Скачать книгу

repair (HDR) of DSB, and transcriptional or epigenetic regulation via fusion of an inactivated CRISPR Cas protein (“endonuclease dead” dCas9) with a transcriptional activator (CRISPR activation, CRISPRa) for upregulation of gene expression, with a transcriptional repressor (CRISPR interference, CRISPRi) for downregulation of gene expression, or with an epigenetic modifying enzyme (CRISPRepi) for DNA methylation or post‐translational modifications of histone proteins. While these platforms were largely developed by academic labs, their rapid implementation in biomedical and pharmaceutical research settings has been greatly facilitated by reagent providers and contract research organizations (CROs) that offer state‐of‐the‐art reagents and contract services. In fact, it is now routine practice for scientists to use commercially available CRISPR reagents for in‐house studies and/or to consider working with a CRO on a specific genome editing project. This article aims to summarize our learnings and provide guidance on the selection of appropriate reagents and/or CROs for CRISPR‐based studies.

      4.2.1 Publicly Available Resources

      CRISPR technologies have been quoted as being the “Swiss army knife” equivalent for the science world, due to the ease of their design and generation – as compared with zinc‐finger nucleases (ZFNs) and transcription activator‐like effector nucleases (TALENS) – and the diversity of their applications (Doench 2018; Mans et al. 2015). Furthermore, the “open‐source” culture of the CRISPR field has helped accelerate its continued innovation (Zhang 2019). This has been facilitated by numerous resources like web‐based tutorials, publicly available webinars, databases for data deposition, and annual CRISPR meetings. For example, a freely available resource called the Open Repository for CRISPR Screens (ORCS) (https://orcs.thebiogrid.org) was developed by the Biological General Repository for Interaction Datasets (BioGRID) (Oughtred et al. 2019), which enables researchers to search, filter, and download CRISPR screen datasets. Version 1.0.3 of the ORCS contains 895 CRISPR screens from 3 major model organism species and 629 cell lines. In addition, when novel methodologies are published, the associated constructs often become available through repositories like Addgene, an international nonprofit repository (Kamens 2015), to which over 350 labs have contributed. Reagent sharing has the advantage that it enables vigorous testing of the new technology and encourages rapid further improvements. However, Addgene is not accessible to for‐profit organizations; thus, for industry/biotech institutions, the only access to reagents is via commercial providers.

      4.2.2 Cas9 Enzymes

Company Location Reagents
Agilent Santa Clara, CA Oligo library synthesis; synthetic gRNA and libraries
Cellecta Mountain View, CA Cas9 and gRNA expression vectors, lentiviral gRNA libraries
GenScript Jiangning, China Cas9 nuclease; Cas9 and gRNA expression vectors; lentiviral gRNA libraries
Horizon Discovery Cambridge, United Kingdom Cas9 nucleases; Cas9 and gRNA expression vectors; synthetic, plasmid, and lentiviral gRNA and libraries
Integrated DNA Technologies Coralville, IA Oligo library synthesis; Cas9 nucleases; Cpf1 nuclease; Cas9 and gRNA expression vectors; synthetic gRNA libraries
Merck KGaA Darmstadt, Germany Cas9 nucleases; Cas9 and gRNA expression vectors; synthetic, plasmid, and lentiviral gRNA and libraries
New England Biolabs Ipswich, MA Cas9 nucleases
Oxgene Oxford, United Kingdom Plasmid and lentiviral gRNA libraries
Synthego Redwood City, CA Synthetic gRNA and libraries
System Biosciences Palo Alto, CA Cas9 and gRNA expression vectors
Takara Bio Mountain View, CA Cas9 nucleases; Cas9 and gRNA expression vectors; synthetic, plasmid, and lentiviral gRNA and libraries
ThermoFisher Carlsbad, CA Cas9 nucleases; Cas9 and gRNA expression vectors; synthetic and lentiviral gRNA and libraries
Transomic Technologies Huntsville, AL Cas9 and gRNA expression

Скачать книгу