Fractal symmetry of protein interior: what have we learned?

Banerji, Anirban; Ghosh, Indira

doi:10.1007/s00018-011-0722-6

Cited by 35 publications

(31 citation statements)

References 143 publications

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“…Equations containing fractal operators are used to analyze the behavior of systems characterized by: (1) power-law nonlinearity (2) power-law long-range spatial correlations or long-term memory (3) fractal or multi-fractal properties [22]. During the last years, the number of applications of fractional dynamics in science and particularly in physics has been steadily growing and include models of fractional relaxation and oscillation phenomena, anomalous transport in fluids and plasma, wave propagation in complex media, viscoelastic materials, non-Markovian evolution of quantum fields, networks of fractional oscillators and so on [23][24][25][26][27][28][29].…”

Section: Fractality and Fractionalitymentioning

confidence: 99%

“…In recent years fractal geometry analysis has attracted attention of biologist as a useful and desirable tool to characterize the configuration and structure of biological structures. The considered issues include: fractal geometry analysis of configuration, structure and diffusion of proteins [24][25][26][27][28][29], fractal analysis of the DNA sequence, walks and aggregation [30][31][32][33][34] and fractal model of light scattering in biological tissue and cells [35]. (…”

Section: -1 Fractalitymentioning

confidence: 99%

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Fractional Dynamics in Bioscience and Biomedicine and the Physics of Cancer

Nasrolahpour

2017

Preprint

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Almost all phenomena and structures in nature exhibit some degrees of fractionality or fractality. Fractional calculus and fractal theory are two interrelated concepts. In this article we study the memory effects in nature and particularly in biological structures. Based on this fact that natural way to incorporate memory effects in the modeling of various phenomena and dealing with complexities is using of fractional calculus, in this article we present different examples in various branch of science from cosmology to biology and we investigate this idea that are we able to describe all of such these phenomena using the well-know and powerful tool of fractional calculus. In particular we focus on fractional calculus approach as an effective tool for better understanding of physics of living systems and organism and especially physics of cancer.Keywords: Fractional Dynamics; Memory Effect; Biological Structures; Physics of Cancer IntroductionThe concept of memory effect plays an important role in a large number of phenomena in different contexts and systems from biological structures to cosmological phenomena. For instance: memory effects in nanoscale systems [1,2], optical memory effect [3], gravitational and cosmological memory effect (which means: the induction of a permanent change in the relative separation of the test particles when gravitational radiation passes through a configuration of test particles that make up a gravitational wave detector) [4], memory effects in gene regulatory networks [5], memory effects in economics [6] have been investigated. In addition other kinds of memory effect including: shape memory effect [7][8][9][10], magnetic shape memory effect [11] and temperature memory effect [12] have been also considered in recent years. In all above mentioned references authors have used the standard calculus, however nowadays it is well-known that a natural way to incorporate memory effects in the modeling of various phenomena is using of fractional calculus. On the other hand almost all phenomena and structures in nature exhibit some degrees and levels of fractionality or fractality (low or high level or something between them), also nowadays it is well-known that there is a close relation between fractality and fractionality. In this work we investigate this idea that are we able to describe all of such these phenomena using the well-know and powerful tool of fractional calculus. Therefore for this purpose in the following, concepts of fractality and fractional dynamics are briefly reviewed respectively in Sec. 2.Then in Sec. 3 we introduce fractional calculus as a powerful tool for modeling of memory effects in different context and we present some important applications. At last, in Sec. 4, we will present some conclusions.

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Section: Fractality and Fractionalitymentioning

confidence: 99%

Section: -1 Fractalitymentioning

confidence: 99%

Fractional Dynamics in Bioscience and Biomedicine and the Physics of Cancer

Nasrolahpour

2017

Preprint

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“…Our remark gets supported when one measures the compactness of folded structures in terms of hydrophobicity, mass, or polarizability using fractal dimensions. For instance, the all β proteins were identified with a maximum amount of "unused hydrophobicity" compared to the all α proteins (Banerji & Ghosh, 2011). This may result in quite high remaining conformational entropy in the functional structure.…”

Section: Role Of Entropy In the Pfpmentioning

confidence: 99%

Concepts on the protein folding problem

Gillet¹,

Ghosh²

2013

Journal of Biomolecular Structure and Dynamics

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“…The structural scaffold of these enzymes, the (b/a) 8 (triosephosphate isomerase, TIM) barrel (Fig. 1A), is one of the most abundant and stable protein folds known [8,11]. Structural conservation and rigidity are demonstrated by the small RMSD (< 3 A) between crystalline and solution structures [12,13].…”

Section: Introductionmentioning

confidence: 99%

Identifying critical unrecognized sugar–protein interactions in GH10 xylanases from Geobacillus stearothermophilus using STD NMR

et al. 2013

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1H solution NMR spectroscopy is used synergistically with 3D crystallographic structures to map experimentally significant hydrophobic interactions upon substrate binding in solution under thermodynamic equilibrium. Using saturation transfer difference spectroscopy (STD NMR), a comparison is made between wild‐type xylanase XT6 and its acid/base catalytic mutant E159Q – a non‐active, single‐heteroatom alteration that has been previously utilized to measure binding thermodynamics across a series of xylooligosaccharide–xylanase complexes [Zolotnitsky et al. (2004) Proc Natl Acad Sci USA 101, 11275–11280). In this study, performing STD NMR of one substrate screens binding interactions to two proteins, avoiding many disadvantages inherent to the technique and clearly revealing subtle changes in binding induced upon mutation of the catalytic Glu. To visualize and compare the binding epitopes of xylobiose–xylanase complexes, a ‘SASSY’ plot (saturation difference transfer spectroscopy) is used. Two extraordinarily strong, but previously unrecognized, non‐covalent interactions with H2–5 of xylobiose were observed in the wild‐type enzyme but not in the E159Q mutant. Based on the crystal structure, these interactions were assigned to tryptophan residues at the −1 subsite. The mutant selectively binds only the β–xylobiose anomer. The 1H solution NMR spectrum of a xylotriose–E159Q complex displays non‐uniform broadening of the NMR signals. Differential broadening provides a unique subsite assignment tool based on structural knowledge of face‐to‐face stacking with a conserved tyrosine residue at the +1 subsite. The results obtained herein by substrate‐observed NMR spectroscopy are discussed further in terms of methodological contributions and mechanistic understanding of substrate‐binding adjustments upon a charge change in the E159Q construct.

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Fractal symmetry of protein interior: what have we learned?

Cited by 35 publications

References 143 publications

Fractional Dynamics in Bioscience and Biomedicine and the Physics of Cancer

Fractional Dynamics in Bioscience and Biomedicine and the Physics of Cancer

Concepts on the protein folding problem

Identifying critical unrecognized sugar–protein interactions in GH10 xylanases from Geobacillus stearothermophilus using STD NMR

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