TY - JOUR
T1 - Spectroscopy of proteins at low temperature. Part I
T2 - Experiments with molecular ensembles
AU - Berlin, Yuri
AU - Burin, Alexander
AU - Friedrich, Josef
AU - Köhler, Jürgen
N1 - Funding Information:
We thank our friends who have collaborated with us on various aspects of low temperature physics of proteins: Thijs Aartsma, Judit Fidy, Fritz Parak, Vladimir Ponkratov, Mark Ratner, Jane Vanderkooi. Research was supported by the DFG [SFB 533, B5], the Volkswagen Foundation, the DAAD and the Fonds der Chemischen Industrie. A.B. is supported by the Louisiana Board of Regents [ContractNo LEQSF (2005-08)-RD-29].
PY - 2006/12
Y1 - 2006/12
N2 - We discuss aspects of the physics of proteins at low temperature as they are reflected in highly resolved optical spectra of molecular probes. Typical probe molecules are heme-like dyes, aromatic amino acids, but also extended molecular aggregates in light harvesting complexes. We put emphasis on the interactions of the probe with its protein environment, on the range of these interactions, on their specific behavior in external fields, as well as on the characteristic parameters of the protein which can be determined with optical techniques at low temperatures but are not easily accessible otherwise. However, the focus of the review is on spectral diffusion physics of proteins, i.e. on their motion in conformational phase space, and on how this motion is reflected in the optical spectra. These structure changing-processes reflect the non-ergodic nature of low temperature proteins. They are most clearly detected at low temperature where the resolution of the experiment is close to the ultimate limit as given by the natural linewidth and where the dynamics become slow enough to be conveniently measured. In part I we discuss aspects of ensemble experiments, in part II we focus on experiments with single protein complexes. We offer lines of reasoning which may serve as guidelines for an understanding of the phenomena.
AB - We discuss aspects of the physics of proteins at low temperature as they are reflected in highly resolved optical spectra of molecular probes. Typical probe molecules are heme-like dyes, aromatic amino acids, but also extended molecular aggregates in light harvesting complexes. We put emphasis on the interactions of the probe with its protein environment, on the range of these interactions, on their specific behavior in external fields, as well as on the characteristic parameters of the protein which can be determined with optical techniques at low temperatures but are not easily accessible otherwise. However, the focus of the review is on spectral diffusion physics of proteins, i.e. on their motion in conformational phase space, and on how this motion is reflected in the optical spectra. These structure changing-processes reflect the non-ergodic nature of low temperature proteins. They are most clearly detected at low temperature where the resolution of the experiment is close to the ultimate limit as given by the natural linewidth and where the dynamics become slow enough to be conveniently measured. In part I we discuss aspects of ensemble experiments, in part II we focus on experiments with single protein complexes. We offer lines of reasoning which may serve as guidelines for an understanding of the phenomena.
KW - Aging
KW - Biomolecular aggregates
KW - Chromophore-protein interactions
KW - Conformational substates
KW - Energy landscape
KW - Excitons in biomolecules
KW - Hole burning
KW - LH2
KW - Pressure tuning
KW - Protein spectroscopy
KW - Single molecule spectroscopy
KW - Spectral diffusion
KW - Stark-effect
UR - http://www.scopus.com/inward/record.url?scp=33751232637&partnerID=8YFLogxK
U2 - 10.1016/j.plrev.2006.09.001
DO - 10.1016/j.plrev.2006.09.001
M3 - Review article
AN - SCOPUS:33751232637
SN - 1571-0645
VL - 3
SP - 262
EP - 292
JO - Physics of Life Reviews
JF - Physics of Life Reviews
IS - 4
ER -