Your search keyword '"Ya-Ting Kao"' showing total 50 results

1. Targeted Covalent Inhibitors Allosterically Deactivate the DEDDh Lassa Fever Virus NP Exonuclease from Alternative Distal Sites

Author

Kuan-Wei Huang, Jing-Wen Chen, Tzu-Yu Hua, Yu-Yu Chu, Tsai-Yuan Chiu, Jung-Yu Liu, Chun-I Tu, Kai-Cheng Hsu, Ya-Ting Kao, Jhih-Wei Chu, and Yu-Yuan Hsiao

Subjects

Chemistry, QD1-999

Published

2021

2. Effects of Distal Mutations on Ligand-Binding Affinity in E. coli Dihydrofolate Reductase

Author

Chen-Hua Huang, Yun-Wen Chen, Tsun-Tsao Huang, and Ya-Ting Kao

Subjects

Chemistry, QD1-999

Published

2021

3. Targeted Covalent Inhibitors Allosterically Deactivate the DEDDh Lassa Fever Virus NP Exonuclease from Alternative Distal Sites

Author

Kai-Cheng Hsu, Ya-Ting Kao, Jung-Yu Liu, Tsai-Yuan Chiu, Jhih-Wei Chu, Tzu-Yu Hua, Chun-I Tu, Jing-Wen Chen, Yu-Yuan Hsiao, Kuan-Wei Huang, and Yu-Yu Chu

Subjects

Exonuclease, biology, Chemistry, DEDDh exonuclease, Lassa fever virus, Virology, Article, NP exonuclease, molecular dynamics, inhibitor, Covalent bond, organomercurial, biology.protein, QD1-999

Abstract

For using targeted covalent inhibitors (TCIs) as anticancer and antiviral drugs, we establish that the model compounds PCMPS (p-chloromercuriphenyl sulfate) and PCMB (p-chloromercuribenzoate) are inhibitors of the DEDDh family of exonucleases. The underlying mechanism is analyzed by X-ray crystallography, activity/nucleic acid-binding assays, and all-atom molecular dynamics (MD) simulations. The first TCI-complexed structures of a DEDDh enzyme, the Lassa fever virus NP exonuclease (NPexo), are resolved to elucidate that the Cys409 binding site is away from the active site and the RNA-binding lid. The NPexo C409A structures indicate Cys461 as the alternative distal site for obstructing the equally active mutant. All-atom MD simulations of the wild type and mutant NPexos in explicit solvent uncover an allosteric inhibition mechanism that the local perturbation induced by PCMPS sulfonate propagates to impact the RNA-binding lid conformation. Binding assay studies confirm that PCMPS does affect the RNA binding of NPexo. The predicted relative potency between PCMPS and PCMB is also in line with experiments. The structural data and inhibition mechanism established in this work provide an important molecular basis for the drug development of TCIs.

Published

2021

4. Efficient and Reversible Catalysis of Formic Acid‐Carbon Dioxide Cycle Using Carbamate‐Substituted Ruthenium‐Dithiolate Complexes

Author

Chi Hsuan Liao, Wan Hsiang Lien, Ya Ting Kao, Tung-Kung Wu, Yi Ting Chen, Sheng Cih Huang, Jen Shiang K. Yu, Feng-Pai Chou, Hui Min Tsai, and Chin-Yuan Chang

Subjects

Carbamate, Hydrogen, Chemistry, Formic acid, business.industry, medicine.medical_treatment, Organic Chemistry, Inorganic chemistry, chemistry.chemical_element, Solar energy, Catalysis, Ruthenium, Carbon cycle, Inorganic Chemistry, chemistry.chemical_compound, Carbon dioxide, medicine, Physical and Theoretical Chemistry, business

Published

2021

5. Effects of Distal Mutations on Ligand-Binding Affinity in

Author

Tsun-Tsao Huang, Chen-Hua Huang, Ya-Ting Kao, and Yun-Wen Chen

Subjects

Mutation, biology, Chemistry, General Chemical Engineering, Point mutation, Mutant, Wild type, General Chemistry, medicine.disease_cause, Article, Cofactor, Dissociation constant, Catalytic cycle, Dihydrofolate reductase, medicine, Biophysics, biology.protein, QD1-999

Abstract

Mutations far from the center of chemical activity in dihydrofolate reductase (DHFR) can affect several steps in the catalytic cycle. Mutations at highly conserved positions and the distal distance of the catalytic center (Met-42, Thr-113, and Gly-121) were designed, including single-point and double-point mutations. Upon ligand binding, the fluorescence of the intrinsic optical probe, tryptophan, decreases due to either fluorescence quenching or energy transfer. We demonstrated an optical approach in measuring the equilibrium dissociation constant for enzyme–cofactor, enzyme–substrate, and enzyme–product complexes in wildtype ecDHFR and each mutant. We propose that the effects of these distal mutations on ligand-binding affinity stem from the spatial steric hindrance, the disturbance on the hydrogen network, or the modification of the protein flexibility. The modified N-terminus tag in DHFR acts as a cap on the entrance of the substrate-binding cavity, squeezes the adenosine binding subdomain, and influences the binding of NADPH in some mutants. If the mutation positions are away from the N-terminus tag and the adenosine binding subdomain, the additive effects due to the N-terminus tag were not observed. In the double-mutant-cycle analysis, double mutations show nonadditive properties upon either cofactor or substrate binding. Also, in general, the first point mutation strongly affects the ligand binding compared to the second one.

Published

2021

6. Hydration dynamics and time scales of coupled water-protein fluctuations

Author

Tanping Li, Hassanali, Ali A., Ya-Ting Kao, Dongping Zhong, and Singer, Sherwin J.

Subjects

Myoglobin -- Optical properties, Myoglobin -- Spectra, Excited state chemistry -- Research, Hydration (Chemistry) -- Observations, Chemistry

Abstract

A study on water and protein dynamic of Sperm-Whale myoglobin (Mb) following photoexcitation of a particular site, Trp7 is presented. It is observed that large inertial relaxations forecasted by simulations were not present in experiment and hence improvements in the theoretical model are presented.

Published

2007

7. Ultrafast hydration dynamics in melittin folding and aggregation: Helix formation and tetramer self-assembly

Author

Weihong Qiu, Luyuan Zhang, Ya-Ting Kao, Wenyun Lu, and Tanping Li

Subjects

Hydration (Chemistry) -- Analysis, Protein folding -- Analysis, Protein research, Chemicals, plastics and rubber industries

Abstract

The hydration dynamics in different conformations of melittin from a random coil, to a folded alpha-helix, and to self-assembled tetramer is studied using intrinsic tryptophan as a molecular probe. It is observed that the solvation dynamics occurs in 0.62 and 14.7 ps in a random-coiled primary structure, which indicates critical role of hydration dynamics in peptide conformational transitions and protein structural stability and integrity.

Published

2005

8. A tunable fluorescent timer method for imaging spatial-temporal protein dynamics using light-driven photoconvertible protein

Author

Wei Min, Fang Xu, Xinxin Zhu, Ya-Ting Kao, and Luyuan Zhang

Subjects

endocrine system, Protein dynamics, General Engineering, General Physics and Astronomy, Nanotechnology, General Chemistry, Biology, Fluorescence, General Biochemistry, Genetics and Molecular Biology, Live cell imaging, Laser intensity, Light driven, Fluorescence microscope, General Materials Science, Timer, Biological system

Abstract

Cellular function is largely determined by protein behaviors occurring in both space and time. While regular fluorescent proteins can only report spatial locations of the target inside cells, fluorescent timers have emerged as an invaluable tool for revealing coupled spatial-temporal protein dynamics. Existing fluorescent timers are all based on chemical maturation. Herein we propose a light-driven timer concept that could report relative protein ages at specific sub-cellular locations, by weakly but chronically illuminating photoconvertible fluorescent proteins inside cells. This new method exploits light, instead of oxygen, as the driving force. Therefore its timing speed is optically tunable by adjusting the photoconverting laser intensity. We characterized this light-driven timer method both in vitro and in vivo and applied it to image spatiotemporal distributions of several proteins with different lifetimes. This novel timer method thus offers a flexible “ruler” for studying temporal hierarchy of spatially ordered processes with exquisite spatial-temporal resolution. (© 2015 WILEY-VCH Verlag GmbH &Co. KGaA, Weinheim)

Published

2014

9. Ultrafast dynamics of resonance energy transfer in myoglobin: probing local conformation fluctuations

Author

Stevens, Jeffrey A., Link, Justin J., Ya-Ting Kao, Chen Zang, Lijuan Wang, and Dongping Zhong

Subjects

Energy transformation -- Analysis, Mutagenesis -- Analysis, Myoglobin -- Structure, Myoglobin -- Chemical properties, Myoglobin -- Thermal properties, Tryptophan -- Chemical properties, Chemicals, plastics and rubber industries

Published

2010

10. Comparative photochemistry of animal type 1 and type 4 cryptochromes

Author

Ozturk, Nuri, Selby, Christopher P., Sang-Hun Song, Rui Ye, Chuang Tan, Ya-Ting Kao, Dongping Zhong, and Sancar, Aziz

Subjects

Proteins -- Spectra, Proteins -- Research, Phosphotransferases -- Research, Biological sciences, Chemistry

Abstract

The article studies the purification of type 4 cryptochromes (CRYs) of zebrafish and chicken as recombinant proteins with full flavin complement and evaluate the spectroscopic properties of type 4 and type 1 CRYs. Results revealed that in contrast to animal type 2 CRYs and Arabidopsis CRY1 neither insect type 1 nor type 4 CRYs has autokinase activities.

