On the existence of superradiant excitonic states in microtubules

TL;DR

This study demonstrates that microtubules can host superradiant excitonic states due to their specific molecular arrangement, potentially enabling highly efficient long-range energy transfer in biological systems.

Contribution

The paper reveals the existence of superradiant and supertransfer excitonic states in microtubules, a novel insight into their quantum optical properties and potential biological functions.

Findings

Microtubules exhibit a superradiant ground state due to molecular arrangement.

Supertransfer coupling enhances excitation spreading velocity.

Microtubules show robustness to static disorder, supporting efficient energy transfer.

Abstract

Microtubules are biological protein polymers with critical and diverse functions. Their structures share some similarities with photosynthetic antenna complexes, particularly in the ordered arrangement of photoactive molecules with large transition dipole moments. As the role of photoexcitations in microtubules remains an open question, here we analyze tryptophan molecules, the amino acid building block of microtubules with the largest transition dipole strength. By taking their positions and dipole orientations from realistic models capable of reproducing tubulin experimental spectra, and using a Hamiltonian widely employed in quantum optics to describe light-matter interactions, we show that such molecules arranged in their native microtubule configuration exhibit a superradiant ground state, which represents an excitation fully extended on the chromophore lattice. We also show that such a superradiant ground state emerges due to supertransfer coupling between the ground states of smaller blocks of the microtubule. In the dynamics we find that the spreading of excitation is ballistic in the absence of external sources of disorder and strongly dependent on initial conditions. The velocity of photoexcitation spreading is shown to be enhanced by the supertransfer effect with respect to the velocity one would expect from the strength of the nearest-neighbor coupling between tryptophan molecules in the microtubule. Finally, such structures are shown to have an enhanced robustness to static disorder when compared to geometries that include only short-range interactions. These cooperative effects (superradiance and supertransfer) may induce ultra-efficient photoexcitation absorption and could enhance excitonic energy transfer in microtubules over long distances under physiological conditions.