Trees can suck up pollutants to turn them into useful amino acidsAugust 19th, 2008 - 1:59 pm ICT by ANI
Washington, August 19 (ANI): Researchers at Purdue University in West Lafayette, Indiana, US, have shown that trees can suck up organic nitrogen compounds produced from pollutants and turn them into useful amino acids.
Plants are already known to use their leaves to absorb inorganic airborne nitrogen molecules, such as ammonia or nitrogen dioxide, and turn them into amino acids.
A relatively reactive compound called peroxyacetyl nitrate can be absorbed by leaves, although it’’s not clear whether plants actually use it.
“There’’s a difference between (nitrogen species) going into the leaves and that process being useful,” said Paul Shepson from Purdue University.
The organic nitrates in question are created from the plant’’s own chemicals.
Many trees emit reactive molecules known as volatile organic compounds (VOCs), the most common of which is called isoprene.
These VOCs are so reactive that they quickly get consumed in the atmosphere, and some react with nitrogen oxides (NOx) - emitted from combustion engines - to form longer-lived organic nitrate compounds, more stable than peroxyacetyl nitrate.
Shepson’’s team studied how seedlings of the trembling aspen, a widespread North American native and an isoprene emitter, reacted to an analogue of these compounds called 1-nitroxy-3-methyl butane.
This compound had been radiolabelled with a specific stable nitrogen isotope - nitrogen-15 - which makes up less than half a per cent of Earth’’s nitrogen.
The team then mushed up the leaves and measured how much nitrogen-15 was in them.
The researchers tracked two amino acids: glutamate, the first amino acid the tree makes from absorbed nitrogen compounds, and aspartate, which is formed further downstream in the biochemical process.
In test leaves, both amino acids contained low but significant levels of the nitrogen isotope, whereas those in control leaves contained almost none.
The team also measured how fast the labelled organic nitrate was taken up, and found that it was absorbed at up to half the rate of NO2, and one tenth the rate of peroxyacetyl nitrates.
According to Shepson, he was surprised to find any nitrogen-15 in the leaves at all.
Organic nitrates are relatively unreactive, so the leaves must have a specific biochemical pathway for breaking them down. The team estimates that these organic nitrates may contribute about 1% of the total nitrogen used by trees.
Knowing that the forest canopy can take up and use organic nitrogen has potential implications for polluted areas where NOx is reacting with the VOCs from plants.
“If plants really can use the by-product - organic nitrates - then this will ultimately help to remove NOx from the atmosphere,” said Bill Collins from the UK’’s Meteorological Office. “The process would be an efficient way to transport nitrogen away from polluted areas,” he added. (ANI)
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Tags: nitrogen compounds, nitrogen dioxide, nitrogen molecules, nitrogen oxides, nitrogen species, organic nitrates, organic nitrogen, reactive molecules, volatile organic compounds, west lafayette indiana