Exchange of arms between chromosomes using molecular scissors
For thousands of years, humans have taken advantage of the fact that the genetic material of organisms changes by evolution. They cultivate crops that produce high yields, are aromatic or resistant against diseases, pests, and extreme climatic conditions. For this purpose, they choose plants with various favorable properties and crossbreed them. This approach, however, is very time-consuming. Moreover, it is impossible to prevent disadvantageous traits from entering the plants.
Molecular biologist Professor Holger Puchta studies how plants can be cultivated more quickly and more precisely. For his CRISBREED project, he received an Advanced Grant of the European Research Council (ERC) in the amount of EUR 2.5 million. Holger Puchta is considered a pioneer of genome editing. He uses molecular scissors to specifically modify the DNA (deoxyribonucleic acid) that carries the genetic information in crops. With the help of this CRISPR/Cas technology, genes can be removed, inserted, or exchanged easily. CRISPR/Cas stands for a certain section on the DNA (CRISPR – Clustered Regularly Interspaced Short Palindromic Repeats) and an enzyme (Cas) that recognizes this section and cuts the DNA precisely at this point. Crops produced by genome editing do not contain any DNA, which is why they are not to be equated with classical genetically modified organisms.
First Exchange of Arms between Chromosomes
Within CRISBREED, researchers of the Chair for Molecular Biology and Biochemistry of KIT’s Botanical Institute headed by Professor Holger Puchta, in cooperation with Professor Andreas Houben from IPK, Gatersleben, have now achieved first decisive progress in using the molecular CRISPR/Cas scissors: For the first time, they have exchanged arms between chromosomes of the thale cress model plant (Arabidopsis thaliana) with the help of the Cas9 protein originating from the Staphylococcus aureus bacterium. “The genome consists of a certain number of chromosomes, on which the individual genes are arranged in fixed order,” Puchta explains. “So far, CRISPR/Cas has enabled modifications of single genes only. Now, we can modify and recombine entire chromosomes.” These novel chromosomes are then heritable.
The findings presented in Nature Plants promise to result in major advantages for crop cultivation: It is generally difficult to combine positive properties and eliminate negative properties at the same time, because the decisive genes often are arranged in very close proximity on the same chromosome and transmitted together. By the exchange of arms between chromosomes, these properties can now be separated. “We now have the possibility to specifically control the modification of chromosomes and to strengthen or loosen the links between properties,” Puchta explains. “This controlled restructuring of the genome will revolutionize future crop cultivation.”
CRISPR/Cas9-mediated induction of heritable chromosomal translocations in Arabidopsis
Natalja Beying, Carla Schmidt, Michael Pacher, Andreas Houben, and Holger Puchta
Nature Plants (2020)
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