Ghent – 22 January 2014. Mechanisms that determine the size of plants have fascinated plant scientists of all times, however they are far from understood. An international research team led by plant scientists from VIB and Ghent University report an important breakthrough in the scientific journal The Plant Cell. They identified a protein complex that controls the transition from cell division to cell specialization. By extending the activity of the complex during leaf growth, more cells divide, giving rise to larger leaves. These insights can now be used to guide plant breeding initiatives towards higher plant productivity.
More dividing cells, larger leaves
Cell division is essential for growth and development of all multicellular organisms. In plants, leaf growth consists of two different phases. A first phase is characterized by intense cell division, which leads to the formation of many new cells. During the second phase, cell division activity declines, the cells elongate and acquire a certain expertise. In a small leaf that just initiated from the stem, almost all cells are in the active division phase. Later on, when the leaf matures, cells at the top of the leaf switch to the specialization phase. The more time cells stay in the first phase, the more cells are being formed and the bigger the ultimate leaf size will be. It was already known that the protein ANGUSTIFOLIA3 (AN3) fulfils an important role in determining the timing and activity of cell division in the leaf. However, the precise mode of action of AN3 was not yet understood.
To unravel a biological process on a molecular level, scientists typically develop plants in which genes are switched on or off. Studying the effect of these "aberrant" situations on plant growth can in some cases resolve the function of these genes. However, this approach often is like finding a needle in a haystack. Plant scientists of VIB and Ghent University therefore used various state-of-the-art techniques to study the effect of the "aberrant" molecular situation on all genes and all proteins at once. As such, the researchers could elucidate the function of AN3 in the model plant Arabidopsis.
Unpacking DNA to switch on gene activity
All cells of a particular plant contain the same genetic information, which is stored in their DNA. DNA is packed in a condensed structure, the chromatin. When certain genes need to be activated, the chromatin will be unpacked to make specific DNA regions accessible. This process is mediated by so-called "chromatin remodeling" complexes. An international team of scientists led by Dirk Inzé of VIB and Ghent University demonstrated that AN3 functions as part of a chromatin remodeling complex. More precisely, AN3 recruits the chromatin remodeling complex towards specific DNA regions that harbor cell division genes. As long as AN3 is active and keeps recruiting the chromatin remodeling complex, cells retain their division activity, resulting in plant organs with increased size. The AN3 protein complex regulates the length of the cell division phase in the leaf and hence the transition from cell division towards cell specialization. This research was performed in collaboration with the University of Pennsylvania (USA), the French "Institut de Biologie des Plantes", the Polish University of Warsaw and the Polish Academy of Sciences. The obtained insights can now be used to orchestrate plant breeding activities more efficiently, for example towards higher plant productivity.
Liesbeth Vercruyssen et al.
binds to SWI/SNF chromatin remodeling complexes to regulate transcription during Arabidopsis leaf development.
The Plant Cell online 17 januari 2014 doi: 10.1105/tpc 113.115907
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The Plant Cell