Published

2009

11. Protein hydration dynamics and molecular mechanism of coupled water-protein fluctuations

Author

Luyuan Zhang, Yi Yang, Ya-Ting Kao, Lijuan Wang, and Dongping Zhong

Subjects

Hydration (Chemistry) -- Analysis, Myoglobin -- Structure, Myoglobin -- Chemical properties, Protein folding -- Analysis, Tryptophan -- Chemical properties, Chemistry

Abstract

A systematic global mapping of water motions in the hydration layer around a model protein of apomyoglobin in both native and molten globule states is reported. The results provide insight into a series of correlations of hydrating water dynamics and coupled fluctuations with local protein's chemical and structural properties which are significant for various water behaviors in the hydration layer with wide heterogeneity.

Published

2009

12. Molecular-Switch-Mediated Multiphoton Fluorescence Microscopy with High-Order Nonlinearity

Author

Xinxin Zhu, Wei Min, and Ya-Ting Kao

Subjects

Molecular switch, education.field_of_study, Fluorescence-lifetime imaging microscopy, Optical sectioning, business.industry, Chemistry, Population, Optics, Two-photon excitation microscopy, Fluorescence microscope, General Materials Science, Physical and Theoretical Chemistry, business, education, Spectroscopy, Penetration depth

Abstract

Two-photon excited fluorescence microscopy is now an indispensable imaging tool for studying biological samples because of its intrinsic optical sectioning. However, both of its contrast and penetration depth are still limited when imaging deep inside of scattering samples. Herein, we propose a general spectroscopy concept to enhance the image contrast and the fundamental depth limit of two-photon imaging. We show that the population transfer kinetics of the photoinduced molecular switches could generate additional high-order nonlinearity between the signal and the laser intensity. Due to the long-lived nature of these switchable states, the incident photons can operate in a sequential manner, and the nonlinearity effect could accumulate (up to sixth order) as the population is being cycled through these states. Conceptually different from conventional multiphoton processes mediated by transient virtual states, our strategy constitutes a new class of fluorescence microscopy with high-order nonlinearity th...

Published

2012

13. Focal switching of photochromic fluorescent proteins enables multiphoton microscopy with superior image contrast

Author

Wei Min, Xinxin Zhu, Ya-Ting Kao, and Fang Xu

Subjects

Microscopy, ocis:(180.4315) Nonlinear microscopy, Materials science, business.industry, Scattering, Image processing, Signal, Fluorescence, Atomic and Molecular Physics, and Optics, Light scattering, Dronpa, Optics, ocis:(190.4180) Multiphoton processes, ocis:(180.2520) Fluorescence microscopy, Fluorescence microscope, Laser power scaling, business, Biotechnology

Abstract

Probing biological structures and functions deep inside live organisms with light is highly desirable. Among the current optical imaging modalities, multiphoton fluorescence microscopy exhibits the best contrast for imaging scattering samples by employing a spatially confined nonlinear excitation. However, as the incident laser power drops exponentially with imaging depth into the sample due to the scattering loss, the out-of-focus background eventually overwhelms the in-focus signal, which defines a fundamental imaging-depth limit. Herein we significantly improve the image contrast for deep scattering samples by harnessing reversibly switchable fluorescent proteins (RSFPs) which can be cycled between bright and dark states upon light illumination. Two distinct techniques, multiphoton deactivation and imaging (MPDI) and multiphoton activation and imaging (MPAI), are demonstrated on tissue phantoms labeled with Dronpa protein. Such a focal switch approach can generate pseudo background-free images. Conceptually different from wave-based approaches that try to reduce light scattering in turbid samples, our work represents a molecule-based strategy that focused on imaging probes.

Published

2012

14. Electron Tunneling Pathways and Role of Adenine in Repair of Cyclobutane Pyrimidine Dimer by DNA Photolyase

Author

Ya Ting Kao, Xunmin Guo, Aziz Sancar, Zheyun Liu, Chuang Tan, Dongping Zhong, Jiang Li, and Lijuan Wang

Subjects

Models, Molecular, DNA Repair, Light, Stereochemistry, Dimer, Pyrimidine dimer, Photochemistry, Biochemistry, Article, Catalysis, Cyclobutane, Electron Transport, chemistry.chemical_compound, Electron transfer, Colloid and Surface Chemistry, Catalytic Domain, Escherichia coli, Photolyase, Chemistry, Adenine, General Chemistry, DNA photolyase, Electron transport chain, Thymine, Pyrimidine Dimers, Biocatalysis, Deoxyribodipyrimidine Photo-Lyase

Abstract

Electron tunneling pathways in enzymes are critical to their catalytic efficiency. Through electron tunneling, photolyase, a photoenzyme, splits UV-induced cyclobutane pyrimidine dimer into two normal bases. Here, we report our systematic characterization and analyses of photoinitiated three electron transfer processes and cyclobutane ring splitting by following the entire dynamical evolution during enzymatic repair with femtosecond resolution. We observed the complete dynamics of the reactants, all intermediates and final products, and determined their reaction time scales. Using (deoxy)uracil and thymine as dimer substrates, we unambiguously determined the electron tunneling pathways for the forward electron transfer to initiate repair and for the final electron return to restore the active cofactor and complete the catalytic photocycle. Significantly, we found that the adenine moiety of the unusual bent flavin cofactor is essential to mediating all electron-transfer dynamics through a superexchange mechanism, leading to a delicate balance of time scales. The cyclobutane ring splitting takes tens of picoseconds, while electron-transfer dynamics all occur on a longer time scale. The active-site structural integrity, unique electron tunneling pathways, and the critical role of adenine ensure the synergy of these elementary steps in this complex photorepair machinery to achieve maximum repair efficiency which is close to unity. Finally, we used the Marcus electron-transfer theory to evaluate all three electron-transfer processes and thus obtained their reaction driving forces (free energies), reorganization energies, and electronic coupling constants, concluding that the forward and futile back-electron transfer is in the normal region and that the final electron return of the catalytic cycle is in the inverted region.

Published

2012

15. Protein-flexibility mediated coupling between photoswitching kinetics and surrounding viscosity of a photochromic fluorescent protein

Author

Xinxin Zhu, Wei Min, and Ya-Ting Kao

Subjects

Models, Molecular, Light, Photoisomerization, Photochemistry, Protein Conformation, Ultraviolet Rays, Recombinant Fusion Proteins, Kinetics, Fluorescence, Histones, Microviscosity, Dronpa, Photochromism, Protein structure, Isomerism, Genes, Reporter, Animals, Humans, Fluorescent Dyes, Multidisciplinary, Viscosity, Chemistry, Chromophore, Anthozoa, Solutions, Luminescent Proteins, HEK293 Cells, Amino Acid Substitution, Microscopy, Fluorescence, Physical Sciences, Solvents, Biophysics, Crystallization

Abstract

Recent advances in fluorescent proteins (FPs) have generated a remarkable family of optical highlighters with special light responses. Among them, Dronpa exhibits a unique capability of reversible light-regulated on-off switching. However, the environmental dependence of this photochromism is largely unexplored. Herein we report that the photoswitching kinetics of the chromophore inside Dronpa is actually slowed down by increasing medium viscosity outside Dronpa. This finding is a special example of an FP where the environment can exert a hydrodynamic effect on the internal chromophore. We attribute this effect to protein-flexibility mediated coupling where the chromophore’s cis-trans isomerization during photoswitching is accompanied by conformational motion of a part of the protein β-barrel whose dynamics should be hindered by medium friction. Consistent with this mechanism, the photoswitching kinetics of Dronpa-3, a structurally more flexible mutant, is found to exhibit a more pronounced viscosity dependence. Furthermore, we mapped out spatial distributions of microviscosity in live cells experienced by a histone protein using the photoswitching kinetics of Dronpa-3 fusion as a contrast mechanism. This unique reporter should provide protein-specific information about the crowded intracellular environments by offering a genetically encoded microviscosity probe, which did not exist with normal FPs before.

