Herbivorous insects are estimated to be responsible for destroying one-fifth of the world's total crop production annually, but a new, natural approach to pesticides that turns insects' taste and smell preferences against them could help reduce this toll.
‘Taste-based feeding traps using natural products could be an eco-friendly, cost-efficient and sustainable alternative to synthetic insecticides in the future,’ said Dr Stefan Pentzold from the Max Planck Institute for Chemical Ecology in Jena, Germany.
He and his team are looking at which taste receptors the poplar leaf beetle uses to recognise its favourite food — the leaves of poplar trees — and how this affects its feeding behaviour, as part of the EU-funded ChemoSense project. The answers could lead to novel pest management strategies in forestry and agriculture.
‘Despite their essential role in the insects' food intake, survival and reproduction, relatively little is known about taste receptors, especially in beetles,’ he said. ‘This is surprising given their importance as agricultural and forestry pests, their global distribution and huge species numbers as herbivorous insects.’
Insects, like all animals, have preferences for what food they like and can distinguish one taste from another. But how do they decide whether a plant is tasty or not?
‘This is quite complex and often depends on the plant’s chemical composition and whether an insect is a generalist — an insect feeding on many different plant species — or a specialist, who feeds on very few plant species,’ said Dr Pentzold.
For example, although poplar leaves actual deter many generalist insects because of their toxic and bitter-tasting substances, the specialist poplar leaf beetle finds these substances tasty and ingests them for self-defense against predators, says Dr Penztold.
‘Taste-based feeding traps using natural products could be an eco-friendly, cost-efficient and sustainable alternative to synthetic insecticides’
Dr Stefan Pentzold, Max Planck Institute for Chemical Ecology, Germany
Insects use their hair-covered legs, mouthparts and antennae to taste their food before eating. Through these taste hairs, insects can sense their preferred plants’ chemical make-up.
‘Tastant substances (any substance which stimulates the sense of taste) in the leaf can diffuse into the taste hairs through a pore and reach the taste receptors inside the insect,’ explained Dr Pentzold. ‘If the substance is recognised, a signal is transmitted to the insect’s brain where the final check takes place that tells the mouthpart’s muscles “eat me” or “don’t eat me”.’
However, some insects have taste buds in odd places, making this process even more complex. ‘We found that the poplar leaf beetle’s taste receptors are not only present in external organs but also in internal organs and tissues, such as the gut and haemolymph (the insect equivalent of blood),’ said Dr Pentzold. ‘It’ll be fascinating if these are acting as nutrient sensors, telling the insect “I’m hungry” or “I’m full”.’
In addition to taste, insects rely on smell to find food and mates, and avoid predators or even plants. One such plant is the medicinal desert plant Achillea fragrantissima, commonly known as lavender cotton.
Dr Osnat Malka, chief scientist of Israeli agritech company EdenShield, said:‘Many insects don’t like this desert plant, which has a very strong smell and natural toxic substances, and choose to go to other plants instead.’
EdenShield is developing a green alternative to pesticides based on extracts of the native plant found in the Judaean Desert. The hope is, this natural insect repellent helps farmers protect their crops against pests in greenhouses without damaging the environment or human health.
‘Whiteflies and thrips are the most common pests in agriculture and greenhouses,’ explained Dr Malka. ‘They are very small so they can easily go inside greenhouses and, as generalists, they can feed on different kind of plants.’
The product called GateKeeper, funded by the EU's specialised scheme for small, highly innovative firms, is a spray made with natural plant extracts that is used at the entrance of greenhouses to keep these pests out and away from the crops. Although some still do enter, their numbers are reduced significantly.
‘The insects prefer not to go inside these greenhouses, mainly because they don’t like the smell and prefer other alternatives. In our experiments, when these insects are given a choice, they prefer to go to greenhouses without this plant compound,’ explained Dr Malka.
She believes that these products could be a new class of ecological substances for insect pest control. ‘I think we need to change our attitude and see how nature handles these insects — so why they are choosing one plant and not another plant — and use this for our benefit,’ said Dr Malka.
If you liked this article, please consider sharing it on social media.
Lithium-sulphur batteries, which are lighter and cheaper than today’s models, may be the next generation of power cells that we use in electric cars or mobile phones – if scientists can get them to last for longer.
The world’s poorest – who have lost their incomes from illness or because of lockdowns – are disproportionately impacted by the coronavirus pandemic and, unless they receive enough support, hunger levels will soar and some countries may see rising violence, experts say.
We are seeing a failure of global health governance in response to Covid-19 because there are too many agencies with different interests, according Professor Colin McInnes, pro-vice chancellor at Aberystwyth University in Wales, UK, who says global institutions such as the World Health Organization and World Bank should stand together in crises.
The iridescence of marble berries and the clever, light-bending perforations of microalgae are some lessons from nature that scientists are drawing upon to create biodegradable glitter and makeup pigments, and bionic algae to use in lasers or to clean pollutants.
The next-generation batteries could pack 5 times more energy, but there are problems.
Prof. Colin McInnes says international organisations are failing to stand together.
Metagenomics can help us spot emerging diseases such as coronavirus, says virologist Marion Koopmans.