Researchers at the University of Cambridge have demonstrated that the plant hormone gibberellin (GA) is essential for the formation and maturation of nitrogen-fixing root nodules in legumes and can also increase nodule size.
Cereal crops like wheat, maize and rice are nitrogen-hungry crops and depend heavily on synthetic fertilizers to meet their nitrogen needs. However, synthetic nitrogen fertilizers require an enormous amount of energy to manufacture, are expensive for farmers and cause negative environmental impacts like water pollution.
Unlike cereals, legumes, like peas, beans and pulses, can obtain their own nitrogen through a natural symbiotic relationship with nitrogen-fixing bacteria, forming lateral root-derived organs called nodules. This nitrogen-fixing ability also leads to higher protein content in legume crops, making them more nutritious for human consumption.
However, legume crops stop producing root nodules when the soil has relatively high concentrations of nitrogen and, as a result, potentially miss out on producing higher yields.
Scientists around the world are working on how to both boost legume yields and transfer nitrogen-fixing abilities from legumes to cereals, but this involves unraveling and understanding the complex genetic and biochemical pathways involved in nodule formation and nitrogen fixation.
In research published in The Plant Cell, Dr. Alexander Jones' research group at the Sainsbury Laboratory Cambridge University (SLCU) and Professor Giles Oldroyd's group at the Crop Science Centre have made a major step towards this goal by revealing the GA dynamics that govern the development, morphology and function of nitrogen-fixing root nodules.
Dr. Jones said, "There were some confusing and conflicting reports about the function of GA in nodule symbiosis. Experiments showed that adding GA reduces nodulation and removing GA increases nodulation in legumes like Medicago truncatula, which suggests GA is antagonistic towards nodulation. But there is also a legume mutant in peas that produces less GA and has fewer nodules, which suggests that GA is somehow required for nodulation."
"These conflicting results suggest there is probably something going on with spatial-temporal GA patterning. For example, there may be specific places where GA needs to be and some places where it needs to be absent. Or that the precise concentration of GA is important."
Using the highly sensitive next-generation biosensor nlsGIBBERELLIN PERCEPTION SENSOR 2 (GPS2) developed by the Jones Group, Dr. Colleen Drapek was able to visualize exactly where and when GA was present and in what relative concentrations it occurred. She found GA accumulated in the nodule primordium (the zone in the root cortex where cells start dividing in the early stages of nodule formation) in Medicago infected with rhizobium bacteria.
Dr. Drapek said, "Right at the beginning of nodule formation you start to see an accumulation of GA in the nodule primordia, but very little GA anywhere else in the root. As the root nodule further develops, you see GA accumulating at quite high concentrations and remaining at high levels in the mature nodule."
Dr. Drapek used GA and symbiotic Medicago mutants to further test what GA was doing by targeting overexpression of enzymes that break GA down or synthesize GA. The result for the former was that no nodules formed and the latter had larger nodules. She adds, "This shows GA is very important for nodules, but that its function is specific to zones where the nodule is being initiated and not surrounding areas. We know that low GA is good for the initial rhizobium infection of the roots, but then later you need GA to be present for the nodulation process to proceed and for nodules to mature."
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