Excited state electronic properties of DNA photolyase and fluorescent nucleobase analogues (FBA): An experimental and theoretical study

Kodali, Goutham

January 2009

An overexposure to ultraviolet radiation can cause sunburn and some forms of skin cancer. UV light causes many different photoproducts. The cys-syn cyclobutylpyrimidine dimer (CPD) is the major photoproduct upon UV irradiation. DNA photolyase (PL) is a light-driven flavoprotein that repairs CPD in UV-damaged DNA. This repair process occurs in the presence of blue light through ultrafast photo-induced electron transfer from reduced anionic flavin adenine dinucleotide (FADH¯) to the CPD by an unknown mechanism. Since the excited state flavin transfers an electron to repair the damaged DNA, it is of utmost importance that we understand better the excited state properties of the flavins. In this work the excited state electronic properties of all three-oxidation states of flavin: oxidized form (FAD), semiquinone radical form (FADH•) and reduced anionic form (FADH¯) were studied using Stark spectroscopy and complimented by time dependent density functional theory (TD-DFT) calculations. These results are presented and discussed in Chapter 3 and 4. The difference dipole moments (Δμ) and the difference polarizabilities (Tr(Δα01)) were experimentally determined for first two lowest optically accessible states. The results are discussed in the context of photoreduction of flavins in wider class of flavoprotein blue light photoreceptors and catalytic electron transfer process in DNA repair. In the later part of this thesis (Chapters 5 and 6) the excited state electronic properties of monomeric 2-Aminopurine (2AP), 8-Vinyladenine 8VA were presented. These 8VA, 2AP are examples of fluorescent nucleotide analogues of adenine that can be incorporated into DNA with little perturbation of the normal double-helical structure. The fluorescence of these analogues is quenched when incorporated in double-stranded DNA (dsDNA). The basic mechanism underlying the fluorescence quenching by base stacking of 2AP and 8VA are is not well understood, and thus exploring the excited state electronic structures of these bases is an important first step. We have explored the excited state properties of 2AP and 8VA in frozen LiCl and ethanol solutions using Stark spectroscopy. High-level ab initio and TD-DFT calculations were performed to compliment the experimental results. / Chemistry

Chemistry, Physical

Chemistry, Biochemistry

Chemistry, General

Dna

Dna Photolyase

Fba

Flavins

Fluorescent Nucleobase Analogues

Stark Spectroscopy

Caractérisation et ciblage de la reconnaissance dynamique de Trp37-G lors de l’interaction de la protéine NCp7 de HIV-1 avec des acides nucléiques / Characterization and targeting the dynamic recognition of Trp37-G during the interaction of NCp7 protein of HIV-1 with nucleic acids

Sharma, Rajhans

10 April 2018

La protéine de la nucléocapside (NC) possède un rôle important dans le cycle de viral du VIH-1 grâce à sa propriété chaperone des acides nucléiques (NA) qui implique la reconnaissance de son résidu Trp37 avec un résidu Guanine de l'acide nucléique cible. Nous avons caractérisé cette reconnaissance dynamique Trp37-G en utilisant des séquences impliquées dans la transcription inverse et l'assemblage de l'ARN génomique. En utilisant les analogues nucléosidiques fluorescents thienoguanosine (thG) et 2-thiényl-3-hydroxychromone (3HCnt), nous avons déterminé l'ensemble des constantes de vitesse cinétiques du mécanisme d’hybridation de la séquence (-)PBS avec (+)PBS en absence et en présence de NC. Nous avons également étudié le rôle du NA sucre dans les complexes NC-ARN et NC-ADN, puisque la protéine NC se lie avec la polarité opposée aux séquences d'ADN et d'ARN. Nous avons confirmé que l'interaction du résidu Trp37 avec les amino-acides de type guanines était critique lors de la formation des complexes avec les deux mutants d’ARN et d’ADN de PBS et de SL3. Enfin, nous avons réalisé un criblage de potentiels inhibiteurs de la protéine NC et examiné les touches identifiées à partir d’un test basé sur la fluorescence de la sonde thG. / Nucleocapsid protein (NC) plays crucial roles in HIV-1 life cycle through its nucleic acid (NA) chaperoning property that involves recognition of it’s Trp37 residue with a Guanine residue of the target nucleic acid sequences. Herein, we characterized this dynamic Trp37-G recognition with sequences involved in reverse transcription and genomic RNA packaging. Using the fluorescent thienoguanosine (thG) and 2-thienyl-3-hydroxychromone (3HCnt) nucleoside analogues, we determined the whole set of kinetic rate constants for annealing of (-)PBS with (+)PBS in the absence and presence of NC. We also investigated the role of NA sugar in NC-RNA and NC-DNA complexes, as NC binds with opposite polarity to DNA and RNA sequences. We confirmed that the interaction of the Trp37 residue with guanines was critical for the formation of complexes with both RNA and DNA variants of PBS and SL3. Finally, we performed screening of NC inhibitors and tested the selected hits on a thG-based assay.

VIH-1

Nucléocapside protéine

Analogues nucléosidiques fluorescents

Thiéoguanosine

Primer binding site

SL3

Acides nucléiques dynamique

Fluorescence spectroscopie

Protéine-acides nucléiques interaction

HIV-1

Nucleocapsid protein

Fluorescent nucleobase analogues

Thieoguanosine

Primer binding site

SL3

Nucleic acid dynamics

Fluorescence spectroscopy

Protein-nucleic acids interaction

579.2

616.91