloning, Molecular, Escherichia coli, Gene Expression, Humans, Maltose-Binding Proteins chemistry, Maltose-Binding Proteins genetics, Maltose-Binding Proteins isolation & purification, Molecular Sequence Data, Phosphoproteins chemistry, Phosphoproteins genetics, Phosphoproteins isolation & purification, Protein Binding, Solubility, Steroidogenic Acute Regulatory Protein, Maltose-Binding Proteins biosynthesis, Phosphoproteins biosynthesis

Abstract

Steroidogenic acute regulatory protein (StAR) is responsible for the rapid delivery of cholesterol to mitochondria where the lipid serves as a source for steroid hormones biosynthesis in adrenals and gonads. Despite many successful investigations, current understanding of the mechanism of StAR action is far from being completely clear. StAR was mostly obtained using denaturation/renaturation or in minor quantities in a soluble form at decreased temperatures that, presumably, limited the possibilities for its consequent detailed exploration. In our hands, existing StAR expression constructs could be bacterially expressed almost exclusively as insoluble forms, even upon decreased expression temperatures and in specific strains of Escherichia coli, and isolated protein tended to aggregate and was difficult to handle. To maximize the yield of soluble protein, optimized StAR sequence encompassing functional domain STARD1 (residues 66-285) was fused to the C-terminus of His-tagged Maltose-Binding Protein (MBP) with the possibility to cleave off the whole tag by 3C protease. The developed protocol of expression and purification comprising of a combination of subtractive immobilized metal affinity chromatography (IMAC) and size-exclusion chromatography allowed us to obtain up to 25 mg/1 L culture of completely soluble StAR protein, which was (i) homogenous according to SDS-PAGE, (ii) gave a single symmetrical peak on a gel-filtration, (iii) showed the characteristic CD spectrum and (iv) pH-dependent ability to bind a fluorescently-labeled cholesterol analogue. We conclude that our strategy provides fully soluble and native StAR protein which in future could be efficiently used for biotechnology and drug discovery aimed at modulation of steroids production., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2016

36. Does Interaction between the Motor and Regulatory Domains of the Myosin Head Occur during ATPase Cycle? Evidence from Thermal Unfolding Studies on Myosin Subfragment 1.

Author

Logvinova DS, Markov DI, Nikolaeva OP, Sluchanko NN, Ushakov DS, and Levitsky DI

Subjects

Adenosine Diphosphate metabolism, Animals, Calorimetry, Differential Scanning, Fluorescence, Humans, Models, Molecular, Protein Binding, Protein Denaturation, Protein Structure, Tertiary, Rabbits, Temperature, Tryptophan metabolism, Adenosine Triphosphatases metabolism, Myosin Subfragments chemistry, Myosin Subfragments metabolism, Protein Unfolding

Abstract

Myosin head (myosin subfragment 1, S1) consists of two major structural domains, the motor (or catalytic) domain and the regulatory domain. Functioning of the myosin head as a molecular motor is believed to involve a rotation of the regulatory domain (lever arm) relative to the motor domain during the ATPase cycle. According to predictions, this rotation can be accompanied by an interaction between the motor domain and the C-terminus of the essential light chain (ELC) associated with the regulatory domain. To check this assumption, we applied differential scanning calorimetry (DSC) combined with temperature dependences of fluorescence to study changes in thermal unfolding and the domain structure of S1, which occur upon formation of the ternary complexes S1-ADP-AlF4- and S1-ADP-BeFx that mimic S1 ATPase intermediate states S1**-ADP-Pi and S1*-ATP, respectively. To identify the thermal transitions on the DSC profiles (i.e. to assign them to the structural domains of S1), we compared the DSC data with temperature-induced changes in fluorescence of either tryptophan residues, located only in the motor domain, or recombinant ELC mutants (light chain 1 isoform), which were first fluorescently labeled at different positions in their C-terminal half and then introduced into the S1 regulatory domain. We show that formation of the ternary complexes S1-ADP-AlF4- and S1-ADP-BeFx significantly stabilizes not only the motor domain, but also the regulatory domain of the S1 molecule implying interdomain interaction via ELC. This is consistent with the previously proposed concepts and also adds some new interesting details to the molecular mechanism of the myosin ATPase cycle.

