posted on 2017-09-21, 16:08authored byLinus F. Reichenbach, Ahmad Ahmad Sobri, Nathan R. Zaccai, Christopher Agnew, Nicholas Burton, Lucy P. Eperon, Sara de Ornellas, Ian C. Eperon, R. Leo. Brady, Glenn A. Burley
Relative to naturally occurring Watson-Crick base pairs, the synthetic nucleotide P pairs with Z within DNA duplexes through a unique hydrogen-bond arrangement. The loss of this synthetic genetic information by PCR results in the conversion of P-Z into a G-C base pair. Here, we show structural and spectroscopic evidence that the loss of this synthetic genetic information occurs via G-Z mispairing. Remarkably, the G-Z mispair is both plastic and pH dependent; it forms a double-hydrogen-bonded “slipped” pair at pH 7.8 and a triple-hydrogen-bonded Z-G pair when the pH is above 7.8. This study highlights the need for robust structural and functional methods to elucidate the mechanisms of mutation in the development of next-generation synthetic genetic base pairs.
History
Citation
Chem, 2016, 1 (6), pp. 946-958
Author affiliation
/Organisation/COLLEGE OF MEDICINE, BIOLOGICAL SCIENCES AND PSYCHOLOGY/MBSP Non-Medical Departments/Molecular & Cell Biology
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