A CRISPR-based gene editing technique called twin prime editing could be a new and safer approach to gene therapy.
Researchers at the Broad Institute of MITMIT is an acronym for the Massachusetts Institute of Technology. It is a prestigious private research university in Cambridge, Massachusetts that was founded in 1861. It is organized into five Schools: architecture and planning; engineering; humanities, arts, and social sciences; management; and science. MIT’s impact includes many scientific breakthroughs and technological advances.”>MIT and Harvard have developed a new version of prime editing that can install or swap out gene-sized DNADNA, or deoxyribonucleic acid, is a molecule composed of two long strands of nucleotides that coil around each other to form a double helix. It is the hereditary material in humans and almost all other organisms that carries genetic instructions for development, functioning, growth, and reproduction. Nearly every cell in a person’s body has the same DNA. Most DNA is located in the cell nucleus (where it is called nuclear DNA), but a small amount of DNA can also be found in the mitochondria (where it is called mitochondrial DNA or mtDNA).”>DNA sequences. First developed in 2019, prime editing is a precise method of making a wide diversity of gene edits in human cells, including small substitutions, insertions, and deletions.
In a study published on December 9, 2021, in Nature Biotechnology, the team describes twin prime editing (twinPE), a technique that makes two adjacent prime edits to introduce larger sequences of DNA at specific locations in the genome with few unwanted byproducts. With further development, the technology could potentially be used as a new form of gene therapy to insert therapeutic genes in a safe and highly targeted manner to replace mutated or missing genes.
The researchers demonstrated the therapeutic potential of twinPE by editing, in human cells, a gene linked to Hunter syndrome, a rare genetic disorder. This disease is caused by an inversion of a specific 40,000 base pair long stretch of DNA. The team used twinPE to introduce an inversion of a similar length at the same site in the genome, showing how the method could be used to correct the disease-causing mutation. The team also used twin PE to precisely insert gene-sized DNA cargo of thousands of base pairs into therapeutically relevant sites in the genome.
The approach addresses a limitation of the original prime editing system, which can edit only several dozen base pairs. However, the study or treatment of some genetic diseases could require larger edits. Like the original prime editing method, twinPE also does not completely sever the DNA double helix by cutting both strands simultaneously at the same location, which can induce poorly controlled editing outcomes and harmful chromosomal abnormalities.
“Inserting a healthy gene in a patient at a site of our choosing without generating double-strand breaks and mixtures of byproducts has been one of the longstanding challenges in gene editing,” said David Liu, senior author of the study, Richard Merkin Professor and director of the Merkin Institute of Transformative Technologies in Healthcare at the Broad Institute, professor at Harvard University, and a Howard Hughes Medical Institute investigator.
“TwinPE could be a potentially safer and more precise way to insert whole genes of therapeutic interest into positions we specify, such as the location of the native gene in healthy individuals or ‘safe harbor’ sites thought to minimize the risk of side-effects.”
Editing in prime time
Prime editing, developed by Liu’s lab, enables DNA substitutions, insertions, and deletions, and promises to correct the majority of known disease-causing genetic variations. Recent improvements to prime editing technology increased its efficiency, edging it closer to therapeutic applications. But editing sequences longer than 100 base pairs remained inefficient.
Twin prime editing fills this gap. The system uses a prime editor protein and two prime editing guide RNAs, which guide the editing machinery and encode the edits. Each of the two guide RNAs direct the editing protein to make a single-stranded nick in the DNA at different targeted sites in the genome, avoiding the kind of double-strand break that creates unwanted byproducts in other methods. The system then synthesizes two new complementary DNA strands containing the desired sequence in between the two nicks. Using this approach, the team was able to insert, substitute, or delete sequences up to about 800 base pairs long.
To edit even larger sequences, the researchers used their twin prime editing system to install “landing sites” in the genome for enzymes called site-specific recombinases, which catalyze the integration of DNA at specific sites in the genome. The team then treated the cells with a recombinase enzyme and introduced the long pieces of DNA they wanted to insert into the genome. Combining twinPE and recombinase enzymes allowed the scientists to edit sequences thousands of base pairs long — the length of entire genes.
Liu and his team are now testing different recombinases that might make twinPE more efficient. They are also assessing twinPE’s ability to install even longer genetic sequences.
“It’s been a longstanding aspiration of many labs including ours to be able to advance gene therapy in the way that scientists have advanced gene editing over the past several years,” Liu said. “This study, together with other efforts of other scientists, could mark the beginnings of a new generation of gene therapy strategies, just as CRISPR nucleases, base editors, and prime editors represented the beginnings of a new generation of gene editing technologies.”
Reference: “Programmable deletion, replacement, integration and inversion of large DNA sequences with twin prime editing” by Andrew V. Anzalone, Xin D. Gao, Christopher J. Podracky, Andrew T. Nelson, Luke W. Koblan, Aditya Raguram, Jonathan M. Levy, Jaron A. M. Mercer and David R. Liu, 9 December 2021, Nature Biotechnology.
This work was supported by the Merkin Institute of Transformative Technologies in Healthcare, the National Institutes of Health, and the Howard Hughes Medical Institute.