Alkylation of adenine : a synthetic and computational study of the reaction mechanism

Buyens, Dominique M.S.

January 2015

This dissertation describes the benzylation of adenine under basic conditions, the unequivocal determination of the identity of the products of this reaction, an exploration of the effect of solvent on the reaction, a thorough computational study of the reaction mechanism and an investigation into the hydrogen-deuterium exchange reaction of the N-benzyladenine products and related compounds. The preferential sites of alkylation of adenine under basic conditions in DMSO were proven to be the N9 and N3 positions. X-ray crystal structures were obtained for both compounds. Formation of the N9-benzyladenine product is the most favoured in polar aprotic solvents, such as DMSO, and as the proportion of polar protic solvents, such as water, increases, so does the formation of the N3-benzyladenine product. Characteristic 1H NMR  chemical shifts of the purine ring protons and HMBC 1H-13C correlation NMR spectroscopy were useful tools to assign the 1H and 13C NMR spectra chemical shifts and confirm that the solution structures were the same as the isolated crystals. Simulating the SN2 mechanism for the N1-, N3-, N7- and N9-pathways computationally, employing DMSO as the simulated solvent, resulted in ambiguous results when considering the electronic energies of initial, TS and final products alone. However, a novel approach was developed (employing IQA-defined energy terms) to study fragment interactions along the reaction paths. It provided a full explanation of the reaction mechanism and yielded results which supported the N3/N9 positions of alkylation over the N1/N7 sites. The preference for the sites of alkylation occurs after the transition state, in which the N1/N7 reaction paths fail to proceed favourably to the end product, N1- and N7-benzyladenine, respectively. The N9-pathway dominates the N3-pathway at the product formation step, which corresponds to the N9- benzyladenine being the major product, as shown in Figure 1, and the N3-benzyladenine being the minor product from the benzylation of adenine. The faster rate of deuteration at the C8 position of N9-benzyladenine as compared to the deuteration rates at the C2 and the C8 of N3-benzyladenine, have shown support for a sp3 mediated mechanism and a carbene mediated mechanism of deuteration based on the “push” and “pull” mechanisms proposed for the C8 proton transfer of ATP in kinase enzymes. The deuteration of the C8 proton of 2,6-dichloropurine derivatives supports the existence of the carbene mediated mechanism since these compounds lack the amine moiety necessary for the sp3 mediated mechanism. These results demonstrate how experimentation and computation have led to greater insights into the reactivity of adenine and its derivatives. This strategy provides a useful platform for future research into adenine reaction mechanisms and the role adenine plays in kinase catalysis. / Dissertation (MSc)--University of Pretoria, 2015. / National Research Foundation (NRF) / Chemistry / MSc / Unrestricted

SNZ mechanism

N-benzyladenine

IQA fragment analysis

Purine deuteration

UCTD

Regulation of kinases by synthetic imidazoles, nucleotides and their deuterated analogues

Nkosi, Thokozani Clement

19 April 2016

Deuteration is the replacement of a hydrogen atom by deuterium atom in a molecule. The replacement begins at the most acidic hydrogen in the molecule. In ATP, the deshielded hydrogen is C8-H which is the first replaced during deuteration. During ATP deuteration some of the ATP is hydrolysed to ADP concurrently. Using kinetic analysis, it was confirmed that the ATP hydrolysis that occurs is 1st order in ATP concentration, while the hydrogen replacement is 2nd order. The ATP and its C8 deuterated analogue were tested against three enzymes shikimate kinase (SK), acetate kinase (AK) and glutamine synthetase (GS) to determine if a kinetic isotope effect (KIE) exists in these systems. With AK and GS, the KIED increased as the KIEH decreased, while with SK the KIED decreased as the KIEH increased as the concentration of the ATP or deuterated analogue increased. Deuteration of imidazole and purine compounds reduced the specific activity of AK or SK at low concentrations in an enzyme-catalysed reaction. From a library of imidazole-containing compounds that inhibited SK, three compounds were selected and their IC50 values were determined on the SK-catalysed reaction. These compounds show a differential potency and efficiency between their protonated and deuterated analogues when compared in a 1:1 mixture. Synthesized purines incorporating three different substituents at N-9 were tested against AK or SK for their ability to lower the specific activity of the enzymes used / Physics / M. Sc. (Physics)

Acetate kinase

Glutamine synthetase

Shikimate kinase

Adenosine triphosphate rate order

Proton nuclear magnetic resonance

Enzyme activity and kinetics

Imidazole and purine deuteration

572.744

Deuterium

Acetates

Glutamine synthetase

Adenosine triphosphate

Proton magnetic resonance

Enzyme activation

Enzyme kinetics

Regulation of kinases by synthetic imidazoles, nucleotides and their deuterated analogues

Nkosi, Thokozani Clement

19 April 2016

Deuteration is the replacement of a hydrogen atom by deuterium atom in a molecule. The replacement begins at the most acidic hydrogen in the molecule. In ATP, the deshielded hydrogen is C8-H which is the first replaced during deuteration. During ATP deuteration some of the ATP is hydrolysed to ADP concurrently. Using kinetic analysis, it was confirmed that the ATP hydrolysis that occurs is 1st order in ATP concentration, while the hydrogen replacement is 2nd order. The ATP and its C8 deuterated analogue were tested against three enzymes shikimate kinase (SK), acetate kinase (AK) and glutamine synthetase (GS) to determine if a kinetic isotope effect (KIE) exists in these systems. With AK and GS, the KIED increased as the KIEH decreased, while with SK the KIED decreased as the KIEH increased as the concentration of the ATP or deuterated analogue increased. Deuteration of imidazole and purine compounds reduced the specific activity of AK or SK at low concentrations in an enzyme-catalysed reaction. From a library of imidazole-containing compounds that inhibited SK, three compounds were selected and their IC50 values were determined on the SK-catalysed reaction. These compounds show a differential potency and efficiency between their protonated and deuterated analogues when compared in a 1:1 mixture. Synthesized purines incorporating three different substituents at N-9 were tested against AK or SK for their ability to lower the specific activity of the enzymes used / Physics / M. Sc. (Physics)

Acetate kinase

Glutamine synthetase

Shikimate kinase

Adenosine triphosphate rate order

Proton nuclear magnetic resonance

Enzyme activity and kinetics

Imidazole and purine deuteration

572.744

Deuterium

Acetates

Glutamine synthetase

Adenosine triphosphate

Proton magnetic resonance

Enzyme activation

Enzyme kinetics