Methods and applications in DNA sequence alignments /

Sherwood, Ellen,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 5 uppsatser.

Spectroscopy of Occupied and Unoccupied States in Bio-Molecular Layers

Seifert, Stefan

27 September 2006

The present thesis investigates the electronic and structural properties of adenine, cytosine, and guanine layers on hydrogen passivated silicon (111)(7x7). The (7x7) reconstruction of the silicon surface was achieved by direct current heating of the samples in UHV conditions. After in situ hydrogen passivation layers of the DNA bases were prepared in different thicknesses by means of organic molecular beam deposition, all samples were characterized employing valence band and core level photoemission spectroscopy. Additionally the near edge x-ray absorption fine structure of the DNA base layers was investigated. A detailed and consistent picture of structural and electronic properties of the nucleotide bases in the solid state could be developed by comparison of measurements and DFT/B3LYP calculations.

DNA base

adenine

core level

cytosine

guanine

molecular orientation

valence band

ddc:500

NEXAFS

Photoemission

Solving repeat problems in shotgun sequencing /

Arner, Erik,

January 2006

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2006. / Härtill 3 uppsatser.

Trinucleotide Repeat Instability is Modulated by DNA Base Lesions and DNA Base Excision Repair

Beaver, Jill M

30 September 2016

Trinucleotide repeat (TNR) expansions are the cause of over 40 human neurodegenerative diseases, and are linked to DNA damage and base excision repair (BER). We explored the role of DNA damage and BER in modulating TNR instability through analysis of DNA structures, BER protein activities, and reconstitution of repair using human BER proteins and synthesized DNA containing various types of damage. We show that DNA damage and BER can modulate TNR expansions by promoting removal of a TNR hairpin through coordinated activities of BER proteins and cofactors. We found that during repair in a TNR hairpin, coordination between the 5’-flap endonuclease activity of flap endonuclease 1 (FEN1), 3’-5’ exonuclease activity of AP endonuclease 1 (APE1), and activity of DNA ligase I (LIG I) can resolve the double-flap structure produced during BER in the hairpin loop. The resolution of the double-flap structure resulted in hairpin removal and prevention or attenuation of TNR expansions and provides the first evidence that coordination among BER proteins can remove a TNR hairpin. We further explored the role of BER cofactors in modulating TNR instability and found that the repair cofactor proliferating cell nuclear antigen (PCNA) facilitates genomic stability by promoting removal of a TNR hairpin. Hairpin removal was accomplished by altering dynamic TNR structures to allow more efficient FEN1 cleavage and DNA polymerase β (pol β) synthesis and stimulating the activity of LIG I. This study provides the first evidence that a DNA repair cofactor plays an important role in modulating TNR instability. Finally, we explored the effects of sugar modifications in abasic sites on activities of BER proteins and BER efficiency during repair in a TNR tract. We found that an oxidized sugar inhibits the activities of BER enzymes, interrupting their coordination and preventing efficient repair. Inefficient repair results in accumulation of repair intermediates with DNA breaks, contributing to genomic instability. Our results indicate that DNA base lesions and BER play a crucial role in modulating TNR instability. The research presented herein provides a molecular basis for further developing BER as a target for prevention and treatment of neurodegenerative diseases caused by TNR expansion.

DNA repair

trinucleotide repeats

DNA damage

trinucleotide repeat instability

DNA base excision repair

Biochemistry

Using Quantum Mechanics to Investigate the Photophysical Properties of the DNA and RNA Bases and their Fluorescent Analogs