Published

2015

37. Stabilizing the central part of tropomyosin increases the bending stiffness of the thin filament.

Author

Nabiev SR, Ovsyannikov DA, Kopylova GV, Shchepkin DV, Matyushenko AM, Koubassova NA, Levitsky DI, Tsaturyan AK, and Bershitsky SY

Subjects

Animals, Elasticity, Humans, Microscopy, Fluorescence, Muscle, Skeletal, Optical Tweezers, Protein Conformation, Rabbits, Recombinant Proteins chemistry, Recombinant Proteins genetics, Tropomyosin genetics, Actins chemistry, Tropomyosin chemistry

Abstract

A two-beam optical trap was used to measure the bending stiffness of F-actin and reconstructed thin filaments. A dumbbell was formed by a filament segment attached to two beads that were held in the two optical traps. One trap was static and held a bead used as a force transducer, whereas an acoustooptical deflector moved the beam holding the second bead, causing stretch of the dumbbell. The distance between the beads was measured using image analysis of micrographs. An exact solution to the problem of bending of an elastic filament attached to two beads and subjected to a stretch was used for data analysis. Substitution of noncanonical residues in the central part of tropomyosin with canonical ones, G126R and D137L, and especially their combination, caused an increase in the bending stiffness of the thin filaments. The data confirm that the effect of these mutations on the regulation of actin-myosin interactions may be caused by an increase in tropomyosin stiffness., (Copyright © 2015 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2015

38. Effects of two stabilizing substitutions, D137L and G126R, in the middle part of α-tropomyosin on the domain structure of its molecule.

Author

Matyushenko AM, Artemova NV, Sluchanko NN, and Levitsky DI

Subjects

Amino Acid Substitution, Calorimetry, Differential Scanning, Protein Structure, Tertiary, Protein Unfolding, Pyrenes chemistry, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins genetics, Spectrometry, Fluorescence, Transition Temperature, Tropomyosin genetics, Tropomyosin metabolism, Tropomyosin chemistry

Abstract

We applied differential scanning calorimetry (DSC) to investigate the effects of substitutions D137L and G126R (i.e. replacement of conserved non-canonical residues Asp137 and Gly126 by canonical ones) in the middle part of tropomyosin (Tm), as well as the combined one, D137L/G126R, on the thermal unfolding of Tm. Special approaches (e.g. combination of DSC with measurements of temperature dependences of pyrene excimer fluorescence) were applied to assign separate thermal transitions (calorimetric domains) on the DSC profiles to the certain parts of Tm molecule. The results show that substitutions D137L and G126R (and, especially, the combined one, D137L/G126R) may stabilize not only the middle region of Tm, but also the other parts of its molecule including N- and C-terminal parts. These results suggest that the stabilization of the Tm middle part can be transmitted along the coiled-coil length displaying long-range effects., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2015

39. Structural and functional effects of two stabilizing substitutions, D137L and G126R, in the middle part of α-tropomyosin molecule.

Author

Matyushenko AM, Artemova NV, Shchepkin DV, Kopylova GV, Bershitsky SY, Tsaturyan AK, Sluchanko NN, and Levitsky DI

Subjects

Actins chemistry, Actins metabolism, Calcium chemistry, Calcium metabolism, Myosins chemistry, Myosins metabolism, Protein Structure, Secondary, Protein Structure, Tertiary, Tropomyosin genetics, Tropomyosin chemistry, Tropomyosin metabolism

