Thesis

Novel biocatalytic strategies for the synthesis of N-functionalised amino acids

Creator
Rights statement
Awarding institution
  • University of Strathclyde
Date of award
  • 2018
Thesis identifier
  • T15982
Person Identifier (Local)
  • 201456026
Qualification Level
Qualification Name
Department, School or Faculty
Abstract
  • Chiral unnatural amino acids represent a class of building blocks that has gained significant attention within the pharmaceutical and agrochemical industries in recent years. Therefore, the availability of synthetic methods for novel unnatural N-protected α-amino acid derivatives is critical. Their synthesis has attracted considerable interest, however access to N-protected amino acids often requires the use of toxic reagents and hazardous solvents or stoichiometric quantities of hazardous hydrides. A number of biocatalytic approaches to chiral amino acids have been reported in recent years that provide access to this class of compounds using greener, less hazardous methodologies, however the identification of enzyme classes that could carry out reactions efficiently under industrially applicable conditions with a large substrate scope still represents a challenge. To this end, the development of a panel of novel biocatalysts to carry out reductive amination reactions for use in large scale drug synthesis has been attempted in this project. This entailed an examination of the existing wild type enzymes from three different classes (N-methylamino acid dehydrogenases, ketimine reductases and Δ1 -pyrroline5-carboxylate reductases), which required expression and screening. A variety of substrates were tested to determine the substrate scope of the enzymes. Additionally, a set of racemic product standards was selected and synthesised by chemical methods for comparison with the enzymatic products. This allowed the identification of new substrates that could be accepted for reductive amination, allowing for the synthesis of N-functionalised amino acids not previously accessible by enzyme catalysis.
Advisor / supervisor
  • Sutton, Peter (Peter W.)
  • Lovelock, Sarah L.
  • Watson, Allan J.B.
  • Roiban, Gheorghe-Doru
Resource Type
Note
  • Previously held under moratorium in Chemistry department (GSK) from 31st May 2018 until until 18th June 2021
DOI
Funder
Embargo Note
  • This thesis is restricted to Strathclyde users only until 22nd June 2025.

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