Aims

The aims of the course are to:

• To provide a basic grounding in biomolecular engineering along with underpinning molecular biology.
• To increase awareness for the opportunities for bioengineering within modern biology.
• To have enough background knowledge and familiarity with the terminology to be able to play a productive role collaborating with biologists.
• To provide the grounding for a new Part IIB course, Molecular Bioengineering II, that is expected to run for the first time in 2021-2022.

Objectives

As specific objectives, by the end of the course students should be able to:

• An appreciation of the potential of engineering living systems
• An appreciation of the capabilities of applying evolution in a laboratory setting
• Understanding of the fundamental molecules and processes required for gene expression and replication
• Understanding gene structure and regulation in simple organisms
• To have a basic knowledge of what is feasible with genetic engineering, and the underpinning molecular techniques
• Designing synthetic genetic circuits: understanding basic mathematical and molecular biological frameworks
• Designing synthetic genetic circuits: living systems vs cell-free systems
• To understand the latest technologies for genome sequencing, genome analysis, and genome-scale experimental methods
• An appreciation for DNA as a construction material for information storage and other applications

Content

The structure of the course will be as follows.

Lectures 1-5 (GM): Evolution; storage and use of genetic information; DNA amplification; molecular cloning

Lectures 6-11 (SB): Gene expression and regulation; enzyme kinetics; synthetic control circits

Lectures 12-13 (GM): Genomes, genome sequencing and transcriptomics

Lectures 14-16 (GM): Cell-free systems; expanding the genetic code; DNA for construction and data storage; DNA dynamics