Published

2012

16. Ultrafast dynamics of flavins in five redox states

Author

Ya-Ting Kao, Saxena, Chaitanya, Ting-Fang He, Lijun Guo, Lijuan Wang, Sancar, Aziz, and Donping Zhong

Subjects

Excited state chemistry -- Research, Flavin adenine dinucleotide -- Chemical properties, Flavin adenine dinucleotide -- Electric properties, Flavin mononucleotide -- Electric properties, Flavin mononucleotide -- Chemical properties, Oxidation-reduction reaction -- Analysis, Chemistry

Abstract

The excited-state dynamics of two common flavin molecules in five redox states are studied in solution and in inert protein environments with femtosecond resolution. The time scales of these dynamics in five redox states have helped in understanding the excited-state behavior of flavins and also the functionality of flavins in flavoproteins for their biological activities.

Published

2008

17. Purification and characterization of a type III photolyase from Caulobacter crescentus

Author

Ozturk, Nuri, Ya-Ting Kao, Selby, Christopher P., Kavakh, I. Halil, Partch, Carrie L., Dongoing Zhong, and Sancar, Aziz

Subjects

Caulobacter -- Physiological aspects, Photolysis -- Analysis, Biological sciences, Chemistry

Abstract

Various spectroscopic analyses are conducted to explain the isolation and characterization of a type III photolyase, obtained from Caulobacter crescentus. The enzyme is shown to cosegregate with plant cryptochromes, as it contains both the methenyl tetrahydrofolate photoantenna and the FAD catalytic cofactor.

Published

2008

18. Dynamics and mechanism of cyclobutane pyrimidine dimer repair by DNA photolyase

Author

Lijuan Wang, Zheyun Liu, Chuang Tan, Xunmin Guo, Jiang Li, Ya Ting Kao, Aziz Sancar, and Dongping Zhong

Subjects

Deoxyribodipyrimidine photo-lyase, chemistry.chemical_compound, Multidisciplinary, chemistry, DNA repair, Mutagenesis, Fungal genetics, Pyrimidine dimer, DNA photolyase, Biological Sciences, Photolyase, Photochemistry, Cyclobutane

Abstract

Photolyase uses blue light to restore the major ultraviolet (UV)-induced DNA damage, the cyclobutane pyrimidine dimer (CPD), to two normal bases by splitting the cyclobutane ring. Our earlier studies showed that the overall repair is completed in 700 ps through a cyclic electron-transfer radical mechanism. However, the two fundamental processes, electron-tunneling pathways and cyclobutane ring splitting, were not resolved. Here, we use ultrafast UV absorption spectroscopy to show that the CPD splits in two sequential steps within 90 ps and the electron tunnels between the cofactor and substrate through a remarkable route with an intervening adenine. Site-directed mutagenesis reveals that the active-site residues are critical to achieving high repair efficiency, a unique electrostatic environment to optimize the redox potentials and local flexibility, and thus balance all catalytic reactions to maximize enzyme activity. These key findings reveal the complete spatio-temporal molecular picture of CPD repair by photolyase and elucidate the underlying molecular mechanism of the enzyme’s high repair efficiency.

Published

2011

19. Femtosecond studies of tryptophan fluorescence dynamics in proteins: Local solvation and electronic quenching

Author

Luyuan Zhang, Ya-Ting Kao, Weihong Qiu, Lijuan Wang, and Dongping Zhong

Subjects

Fluorescence -- Analysis, Hydration (Chemistry) -- Analysis, Tryptophan -- Structure, Tryptophan -- Chemical properties, Tryptophan -- Optical properties, Protein research, Chemicals, plastics and rubber industries

Abstract

A study presents a systematic examination of tryptophan fluorescence dynamics in proteins with femtosecond resolution, in which distinct patterns of femtosecond-resolved fluorescence transients from the blue to the red side of emission are characterized to distinguish local ultrafast salvation and electronic quenching. Tryptophan is found to be an ideal local optical probe for hydration dynamics and protein-water interactions as well as an excellent local molecular reporter for ultrafast electron transfer in proteins.

Published

2006

20. Comparative Photochemistry of Animal Type 1 and Type 4 Cryptochromes

Author

Ya Ting Kao, Rui Ye, Dongping Zhong, Christopher P. Selby, Nuri Ozturk, Chuang Tan, Aziz Sancar, and Sang-Hun Song

Subjects

Light, Photochemistry, Flavin group, Biology, Biochemistry, Article, Cofactor, Cell Line, Avian Proteins, 03 medical and health sciences, 0302 clinical medicine, Cryptochrome, Flavins, Arabidopsis, Anopheles, Escherichia coli, Animals, Drosophila Proteins, Humans, Zebrafish, 030304 developmental biology, Regulation of gene expression, 0303 health sciences, Flavoproteins, HEK 293 cells, Zebrafish Proteins, biology.organism_classification, Rats, Cryptochromes, Cell culture, Flavin-Adenine Dinucleotide, biology.protein, Chickens, Deoxyribodipyrimidine Photo-Lyase, 030217 neurology & neurosurgery

Abstract

Cryptochromes (CRYs) are blue-light photoreceptors with known or presumed functions in light-dependent and light-independent gene regulation in plants and animals. Although the photochemistry of plant CRYs has been studied in some detail, the photochemical behavior of animal cryptochromes remains poorly defined in part because it has been difficult to purify animal CRYs with their flavin cofactors. Here we describe the purification of type 4 CRYs of zebrafish and chicken as recombinant proteins with full flavin complement and compare the spectroscopic properties of type 4 and type 1 CRYs. In addition, we analyzed photoinduced proteolytic degradation of both types of CRYs in vivo in heterologous systems. We find that even though both types of CRYs contain stoichiometric flavin, type 1 CRY is proteolytically degraded by a light-initiated reaction in Drosophila S2, zebrafish Z3, and human HEK293T cell lines, but zebrafish CRY4 (type 4) is not. In vivo degradation of type 1 CRYs does not require continuous illumination, and a single light flash of 1 ms duration leads to degradation of about 80% of Drosophila CRY in 60 min. Finally, we demonstrate that in contrast to animal type 2 CRYs and Arabidopsis CRY1 neither insect type 1 nor type 4 CRYs have autokinase activities.

Published

2009

21. Protein Hydration Dynamics and Molecular Mechanism of Coupled Water−Protein Fluctuations

Author

Dongping Zhong, Yang Yang, Luyuan Zhang, Ya-Ting Kao, and Lijuan Wang

Subjects

Models, Molecular, Protein Folding, Time Factors, Rotation, Fluorescence Polarization, Biochemistry, Protein Structure, Secondary, Catalysis, Colloid and Surface Chemistry, Protein structure, Animals, Humans, Sperm Whale, Myoglobin, Chemistry, Relaxation (NMR), Tryptophan, Solvation, Water, Hydrogen Bonding, General Chemistry, Molten globule, Crystallography, Spectrometry, Fluorescence, Solvation shell, Chemical physics, Structural stability, Picosecond, Protein folding, Apoproteins

Abstract

Protein surface hydration is fundamental to its structural stability and flexibility, and water-protein fluctuations are essential to biological function. Here, we report a systematic global mapping of water motions in the hydration layer around a model protein of apomyoglobin in both native and molten globule states. With site-directed mutagenesis, we use intrinsic tryptophan as a local optical probe to scan the protein surface one at a time with single-site specificity. With femtosecond resolution, we examined 16 mutants in two states and observed two types of water-network relaxation with distinct energy and time distributions. The first water motion results from the local collective hydrogen-bond network relaxation and occurs in a few picoseconds. The initial hindered motions, observed in bulk water in femtoseconds, are highly suppressed and drastically slow down due to structured water-network collectivity in the layer. The second water-network relaxation unambiguously results from the lateral cooperative rearrangements in the inner hydration shell and occurs in tens to hundreds of picoseconds. Significantly, this longtime dynamics is the coupled interfacial water-protein motions and is the direct measurement of such cooperative fluctuations. These local protein motions, although highly constrained, are necessary to assist the longtime water-network relaxation. A series of correlations of hydrating water dynamics and coupled fluctuations with local protein's chemical and structural properties were observed. These results are significant and reveal various water behaviors in the hydration layer with wide heterogeneity. We defined a solvation speed and an angular speed to quantify the water-network rigidity and local protein flexibility, respectively. We also observed that the dynamic hydration layer extends to more than 10 A. Finally, from native to molten globule states, the hydration water networks loosen up, and the protein locally becomes more flexible with larger global plasticity and partial unfolding.

