Anisotropy Decay of Labelled Actin

Ikkai, Takamitsu; Wahl, Philippe; Auchet, Jean-Claude

doi:10.1111/j.1432-1033.1979.tb12836.x

Cited by 54 publications

(35 citation statements)

References 41 publications

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“…Transient absorption anisotropy experiments showed that the actin filaments are more flexible in twisting motion than in bending (42) and the correlation times are in the microsecond range. We agree therefore with previous interpretations (32,35,36) that the correlation times of a few hundred nanoseconds in fluorescence anisotropy decay experiments are attributed to restricted segmental motion within the actin filaments. The segment characterized by these correlation times can be an actin protomer performing restricted motion in the filament, or a set of a few neighboring protomers with restricted and concerted motion.…”

Section: Discussionsupporting

confidence: 93%

“…3 A). Previously it was established that the value of the longer correlation time is inversely proportional to the flexibility of the actin filaments (32,(34)(35)(36)(37). Therefore, the formin-induced decrease of the rotational correlation time suggested that the interactions between neighboring protomers became weaker, and the actin filaments became more flexible, due to the binding of the mDia1-FH2 (see Discussion).…”

Section: The Effect Of Mdia1-fh2 On the Dynamic Properties Of Actin Fmentioning

confidence: 90%

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Conformational Changes in Actin Filaments Induced by Formin Binding to the Barbed End

Papp

Bugyi

Ujfalusi

et al. 2006

Biophysical Journal

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Formins bind actin filaments and play an essential role in the regulation of the actin cytoskeleton. In this work we describe details of the formin-induced conformational changes in actin filaments by fluorescence-lifetime and anisotropy-decay experiments. The results show that the binding of the formin homology 2 domain of a mammalian formin (mouse mDia1) to actin filaments resulted in a less rigid protein structure in the microenvironment of the Cys374 of actin, weakening of the interactions between neighboring actin protomers, and greater overall flexibility of the actin filaments. The formin effect is smaller at greater ionic strength. The results show that formin binding to the barbed end of actin filaments is responsible for the increase of flexibility of actin filaments. One formin dimer can affect the dynamic properties of an entire filament. Analyses of the results obtained at various formin/actin concentration ratios indicate that at least 160 actin protomers are affected by the binding of a single formin dimer to the barbed end of a filament.

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Section: Discussionsupporting

confidence: 93%

Section: The Effect Of Mdia1-fh2 On the Dynamic Properties Of Actin Fmentioning

confidence: 90%

Conformational Changes in Actin Filaments Induced by Formin Binding to the Barbed End

Papp

Bugyi

Ujfalusi

et al. 2006

Biophysical Journal

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“…These long rotational correlation times cannot be specific for the overall motion of the actin filaments, which occur on much longer time‐scale [55] and probably characterize the restricted motion of segments within the actin filaments. In such cases the value of the longer rotational correlation time resolved in fluorescence anisotropy decay experiments is inversely proportional to the flexibility of the actin filaments [12,34,35,56,57]. Accordingly, these data show that in the case of the Mg‐actin filaments the protein matrix is more rigid at pH 6.5 than at pH 7.4.…”

Section: Resultsmentioning

confidence: 98%

“…A large number of experiments confirm that the actin filaments can change their dynamic and/or conformational properties due to the effect of the altered physico‐chemical properties of the surroundings or to the effects of other proteins involved in the force generation [2–7]. The actin filaments present in different dynamic states [6,8–12] can have an effect on the function of the acto–myosin complex through the altered flexibility of the protein matrix [7,12], which can also have significant functional effects at the cellular level [6]. The better understanding of the relationship between the flexibility and the function of actin filaments seems to be important for describing the molecular details of the muscle contraction under physiological and pathological conditions.…”

