Keyword search (4,164 papers available)

"Zazubovich V" Authored Publications:

Title Authors PubMed ID
1 Nonphotochemical Spectral Hole Burning Study of Modified LH2 Complex from em Rbl. acidophilus /em : Do Parts of the Pigment Molecule Affect Small Light-Induced Structural Changes? Levenberg A; Trempe A; Lujan MA; Picorel R; Zazubovich V; 41802209
PHYSICS
2 Rigorous Quantum-Mechanical Modeling of Tunneling-Based Structural Changes Associated with Line Shifts in Optical Spectroscopy Experiments in Pigment-Protein Complexes Eng-Michell J; Yi B; Tan X; Garashchuk S; Zazubovich V; 41662623
PHYSICS
3 High-Resolution Frequency-Domain Spectroscopic and Modeling Studies of Photosystem I (PSI), PSI Mutants and PSI Supercomplexes Zazubovich V; Jankowiak R; 38612659
PHYSICS
4 Identification of Residues Potentially Involved in Optical Shifts in the Water-Soluble Chlorophyll a-Binding Protein through Molecular Dynamics Simulations Mai M; Zazubovich V; Mansbach RA; 38299975
PHYSICS
5 Frequency-Domain Spectroscopic Study of the Photosystem I Supercomplexes, Isolated IsiA Monomers, and the Intact IsiA Ring Reinot T; Khmelnitskiy A; Zazubovich V; Toporik H; Mazor Y; Jankowiak R; 36065077
PHYSICS
6 Functional analysis of low-grade glioma genetic variants predicts key target genes and transcription factors. Manjunath M; Yan J; Youn Y; Drucker KL; Kollmeyer TM; McKinney AM; Zazubovich V; Zhang Y; Costello JF; Eckel-Passow J; Selvin PR; Jenkins RB; Song JS; 33130899
PHYSICS
7 Bound detergent molecules in bacterial reaction centers facilitate detection of tetryl explosive. Modafferi D, Zazubovich V, Kálmán L 32632533
PHYSICS
8 Evidence of Simultaneous Spectral Hole Burning Involving Two Tiers of the Protein Energy Landscape in Cytochrome b6f. Shafiei G, Levenberg A, Lujan MA, Picorel R, Zazubovich V 31763829
PHYSICS
9 How Well Does the Hole-Burning Action Spectrum Represent the Site-Distribution Function of the Lowest-Energy State in Photosynthetic Pigment-Protein Complexes? Zazubovich V, Jankowiak R 31265294
CHEMISTRY
10 Low-temperature protein dynamics of the B800 molecules in the LH2 light-harvesting complex: spectral hole burning study and comparison with single photosynthetic complex spectroscopy. Grozdanov D, Herascu N, Reinot T, Jankowiak R, Zazubovich V 20166717
PHYSICS
11 Parameters of the protein energy landscapes of several light-harvesting complexes probed via spectral hole growth kinetics measurements. Herascu N, Najafi M, Amunts A, Pieper J, Irrgang KD, Picorel R, Seibert M, Zazubovich V 21391534
PHYSICS
12 Self-assembly and sensor response of photosynthetic reaction centers on screen-printed electrodes. Bhalla V, Zazubovich V 22027137
PHYSICS
13 Effects of the distributions of energy or charge transfer rates on spectral hole burning in pigment-protein complexes at low temperatures. Herascu N, Ahmouda S, Picorel R, Seibert M, Jankowiak R, Zazubovich V 22046956
PHYSICS
14 Spectral hole burning, recovery, and thermocycling in chlorophyll-protein complexes: distributions of barriers on the protein energy landscape. Najafi M, Herascu N, Seibert M, Picorel R, Jankowiak R, Zazubovich V 22957798
PHYSICS
15 Modeling of various optical spectra in the presence of slow excitation energy transfer in dimers and trimers with weak interpigment coupling: FMO as an example. Herascu N, Kell A, Acharya K, Jankowiak R, Blankenship RE, Zazubovich V 24506338
PHYSICS
16 On the Controversial Nature of the 825 nm Exciton Band in the FMO Protein Complex. Kell A, Acharya K, Zazubovich V, Jankowiak R 26269993
PHYSICS
17 Fluorescence line narrowing and Δ-FLN spectra in the presence of excitation energy transfer between weakly coupled chromophores. Zazubovich V 25369116
PHYSICS
18 Conformational Changes in Pigment-Protein Complexes at Low Temperatures-Spectral Memory and a Possibility of Cooperative Effects. Najafi M, Herascu N, Shafiei G, Picorel R, Zazubovich V 25985255
PHYSICS
19 Monte Carlo Modeling of Spectral Diffusion Employing Multiwell Protein Energy Landscapes: Application to Pigment-Protein Complexes Involved in Photosynthesis. Najafi M, Zazubovich V 26020801
PHYSICS
20 On the Conflicting Estimations of Pigment Site Energies in Photosynthetic Complexes: A Case Study of the CP47 Complex. Reinot T, Chen J, Kell A, Jassas M, Robben KC, Zazubovich V, Jankowiak R 27279733
PHYSICS
21 A simple and efficient method to prepare pure dimers and monomers of the cytochrome b 6 f complex from spinach. Luján MA, Lorente P, Zazubovich V, Picorel R 28374305
PHYSICS
22 Probing Energy Landscapes of Cytochrome b6f with Spectral Hole Burning: Effects of Deuterated Solvent and Detergent. Levenberg A, Shafiei G, Lujan MA, Giannacopoulos S, Picorel R, Zazubovich V 28956922
PHYSICS
23 Spectral Hole Burning in Cyanobacterial Photosystem I with P700 in Oxidized and Neutral States. Herascu N, Hunter MS, Shafiei G, Najafi M, Johnson TW, Fromme P, Zazubovich V 27661089
CHEMBIOCHEM