Published

2009

22. Purification and Characterization of a Type III Photolyase from Caulobacter crescentus

Author

I. Halil Kavakli, Carrie L. Partch, Dongping Zhong, Nuri Ozturk, Ya Ting Kao, Aziz Sancar, and Christopher P. Selby

Subjects

DNA, Bacterial, DNA Repair, Arabidopsis, Flavoprotein, Pyrimidine dimer, Biochemistry, Chromatography, Affinity, Article, Cofactor, Deoxyribodipyrimidine photo-lyase, Bacterial Proteins, Cryptochrome, Caulobacter crescentus, Escherichia coli, Cloning, Molecular, Photolyase, Phylogeny, biology, biology.organism_classification, Recombinant Proteins, FAD binding, biology.protein, Deoxyribodipyrimidine Photo-Lyase, DNA Damage

Abstract

Photolyase/cryptochrome family is a large family of flavoproteins that encompasses DNA repair proteins, photolyases; and cryptochromes that regulate blue-light dependent growth and development in plants, and light-dependent and light-independent circadian clock-setting in animals. Phylogenetic analysis has revealed a new branch of the family which co-segregates with plant cryptochromes. Here we describe the isolation and characterization of a member of this family named Type III photolyase, from Caulobacter crescentus. Spectroscopic analysis shows that the enzyme contains both the methenyl-tetrahydrofolate photoantenna and the FAD catalytic cofactor. Biochemical analysis shows that it is a bona fide photolyase that repairs cyclobutane pyrimidine dimers. Mutation of an active site Trp to Arg disrupts FAD binding with no measurable effect on MTHF binding. Using enzyme preparations that contain either or both chromophores we were able to determine the efficiency and rate of energy transfer from MTHF to FAD. Photolyase/cryptochrome family is a large family of flavoproteins that encompasses DNA repair proteins, photolyases; and cryptochromes that regulate blue-light dependent growth and development in plants, and light-dependent and light-independent circadian clock-setting in animals. Phylogenetic analysis has revealed a new branch of the family which co-segregates with plant cryptochromes. Here we describe the isolation and characterization of a member of this family named Type III photolyase, from Caulobacter crescentus. Spectroscopic analysis shows that the enzyme contains both the methenyl-tetrahydrofolate photoantenna and the FAD catalytic cofactor. Biochemical analysis shows that it is a bona fide photolyase that repairs cyclobutane pyrimidine dimers. Mutation of an active site Trp to Arg disrupts FAD binding with no measurable effect on MTHF binding. Using enzyme preparations that contain either or both chromophores we were able to determine the efficiency and rate of energy transfer from MTHF to FAD.

Published

2008

23. Ultrafast quenching of tryptophan fluorescence in proteins: Interresidue and intrahelical electron transfer

Author

Ya-Ting Kao, Tanping Li, Dongping Zhong, Yang Yang, Weihong Qiu, Luyuan Zhang, and Lijuan Wang

Subjects

Indole test, Quantitative Biology::Biomolecules, Chemistry, High Energy Physics::Lattice, Protein dynamics, Tryptophan, General Physics and Astronomy, Photochemistry, Molecular dynamics, Electron transfer, Protein structure, Molecular orbital, Physics::Chemical Physics, Physical and Theoretical Chemistry, HOMO/LUMO

Abstract

Quenching of tryptophan fluorescence in proteins has been critical to the understanding of protein dynamics and enzyme reactions using tryptophan as a molecular optical probe. We report here our systematic examinations of potential quenching residues with more than 40 proteins. With site-directed mutation, we placed tryptophan to desired positions or altered its neighboring residues to screen quenching groups among 20 amino acid residues and of peptide backbones. With femtosecond resolution, we observed the ultrafast quenching dynamics within 100 ps and identified two ultrafast quenching groups, the carbonyl- and sulfur-containing residues. The former is glutamine and glutamate residues and the later is disulfide bond and cysteine residue. The quenching by the peptide-bond carbonyl group as well as other potential residues mostly occurs in longer than 100 ps. These ultrafast quenching dynamics occur at van der Waals distances through intraprotein electron transfer with high directionality. Following optimal molecular orbital overlap, electron jumps from the benzene ring of the indole moiety in a vertical orientation to the LUMO of acceptor quenching residues. Molecular dynamics simulations were invoked to elucidate various correlations of quenching dynamics with separation distances, relative orientations, local fluctuations and reaction heterogeneity. These unique ultrafast quenching pairs, as recently found to extensively occur in high-resolution protein structures, may have significant biological implications.

Published

2008

24. Mapping hydration dynamics around a protein surface

Author

Luyuan Zhang, Weihong Qiu, Ya Ting Kao, Lijuan Wang, Dongping Zhong, Yang Yang, and Oghaghare Okobiah

Subjects

Models, Molecular, Time Factors, Multidisciplinary, Myoglobin, Surface Properties, Chemistry, Relaxation (NMR), Dynamics (mechanics), Tryptophan, Water, A protein, Crystallography, X-Ray, Protein Structure, Tertiary, Crystallography, Protein structure, Water dynamics, Chemical physics, Picosecond, Mutation, Physical Sciences, Apoproteins, Surface protein

Abstract

Protein surface hydration is fundamental to its structure and activity. We report here the direct mapping of global hydration dynamics around a protein in its native and molten globular states, using a tryptophan scan by site-specific mutations. With 16 tryptophan mutants and in 29 different positions and states, we observed two robust, distinct water dynamics in the hydration layer on a few ( approximately 1-8 ps) and tens to hundreds of picoseconds ( approximately 20-200 ps), representing the initial local relaxation and subsequent collective network restructuring, respectively. Both time scales are strongly correlated with protein's structural and chemical properties. These results reveal the intimate relationship between hydration dynamics and protein fluctuations and such biologically relevant water-protein interactions fluctuate on picosecond time scales.

Published

2007

25. Formation and Function of Flavin Anion Radical in Cryptochrome 1 Blue-Light Photoreceptor of Monarch Butterfly

Author

Haisun Zhu, Tracy R. Denaro, Ya Ting Kao, Dongping Zhong, Aziz Sancar, Sang-Hun Song, Steven M. Reppert, N. Özlem Arat, and Nuri Ozturk

Subjects

Anions, Photochemistry, Stereochemistry, Flavoprotein, Flavin group, Biochemistry, Cofactor, Residue (chemistry), Electron transfer, Cryptochrome, Flavins, Animals, heterocyclic compounds, Photopigment, Molecular Biology, Action spectrum, Flavoproteins, biology, Cell Biology, Cryptochromes, biology.protein, Insect Proteins, Photoreceptor Cells, Invertebrate, Butterflies, Oxidation-Reduction

Abstract

The monarch butterfly (Danaus plexippus) cryptochrome 1 (DpCry1) belongs in the class of photosensitive insect cryptochromes. Here we purified DpCry1 expressed in a bacterial host and obtained the protein with a stoichiometric amount of the flavin cofactor in the two-electron oxidized, FAD(ox), form. Exposure of the purified protein to light converts the FAD(ox) to the FAD*(-) flavin anion radical by intraprotein electron transfer from a Trp residue in the apoenzyme. To test whether this novel photoreduction reaction is part of the DpCry1 physiological photocycle, we mutated the Trp residue that acts as the ultimate electron donor in flavin photoreduction. The mutation, W328F, blocked the photoreduction entirely but had no measurable effect on the light-induced degradation of DpCry1 in vivo. In light of this finding and the recently published action spectrum of this class of Crys, we conclude that DpCry1 and similar insect cryptochromes do not contain flavin in the FAD(ox) form in vivo and that, most likely, the [see text] photoreduction reaction is not part of the insect cryptochrome photoreaction that results in proteolytic degradation of the photopigment.

Published

2007

26. Fluorescence lifetime and nonradiative relaxation dynamics of DCM in nonpolar solvent

Author

Chih-Wei Chang, Ya-Ting Kao, and Eric Wei-Guang Diau

Subjects

Intersystem crossing, Tertiary amine, Chemistry, Excited state, Relaxation (NMR), Femtosecond, General Physics and Astronomy, Time-dependent density functional theory, Physical and Theoretical Chemistry, Photochemistry, Fluorescence, Excitation

Abstract

The nonradiative dynamics of DCM in hexane have been investigated using femtosecond fluorescence up-conversion technique at three excitation wavelengths (400, 445 and 480 nm). The S 1 lifetime was observed to be 9.8 ± 0.5 ps, which is independent of the excitation and the fluorescence wavelengths. The observed S 1 lifetimes of DCJT and DCJTB are slower than those of DCM and DCMB by one order of magnitude, indicating the significance of the twisting motion of the amino group affecting the S 1 nonradiative dynamics. TDDFT calculations suggest that an intersystem crossing is responsible for the observed S 1 dynamics of DCM in nonpolar solvent.

Published

2003

27. Production of HCO from propenal photolyzed at 193 nm: Relaxation of excited states and distribution of internal states of fragment HCO

Author

Wei-Chen Chen, I-Chia Chen, Ya-Ting Kao, and Chin-Hui Yu

Subjects

Space theory, Spin states, Chemistry, Excited state, Photodissociation, General Physics and Astronomy, Energy partitioning, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics, Fluorescence, Excitation, Dissociation (chemistry)

Abstract

The dynamics of photodissociation of propenal at 193 nm are studied by detecting laser-induced fluorescence of nascent fragment HCO in its transition B 2A′–X 2A′. Rotational states up to N=30 and K=3 of HCO X 2A′ are populated and vibrational states (000), (010), and (001) are detected. The Ka=1 doublet states and the two spin states for all vibrational levels detected are nearly equally populated. Much less rotational excitation is observed than the distributions calculated on a statistical model—phase space theory. This implies that dissociation occurs from the triplet channel with a small exit barrier. Small rotational excitation arises from the repulsive part of the exit barrier and the geometry of the transition state on the triplet surface. Experimental data yield an energy partitioning with translation, rotation, and vibration of HCO at 3.0, 1.3, and 1.5 kcal/mol, respectively, in total accounting for 11.5% of available energy. These results indicate that the other fragment C2H3 has 3.2 kcal/mol...