Kistler, Kurt Andrew

January 2010

The ability of the nucleic acids to absorb ultraviolet light and remain relatively photostable is a property upon which life depends. The nucleobases, which are the primary chromophores, when irradiated display rapid radiationless decay back to the ground state, in general faster than is needed for photoreaction. Fluorescent analogs of these bases have structures similar to the nucleic acid bases, but display much longer excited state lifetimes. Theoretical investigations using quantum mechanical methods can provide insight into the precise mechanisms of these decay processes, and to the molecular specifics that contribute to them. The results of multi-reference configuration interaction (MRCI) ab initio investigations into these mechanisms are presented, with emphasis on cytosine and its fluorescent analog 5-methyl-2-pyrimidinone (5M2P). A comprehensive picture of the potential energy surfaces of these two bases is given, including stationary points and conical intersections, where radiationless transitions are promoted, between up to three state surfaces, as well as pathways connecting these points for each base. Cytosine is shown to have two different energetically accessible radiationless decay channels. The fluorescence of 5M2P is also demonstrated theoretically, with mechanism proposed. The potential energy surfaces of the two bases have many close similarities, with the different photophysical properties being attributed to subtle energetic differences between the two bases. Nonadiabatic coupling and the geometric phase effect are analyzed in detail near conical intersections in cytosine, including in a region close to a three-state conical intersection. A substituent effect study on the 2-pyrimidinone ring system shows that the presence, position and orientation of the amino group in cytosine is central to its photophysical properties, particularly its high absorption energy, and can be explained with a simple Frontier Molecular Orbital model. The effects of water solvent on the excitation energies of cytosine and uracil are theoretically investigated using two multi-reference ab initio methods, a quantum mechanical molecular mechanics method using MRCI (MRCI-QM/MM), and the fragment molecular orbital multiconfiguration self-consistent field method (FMO-MCSCF). The solvatochromic shifts calculated from both methods agree well with other more expensive methods and experimental data. The effects of water on the photophysical pathways of cytosine is also investigated using MRCI-QM/MM, including considerations of solvent reorganization. Results show that the overall effect of water on the decay mechanisms is small, with neither decay channel being significantly blocked or favored. / Chemistry

Chemistry, Physical

Quantum Physics

Biophysics, General

Cytosine

Dna Base

Fluorescence

Nonadiabatic Transitions

Photophysics

Radiationless Decay

Density Functional Theory: Dispersion Interactions & Biological Applications

Arabi, Alya A.

14 August 2012

London or dispersion interactions are weak van der Waals (vdW) interactions. They are important in determining the structure and properties of many chemical and biochemical systems. In this thesis, an optimizer using the nonempirical generalized gradient approximation (GGA) functional PW86+PBE+XDM, to capture van der Waals interactions, is presented. The work in this thesis covers the assessment of a variety of basis sets for their ability to reproduce accurate GGA repulsive and binding energies. Selected basis sets were then used to compute binding energies of 65 vdW complexes at equilibrium. This functional was also tested for binding energies of two sets of vdW complexes at distorted geometries. The last part deals with forces to investigate their accuracy using PW86+PBE+XDM in order to build an optimizer for vdW complexes using a nonempirical DFT method. Eventually, after confirming a high reproducibility of the optimizer on the geometries and binding energies, it was used in two biologically relevant applications. This optimizer is a unique tool to compute deformation energies with a nonempirical DFT method. The second part of this thesis covers a biologically relevant application where a conventional DFT is used. This application is related to the carrier of the genetic codes in living cells, DNA. DNA undergoes harmful mutations under external perturbations such as applied external electric fields. In this study, DNA base pairs were first mimicked by a simpler model, namely, the formic acid dimer. The effect of applied external electric fields on the geometries of the formic acid dimer is studied. The effect of these applied fields on the potential energy surface, the barrier height and the frequency of the double proton transfer in the formic acid dimer are also investigated. The study was then repeated on DNA base pairs to study the effect of an external applied electric field on the tunneling corrected rate constants of the double proton transfer reactions in AT and GC.

Spectroscopy of Occupied and Unoccupied States in Bio-Molecular Layers

Seifert, Stefan

30 October 2005

The present thesis investigates the electronic and structural properties of adenine, cytosine, and guanine layers on hydrogen passivated silicon (111)(7x7). The (7x7) reconstruction of the silicon surface was achieved by direct current heating of the samples in UHV conditions. After in situ hydrogen passivation layers of the DNA bases were prepared in different thicknesses by means of organic molecular beam deposition, all samples were characterized employing valence band and core level photoemission spectroscopy. Additionally the near edge x-ray absorption fine structure of the DNA base layers was investigated. A detailed and consistent picture of structural and electronic properties of the nucleotide bases in the solid state could be developed by comparison of measurements and DFT/B3LYP calculations.

info:eu-repo/classification/ddc/500

ddc:500

NEXAFS

Photoemission

DNA base

adenine

core level

cytosine

guanine

molecular orientation

valence band

Techniques for Storing and Processing Next-Generation DNA Sequencing Data

Camerlengo, Terry Luke

02 June 2014

No description available.

Bioinformatics

DNA sequence storage

4 bit encoding

reference-based compression

Needleman-Wusnch

DNA base pair compression

sequence compression

MongoDB

NGS Data management

bioinformatics

NoSQL

3 bases per byte