Abstract

Tropomyosin (Tm) is an α-helical coiled-coil protein that binds along the length of actin filament and plays an essential role in the regulation of muscle contraction. There are two highly conserved non-canonical residues in the middle part of the Tm molecule, Asp137 and Gly126, which are thought to impart conformational instability (flexibility) to this region of Tm which is considered crucial for its regulatory functions. It was shown previously that replacement of these residues by canonical ones (Leu substitution for Asp137 and Arg substitution for Gly126) results in stabilization of the coiled-coil in the middle of Tm and affects its regulatory function. Here we employed various methods to compare structural and functional features of Tm mutants carrying stabilizing substitutions Arg137Leu and Gly126Arg. Moreover, we for the first time analyzed the properties of Tm carrying both these substitutions within the same molecule. The results show that both substitutions similarly stabilize the Tm coiled-coil structure, and their combined action leads to further significant stabilization of the Tm molecule. This stabilization not only enhances maximal sliding velocity of regulated actin filaments in the in vitro motility assay at high Ca(2+) concentrations but also increases Ca(2+) sensitivity of the actin-myosin interaction underlying this sliding. We propose that the effects of these substitutions on the Ca(2+)-regulated actin-myosin interaction can be accounted for not only by decreased flexibility of actin-bound Tm but also by their influence on the interactions between the middle part of Tm and certain sites of the myosin head., (© 2014 FEBS.)

Published

2014

40. Gly126Arg substitution causes anomalous behaviour of α-skeletal and β-smooth tropomyosins during the ATPase cycle.

Author

Rysev NA, Nevzorov IA, Avrova SV, Karpicheva OE, Redwood CS, Levitsky DI, and Borovikov YS

Subjects

Actins metabolism, Fluorescein-5-isothiocyanate metabolism, Fluoresceins metabolism, Humans, Phalloidine metabolism, Protein Structure, Secondary, Tropomyosin chemistry, Adenosine Triphosphatases metabolism, Amino Acid Substitution, Muscle, Skeletal metabolism, Muscle, Smooth metabolism, Mutation, Tropomyosin genetics, Tropomyosin metabolism

Abstract

To investigate how TM stabilization induced by the Gly126Arg mutation in skeletal α-TM or in smooth muscle β-TM affects the flexibility of TMs and their position on troponin-free thin filaments, we labelled the recombinant wild type and mutant TMs with 5-IAF and F-actin with FITC-phalloidin, incorporated them into ghost muscle fibres and studied polarized fluorescence at different stages of the ATPase cycle. It has been shown that in the myosin- and troponin-free filaments the Gly126Arg mutation causes a shift of TM strands towards the outer domain of actin, reduces the number of switched on actin monomers and decreases the rigidity of the C-terminus of α-TM and increases the rigidity of the N-terminus of β-TMs. The binding of myosin subfragment-1 to the filaments shifted the wild type TMs towards the inner domain of actin, decreased the flexibility of both terminal parts of TMs, and increased the number of switched on actin monomers. Multistep alterations in the position of α- and β-TMs and actin monomers in the filaments and in the flexibility of TMs and F-actin during the ATPase cycle were observed. The Gly126Arg mutation uncouples a correlation between the position of TM and the number of the switched on actin monomers in the filaments., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2014

41. Stabilization of the Central Part of Tropomyosin Molecule Alters the Ca2+-sensitivity of Actin-Myosin Interaction.

Author

Shchepkin DV, Matyushenko AM, Kopylova GV, Artemova NV, Bershitsky SY, Tsaturyan AK, and Levitsky DI

Abstract

We show that the mutations D137L and G126R, which stabilize the central part of the tropomyosin (Tm) molecule, increase both the maximal sliding velocity of the regulated actin filaments in the in vitro motility assay at high Са(2+) concentrations and the Са(2+)-sensitivity of the actin-myosin interaction underlying this sliding. Based on an analysis of the recently published data on the structure of the actin-Tm-myosin complex, we suppose that the physiological effects of these mutations in Tm can be accounted for by their influence on the interactions between the central part of Tm and certain sites of the myosin head.

