The Role of Base Modifications on Tyrosyl-tRNA Structure, Stability, and Function in Bacillus subtilis and Bacillus anthracis

Denmon, Andria

16 September 2013

tRNA molecules contain more than 80 chemically unique nucleotide base modifications that contribute to the chemical and physical diversity of RNAs as well as add to the overall fitness of the cell. For instance, base modifications have been shown to play a critical role in tRNA molecules by improving the fidelity and efficiency of translation. Most of this work has been carried out extensively in Gram-negative bacteria, however, the role of modified bases in tRNAs as they relate to thermostability, structure, and transcriptional regulation in Gram-positive bacteria, such as Bacillus subtilis and Bacillus anthracis, are not well characterized. Infections by Gram-positive bacteria that have become more resistant to established drug regiments are on the rise, making Gram-positive bacteria a serious threat to public safety. My thesis work examined what role partial base modification of the tyrosyl-anticodon stem-loops (ASLTyr ) of B. subtilis and B. anthracis have on thermostability, structure, and transcriptional regulation. The ASLTyr molecules have three modified residues which include Queuine (Q34), 2-thiomethyl-N6-dimethylallyl (ms2i6A37), and pseudouridine (Y39). Differential Scanning Calorimetry (DSC) and UV melting were employed to examine the thermodynamic effects of partial modification on ASLTyr stability. The DSC and UV data indicated that the Y39 and i6A37 modifications improved the molecular stability of the ASL. To examine the effects of partial base modification on ASLTyr structure, NMR spectroscopy was employed. The NMR data indicated that the unmodified and [Y39]-ASLTyr form a protonated C-A+ Watson-Crick-like base pair instead of the canonical bifurcated C-A+ interaction. Additionally, the loop regions of the unmodified and [Y39]-ASLTyr molecules were well ordered. Interestingly, the [i6A37]- and [i6A37; Y39]- ASLTyr molecules did not form a protonated C-A+ base pair and the bases of the loop region were not well ordered. The NMR data also suggested that the unmodified and partially modified molecules do not adopt the canonical U-turn structure. The structures of the unmodified, [Y39]-, and [i6A37;Y39]-ASLTyr molecules did not depend on the presence of Mg2+, but the structure of the [i6A37]-ASLTyr molecule did depend on the presence of multivalent cations. Finally, to determine the repercussions that partial modification has on physiology and tRNA mediated transcriptional regulation in B. anthracis, antibiotic sensitivity tests, growth curves, and quantitative real-time polymerase chain reaction (qRT-PCR) were employed. Strains deficient in ms2 showed comparable growth to the parent strain when cultured in defined media, but Q deficient strains did not. The loss of ms2i6A37 conferred resistance to spectinomycin and ciprofloxacin, whereas the loss of Q34 resulted in sensitivity to erythromycin. Changes in the ratio full-length to truncated transcripts of the tyrS1 and tyrS2 genes were used to monitor tRNA mediated transcriptional regulation. The qRT-PCR data suggested that tyrS1 and tyrS2 are T-box regulated and that the loss of ms2i6A37 and Q34 might affect the interaction of the tRNATyr molecule with the specifier sequence, which is located in the 5’-untranscribed region (UTR) of the messenger RNA (mRNA).

tRNA

Tyrosine

Base Modification

2-methylthio-N6-isopentenyladenosine

Pseudouridine

Queuosine

NMR spectroscopy

T box Mechanism

DNA damage induced by low energy electrons (LEEs) / Dommages à l'ADN induits par les électrons de basse énergie

Choofong, Surakarn

January 2016

Abstract : The major objective of our study is to investigate DNA damage induced by soft X-rays (1.5 keV) and low-energy electrons (˂ 30 eV) using a novel irradiation system created by Prof. Sanche’s group. Thin films of double-stranded DNA are deposited on either glass and tantalum substrates and irradiated under standard temperature and pressure surrounded by a N[subscript 2] environment. Base release (cytosine, thymine, adenine and guanine) and base modifications (8-oxo-7,8-dihydro -2’-deoxyguanosine, 5-hydroxymethyl-2’-deoxyuridine, 5-formyl-2’-deoxyuridine, 5,6-dihydrothymidine and 5,6-dihydro-2’-deoxy uridine) are analyzed and quantified by LC-MS/MS. Our results reveal larger damage yields in the sample deposited on tantalum than those on glass. This can be explained by an enhancement of damage due to low-energy electrons, which are emitted from the metal substrate. From a comparison of the yield of products, base release is the major type of damage especially for purine bases, which are 3-fold greater than base modifications. A proposed pathway leading to base release involves the formation of a transient negative ion (TNI) followed by dissociative electron attachment (DEA) at the N-g lycosidic bond. On the other hand, base modification products consist of two major types of chemical modifications, which include thymine methyl oxidation products that likely arises from DEA from the methyl group of thymine, and 5,6-dihydropyrimidine that can involve the initial addition of electrons, H atoms, or hydride ions to the 5,6-pyrimidine double bond. / Résumé: L'objectif majeur de ce projet étude est d'étudier les lésions d'ADN induites par les rayons X mous (1,5 keV) et des électrons de faible énergie (˂ 30 eV) à partir d'un nouveau système d'irradiation créé par le groupe du Pr. Sanche. De minces couches d'ADN double brin sont déposées soit sur du verre ou sur les substrats de tantale. Celles-ci sont irradiées sous une température et pression environnante, mais dans une atmosphère de N[indice inférieur 2]. Les bases relâchées (cytosine, la thymine, l'adénine et la guanine) et les produits de modification de base (8-oxo-7,8-dihydro-2'-désoxyguanosine, 5-hydroxyméthyl-2'-désoxyuridine, 5-formyl-2'-désoxyuridine, 5,6-dihydrothymine et 5,6-dihydrouridine) sont analysés et quantifiés par LC-MS/MS. Nos résultats révèlent un plus grand rendement de dommages dans les échantillons déposés sur le tantale que celles sur le verre. Cette différence peut être expliquée par l’interaction des électrons de faible énergie qui sont photo émis des substrats métalliques. D'après les résultats obtenus, la libération de bases est un produit majeur en comparaison avec la modification de bases. Ceci provient, en particulier, surtout des purines qui libèrent la base a un niveau trois fois plus grand que la modification de la base. Une voie proposée, conduisant à la libération de base, implique la formation d'ions négatifs transitoires (TNI), suivie par l'attachement d'électrons dissociatifs (DEA) à la liaison N-glycosidique. En outre, les produits de modification de base sont composés en deux grands types de modifications chimiques. L’un des produits est l’oxydation du groupe méthyle de la thymine, qui probablement consiste de en d'hydrure (-H[indice supérieur -]) par l'intermédiaire de DEA. Alors que l’autre modification chimique est la formation de 5,6-dihydropyrimidine qui implique l'addition d'hydrure à la double liaison du 5,6-pyrimidine.

Dommage à l'ADN

Libération de base

Modification de base

Électrons de basse énergie

LC-MS/MS

DNA damage

Base release

Base modification

Low-energy electrons