“CRISPR technologies can be programmed to target specific sequences of genetic code and to edit DNA at precise locations, thus allowing research scientists to permanently modify genes in living cells and model organisms to explore gene function in the laboratory, including genes associated with human disease,” said first author Dr. David Marciano, instructor in the Olivier Lichtarge laboratory at Baylor College of Medicine.
However, this approach presents some challenges, such as constraints on the sequences that can be targeted, the possibility of off-target effects and the requirement of a unique guide RNA for each target gene. Swings, Marciano and their colleagues established an international collaboration that led to a simple solution that circumvents all these issues.
“Toon and I had a set of projects in which we had to construct many mutations and guide RNAs for different genes in the bacterium E. coli. We realized we wouldn’t need a new guide RNA for each gene if we just targeted a universal sequence found in gene knockout collections. The sequence we targeted is found in many genetic collections of medically important bacteria and is even in some fruit fly collections,” Marciano said.
The researchers used a library of E. coli clones called the Keio collection. Each clone in this collection has had one gene replaced by a kanamycin resistance gene. The collection was made available in 2006 through an international collaboration between Keio University of Japan and Purdue University in the United States.
Their approach avoids some technical aspects of CRISPR and makes it available as an off-the-shelf ingredient for genetic engineering. It removes the need to design and clone a guide RNA and simplifies the strategy for constructing a rescue template. Also, the Keio collection can be found in laboratories across the globe and individual clones are available for a nominal fee from centralized genetic stock centers.
“Many model organisms, besides E. coli, have collections of gene replacements or insertions that could be targeted by a single guide RNA in a similar manner,” Swings said. “We hope our work provides a broad platform for a variety of genetic engineering approaches.”
“This is a nice example of the power of bacterial genetics. This is where CRISPR was first discovered, and now again, a different bacterial technology may make it even more useful,” said corresponding author Dr. Olivier Lichtarge, Cullen Chair of Molecular and Human Genetics, and professor of biochemistry and molecular biology and of pharmacology Baylor College of Medicine. Lichtarge also is a member of the Dan L Duncan Comprehensive Cancer Center at Baylor.
“The developed platform based on CRISPR technology will be valuable to many researchers in microbiology to perform rapid single nucleotide editing of their genes of interest or to generate chromosomal mutant collections, one of the first steps in understanding gene function,” said corresponding author Dr. Jan Michiels, group leader at VIB-KU Leuven Center for Microbiology and professor of biochemistry and molecular microbiology at the University of Leuven. Other contributors to this work include Benu Atri, Rachel E. Bosserman, Chen Wang, Marlies Leysen, Camille Bonte, Thomas Schalck, Ian Furey, Bram Van den Bergh, Natalie Verstraeten, Peter J. Christie and Christophe Herman. The authors are affiliated with one or more of the following institutions: Baylor College of Medicine, VIB, University of Leuven and McGovern Medical School, Houston.
Source: VIB