Keeping them short

Representational Image.


Modern ways of agriculture held out a promise of unlimited food to feed growing populations. The boom in produce was mainly through high yielding varieties of crops and massive input of artificial fertilisers. Of fertilisers, however, both production and the run-off, from fields, are proving an environmental hazard, which would negate the value of the food produced.

Shan Li, Yonghang Tian, Kun Wu, Yafeng Ye, Jianping Yu, Jianqing Zhang, Qian Liu, Mengyun Hu, Hui Li, Yiping Tong, Nicholas P Harberd and Xiangdong Fu, from the Chinese Academy of Sciences, Beijing, Hebei Academy of Agriculture and Forestry Sciences, Shijashuang, China and the University of Oxford, report in the journal, Nature, that there is a relationship between the genetic factors that help a food plant stay short in stature, which helps stability of the plant and its output, and how efficiently the plant assimilates nitrogen from fertiliser. Tinkering with the genetic factors then enables plants to stay short in stature, but still use fertiliser efficiently.

“The Green Revolution of the 1960s boosted crop yields, and was partly driven by widespread adoption of semi-dwarf Green Revolution varieties of cereals”, the Nature paper says. The paper explains that semidwarfism reduces the flattening of plants by wind and rain, an effect called “lodging”, which reduces the grain yield of plants. Semi-dwarfism in plants is because of the growth suppressing protein, Della.

As plants need to grow, normal plants have a factor, GA, which suppresses Della. In semidwarf and high yielding plants, Della is either resistant to GA or there is low production of GA, the paper says. In both cases, Della is able to accumulate and the plant stays short.

Keeping the height of the plant low is also helped by the plant being relatively insensitive to nitrogen. Della has the effect of reducing the plants’ growth response to nitrogen. However, “nitrogen allocation to grain continues,” the paper says.

With low nitrogen intake in hybrid plants, there is a need to increase the quantity of fertiliser use, so that supply of nitrogen for grain production is not affected. Fertiliser use, however, damages the environment. The production, both in the form of ammonium salts, which are used in anaerobic crops, like rice, or nitrites, which are used with aerobic crops, like wheat, need huge energy for production.

That is because ordinary nitrogen, which is abundant in the atmosphere, is of no use for vegetation. Ordinary nitrogen is the molecular form, which is exceedingly stable, a leader among inert substances and difficult for plants to use.

Useful nitrogen, which is found in fertilisers, is the reactive, “active” kind and it takes energy to prise the nitrogen molecule apart. This apart, most of the fertiliser that is used, is not absorbed by the plant and waste irrigation water contaminates water bodies.

“Development of new Green Revolution varieties that combine high yields with reduced nitrogen supply is thus an urgent goal for global sustainable agriculture,” authors of the paper say. They hence set out to analyse how these plants integrated the priorities —low stature, plentiful grain production and low nitrogen inputs.

A survey of different existing and cross-bred rice varieties and analyses of their genetic composition revealed that the intake of the nitrogen-rich ammonium ion, as well as growth, in response to nitrogen supply, was regulated by the protein, GRF4. GRF4 thus counteracts the growth-repressive effect of the Della protein.

Significantly, it was found that GRF4 abundance itself was dependent on low levels of nitrogen. As increasing GRF4 abundance leads to an increase in nitrogen uptake too, this creates a feedback loop — where low levels nitrogen increase GRF4 levels, which increases the nitrogen level, which then restricts the growth of GRF4, leading to a drop in nitrogen levels.

A case of “homeostatic coordination of plant nitrogen metabolism”, the paper says, “GRF4 is a nitrogen-responsive regulator promoting both ammonia ion uptake and growth in response to nitrogen supply, and counteracting the inhibitory effects of the Della protein.”

The group next examined the way that the GRF4-Della protein interaction affected the food producing mechanism —of plants fixing carbon from the air in the presence of sunlight. While GRF4 was found to promote the genes that help photosynthesis, and the Della protein restrained them, it was seen that semi-dwarf, Green Revolution varieties did have higher rates of photosynthesis.

The effect of Della to suppress growth was reversed, and more, in varieties with GFR4, while keeping the uptake of carbon and nitrogen in the same balance. And finally, it was seen that GFR4 had the effect of increasing grain yield and the efficiency of nitrogen use.

“Although long thought to exist,” the paper says, the study has shown the working of GRF4, which regulates multiple nitrogen metabolism genes, with a self-regulating, nitrogen sensitive, feedback mechanism. With an antagonistic relationship with Della, a growth repressor, there comes into being a coordinated regulation of plant growth and metabolism, the paper says.

And then, “increasing the abundance of GRF4 in Green Revolution varieties tips the GRF4-Della balance to favour GRF4, conferring increases in carbon and nitrogen assimilation, biomass, leaf and stem width, but having little effect on plant height.

The practical plant breeding consequence of this is that it enables plants to assimilate nutrients without the loss of the beneficial semidwarfism conferred by Della accumulation. Nitrogen use economy can thus be improved, without the yield penalties of increased lodging,” the paper says.

In the matter of environmental damage, the Stockholm Resilience Centre names phosphorus and nitrogen flows as planetary boundaries that have already been breached. Methods to keep grain production at the levels that we need for the growing world population, without aggravating nitrogen use in agriculture, is a priority.

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