Published

2013

42. Effects of actin-binding proteins on the thermal stability of monomeric actin.

Author

Pivovarova AV, Chebotareva NA, Kremneva EV, Lappalainen P, and Levitsky DI

Subjects

Actin Depolymerizing Factors metabolism, Actins chemistry, Adenosine Diphosphate chemistry, Adenosine Diphosphate metabolism, Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, Animals, Calorimetry, Differential Scanning, Profilins metabolism, Protein Multimerization, Protein Stability, Protein Unfolding, Rabbits, Temperature, Actins metabolism, Adenosine Diphosphate analogs & derivatives, Adenosine Triphosphate analogs & derivatives, Microfilament Proteins metabolism

Abstract

Differential scanning calorimetry (DSC) was applied to investigate the thermal unfolding of rabbit skeletal muscle G-actin in its complexes with actin-binding proteins, cofilin, twinfilin, and profilin. The results show that the effects of these proteins on the thermal stability of G-actin depend on the nucleotide, ATP or ADP, bound in the nucleotide-binding cleft between actin subdomains 2 and 4. Interestingly, cofilin binding stabilizes both ATP-G-actin and ADP-G-actin, whereas twinfilin increases the thermal stability of the ADP-G-actin but not that of the ATP-G-actin. By contrast, profilin strongly decreases the thermal stability of the ATP-G-actin but has no appreciable effect on the ADP-G-actin. Comparison of these DSC results with literature data reveals a relationship between the effects of actin-binding proteins on the thermal unfolding of G-actin, stabilization or destabilization, and their effects on the rate of nucleotide exchange in the nucleotide-binding cleft, decrease or increase. These results suggest that the thermal stability of G-actin depends, at least partially, on the conformation of the nucleotide-binding cleft: the actin molecule is more stable when the cleft is closed, while an opening of the cleft leads to significant destabilization of G-actin. Thus, DSC studies of the thermal unfolding of G-actin can provide new valuable information about the conformational changes induced by actin-binding proteins in the actin molecule.

Published

2013

43. Monomeric 14-3-3ζ has a chaperone-like activity and is stabilized by phosphorylated HspB6.

Author

Sluchanko NN, Artemova NV, Sudnitsyna MV, Safenkova IV, Antson AA, Levitsky DI, and Gusev NB

Subjects

Chymotrypsin metabolism, HSP20 Heat-Shock Proteins genetics, Hot Temperature, Humans, Mutagenesis, Site-Directed, Mutation, Myosin Subfragments chemistry, Phosphates pharmacology, Phosphoproteins genetics, Phosphorylation, Protein Multimerization, Protein Stability, Protein Structure, Quaternary, Proteolysis drug effects, 14-3-3 Proteins chemistry, 14-3-3 Proteins metabolism, HSP20 Heat-Shock Proteins metabolism, Phosphoproteins metabolism

Abstract

Members of the 14-3-3 eukaryotic protein family predominantly function as dimers. The dimeric form can be converted into monomers upon phosphorylation of Ser(58) located at the subunit interface. Monomers are less stable than dimers and have been considered to be either less active or even inactive during binding and regulation of phosphorylated client proteins. However, like dimers, monomers contain the phosphoserine-binding site and therefore can retain some functions of the dimeric 14-3-3. Furthermore, 14-3-3 monomers may possess additional functional roles owing to their exposed intersubunit surfaces. Previously we have found that the monomeric mutant of 14-3-3ζ (14-3-3ζ(m)), like the wild type protein, is able to bind phosphorylated small heat shock protein HspB6 (pHspB6), which is involved in the regulation of smooth muscle contraction and cardioprotection. Here we report characterization of the 14-3-3ζ(m)/pHspB6 complex by biophysical and biochemical techniques. We find that formation of the complex retards proteolytic degradation and increases thermal stability of the monomeric 14-3-3, indicating that interaction with phosphorylated targets could be a general mechanism of 14-3-3 monomers stabilization. Furthermore, by using myosin subfragment 1 (S1) as a model substrate we find that the monomer has significantly higher chaperone-like activity than either the dimeric 14-3-3ζ protein or even HspB6 itself. These observations indicate that 14-3-3ζ and possibly other 14-3-3 isoforms may have additional functional roles conducted by the monomeric state.

