Daniel McGillivray Brown. 3 February 1923—24 April 2012

Abstract

Dan Brown was a nucleic acids chemist of the highest order, beginning with pioneering work under Lord Alexander Todd in the 1950s at University of Cambridge on chemical methods for synthesis of nucleosides and nucleotides. This work helped to confirm the furanose chemical structure of the sugar in nucleosides as well as the 3′-5′ phosphodiester linkage in DNA and RNA, perhaps the most well thought of achievement of his career. Later, as a chemistry department lecturer, he established the chemical structures of glycerol monophosphoinositides as well as triphosphoinositides. Turning back to the nucleic acids in 1961, he became fascinated by the effect of mutagens on DNA. He elucidated the mechanism for the reaction of hydroxylamine on cytidine to form an initial ‘bis-adduct’ and thereafter N 6 -hydroxycytidine. Moving in 1982 to the MRC Laboratory of Molecular Biology, he developed a method to prepare single-stranded DNA probes for detection of RNA sequences and in addition worked on a novel automated device for oligonucleotide synthesis. Reverting to his interest in mutagens, he then designed and synthesized hydrogen bonding degenerate bases and developed novel P and K modified pyrimidine and purine bases respectively as transition mutagens. Finally, he synthesized the base analogue 5-nitroindole as a potential universal base, which became useful in cycle DNA sequencing, and in addition developed the concept of ‘error catastrophe’ for the ribonucleoside of the P base as an antiviral agent. The P, K and 5-nitroindole bases became the most valued chemical entities of his career to molecular biologists. His legacy to the nucleic acids includes both his significant contributions to studies of the chemical nature of DNA and RNA and their constituents as well as a variety of enabling nucleic acids chemistry methods and mechanisms of DNA mutagenicity.