Surface plasmon resonance study of the actin-myosin sarcomeric complex and tubulin dimers

Schuessler, H. A.; Mershin, Andreas; Kolomenskii, Alexander; Nanopoulos, Dimitri V.

doi:10.1080/09500340308233570

Cited by 12 publications

(24 citation statements)

References 23 publications

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“…The small discrepancies between the theory and experiment for n tub and dn/dc tub can be due to (i) the deviation of tubulin dimer shape from a spherical one assumed in the theory, (ii) small concentration uncertainties, (iii) effects of the buffer on dn/dc [25] or (iv) additional polarization effects in tubulin due to its large dipole moment [26,27]. The high-frequency polarizability (α tub ) of tubulin can [8,9] are at 760 nm and 26 • C and from Bon et al [2] for 527 nm and room temperature.…”

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confidence: 94%

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Resolving controversy of unusually high refractive index of a tubulin

Krivosudský¹,

Cifra²

2017

EPL

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Refractive index of tubulin is an important parameter underlying fundamental electromagnetic and biophysical properties of microtubules -protein fibers essential for several cell functions including cell division. Yet, the only experimental data available in the current literature show values of tubulin refractive index (n = 2.36 -2.90) which are much higher than established theories predict based on the weighted contribution of the polarizability of individual amino acids constituting the protein. To resolve this controversy, we report here modeling and rigorous experimental analysis of refractive index of purified tubulin dimer. Our experimental data revealed that the refractive index of tubulin is n = 1.64 at the wavelength 589 nm and 25 • C, that is much closer to the values predicted by established theories than the earlier experimental data provide.

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confidence: 94%

“…which with the calculated number density of molecules N = 8.7×10 21 molecules per m 3 at given concentration (C tub ) is equal to α tub = 1.1×10 −33 Cm 2 V −1 . What effect caused the high values of detected refractive index in the earlier experimental works [2,8,9] is unclear.…”

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confidence: 97%

Resolving controversy of unusually high refractive index of a tubulin

Krivosudský¹,

Cifra²

2017

EPL

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“…2 The tubulin monomer contains approximately 450 amino acids comprising some 7000 atoms with a combined mass of 55 kDa. 3 (b) Tubulin's secondary structure is of crucial importance for the dynamical model applied in this article. This structure is dominated by α-helices, polypeptide wound chains of amino acids, represented by rods in Fig.…”

Section: Introductionmentioning

confidence: 99%

Microtubules as Active Tracks for Bi-Directional Cellular Traffic of Motor Proteins

Satarić

Budinski-Petković

Lončarević

2007

Int. J. Mod. Phys. B

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“…Fig. 12 shows the experimental arrangement of our custom-built SPR sensor [18,135,136]. In addition to the experimental arrangement shown, we used the commercial SPR-based BIAcore 3000 and 1000 sensors, which furnished the additional convenience of automated injection of very small volumes of analyte solutions and allowed for cross-checking of results.…”

Section: Surface Plasmon Resonance (Spr) 431 Spr Basicsmentioning

confidence: 99%

“…Since the effective permittivities depend on the frequency of the exciting laser light, the resonance angle does too. The most convenient geometry for the development of a sensor is the Kretschmann-Raether configuration which consists of a glass prism, a metal film and the adjacent medium that is to be probed [135,136]. Fig.…”

Section: Surface Plasmon Resonance (Spr) 431 Spr Basicsmentioning

confidence: 99%

Towards Experimental Tests of Quantum Effects in Cytoskeletal Proteins

Mershin

Sanabria

Miller

et al.

The Emerging Physics of Consciousness

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PREFACEThis volume is appropriately titled "The Emerging Physics of Consciousness" and much of it is focused on using some aspect of "quantum weirdness" to solve the problems associated with the phenomenon of consciousness. This is sometimes done in hopes that perhaps the two mysteries will somehow cancel each other through such phenomena as quantum coherence and entanglement or superposition of wavefunctions. We are not convinced that such a cancellation can take place. In fact, finding that quantum phenomena are involved in consciousness, what we will call the "Quantum Consciousness Idea" (QCI) (fathered largely by Penrose and Hameroff [1][2][3]), is likely to confound both mysteries and is of great interest.In our contribution, we want to emphasize the "Emerging" part of this volume's title by pointing out that there is a glaring need for properly controlled and reproducible experimental work if any proposed quantum phenomena in biological matter, let alone consciousness are to be taken seriously.There are three broad kinds of experiments that one can devise to test hypotheses involving the relevance of quantum effects to the phenomenon of consciousness. The three kinds address three different scale ranges associated roughly with tissue-to-cell (1cm-10µm), cell-toprotein (10µm-10nm) and protein-to-atom (10nm-1Å) sizes. Note that we are excluding experiments that aim to detect quantum effects at the "whole human" or even "society" level as these have consistently given either negative results or been plagued by irreproducibility and bad science (e.g. the various extra sensory perception and remote viewing experiments [4]).The consciousness experiments belonging to the tissue-cell scale frequently utilize apparatus such as electro-encephalographs (EEG) or magnetic resonance imaging (MRI) to track

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Surface plasmon resonance study of the actin-myosin sarcomeric complex and tubulin dimers

Cited by 12 publications

References 23 publications

Resolving controversy of unusually high refractive index of a tubulin

Resolving controversy of unusually high refractive index of a tubulin

Microtubules as Active Tracks for Bi-Directional Cellular Traffic of Motor Proteins

Towards Experimental Tests of Quantum Effects in Cytoskeletal Proteins

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