Published

2001

28. A tunable fluorescent timer method for imaging spatial-temporal protein dynamics using light-driven photoconvertible protein

Author

Xinxin, Zhu, Luyuan, Zhang, Ya-Ting, Kao, Fang, Xu, and Wei, Min

Subjects

Models, Molecular, Luminescent Proteins, HEK293 Cells, Spectrometry, Fluorescence, Time Factors, Light, Intracellular Space, Animals, Humans, Protein Structure, Secondary, Molecular Imaging

Abstract

Cellular function is largely determined by protein behaviors occurring in both space and time. While regular fluorescent proteins can only report spatial locations of the target inside cells, fluorescent timers have emerged as an invaluable tool for revealing coupled spatial-temporal protein dynamics. Existing fluorescent timers are all based on chemical maturation. Herein we propose a light-driven timer concept that could report relative protein ages at specific sub-cellular locations, by weakly but chronically illuminating photoconvertible fluorescent proteins inside cells. This new method exploits light, instead of oxygen, as the driving force. Therefore its timing speed is optically tunable by adjusting the photoconverting laser intensity. We characterized this light-driven timer method both in vitro and in vivo and applied it to image spatiotemporal distributions of several proteins with different lifetimes. This novel timer method thus offers a flexible "ruler" for studying temporal hierarchy of spatially ordered processes with exquisite spatial-temporal resolution.

Published

2013

29. Ultrafast Dynamics of Nonequilibrium Electron Transfer in Photoinduced Redox Cycle: Solvent Mediation and Conformation Flexibility

Author

Yang Yang, Ali Hassanali, Ya-Ting Kao, Zheyun Liu, Dongping Zhong, Xunmin Guo, Qin-Hua Song, and Lijuan Wang

Subjects

chemistry.chemical_classification, Acetonitriles, Time Factors, Tryptophan, Water, Electron donor, Electron acceptor, Photochemistry, Article, Surfaces, Coatings and Films, Solvent, Dioxanes, Electron Transport, Electron transfer, chemistry.chemical_compound, chemistry, Covalent bond, Picosecond, Femtosecond, Materials Chemistry, Solvents, Physical and Theoretical Chemistry, Acetonitrile, Oxidation-Reduction, Thymine

Abstract

We report here our systematic characterization of a photoinduced electron-transfer (ET) redox cycle in a covalently linked donor-spacer-acceptor flexible system, consisting of N-acetyl-tryptophan methylester as an electron donor and thymine as an electron acceptor in three distinct solvents of water, acetonitrile, and dioxane. With femtosecond resolution, we determined all the ET time scales, forward and backward, by following the complete reaction evolution from reactants to intermediates and finally to products. Surprisingly, we observed two distinct ET dynamics in water, corresponding to a stacked configuration with ultrafast ET in 0.7 ps and back ET in 4.5 ps and a partially folded C-clamp conformation with ET in 322 ps but back ET in 17 ps. In acetonitrile and dioxane, only the C-clamp conformations were observed with ET in 470 and 1068 ps and back ET in 110 and 94 ps, respectively. These relatively slow ET dynamics in hundreds of picoseconds all showed significant conformation heterogeneity and followed a stretched decay behavior. With both forward and back ET rates determined, we derived solvent reorganization energies and coupling constants. Significantly, we found that solvent molecules intercalated in the cleft of the C-clamp structure mediate electron transfer with a tunneling parameter (β) of 1.0-1.4 Å(-1) and the high-frequency vibration modes in the product(s) couple with the back ET process, leading to the ultrafast back ET dynamics in tens of picoseconds. These findings provide mechanistic insights of nonequilibrium ET dynamics modulated by conformation flexibility, mediated by unique solvent configuration, and accelerated by vibrational coupling.

Published

2012

30. Dynamics and mechanism of DNA repair in a biomimetic system: Flavin-thymine dimer adduct

Author

Lijuan Wang, Ya-Ting Kao, Chaitanya Saxena, Dongping Zhong, and Qin Hua Song

Subjects

DNA Repair, DNA repair, Stereochemistry, Dimer, Pyrimidine dimer, General Chemistry, Flavin group, Photochemistry, Biochemistry, Catalysis, Article, Adduct, Thymine, Electron Transport, chemistry.chemical_compound, DNA Adducts, Colloid and Surface Chemistry, chemistry, Flavins, Photolyase, Dimerization, DNA

Abstract

To mimic photolyase for efficient repair of UV-damaged DNA, numerous biomimetic systems have been synthesized but all show low repair efficiency. The molecular mechanism of this low efficient process is still poorly understood. Here, we reported our direct mapping of the repair processes of a flavin-thymine dimer adduct with femtosecond resolution. We followed the entire dynamic evolution and observed direct electron transfer from the excited flavin to the thymine dimer in 79 picoseconds (ps). We further observed two competitive pathways, productive dimer ring splitting within 435 ps and futile back electron transfer in 95 ps. Our observation reveals that the underlying mechanism for the low repair quantum yield of flavin-thymine dimer adducts is the short-lived excited flavin moiety and the fast dynamics of futile back electron transfer without repair.

Published

2012

31. Ultrafast Dynamics and Anionic Active States of the Flavin Cofactor in Cryptochrome and Photolyase

Author

Ya Ting Kao, Dongping Zhong, Sang-Hun Song, Aziz Sancar, Nuri Ozturk, Jiang Li, Chuang Tan, and Lijuan Wang

Subjects

Semiquinone, Electron-Transferring Flavoproteins, Protein Conformation, Coenzymes, Flavoprotein, Flavin group, Photochemistry, Biochemistry, Article, Catalysis, Cofactor, Electron Transport, Electron transfer, chemistry.chemical_compound, Colloid and Surface Chemistry, Cryptochrome, Flavins, Animals, Photolyase, Flavin adenine dinucleotide, Flavoproteins, biology, General Chemistry, Cryptochromes, chemistry, Flavin-Adenine Dinucleotide, biology.protein, Butterflies, Deoxyribodipyrimidine Photo-Lyase, Oxidation-Reduction

Abstract

We report here our systematic studies of the dynamics of four redox states of the flavin cofactor in both photolyases and insect type 1 cryptochromes. With femtosecond resolution, we observed ultrafast photoreduction of oxidized state flavin adenine dinucleotide (FAD) in subpicosecond and of neutral radical semiquinone (FADH(*)) in tens of picoseconds through intraprotein electron transfer mainly with a neighboring conserved tryptophan triad. Such ultrafast dynamics make these forms of flavin unlikely to be the functional states of the photolyase/cryptochrome family. In contrast, we find that upon excitation the anionic semiquinone (FAD(*-)) and hydroquinone (FADH(-)) have longer lifetimes that are compatible with high-efficiency intermolecular electron transfer reactions. In photolyases, the excited active state (FADH(-)*) has a long (nanosecond) lifetime optimal for DNA-repair function. In insect type 1 cryptochromes known to be blue-light photoreceptors the excited active form (FAD(*-)*) has complex deactivation dynamics on the time scale from a few to hundreds of picoseconds, which is believed to occur through conical intersection(s) with a flexible bending motion to modulate the functional channel. These unique properties of anionic flavins suggest a universal mechanism of electron transfer for the initial functional steps of the photolyase/cryptochrome blue-light photoreceptor family.

