A billion years of evolution manifest in nanosecond protein dynamics
Protein dynamics form a critical bridge between protein structure and function, yet the impact of evolution on ultrafast processes inside proteins remains enigmatic. This study delves deep into nanosecond-scale protein dynamics of a structurally and functionally conserved protein across species sepa...
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| creator | Heckmeier, Philipp J Ruf, Jeannette Rochereau, Charlotte Hamm, Peter |
| description | Protein dynamics form a critical bridge between protein structure and
function, yet the impact of evolution on ultrafast processes inside proteins
remains enigmatic. This study delves deep into nanosecond-scale protein
dynamics of a structurally and functionally conserved protein across species
separated by almost a billion years, investigating ten homologs in complex with
their ligand. By inducing a photo-triggered destabilization of the ligand
inside the binding pocket, we resolved distinct kinetic footprints for each
homolog via transient infrared spectroscopy . Strikingly, we found a cascade of
rearrangements within the protein complex which manifest in three discrete time
points of dynamic activity, conserved over hundreds of millions of years within
a narrow window. Among these processes, one displays a subtle temporal shift
correlating with evolutionary divergence, suggesting reduced selective pressure
in the past. Our study not only uncovers the impact of evolution on molecular
processes in a specific case, but has also the potential to initiate a novel
field of scientific inquiry within molecular paleontology, where species are
compared and classified based on the rapid pace of protein dynamic processes; a
field which connects the shortest conceivable time scale in living matter
(10^-9 s) with the largest ones (10^16 s). |
| doi_str_mv | 10.48550/arxiv.2309.06298 |
| format | Article |
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function, yet the impact of evolution on ultrafast processes inside proteins
remains enigmatic. This study delves deep into nanosecond-scale protein
dynamics of a structurally and functionally conserved protein across species
separated by almost a billion years, investigating ten homologs in complex with
their ligand. By inducing a photo-triggered destabilization of the ligand
inside the binding pocket, we resolved distinct kinetic footprints for each
homolog via transient infrared spectroscopy . Strikingly, we found a cascade of
rearrangements within the protein complex which manifest in three discrete time
points of dynamic activity, conserved over hundreds of millions of years within
a narrow window. Among these processes, one displays a subtle temporal shift
correlating with evolutionary divergence, suggesting reduced selective pressure
in the past. Our study not only uncovers the impact of evolution on molecular
processes in a specific case, but has also the potential to initiate a novel
field of scientific inquiry within molecular paleontology, where species are
compared and classified based on the rapid pace of protein dynamic processes; a
field which connects the shortest conceivable time scale in living matter
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function, yet the impact of evolution on ultrafast processes inside proteins
remains enigmatic. This study delves deep into nanosecond-scale protein
dynamics of a structurally and functionally conserved protein across species
separated by almost a billion years, investigating ten homologs in complex with
their ligand. By inducing a photo-triggered destabilization of the ligand
inside the binding pocket, we resolved distinct kinetic footprints for each
homolog via transient infrared spectroscopy . Strikingly, we found a cascade of
rearrangements within the protein complex which manifest in three discrete time
points of dynamic activity, conserved over hundreds of millions of years within
a narrow window. Among these processes, one displays a subtle temporal shift
correlating with evolutionary divergence, suggesting reduced selective pressure
in the past. Our study not only uncovers the impact of evolution on molecular
processes in a specific case, but has also the potential to initiate a novel
field of scientific inquiry within molecular paleontology, where species are
compared and classified based on the rapid pace of protein dynamic processes; a
field which connects the shortest conceivable time scale in living matter
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function, yet the impact of evolution on ultrafast processes inside proteins
remains enigmatic. This study delves deep into nanosecond-scale protein
dynamics of a structurally and functionally conserved protein across species
separated by almost a billion years, investigating ten homologs in complex with
their ligand. By inducing a photo-triggered destabilization of the ligand
inside the binding pocket, we resolved distinct kinetic footprints for each
homolog via transient infrared spectroscopy . Strikingly, we found a cascade of
rearrangements within the protein complex which manifest in three discrete time
points of dynamic activity, conserved over hundreds of millions of years within
a narrow window. Among these processes, one displays a subtle temporal shift
correlating with evolutionary divergence, suggesting reduced selective pressure
in the past. Our study not only uncovers the impact of evolution on molecular
processes in a specific case, but has also the potential to initiate a novel
field of scientific inquiry within molecular paleontology, where species are
compared and classified based on the rapid pace of protein dynamic processes; a
field which connects the shortest conceivable time scale in living matter
(10^-9 s) with the largest ones (10^16 s).</abstract><doi>10.48550/arxiv.2309.06298</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Biological Physics |
| title | A billion years of evolution manifest in nanosecond protein dynamics |
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