Published

2012

44. Tropomyosin: double helix from the protein world.

Author

Nevzorov IA and Levitsky DI

Subjects

Actin Cytoskeleton metabolism, Animals, Humans, Muscle Contraction, Muscles chemistry, Muscles metabolism, Muscles physiology, Organ Specificity, Protein Binding, Protein Conformation, Protein Isoforms chemistry, Protein Isoforms metabolism, Protein Isoforms physiology, Protein Stability, Tropomyosin metabolism, Tropomyosin physiology, Tropomyosin chemistry

Abstract

This review concerns the structure and functions of tropomyosin (TM), an actin-binding protein that plays a key role in the regulation of muscle contraction. The TM molecule is a dimer of α-helices, which form a coiled-coil. Recent views on the TM structure are analyzed, and special attention is concentrated on those structural traits of the TM molecule that distinguish it from the other coiled-coil proteins. Modern data are presented on TM functional properties, such as its interaction with actin and ability to move on the surface of actin filaments, which underlies the regulation of the actin-myosin interaction upon contraction of skeletal and cardiac muscles. Also, part of the review is devoted to analysis of the effects of mutations in TM genes associated with muscle diseases (myopathies) on the structure and functions of TM.

Published

2011

45. Conserved noncanonical residue Gly-126 confers instability to the middle part of the tropomyosin molecule.

Author

Nevzorov IA, Nikolaeva OP, Kainov YA, Redwood CS, and Levitsky DI

Subjects

Amino Acid Substitution, Glycine genetics, Glycine metabolism, Humans, Mutation, Missense, Protein Stability, Protein Structure, Secondary, Tropomyosin genetics, Tropomyosin metabolism, Glycine chemistry, Protein Folding, Tropomyosin chemistry

Abstract

Tropomyosin (Tm) is a two-stranded α-helical coiled-coil protein with a well established role in regulation of actin cytoskeleton and muscle contraction. It is believed that many Tm functions are enabled by its flexibility whose nature has not been completely understood. We hypothesized that the well conserved non-canonical residue Gly-126 causes local destabilization of Tm. To test this, we substituted Gly-126 in skeletal muscle α-Tm either with an Ala residue, which should stabilize the Tm α-helix, or with an Arg residue, which is expected to stabilize both α-helix and coiled-coil structure of Tm. We have shown that both mutations dramatically reduce the rate of Tm proteolysis by trypsin at Asp-133. Differential scanning calorimetry was used for detailed investigation of thermal unfolding of the Tm mutants, both free in solution and bound to F-actin. It was shown that a significant part of wild type Tm unfolds in a non-cooperative manner at low temperature, and both mutations confer cooperativity to this part of the Tm molecule. The size of the flexible middle part of Tm is estimated to be 60-70 amino acid residues, about a quarter of the Tm molecule. Thus, our results show that flexibility is unevenly distributed in the Tm molecule and achieves the highest extent in its middle part. We conclude that the highly conserved Gly-126, acting in concert with the previously identified non-canonical Asp-137, destabilizes the middle part of Tm, resulting in a more flexible region that is important for Tm function.

