CRISPR/Cas-mediated chromosome engineering: opening up a new avenue for plant breeding

The advent of powerful site-specific nucleases, particularly the clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein (Cas) system, which enables precise genome manipulation, has revolutionized plant breeding. Until recently, the main focus of researchers has been to simply knock-in or knock-out single genes, or to induce single base changes, but constant improvements of this technology have enabled more ambitious applications that aim to improve plant productivity or other desirable traits. One long-standing aim has been the induction of targeted chromosomal rearrangements (crossovers, inversions, or translocations). The feasibility of this technique has the potential to transform plant breeding, because natural rearrangements, like inversions, for example, typically present obstacles to the breeding process. In this way, genetic linkages between traits could be altered to combine or separate favorable and deleterious genes, respectively. In this review, we discuss recent breakthroughs in the field of chromosome engineering in plants and their potential applications in the field of plant breeding. In the future, these approaches might be applicable in shaping plant chromosomes in a directed manner, based on plant breeding needs.

Automated summary

The powerful CRISPR/Cas system has revolutionized plant breeding by enabling precise genome manipulation, moving beyond simply knocking in or out single genes to inducing targeted chromosomal rearrangements. This technique has the potential to transform plant breeding by altering genetic linkages between traits and overcoming natural obstacles to breeding processes like inversions. Recent breakthroughs in chromosome engineering in plants suggest potential applications in shaping plant chromosomes based on breeding needs.