 

Title:Effects of the distributions of energy or charge transfer rates on spectral hole burning in pigment-protein complexes at low temperatures.
Authors:Herascu NAhmouda SPicorel RSeibert MJankowiak RZazubovich V
Link:https://www.ncbi.nlm.nih.gov/pubmed/22046956?dopt=Abstract
Publication:
Keywords:
PMID:22046956 Category:J Phys Chem B Date Added:2019-06-04
Dept Affiliation: PHYSICS
1 Department of Physics, Concordia University, Montreal, Quebec, Canada.

Description:

Effects of the distributions of energy or charge transfer rates on spectral hole burning in pigment-protein complexes at low temperatures.

J Phys Chem B. 2011 Dec 22;115(50):15098-109

Authors: Herascu N, Ahmouda S, Picorel R, Seibert M, Jankowiak R, Zazubovich V

Abstract

Effects of the distributions of excitation energy transfer (EET) rates (homogeneous line widths) on the nonphotochemical (resonant) spectral hole burning (SHB) processes in photosynthetic chlorophyll-protein complexes (reaction center [RC] and CP43 antenna of Photosystem II from spinach) are considered. It is demonstrated that inclusion of such a distribution results in somewhat more dispersive hole burning kinetics. More importantly, however, inclusion of the EET rate distributions strongly affects the dependence of the hole width on the fractional hole depth. Different types of line width distributions have been explored, including those resulting from Förster type EET between weakly interacting pigments as well as Gaussian ones, which may be a reasonable approximation for those resulting, for instance, from so-called extended Förster models. For Gaussian line width distributions, it is possible to determine the parameters of both line width and tunneling parameter distributions from SHB data without a priori knowledge of any of them. Concerning more realistic asymmetric distributions, we demonstrate, using the simple example of CP43 antenna, that one can use SHB modeling to estimate electrostatic couplings between pigments and support or exclude assignment of certain pigment(s) to a particular state.

PMID: 22046956 [PubMed - indexed for MEDLINE]




BookR developed by Sriram Narayanan
for the Concordia University School of Health
Copyright © 2011-2026
Cookie settings
Concordia University