The end of the reproductive period, when flowers and fruits are produced, is a crucial moment in plants’ life cycles. However, the factors that control this process must be better understood.
A research team led by the Research Institute for Plant Molecular and Cellular Biology (IBMCP), a joint center of the Consejo Superior de Investigaciones Científicas (Spanish National Research Council; CSIC) and the Universitat Politècnica de València (UPV), has found that a gene called FUL controls the duration of the reproductive phase in crops such as peas. This gene could be used as a biotechnological tool to prolong this phase, thus increasing the production of fruits and seeds in peas and other legumes such as chickpeas, lentils, or beans.
The work has been published in the Proceedings of the National Academy of Sciences (PNAS).
Genetic factors
Annual plants have only one reproductive season, producing flowers and fruits. Scientists are looking for genetic factors that cause plants to stop flowering to control the length of their reproductive phase. A few years ago, the group led by Cristina Ferrándiz, a CSIC research professor at the IBMCP, identified a gene called FUL (FRUITFULL) as an important regulator of the flowering stops.
“The first studies were conducted only in Arabidopsis, a laboratory plant of no agronomic interest,” Ferrándiz recalls. “We wanted to know if this function of FUL was the same in other species, especially crop species, and if we could use this knowledge to generate plants that produce flowers and fruits for longer, and therefore have a higher yield,” she summarizes. To this end, the team led by CSIC researcher Francisco Madueño at the IBMCP, and including French and Canadian scientists, studied the role of the FUL gene in pea plants, a legume with high nutritional value.
“We have seen that mutations that lead to a loss of function of the FUL genes in peas cause the plants to produce flowers, and consequently fruits, for much longer. This tells us that FUL controls the duration of the reproductive phase not only in the laboratory plant Arabidopsis but also in other species, including crop plants,” explains Ferrándiz.
“The prolonged flower and fruit production means that in certain pea varieties, mutations in the FUL genes can double the seed production, with identical nutritional characteristics to non-mutant plants, both in the greenhouse and the field,” she says.
Mutants generated by classical methods
The research’s authors emphasize that to obtain the mutations in the FUL genes analyzed, they used mutant banks obtained by classical methods without generating transgenic plants.
As a result, “the method for obtaining new plant varieties can be based on traditional mutagenesis, as used today and in this study, or on gene editing using CRISPR, the most promising and powerful tool for precision agriculture in the near future,” says Madueño.
“The potential application of these results is to use the FRUITFULL genes as a biotechnological tool to improve the yield of leguminous crops. The most significant increase in seed yield has been observed in medium-yielding pea varieties. In contrast, in high-yielding varieties, which already have a very high yield, the effect of mutations in the FUL genes is small,” says Ferrándiz.
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