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Aphids. You might stumble across them in your backyard, snacking on your veggie patch, in fields and orchards where crops are grown and even along roadsides.

But this group of sap-sucking bugs are among the .

Two species, the and the , are common pest aphids in Australia, affecting a wide range of crops—including grains, horticultural crops and ornamentals like cut flowers.

Australia has very few native aphids, but these invasive species not only cause direct damage but can also transmit more than .

And it's this transmission that can lead to substantial yield losses and economic impacts.

Aphids are the main carrier (or vector) of major plant diseases like the and the . Despite their names, the viruses are not exclusive to turnips or barley and can affect a range of crops and weeds.

The direct damage from the aphid, combined with the spread of viruses, can be devastating—causing .

Harmful hitchhikers

Most people are conscious of biosecurity risks because we know new exotic species can cause so much damage if they enter Australia.

There are some recent examples of biosecurity failures, including , and fire ants that can .

But we've also had some new aphid pests enter the country and cause damage, including the and the .

However, new species of pests entering Australia shouldn't be our only biosecurity concern.

There's also the danger that new incursions of aphids already in the country can carry harmful hitchhikers.

One type of hitchhiker involves the genes that decrease the effectiveness of pesticides.

Aphids are well known for developing genetic . If new clones of aphid pests carrying resistance genes enter the country, this can make our existing pesticides ineffective.

There's also another hitchhiker found in the bacteria and other microbes carried by aphids.

These can include new strains of viruses that cause diseases in plants. Or bacteria that make aphids less susceptible to the ways we try to control them.

Sustainable control of pests

Globally, there are that have led to a around its use.

Many agricultural industries are shifting towards the use of more sustainable control methods, which include preserving and releasing .

These wasps lay their eggs inside an aphid, where the wasp larvae then feed on its internal tissues, eventually killing the host.

There are thousands of species of parasitoid wasps, and several species used on aphids are now reared commercially to control aphids.

These wasps can also act as natural protectors of crops and are becoming increasingly important biological control agents.

But the bacteria living inside aphids—called ""—could jeopardize the effectiveness of the wasps.

Targeting symbionts

Aphid symbionts live inside the organs and cells of aphids, evolving alongside them.

Some provide benefits to the host, while others act like parasites. The most common bacterium, , is found in almost all aphids and provides nutrients that aphids can't easily get.

are targeting these symbionts to help reduce the impacts of aphids and other pests on plants. Some of these approaches also aim to affect the ability of aphids to .

However, other symbionts make it harder to control aphids with natural enemies like parasitoid wasps.

One particularly problematic bacterial symbiont is , a microbe found in many aphid species that prevents the parasitoids from successfully controlling them.

In Australia, by the Pest & Environmental Adaptation Research Group (PEARG) have discovered that, fortunately, aphids like the green peach aphids and oat aphids found here lack this bacterium.

But overseas, Hamiltonella can be found in many of our major pest aphid species.

While a few bacterial symbionts do occur in Australian aphids, these don't seem to have had much impact on biological control with parasitoids and other natural enemies.

For example, in 2008 and in 2023, the symbiont was detected in green peach aphids locally, and there are instances of this bacterium providing parasitoid protection.

But, so far, it has remained rare.

Keeping Australia protected

A growing danger for Australia is new introductions of aphids harboring Hamiltonella or other harmful symbionts from overseas, given that many are so common.

As Australia increasingly switches to biological control, these introductions could represent economic risks to industry.

So, it becomes more important to check for these microbes as well as other hitchhiking risks to pesticide resistance.

At the Pest & Environmental Adaptation Research Group, under the Australia Grains Horticulture Pest Innovation Program (AGHPIP), we are developing molecular methods to identify and understand symbionts and resistance genes in some of our most significant grain and horticultural aphid pests.

We are also investigating how we can take advantage of bacterial symbionts to make pests less harmful, including modifying the bacteria they carry to reduce their ability to transmit viruses.

These kinds of controls could help to provide new directions in sustainable pest control and keep Australia protected from increasing insect threats.