Published

2008

32. Ultrafast Dynamics of Flavins in Five Redox States

Author

Dongping Zhong, Aziz Sancar, Ting-Fang He, Lijuan Wang, Chaitanya Saxena, Ya Ting Kao, and Lijun Guo

Subjects

Insecta, Semiquinone, Free Radicals, Flavin Mononucleotide, Photochemistry, Flavin mononucleotide, Flavoprotein, Flavin group, Ring (chemistry), Biochemistry, Catalysis, Article, chemistry.chemical_compound, Electron transfer, Colloid and Surface Chemistry, Animals, Physics::Chemical Physics, Flavin adenine dinucleotide, biology, Flavoproteins, General Chemistry, Conical intersection, Kinetics, Spectrometry, Fluorescence, chemistry, biology.protein, Flavin-Adenine Dinucleotide, Oxidation-Reduction

Abstract

We report here our systematic studies of excited-state dynamics of two common flavin molecules, FMN and FAD, in five redox states of oxidized form, neutral and anionic semiquinones, and neutral and anionic fully-reduced hydroquinones in solution and in inert protein environments with femtosecond resolution. Using protein environments, we are able to stabilize two semiquinone radicals and thus observed their weak emission spectra. Significantly, we observed a strong correlation between their excited-state dynamics and the planarity of their flavin isoalloxazine ring. For a bent ring structure, we all observed ultrafast dynamics from a few to hundreds of picoseconds and strong excitation-wavelength dependence of emission spectra, indicating deactivation during relaxation. A butterfly bending motion is invoked to get access to conical intersection(s) to facilitate deactivation. These states include the anionic semiquinone radical and fully-reduced neutral and anionic hydroquinones in solution. In a planar configuration, flavins have a long lifetime in nanoseconds except for the stacked conformation of FAD, where the intramolecular electron transfer between the ring and the adenine moiety in 5-9 ps as well as the subsequent charge recombination in 30-40 ps were observed. These observed distinct dynamics, controlled by the flavin ring flexibility, are fundamental to flavoenzyme’s functions as observed in photolyase with a planar structure to lengthen the lifetime to maximize DNA repair efficiency and in insect Type 1 cryptochrome with a flexible structure to vary the excited-state deactivation to modulate the functional channel.

Published

2008

33. Hydration dynamics and time scales of coupled water-protein fluctuations

Author

Sherwin J. Singer, Ya-Ting Kao, Dongping Zhong, Ali Hassanali, and Tanping Li

Subjects

Models, Molecular, Photochemistry, Crystallography, X-Ray, Biochemistry, Catalysis, Protein Structure, Secondary, symbols.namesake, Colloid and Surface Chemistry, Computational chemistry, Stokes shift, Molecule, Animals, Computer Simulation, Sperm Whale, Chemistry, Myoglobin, Protein dynamics, Dynamics (mechanics), Water, General Chemistry, Photoexcitation, Solutions, Kinetics, Chemical physics, Picosecond, Femtosecond, symbols, Relaxation (physics), Thermodynamics

Abstract

We report experimental and theoretical studies on water and protein dynamics following photoexcitation of apomyoglobin. Using site-directed mutation and with femtosecond resolution, we experimentally observed relaxation dynamics with a biphasic distribution of time scales, 5 and 87 ps, around the site Trp7. Theoretical studies using both linear response and direct nonequilibrium molecular dynamics (MD) calculations reproduced the biphasic behavior. Further constrained MD simulations with either frozen protein or frozen water revealed the molecular mechanism of slow hydration processes and elucidated the role of protein fluctuations. Observation of slow water dynamics in MD simulations requires protein flexibility, regardless of whether the slow Stokes shift component results from the water or protein contribution. The initial dynamics in a few picoseconds represents fast local motions such as reorientations and translations of hydrating water molecules, followed by slow relaxation involving strongly coupled water-protein motions. We observed a transition from one isomeric protein configuration to another after 10 ns during our 30 ns ground-state simulation. For one isomer, the surface hydration energy dominates the slow component of the total relaxation energy. For the other isomer, the slow component is dominated by protein interactions with the chromophore. In both cases, coupled water-protein motion is shown to be necessary for observation of the slow dynamics. Such biologically important water-protein motions occur on tens of picoseconds. One significant discrepancy exists between theory and experiment, the large inertial relaxation predicted by simulations but clearly absent in experiment. Further improvements required in the theoretical model are discussed.

Published

2007

34. Protein surface hydration mapped by site-specific mutations

Author

Ya Ting Kao, Yang Yang, Wesley E. Stites, Ahmed H. Zewail, Dongping Zhong, Weihong Qiu, Lijuan Wang, and Luyuan Zhang

Subjects

Models, Molecular, Time Factors, Surface Properties, Crystallography, X-Ray, Molecular dynamics, Protein structure, Side chain, Micrococcal Nuclease, Multidisciplinary, biology, Chemistry, Dynamics (mechanics), Solvation, Charge density, Water, Fluorescence, Protein Structure, Tertiary, Crystallography, Spectrometry, Fluorescence, Chemical physics, Physical Sciences, Mutation, biology.protein, Mutagenesis, Site-Directed, Caltech Library Services, Micrococcal nuclease

Abstract

Water motion at protein surfaces is fundamental to protein structure, stability, dynamics, and function. By using intrinsic tryptophans as local optical probes, and with femtosecond resolution, it is possible to probe surface-water motions in the hydration layer. Here, we report our studies of local hydration dynamics at the surface of the enzyme Staphylococcus nuclease using site-specific mutations. From these studies of the WT and four related mutants, which change local charge distribution and structure, we are able to ascertain the contribution to solvation by protein side chains as relatively insignificant. We determined the time scales of hydration to be 3–5 ps and 100–150 ps. The former is the result of local librational/rotational motions of water near the surface; the latter is a direct measure of surface hydration assisted by fluctuations of the protein. Experimentally, these hydration dynamics of the WT and the four mutants are also consistent with results of the total dynamic Stokes shifts and fluorescence emission maxima and are correlated with their local charge distribution and structure. We discuss the role of protein fluctuation on the time scale of labile hydration and suggest reexamination of recent molecular dynamics simulations.

Published

2006

35. Femtosecond studies of tryptophan fluorescence dynamics in proteins: local solvation and electronic quenching

Author

Lijuan Wang, Dongping Zhong, Ya-Ting Kao, Weihong Qiu, and Luyuan Zhang

Subjects

Models, Molecular, Time Factors, Surface Properties, Biophysics, Electrons, Crystallography, X-Ray, Electron transfer, Thioredoxins, Physics::Atomic and Molecular Clusters, Materials Chemistry, medicine, Physics::Chemical Physics, Physical and Theoretical Chemistry, Serum Albumin, Quantitative Biology::Biomolecules, Quenching (fluorescence), Chemistry, Chemistry, Physical, Protein dynamics, technology, industry, and agriculture, Tryptophan, Solvation, Human serum albumin, Fluorescence, Lipids, Melitten, Surfaces, Coatings and Films, Crystallography, Spectrometry, Fluorescence, Chemical physics, Femtosecond, Solvents, medicine.drug

Abstract

We report our systematic examination of tryptophan fluorescence dynamics in proteins with femtosecond resolution. Distinct patterns of femtosecond-resolved fluorescence transients from the blue to the red side of emission have been characterized to distinguish local ultrafast solvation and electronic quenching. It is shown that tryptophan is an ideal local optical probe for hydration dynamics and protein-water interactions as well as an excellent local molecular reporter for ultrafast electron transfer in proteins, as demonstrated by a series of biological systems, here in melittin, human serum albumin, and human thioredoxin, and at lipid interfaces. These studies clarify the assignments in the literature about the ultrafast solvation or quenching dynamics of tryptophan in proteins. We also report a new observation of solvation dynamics at far red-side emission when the relaxation of the local environment is slower than 1 ps. These results provide a molecular basis for using tryptophan as a local molecular probe for ultrafast protein dynamics in general.

Published

2006

36. Ultrafast hydration dynamics in melittin folding and aggregation: helix formation and tetramer self-assembly

Author

Jongjoo Kim, Tanping Li, Lijuan Wang, Gregory M. Sollenberger, Weihong Qiu, Ya-Ting Kao, Luyuan Zhang, Wenyun Lu, and Dongping Zhong

Subjects

Models, Molecular, Protein Folding, Aqueous solution, Molecular Sequence Data, Solvation, Water, Crystallography, X-Ray, Melitten, Melittin, Random coil, Protein tertiary structure, Fluorescence, Surfaces, Coatings and Films, Folding (chemistry), chemistry.chemical_compound, Crystallography, Biopolymers, chemistry, Tetramer, Molecular Probes, Materials Chemistry, Protein folding, Amino Acid Sequence, Physical and Theoretical Chemistry

Abstract

Melittin, an amphipathic peptide from honeybee venom, consists of 26 amino acid residues and adopts different conformations from a random coil, to an alpha-helix, and to a self-assembled tetramer under certain aqueous environments. We report here our systematic studies of the hydration dynamics in these conformations using single intrinsic tryptophan (W19) as a molecular probe. With femtosecond resolution, we observed the solvation dynamics occurring in 0.62 and 14.7 ps in a random-coiled primary structure. The former represents bulklike water motion, and the latter reflects surface-type hydration dynamics of proteins. As a comparison, a model tripeptide (KWK) was also studied. At a membrane-water interface, melittin folds into a secondary alpha-helical structure, and the interfacial water motion was found to take as long as 114 ps, indicating a well-ordered water structure along the membrane surface. In high-salt aqueous solution, the dielectric screening and ionic solvation promote the hydrophobic core collapse in melittin aggregation and facilitate the tetramer formation. This self-assembled tertiary structure is also stabilized by the strong hydrophilic interactions of charged C-terminal residues and associated ions with water molecules in the two assembled regions. The hydration dynamics was observed to occur in 87 ps, significantly slower than typical water relaxation at protein surfaces but similar to water motion at membrane interfaces. Thus, the observed time scale of approximately 100 ps probably implies appropriate water mobility for mediating the formation of high-order structures of melittin in an alpha-helix and a self-assembled tetramer. These results elucidate the critical role of hydration dynamics in peptide conformational transitions and protein structural stability and integrity.