mentioning

confidence: 99%

Intermonomer flexibility of Ca‐ and Mg‐actin filaments at different pH values

Hild¹,

Nyitrai

Somogyi

2002

European Journal of Biochemistry

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The¯uorescence resonance energy transfer parameter, f, is de®ned as the e ciency of the energy transfer normalized by the quantum yield of the donor in the presence of acceptor. It is possible to characterize the¯exibility of the protein matrix between the appropriate¯uorescent probes by monitoring the temperature dependence of f. The intermonomer¯exi-bility of the Ca-actin and Mg-actin ®laments was characterized by using this method at pH values of 6.5 and 7.4. The protomers were labeled on Cys374 with donor [N-(((iodoacetyl)amino)ethyl)-5-naphthylamine-1-sulfonate; IAEDANS] or acceptor [5-(iodoacetamido)¯uorescein; IAF] molecules. The temperature pro®le of f suggested that the intermonomer¯exibility of actin ®laments was larger at pH 7.4 than pH 6.5 in the case of Mg-F-actin while this di erence was absent in the case of Ca-F-actin. More rigid intermonomer connection was identi®ed at both pH values between the protomers of Mg-F-actin compared to the Ca-F-actin. The results were further supported by time dependent¯uorescence measurements made on IAEDANS and IAF labeled Mg-and Ca-actin ®laments at pH 6.5 and 7.4. Our spectroscopic results may suggest that the altered function of muscle following the change of pH within the muscle cells under physiological or pathological conditions might be a ected by the modi®ed dynamic properties of the magnesium saturated actin ®laments. The change of the intracellular pH does not have an e ect on the intermonomer exibility of the Ca-actin ®laments.Keywords: muscle; cations; protein dynamics;¯uorescence resonance energy transfer;¯uorescence anisotropy decay.The dynamic properties of the actin ®lament have been widely investigated since it was discovered and named by Straub in 1942 [1]. He proposed that the actin ®lament was an active and essential part of the muscle function. A large number of experiments con®rm that the actin ®laments can change their dynamic and/or conformational properties due to the effect of the altered physico-chemical properties of the surroundings or to the effects of other proteins involved in the force generation [2±7]. The actin ®laments present in different dynamic states [6,8±12] can have an effect on the function of the acto±myosin complex through the altered¯exibility of the protein matrix [7,12], which can also have signi®cant functional effects at the cellular level [6]. The better understanding of the relationship between the¯exibility and the function of actin ®laments seems to be important for describing the molecular details of the muscle contraction under physiological and pathological conditions. The pH can change within the muscle cells under physiological and pathological conditions [13±21]. In skeletal muscle cells the pH can decrease physiologically during intense exertion. Renaud and colleagues found that the intracellular pH of the frog sartorius muscles could decrease from 7.1 to 6.5 after a fatiguing stimulation period [16]. The drop in the cytoplasmic pH to 6.12 was also observed in human muscle investigated in vivo during and...

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“…Correlation times on the fs range reflect the rearrangements of atoms/molecules, and these structural changes can be resolved by X-ray crystallography, electron microscopy (EM), cryo-EM and femtobiological approaches [Egelman, 2000; Resch et al, 2002; Sundstrom, 2008]. The ns correlation times are related to the change in the restricted segmental motion of a monomer/protomer or a few neighbouring protomers and can be determined by time-dependent fluorescence anisotropy [Ikkai et al, 1979; Miki et al, 1982a, b] or conventional electron paramagnetic resonance (EPR) [Thomas et al, 1979; Mossakowska et al, 1988]. The torsional twisting and bending motions of the whole actin filament characterised by correlation times in the μs and μs–ms range, can be described by phosphorescence anisotropy [Prochniewicz et al, 1996a; Yoshimura et al, 1984], saturation transfer (ST) EPR [Thomas et al, 1979; Hegyi et al, 1988], and transient absorption anisotropy measurements [Mihashi et al, 1983].…”

Section: Methods To Investigate the Conformational Dynamics Of Actinmentioning

confidence: 99%

Conformational dynamics of actin: Effectors and implications for biological function

2010

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Actin is a protein abundant in many cell types. Decades of investigations have provided evidence that it has many functions in living cells. The diverse morphology and dynamics of actin structures adapted to versatile cellular functions is established by a large repertoire of actin-binding proteins. The proper interactions with these proteins assume effective molecular adaptations from actin, in which its conformational transitions play essential role. This review attempts to summarise our current knowledge regarding the coupling between the conformational states of actin and its biological function.

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Anisotropy Decay of Labelled Actin

Cited by 54 publications

References 41 publications

Conformational Changes in Actin Filaments Induced by Formin Binding to the Barbed End

Conformational Changes in Actin Filaments Induced by Formin Binding to the Barbed End

Intermonomer flexibility of Ca‐ and Mg‐actin filaments at different pH values

Conformational dynamics of actin: Effectors and implications for biological function

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