Genome Editing and the Essential Toolbox of Genetic Perturbation Technologies for Target Biology

Drug attrition in clinical trials due to inaccurate preclinical target validation is a huge problem facing drug discovery. Drug candidates with adequate pharmacokinetics and safety margins still commonly fail, due to lack of efficacy. This suggests that often the ‘wrong’ target has been selected as the focus of the therapeutic program. Successful target validation will increasingly rely on the use of novel genetic and non-genetic tools including CRISPR and targeted protein degradation to disease relevant models.  Genome editing tools such as CRISPR-Cas9 are reshaping what is possible within biological sciences.  This is especially true for target validation and animal model generation.  With genome editing tools, discovery scientists can knock out genes, add tags and mutate genes, all at the endogenous level.  Furthermore, CRISPR enables bench-level access to a universe of targeted and genome-wide functional screens to understand gene function, unlock new drug targets, and deconvolute the mechanism of action of drug-like small molecules.

This course will introduce the state-of-the-art in genome editing, the current limitations and the step-by-step methodologies of how to apply these technologies to improve the drug discovery process, with an emphasis the on the selection of novel targets for drug development.  We will also dive into the methods of conducting pooled CRISPR screens and the considerations for designing them.  Finally, the course will discuss the practical approaches to target identification and validation through a modern toolbox of techniques that will increase the chances of success.

Who Should Attend?

• Target validation processes in drug discovery
• Use of CRISPR and other genome editing tools for assay development, target validation, and exploration of target biology
• Use of emerging tools in the targeted protein degradation to advance target validation goals
• Data Analysis and integration of tools with bioinformatics pipeline
• Gene editing in 2025: workflows for creating knockout and knock-in cell lines
• CRISPR-Cas9 and beyond: tools of the trade
• Applications of genome editing in functional genomics
• A practical guide to using genome editing tools in genetic screens

Course Benefits

• Assay and HTS biologists
• Those focused on target ID and target validation
• Biologists and chemists interested in drug discovery technology
• Scientists working on functional genomics and genetic screens
• Those wanting to learn the details of CRISPR/Cas9 technology and how it can be practically applied in the lab

Course Topics

• Learn up-to-date information on the tools, methods and applications of genome editing
• Discovery workflows for typical experiments and practical use cases
• Discuss case studies of how genome editing is enabling discovery research

Instructors

Scott T. Younger, Ph.D.
Children’s Mercy Research Institute, Children’s Mercy Kansas City

Scott Younger is the Director of Disease Gene Engineering within the Genomic Medicine Center at Children's Mercy Kansas City. His laboratory is focused on dissecting the molecular mechanisms through which rare genetic variants identified in patients at Children's Mercy lead to disease. Younger joined Children's Mercy from the Broad Institute of MIT and Harvard where his group worked on the development of new methodologies to expand the utility of CRISPR-based genetic screens. Prior to working at the Broad Institute he completed his postdoctoral studies at Harvard University as an American Cancer Society Fellow. He holds a Ph.D. in cell and molecular biology from UT Southwestern Medical Center. He also received an M.S. in biotechnology from the University of Texas at San Antonio and a B.S.I. in bioinformatics from Baylor University.

Samuel A. Hasson, Ph.D.
Voyager Therapeutics

Sam Hasson is currently an Associate Director at Voyager Therapeutics (Cambridge, Massachusetts). A major aim of his work is to develop novel applications of AAV-based gene therapy in the CNS to transform the treatment of unmet medical needs. Prior to joining Voyager in 2020, Hasson led groups within Amgen Neuroscience and Pfizer Neuroscience with a focus on the deconvolution of human disease genetics for drug target selection, employing genome editing technologies to enable this process. As a postdoc, he trained with Richard Youle and Jim Inglese at the National Institutes of Health.