D-loop of Actin Differently Regulates the Motor Function of Myosins II and V

Kubota, Hiroaki; Mikhailenko, Sergey V.; Okabe, H.; Taguchi, Hideki; Ishiwata, Shin’ichi

doi:10.1074/jbc.m109.013565

Cited by 15 publications

(12 citation statements)

References 33 publications

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“…One is that because the rate-limiting step in the myosin V ATPase cycle is ADP release (40), the slower transition from weak to strong binding may not be deleterious for this myosin. Consistent with this possibility, Kubota et al (41) reported that the M47A/E360H mutation of Dictyostelium actin slows down the transition of the leading head from the weak to the strong binding state, but it does not reduce gliding velocity. The second possibility is that the conformational states of the actin subunits required for myosin V motility differ from those required for myosin II motility.…”

Section: Discussionsupporting

confidence: 56%

G146V Mutation at the Hinge Region of Actin Reveals a Myosin Class-specific Requirement of Actin Conformations for Motility

Noguchi

Komori

Umeki

et al. 2012

Journal of Biological Chemistry

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Background:The roles of conformational changes of actin in myosin motility are unclear. Results: A G146V mutation in actin, which perturbed its conformation, impaired force generation by myosin II, but not by myosin V. Conclusion: Conformational changes of actin involving Gly-146 have critical roles in motility of myosin II, but not of myosin V. Significance: The mechanism of motility may be different between myosin types.

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Section: Discussionsupporting

confidence: 56%

G146V Mutation at the Hinge Region of Actin Reveals a Myosin Class-specific Requirement of Actin Conformations for Motility

Noguchi

Komori

Umeki

et al. 2012

Journal of Biological Chemistry

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“…It is noteworthy that Rng2CHD did not inhibit actin filament movement on myosin V HMM, which is well established to move actin filaments processively with a lever arm swing (Forkey et al, 2003, Kodera et al, 2010. In line with this finding, two actin mutations, M47A (Kubota et al, 2009) and G146V (Noguchi et al, 2012), both of which likely perturb conformational changes of actin filaments, inhibit actin movements on myosin II, but not on myosin V. We suggest that the movement by myosin II, which is a fast and non-processive motor, requires some unidentified structural property of actin filaments which is dispensable for the slow and processive myosin V involving the lever arm swing. Further studies are needed to understand the mechanism by which actin filaments structurally altered by Rng2CHD fails to move on myosin II.…”

Section: The Mechanism By Which Structural Changes Of Actin Filamentssupporting

confidence: 66%

Actin binding domain of Rng2 sparsely bound on F-actin strongly inhibits actin movement on myosin II

Hayakawa

Takaine

Imai

et al. 2020

Preprint

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The contraction of contractile rings (CRs) depends on sliding between actin filaments and myosin II filaments. The rate of contraction in the fission yeast Schizosaccharomyces pombe is less than 1/120 of the velocity of acto-myosin II movement in vitro, but the mechanism of inhibition has not been described. Here, we found that the calponin-homology actin binding domain of fission yeast IQGAP Rng2 (Rng2CHD) strongly inhibits the motility of actin filaments on skeletal muscle myosin II fragments in vitro, even at a low ratio of bound Rng2CHD to actin protomers, reducing the sliding velocity to half when the binding ratio was 1/75. Rng2CHD also induced structural changes of actin filaments and reduced the affinity between actin filaments and subfragment 1 (S1) of muscle myosin II carrying ADP. Intriguingly, actin-activated ATPase of S1 was only mildly inhibited, even by high concentrations of Rng2CHD. Moreover, the motility of actin filaments by myosin V was not inhibited by Rng2CHD. We propose a new regulatory mechanism for acto-myosin II movement that involves Rng2CHD-induced structural changes of actin filaments.

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“…In fact, tyrosine phosphorylation of actin can protect its D-loop structure from protease cleavage, resultant in a more stable conformation of the actin D-loop than the unphosphorylated form (Baek et al, 2008). Conformational stability of the D-loop holds much importance in conferring cell motile properties, which if unstable can result in a weakened contractile force and much reduced gliding velocity (Kubota et al, 2009). Our finding of reduced ACTB tyrosine phosphorylation in the PFTK1-suppressed cells would seem to be in line with the development of a less stable actin structure, which could have contributed to the repression on HCC cell migration.…”

Section: Discussionmentioning

confidence: 99%

A novel interplay between oncogenic PFTK1 protein kinase and tumor suppressor TAGLN2 in the control of liver cancer cell motility

et al. 2011

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The PFTK1 gene encodes a cdc2-related serine/threonine protein kinase that has been shown to confer cell migratory properties in hepatocellular carcinoma (HCC). However, the prognostic value and biological mechanism by which PFTK1 promotes HCC motility remain largely unknown. Here, we showed from tissue microarray that common upregulations of PFTK1 in primary HCC tumors (n ¼ 133/180) correlated significantly with early age onset (p40 years), advance tumor grading and presence of microvascular invasion (Pp0.05). To understand downstream phosphorylated substrate(s) of PFTK1, phospho-proteins in PFTK1 expressing and knockdown Hep3B cells were profiled by two-dimensional-polyacrylamide gel electrophoresis mass spectrometric analysis. Protein identification of differential spots revealed b-actin (ACTB) and transgelin2 (TAGLN2) as the two most profound phosphorylated changes affected by PFTK1. We verified the presence of TAGLN2 serine phosphorylation and ACTB tyrosine phosphorylation. Moreover, reduced TAGLN2 and ACTB phosphorylations in PFTK1-suppressed Hep3B corresponded to distinct actin depolymerizations and marked inhibition on cell invasion and motility. Given that TAGLN2 is a tumor suppressor whose function has been ascribed in cancer metastasis, we examined if TAGLN2 is an intermediate substrate in the biological path of PFTK1. We showed in PFTK1-suppressed cells that knockdown of TAGLN2 over-rode the inhibitory effect on cell invasion and motility, and a recovery on actin polymerization was evident. Interestingly, we also found that unphosphorylated TAGLN2 in PFTK1-suppressed cells elicited strong actin-binding ability, a mechanism that possibly halts the actin cytoskeleton dynamics. Site-directed mutagenesis of TAGLN2 suggested that PFTK1 regulates the actinbinding affinity of TAGLN2 through the S83 and S163 residues, which if mutated can significantly affect HCC cell motility. Taken together, our data propose a novel, oncogene-tumor suppressor interplay, where oncogenic PFTK1 confers HCC cell motility through inactivating the actin-binding motile suppressing function of TAGLN2 via phosphorylation.

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D-loop of Actin Differently Regulates the Motor Function of Myosins II and V

Cited by 15 publications

References 33 publications

G146V Mutation at the Hinge Region of Actin Reveals a Myosin Class-specific Requirement of Actin Conformations for Motility

G146V Mutation at the Hinge Region of Actin Reveals a Myosin Class-specific Requirement of Actin Conformations for Motility

Actin binding domain of Rng2 sparsely bound on F-actin strongly inhibits actin movement on myosin II

A novel interplay between oncogenic PFTK1 protein kinase and tumor suppressor TAGLN2 in the control of liver cancer cell motility

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