Published

2006

37. Direct observation of DNA repair by photolyase

Author

Lijuan Wang, Dongping Zhong, Aziz Sancar, Chaitanya Saxena, and Ya Ting Kao

Subjects

Engineering, business.industry, DNA repair, Direct observation, Library science, business, Photolyase, Engineering physics

Abstract

Author Institution: Department of Physics, Chemistry and Biochemistry, OSU Biophysics, Chemical Physics and Biochemistry Programs, The Ohio State University, Columbus, Ohio 43210

Published

2006

38. Direct observation of thymine dimer repair in DNA by photolyase

Author

Aziz Sancar, Lijuan Wang, Chaitanya Saxena, Dongping Zhong, and Ya Ting Kao

Subjects

Flavin adenine dinucleotide, Multidisciplinary, Binding Sites, DNA Repair, Free Radicals, DNA repair, Dimer, Pyrimidine dimer, Flavin group, Biological Sciences, Photochemistry, Catalysis, Cyclobutane, chemistry.chemical_compound, Electron transfer, chemistry, Pyrimidine Dimers, Flavin-Adenine Dinucleotide, Photolyase, Deoxyribodipyrimidine Photo-Lyase

Abstract

Photolyase uses light energy to split UV-induced cyclobutane dimers in damaged DNA, but its molecular mechanism has never been directly revealed. Here, we report the direct mapping of catalytic processes through femtosecond synchronization of the enzymatic dynamics with the repair function. We observed direct electron transfer from the excited flavin cofactor to the dimer in 170 ps and back electron transfer from the repaired thymines in 560 ps. Both reactions are strongly modulated by active-site solvation to achieve maximum repair efficiency. These results show that the photocycle of DNA repair by photolyase is through a radical mechanism and completed on subnanosecond time scale at the dynamic active site, with no net change in the redox state of the flavin cofactor.

Published

2005

39. Femtochemistry in enzyme catalysis: DNA photolyase

Author

Ya Ting Kao, Dongping Zhong, Chaitanya Saxena, Aziz Sancar, and Lijuan Wang

Subjects

Models, Molecular, Time Factors, DNA Repair, DNA repair, Photochemistry, Biophysics, Pyrimidine dimer, Crystallography, X-Ray, Biochemistry, Models, Biological, Aspergillus nidulans, Catalysis, Enzyme catalysis, Electron Transport, Electron transfer, Catalytic Domain, Escherichia coli, Photolyase, biology, Chemistry, Active site, Cell Biology, General Medicine, DNA photolyase, Kinetics, biology.protein, Thermodynamics, Femtochemistry, Deoxyribodipyrimidine Photo-Lyase

Abstract

Photolyase uses light energy to split UV-induced cyclobutane pyrimidine dimers in damaged DNA. This photoenzyme encompasses a series of elementary dynamical processes during repair function from early photoinitiation by a photoantenna molecule to enhance repair efficiency, to in vitro photoreduction through aromatic residues to reconvert the cofactor to the active form, and to final photorepair to fix damaged DNA. The corresponding series of dynamics include resonance energy transfer, intraprotein electron transfer, and intermolecular electron transfer, bond breaking-making rearrangements and back electron return, respectively. We review here our recent direct studies of these dynamical processes in real time, which showed that all these elementary reactions in the enzyme occur within subnanosecond timescale. Active-site solvation was observed to play a critical role in the continuous modulation of catalytic reactions. As a model system for enzyme catalysis, we isolated the enzyme-substrate complex in the transition-state region and mapped out the entire evolution of unmasked catalytic reactions of DNA repair. These observed synergistic motions in the active site reveal a perfect correlation of structural integrity and dynamical locality to ensure maximum repair efficiency on the ultrafast time scale.

Published

1999

40. Electron Tunneling Pathways and Role of Adenine in Repair of Cyclobutane Pyrimidine Dimer by DNA Photolyase.

Author

Zheyun Liu, Xunmin Guo, Chuang Tan, Jiang Li, Ya-Ting Kao, Lijuan Wang, Aziz Sancar, and Dongping Zhong

Published

2012

41. Protein-flexibility mediated coupling between photoswitching kinetics and surrounding viscosity of a photochromic fluorescent protein.

Author

Ya-Ting Kao, Xinxin Zhu, and Wei Min

Subjects

*PROTEINS, *FLUORESCENCE, *VISCOSITY, *PHOTOCHROMIC materials, *CHROMOPHORES, *ISOMERIZATION

Abstract

Recent advances in fluorescent proteins (FPs) have generated a remarkable family of optical highlighters with special light responses. Among them, Dronpa exhibits a unique capability of reversible light-regulated on-off switching. However, the environmental dependence of this photochromism is largely unexplored. Herein we report that the photoswitching kinetics of the chromophore inside Dronpa is actually slowed down by increasing medium viscosity outside Dronpa. This finding is a special example of an FP where the environment can exert a hydrodynamic effect on the internal chromophore. We attribute this effect to protein-flexibility mediated coupling where the chromophore's cis-trans isomerization during photoswitching is accompanied by conformational motion of a part of the protein β-barrel whose dynamics should be hindered by medium friction. Consistent with this mechanism, the photoswitching kinetics of Dronpa-3, a structurally more flexible mutant, is found to exhibit a more pronounced viscosity dependence. Furthermore, we mapped out spatial distributions of microviscosity in live cells experienced by a histone protein using the photoswitching kinetics of Dronpa-3 fusion as a contrast mechanism. This unique reporter should provide protein-specific information about the crowded intracellular environments by offering a genetically encoded microviscosity probe, which did not exist with normal FPs before. [ABSTRACT FROM AUTHOR]

Published

2012

42. Dynamics and mechanism of cyclobutane pyrimidine dimer repair by DNA photolyase.

Author

Zheyun Liu, Chuang Tan, Xunmin Guo, Ya-Ting Kao, Jiang Li, Lijuan Wang, Sancar, Aziz, and Dongping Zhong

Subjects

CYCLOBUTANE, PYRIMIDINES, DNA damage, MUTAGENESIS, SPECTRUM analysis, DNA repair, DEOXYRIBODIPYRIMIDINE photolyase

Abstract

Photolyase uses blue light to restore the major ultraviolet (UV)-induced DNA damage, the cyclobutane pyrimidine dimer (CPD), to two normal bases by splitting the cyclobutane ring. Our earlier studies showed that the overall repair is completed in 700 ps through a cyclic electron-transfer radical mechanism. However, the two fundamental processes, electron-tunneling pathways and cyclobutane ring splitting, were not resolved. Here, we use ultrafast UV absorption spectroscopy to show that the CPD splits in two sequential steps within 90 ps and the electron tunnels between the cofactor and substrate through a remarkable route with an intervening adenine. Site-directed mutagenesis reveals that the active-site residues are critical to achieving high repair efficiency, a unique electrostatic environment to optimize the redox potentials and local flexibility, and thus balance all catalytic reactions to maximize enzyme activity. These key findings reveal the complete spatio-temporal molecular picture of CPD repair by photolyase and elucidate the underlying molecular mechanism of the enzyme's high repair efficiency. [ABSTRACT FROM AUTHOR]

Published

2011

43. Ultrafast solvation dynamics at binding and active sites of photolyases.

Author

Chih-Wei Chang, Lijun Guo, Ya-Ting Kao, Jiang Li, Chuang Tan, Tanping Li, Chaitanya Saxena, Zheyun Liu, Lijuan Wang, Aziz Sancar, and Dongping Zhong

Subjects

SOLVATION, LYASES, BINDING sites, CATALYSIS, ENZYME kinetics, SYNERGETICS

Abstract

Dynamic solvation at binding and active sites is critical to protein recognition and enzyme catalysis. We report here the complete characterization of ultrafast solvation dynamics at the recognition site of photoantenna molecule and at the active site of cofactor/ substrate in enzyme photolyase by examining femtosecondresolved fluorescence dynamics and the entire emission spectra. With direct use of intrinsic antenna and cofactor chromophores, we observed the local environment relaxation on the time scales from a few picoseconds to nearly a nanosecond. Unlike conventional solvation where the Stokes shift is apparent, we observed obvious spectral shape changes with the minor, small, and large spectral shifts in three function sites. These emission profile changes directly reflect the modulation of chromophore's excited states by locally constrained protein and trapped-water collective motions. Such heterogeneous dynamics continuously tune local configurations to optimize photolyase's function through resonance energy transfer from the antenna to the cofactor for energy efficiency and then electron transfer between the cof actor and the substrate for repair of damaged DNA. Such unusual solvation and synergetic dynamics should be general in function sites of proteins. [ABSTRACT FROM AUTHOR]

