German researchers decoded the European maize genome. In comparison to North American maize lines, they discovered differences. For cultivation of maize in areas with low yields and for challenges imposed by the climate change these observations of the research team led by Klaus F.X. Mayer, head of the research group "Plant Genome and Systems Biology" at Helmholtz Zentrum München and Chris-Carolin Schön, Professor for Plant Breeding at the Technical University of Munich (TUM) might be of particular interest.
The maize genome tells an intriguing story about domestication and the shaping of the genome by human selection. Around 10,000 years ago, first nation people started to domesticate maize in what is Mexico today. They created the basis for one of today's most important sources of food for both humans and livestock. After the discovery of the "new world" by Columbus, maize was brought from the Americas into Europe. Maize adopted to new growing and climate regimes through controlled breeding and selection and finally spread around the globe.
Due to its history, today's maize lines do not only differ in appearance, their genome contains many differences (presences and absences of genes as well as structural variations). In 2009, researchers decoded the genome of the North American maize accession "B73". This reference sequence, however, only covers a small part of the global maize genome (pan-genome) and is of limited use as a benchmark for European lines. In order to improve maize breeding and adapt to climate change, basic research on the genome of other maize lines is needed.
European maize genome decoded for the first time
German researchers now succeeded in decoding the European maize genome. They analyzed four different European maize lines using modern sequencing technologies and bioinformatics approaches. In comparison with two lines from North America, they found significant differences in the genetic content and genome structure of these lines - after a few hundred to a thousand years of genetic separation only.
Moreover, so-called "knob" regions (condensed chromatin regions in the maize DNA) vary substantially in those maize lines. Knob regions are known to affect adjacent genes. In areas where knobs tend to be more pronounced, surrounding genes cannot be read. This results in a loss of genetic function.
Reveal genetics of efficient hybrid varieties
„We hypothesize that differences in gene content, gene regulation and the influence of knob regions might cause the heterosis effect," says Prof. Klaus Mayer, genomicist at Helmholtz Zentrum München and honorary professor of TUM School of Life Sciences at the Technical University of Munich.
Heterosis occurs when the descendants of crossbreeds are significantly larger and produce higher yields than their parents. If specific genes of a parental generation, e.g. those which determine the height of the maize plant, are not present in a certain region or cannot be read, this will affect the height of the offspring as well. Through crossbreeding with a plant that contains the necessary factor, the defect can be compensated in the next generation.
