Synthetic Biology

Synthetic biology is an interdisciplinary branch of biology, combining biotechnology, molecular biology and biophysics, and is in many ways related to genetic engineering. It can be defined as design and construction of biological devices and biological systems for useful purposes. In particular, the purpose of synthetic biology is the design and fabrication of biological components and systems that do not already exist in the natural world and the re-design and fabrication of existing biological systems.
This course focuses on two aspects of synthetic biology: synthesis and engineering tools and their applications.
Part 1: We will explore how cellular regulation- transcriptional, translational, post-translational and epigenetic- can be used to engineer cells to accomplish well-defined goals.
· Biobricks and IGEM
· The repressilator
· Synthetic bacterial chromosome- Syn3.1
· Synthetic yeast chromosomes for modular metabolic engineering and multicellular phenotypes
· Genomic engineering using transposable elements in vertebrates
· Metabolic prostheses- synthetic biology- inspired treatment strategies for metabolic disorders
· Protein conformational changes in health and disease
Part 2: Protein engineering as an enabling tool in Synthetic Biology:
· Rational design
· Directed evolution
· Expanding the chemistry of life: cell free protein synthesis and nonnatural amino acids
Engineering of membrane proteins that responds to physical stimuli and their applications:
· Light-gated channels and pumps for optogenetics
· Mechanoreceptors for mechanosensing biology
· Temperature- and magnetic field-gated channels for in vivo neurobiology
Introduction to the genetically encoded nanosensors
· Ratiometric and intensimetric nanosensors
· Design and improvement of nanosensor. Rational and empirical design
· In vivo use of nanosensors