Published

2011

46. Thermal denaturation and aggregation of myosin subfragment 1 isoforms with different essential light chains.

Author

Markov DI, Zubov EO, Nikolaeva OP, Kurganov BI, and Levitsky DI

Subjects

Animals, Humans, Polymerization, Protein Isoforms chemistry, Protein Stability, Temperature, Models, Biological, Myosin Light Chains chemistry, Myosin Subfragments chemistry, Protein Denaturation

Abstract

We compared thermally induced denaturation and aggregation of two isoforms of the isolated myosin head (myosin subfragment 1, S1) containing different "essential" (or "alkali") light chains, A1 or A2. We applied differential scanning calorimetry (DSC) to investigate the domain structure of these two S1 isoforms. For this purpose, a special calorimetric approach was developed to analyze the DSC profiles of irreversibly denaturing multidomain proteins. Using this approach, we revealed two calorimetric domains in the S1 molecule, the more thermostable domain denaturing in two steps. Comparing the DSC data with temperature dependences of intrinsic fluorescence parameters and S1 ATPase inactivation, we have identified these two calorimetric domains as motor domain and regulatory domain of the myosin head, the motor domain being more thermostable. Some difference between the two S1 isoforms was only revealed by DSC in thermal denaturation of the regulatory domain. We also applied dynamic light scattering (DLS) to analyze the aggregation of S1 isoforms induced by their thermal denaturation. We have found no appreciable difference between these S1 isoforms in their aggregation properties under ionic strength conditions close to those in the muscle fiber (in the presence of 100 mM KCl). Under these conditions kinetics of this process was independent of protein concentration, and the aggregation rate was limited by irreversible denaturation of the S1 motor domain.

Published

2010

47. Specific cleavage of the DNase-I binding loop dramatically decreases the thermal stability of actin.

Author

Pivovarova AV, Khaitlina SY, and Levitsky DI

Subjects

Actin Cytoskeleton metabolism, Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Aluminum Compounds metabolism, Animals, Calorimetry, Differential Scanning, Cations, Divalent metabolism, Fluorides metabolism, Hot Temperature adverse effects, Ligands, Phalloidine metabolism, Protein Conformation, Protein Stability, Rabbits, Substrate Specificity, Transition Temperature, Actin Cytoskeleton chemistry, Actins chemistry, Actins metabolism, Endopeptidases metabolism, Protein Interaction Domains and Motifs, Protein Unfolding, Subtilisin metabolism

Abstract

Differential scanning calorimetry was used to investigate the thermal unfolding of actin specifically cleaved within the DNaseI-binding loop between residues Met47-Gly48 or Gly42-Val43 by two bacterial proteases, subtilisin or ECP32/grimelysin (ECP), respectively. The results obtained show that both cleavages strongly decreased the thermal stability of monomeric actin with either ATP or ADP as a bound nucleotide. An even more pronounced difference in the thermal stability between the cleaved and intact actin was observed when both actins were polymerized into filaments. Similar to intact F-actin, both cleaved F-actins were significantly stabilized by phalloidin and aluminum fluoride; however, in all cases, the thermal stability of the cleaved F-actins was much lower than that of intact F-actin, and the stability of ECP-cleaved F-actin was lower than that of subtilisin-cleaved F-actin. These results confirm that the DNaseI-binding loop is involved in the stabilization of the actin structure, both in monomers and in the filament subunits, and suggest that the thermal stability of actin depends, at least partially, on the conformation of the nucleotide-binding cleft. Moreover, an additional destabilization of the unstable cleaved actin upon ATP/ADP replacement provides experimental evidence for the highly dynamic actin structure that cannot be simply open or closed, but rather should be considered as being able to adopt multiple conformations., (© 2010 The Authors Journal compilation © 2010 FEBS.)

