Quantum information processing at the cellular level. Euclidean approach
Application of quantum principles to living cells requires a new approximation of the full quantum mechanical description of intracellular dynamics. We discuss what principal elements any such good approximation should contain. As one such element, the notion of "Catalytic force" Cf is int...
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| Main Author | |
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| Format | Journal Article |
| Language | English |
| Published |
23.06.2009
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| Subjects | |
| Online Access | Get full text |
| DOI | 10.48550/arxiv.0906.4279 |
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| Abstract | Application of quantum principles to living cells requires a new
approximation of the full quantum mechanical description of intracellular
dynamics. We discuss what principal elements any such good approximation should
contain. As one such element, the notion of "Catalytic force" Cf is introduced.
Cf is the effect of the molecular target of catalysis on the catalytic
microenvironment that adjusts the microenvironment towards a state that
facilitates the catalytic act. This phenomenon is experimentally testable and
has an intriguing implication for biological organization and evolution, as it
amounts to "optimization without natural selection of replicators". Unlike the
statistical-mechanical approaches to self-organization, the Cf principle does
not encounter the problem of "tradeoff between stability and complexity" at the
level of individual cell. Physically, the Cf is considered as a harmonic-like
force of reaction, which keeps the state of the cell close to the ground state,
defined here as a state where enzymatic acts work most efficiently. Ground
state is subject to unitary evolution, and serves as a starting point in a
general strategy of quantum description of intracellular processes, termed here
"Euclidean approach". The next step of this strategy is transition from the
description of ground state to that one of growing state, and we suggest how it
can be accomplished using arguments from the fluctuation-dissipation theorem.
Finally, given that the most reliable and informative observable of an
individual cell is the sequence of its genome, we propose that the
non-classical correlations between individual molecular events at the single
cell level could be easiest to detect using high throughput DNA sequencing. |
|---|---|
| AbstractList | Application of quantum principles to living cells requires a new
approximation of the full quantum mechanical description of intracellular
dynamics. We discuss what principal elements any such good approximation should
contain. As one such element, the notion of "Catalytic force" Cf is introduced.
Cf is the effect of the molecular target of catalysis on the catalytic
microenvironment that adjusts the microenvironment towards a state that
facilitates the catalytic act. This phenomenon is experimentally testable and
has an intriguing implication for biological organization and evolution, as it
amounts to "optimization without natural selection of replicators". Unlike the
statistical-mechanical approaches to self-organization, the Cf principle does
not encounter the problem of "tradeoff between stability and complexity" at the
level of individual cell. Physically, the Cf is considered as a harmonic-like
force of reaction, which keeps the state of the cell close to the ground state,
defined here as a state where enzymatic acts work most efficiently. Ground
state is subject to unitary evolution, and serves as a starting point in a
general strategy of quantum description of intracellular processes, termed here
"Euclidean approach". The next step of this strategy is transition from the
description of ground state to that one of growing state, and we suggest how it
can be accomplished using arguments from the fluctuation-dissipation theorem.
Finally, given that the most reliable and informative observable of an
individual cell is the sequence of its genome, we propose that the
non-classical correlations between individual molecular events at the single
cell level could be easiest to detect using high throughput DNA sequencing. |
| Author | Ogryzko, Vasily |
| Author_xml | – sequence: 1 givenname: Vasily surname: Ogryzko fullname: Ogryzko, Vasily |
| BackLink | https://doi.org/10.48550/arXiv.0906.4279$$DView paper in arXiv |
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| Snippet | Application of quantum principles to living cells requires a new
approximation of the full quantum mechanical description of intracellular
dynamics. We discuss... |
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| SubjectTerms | Physics - Quantum Physics Physics - Soft Condensed Matter Quantitative Biology - Molecular Networks |
| Title | Quantum information processing at the cellular level. Euclidean approach |
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