Published

2010

44. Ultrafast Dynamics of Resonance Energy Transfer in Myoglobin: Probing Local Conformation Fluctuations.

Author

Jeffrey A. Stevens, Justin J. Link, Ya-Ting Kao, Chen Zang, Lijuan Wang, and Dongping Zhong

Published

2010

45. Ultrafast Dynamics and Anionic Active States of the Flavin Cofactor in Cryptochrome and Photolyase.

Author

Ya-Ting Kao, Chuang Tan, Sang-Hun Song, Nun Oztürk, Jiang Li, Lijuan Wang, Sancar, Aziz, and Dongping Zhong

Subjects

*CRYPTOCHROMES, *QUINONE, *CHARGE exchange, *PHOTORECEPTORS, *FLAVINS

Abstract

We report here our systematic studies of the dynamics of four redox states of the flavin cofactor in both photolyases and insect type 1 cryptochromes. With femtosecond resolution, we observed ultrafast photoreduction of oxidized state flavin adenine dinucleotide (FAD) in subpicosecond and of neutral radical semiquinone (FADH•) in tens of picoseconds through intraprotein electron transfer mainly with a neighboring conserved tryptophan triad. Such ultrafast dynamics make these forms of flavin unlikely to be the functional states of the photolyase/cryptochrome family. In contrast, we find that upon excitation the anionic semiquinone (FAD•-) and hydroquinone (FADH-) have longer lifetimes that are compatible with high- efficiency intermolecular electron transfer reactions. In photolyases, the excited active state (FADH-*) has a long (nanosecond) lifetime optimal for DNA-repair function. In insect type 1 cryptochromes known to be blue-light photoreceptors the excited active form (FAD•-*) has complex deactivation dynamics on the time scale from a few to hundreds of picoseconds, which is believed to occur through conical intersection(s) with a flexible bending motion to modulate the functional channel. These unique properties of anionic flavins suggest a universal mechanism of electron transfer for the initial functional steps of the photolyase/cryptochrome blue-light photoreceptor family. [ABSTRACT FROM AUTHOR]

Published

2008

46. Femtochemistry in enzyme catalysis: DNA photolyase.

Author

Ya-Ting Kao, Chaitanya Saxena, Lijuan Wang, Aziz Sancar, and Dongping Zhong

Abstract

Photolyase uses light energy to split UV-induced cyclobutane pyrimidine dimers in damaged DNA. This photoenzyme encompasses a series of elementary dynamical processes during repair function from early photoinitiation by a photoantenna molecule to enhance repair efficiency, to in vitro photoreduction through aromatic residues to reconvert the cofactor to the active form, and to final photorepair to fix damaged DNA. The corresponding series of dynamics include resonance energy transfer, intraprotein electron transfer, and intermolecular electron transfer, bond breaking-making rearrangements and back electron return, respectively. We review here our recent direct studies of these dynamical processes in real time, which showed that all these elementary reactions in the enzyme occur within subnanosecond timescale. Active-site solvation was observed to play a critical role in the continuous modulation of catalytic reactions. As a model system for enzyme catalysis, we isolated the enzyme–substrate complex in the transition-state region and mapped out the entire evolution of unmasked catalytic reactions of DNA repair. These observed synergistic motions in the active site reveal a perfect correlation of structural integrity and dynamical locality to ensure maximum repair efficiency on the ultrafast time scale. [ABSTRACT FROM AUTHOR]

Published

2007

47. Protein surface hydration mapped by site-specific mutations.

Author

Weihong Qiu, Ya-Ting Kao, Luyuan Zhang, Yi Yang, Lijuan Wang, Stites, Wesley E., Dongping Zhong, and Zewail, Ahmed H.

Subjects

*HYDRATION, *MOLECULAR dynamics, *SOLUTION (Chemistry), *GENETIC mutation, *PROTEINS, *BIOCHEMISTRY

Abstract

Water motion at protein surfaces is fundamental to protein structure, stability, dynamics, and function. By using intrinsic tryptophans as local optical probes, and with femtosecond resolution, it is possible to probe surface-water motions in the hydration layer. Here, we report our studies of local hydration dynamics at the surface of the enzyme Staphylococcus nuclease using site-specific mutations. From these studies of the WT and four related mutants, which change local charge distribution and structure, we are able to ascertain the contribution to solvation by protein side chains as relatively insignificant. We determined the time scales of hydration to be 3–5 ps and 100–150 ps. The former is the result of local librational/rotational motions of water near the surface; the latter is a direct measure of surface hydration assisted by fluctuations of the protein. Experimentally, these hydration dynamics of the WT and the four mutants are also consistent with results of the total dynamic Stokes shifts and fluorescence emission maxima and are correlated with their local charge distribution and structure. We discuss the role of protein fluctuation on the time scale of labile hydration and suggest reexamination of recent molecular dynamics simulations. [ABSTRACT FROM AUTHOR]

Published

2006

48. Direct observation of thymine dimer repair in DNA by photolyase.

Author

Ya-Ting Kao, Saxena, Chaitanya, Lijuan Wang, Sancar, Aziz, and Dongping Zhong

Subjects

*DNA repair, *BIOCHEMICAL genetics, *DIMERS, *NUCLEIC acids, *OLIGOMERS, *GENES

Abstract

Photolyase uses light energy to split UV-induced cyclobutane dimers in damaged DNA, but its molecular mechanism has never been directly revealed. Here, we report the direct mapping of catalytic processes through femtosecond synchronization of the enzymatic dynamics with the repair function. We observed direct electron transfer from the excited flavin cofactor to the dimer in 170 ps and back electron transfer from the repaired thymines in 560 ps. Both reactions are strongly modulated by active-site solvation to achieve maximum repair efficiency. These results show that the photocycle of DNA repair by photolyase is through a radical mechanism and completed on subnanosecond time scale at the dynamic active site, with no net change in the redox state of the flavin cofactor. [ABSTRACT FROM AUTHOR]

Published

2005

49. Dynamics and Mechanism of DNA Repair in a Biomimetic System: Flavin-Thymine Dimer Adduct.

Author

Ya-Ting Kao, Qin-Hua Song, Saxena, Chaitanya, Lijuan Wang, and Dongping Zhong

Subjects

*DNA repair, *BIOMIMETIC chemicals, *FLAVINS, *THYMINE, *DIMERS, *DNA adducts, *CHARGE exchange, *FUNCTIONAL groups

Abstract

To mimic photolyase for efficient repair of UV-damaged DNA, numerous biomimetic systems have been synthesized, but all show low repair efficiency. The molecular mechanism of this low-efficiency process is still poorly understood. Here we report our direct mapping of the repair processes of a flavin-thymine dimer adduct with femtosecond resolution. We followed the entire dynamic evolution and observed direct electron transfer (ET) from the excited flavin to the thymine dimer in 79 ps. We further observed two competitive pathways, productive dimer ring splitting within 435 ps and futile back-ET in 95 ps. Our observations reveal that the underlying mechanism for the low repair quantum yield of flavin-thymine dimer adducts is the short-lived excited flavin moiety and the fast dynamics of futile back-ET without repair. [ABSTRACT FROM AUTHOR]

Published

2012

50. Formation and Function of Flavin Anion Radical in Cryptochrome 1 Blue-Light Photoreceptor of Monarch Butterfly.

Author

Sang-Hun Song, Nun Özturk, Denaro, Tracy R., Arat, N. Oziem, Ya-Ting Kao, Haisun Zhu, Dongping Zhong, Reppert, Steven M., and Sancar, Aziz

Subjects

*MONARCH butterfly, *ANIONS, *CRYPTOCHROMES, *PHOTORECEPTORS, *PROTEINS, *ENZYMES, *STOICHIOMETRY

Abstract

The monarch butterfly (Danaus plexippus) cryptochrome 1 (DpCry1) belongs in the class of photosensitive insect cryptochromes. Here we purified DpCry1 expressed in a bacterial host and obtained the protein with a stoichiometric amount of the flavin cofactor in the two-electron oxidized, FADOX, form. Exposure of the purified protein to light converts the FADOX to the FAD- flavin anion radical by intraprotein electron transfer from a Trp residue in the apoenzyme. To test whether this novel photoreduction reaction is part of the DpCry1 physiological photocycle, we mutated the Trp residue that acts as the ultimate electron donor in flavin photoreduction. The mutation, W328F, blocked the photoreduction entirely but had no measurable effect on the light-induced degradation of DpCry1 in vivo. In light of this finding and the recently published action spectrum of this class of Crys, we conclude that DpCry1 and similar insect cryptochromes do not contain flavin in the FADOX form in vivo and that, most likely, the FADOX hv→ FAD- photoreduction reaction is not part of the insect cryptochrome photoreaction that results in proteolytic degradation of the photopigment. [ABSTRACT FROM AUTHOR]

Published

2007