Published

2010

48. Effects of Myosin "essential" light chain A1 on the aggregation properties of the Myosin head.

Author

Markov DI, Nikolaeva OP, and Levitsky DI

Abstract

We compared the thermal aggregation properties of two isoforms of the isolated myosin head (myosin subfragment 1, S1) containing different "essential" (or "alkali") light chains, A1 or A2. Temperature dependencies for the aggregation of these two S1 isoforms, as measured by the increase in turbidity, were compared with the temperature dependencies of their thermal denaturation obtained from differential scanning calorimetry (DSC) experiments. At relatively high ionic strength (in the presence of 100 mM KCl) close to its physiological values in muscle fibers, we have found no appreciable difference between the two S1 isoforms in their thermally induced aggregation. Under these conditions, the aggregation of both S1 isoforms was independent of the protein concentration and resulted from their irreversible denaturation, which led to the cohesion of denatured S1 molecules. In contrast, a significant difference between these S1 isoforms was revealed in their aggregation measured at low ionic strength. Under these conditions, the aggregation of S1 containing a light chain A1 (but not A2) was strongly dependent on protein concentration, the increase of which (from 0.125 to 2.0 mg/ml) shifted the aggregation curve by ~10 degrees towards the lower temperatures. It has been concluded that the aggregation properties of this S1 isoform at low ionic strength is basically determined by intermolecular interactions of the N-terminal extension of the A1 light chain (which is absent in the A2 light chain) with other S1 molecules. These interactions seem to be independent of the S1 thermal denaturation, and they may take place even at low temperature.

Published

2010

49. Thermally induced structural changes of intrinsically disordered small heat shock protein Hsp22.

Author

Kazakov AS, Markov DI, Gusev NB, and Levitsky DI

Subjects

Actins metabolism, Calorimetry, Differential Scanning, Heat-Shock Proteins genetics, Heat-Shock Proteins metabolism, Heat-Shock Proteins pharmacology, Humans, Molecular Chaperones, Mutation, Protein Binding drug effects, Protein Denaturation, Protein Folding, Protein Serine-Threonine Kinases genetics, Protein Serine-Threonine Kinases metabolism, Protein Serine-Threonine Kinases pharmacology, Protein Structure, Secondary, Protein Structure, Tertiary, alpha-Crystallins chemistry, Heat-Shock Proteins chemistry, Hot Temperature, Protein Serine-Threonine Kinases chemistry

Abstract

We applied different methods (differential scanning calorimetry, circular dichroism, Fourier transform infrared spectroscopy, and intrinsic fluorescence) to investigate the thermal-induced changes in the structure of small heat shock protein Hsp22. It has been shown that this protein undergoes thermal-induced unfolding that occurs within a very broad temperature range (from 27 degrees C to 80 degrees C and above), and this is accompanied by complete disappearance of alpha-helices, significant decrease in beta-sheets content, and by pronounced changes in the intrinsic fluorescence. The results confirm predictions that Hsp22 belongs to the family of intrinsically disordered proteins (IDP) with certain parts of its molecule (presumably, in the alpha-crystallin domain) retaining folded structure and undergoing reversible thermal unfolding. The results are also discussed in terms of downhill folding scenario.

Published

2009

50. Effect of mutations mimicking phosphorylation on the structure and properties of human 14-3-3zeta.

Author

Sluchanko NN, Chernik IS, Seit-Nebi AS, Pivovarova AV, Levitsky DI, and Gusev NB

Subjects

Computer Simulation, Humans, Mutagenesis, Site-Directed, Mutation, Phosphorylation, Protein Conformation, Structure-Activity Relationship, 14-3-3 Proteins chemistry, 14-3-3 Proteins ultrastructure, Models, Chemical, Models, Molecular

Abstract

Effect of mutations mimicking phosphorylation on the structure of human 14-3-3zeta protein was analyzed by different methods. Mutation S58E increased intrinsic Trp fluorescence and binding of bis-ANS to 14-3-3. At low protein concentration mutation S58E increased the probability of dissociation of dimeric 14-3-3 and its susceptibility to proteolysis. Mutation S184E slightly increased Stokes radius and thermal stability of 14-3-3. Mutation T232E induced only small increase of Stokes radius and sedimentation coefficient that probably reflect the changes in the size or shape of 14-3-3. At low protein concentration the triple mutant S58E/S184E/T232E tended to dissociate, whereas at high concentration its properties were comparable with those of the wild type protein. The triple mutant was highly susceptible to proteolysis. Thus, mutation mimicking phosphorylation of Ser58 destabilized, whereas mutation of Ser184 induced stabilization of 14-3-3zeta structure.

Published

2008