by Ashley Hay
The white ibis began its move to the big smoke in the 1970s when large parts of its natural habitat, inland wetlands, became degraded or drought affected. ‘The species is a wetland forager,’ says wildlife officer John Martin, from the Royal Botanic Gardens. ‘Now it forages in inland parks and landfill.’
During the peak of their spring breeding season, more than 9000 of the birds call Sydney home.
Specimens at the Australian Museum show the city’s bird life has changed dramatically over two centuries. Prior to urban development the native shrubs and bushland were populated by large numbers of small insect-eating birds such as the superb fairy-wren and the eastern yellow robin. Today, homeowners prefer to landscape their backyards with tall trees and manicured lawns, an environment that provides little protection for small avian species.
But one bird’s trash is another’s treasure. Yards filled with flowering plants and fruit trees encourage omnivorous birds such as currawongs, bowerbirds and the city’s most despised resident – the noisy miner. ‘They’re a real winner in cities,’ Australian Museum ornithologist Richard Major says. ‘The predominant driver in the decline of small birds is that we’ve made a suitable environment for native noisy miners. They’re so aggressive they push out smaller birds.’
But their disappearance has thrown a lifeline to the many insects that would have ended up as small bird tucker.
Hochuli says many invertebrates such as the golden orb weaver spider and the blue triangle butterfly relish living in the city. The golden orb spiders in Sydney are fatter and more fit, he says. ‘We’re trying to tease out whether it’s more food or the urban heat island effect, as it’s up to 4° Celsius warmer in the city.’
Hochuli has also found some varieties of ant more at home in the city. The green ant, known for its painful bite, will build a nest where there is space and food, regardless of whether it’s your backyard or a sports oval. ‘It’s remarkable how many things persist in urban environments,’ he says.
But the decline in birds that eat small insects means these populations grow unchecked, allowing them to chomp their way through the foliage of the city’s trees.
‘Throughout the city we see these shifts in interactions between species as some jobs are lost,’ he says. And some shifts will be irreversible.
‘We still have functioning ecosystems, they’re just different from what they were 200 years ago,’ Hochuli says.
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While insects can survive in areas no bigger than a nature strip, mammals have been confined to patches of bushland scattered around Sydney and the national parks. But in the northern beaches, the rabbit-sized, long-nosed bandicoot has discovered the advantages of venturing out of Sydney Harbour National Park and into backyards.
‘They forage for invertebrates in the grass and like the surrounding shrubs to nest and escape from predators,’ says Catherine Price, a research associate with the University of Sydney. Price is trying to understand what encourages the small mammal into urban environments. ‘We don’t know if it’s an overflow from the park, or if they’ve got particular behavioural traits that allow them to evade dogs and cats, and use the urban habitat that benefits them,’ she says.
Despite the remarkable ability of some species to fit comfortably into Sydney’s sprawling landscape, Martin says the city’s wildlife is far less diverse than it used to be. ‘We are talking about a handful of species that have thrived, many more have lost out,’ he says.
It’s not just native wildlife that has sought comfort in city living; invasive species such as black rats, cockroaches and foxes have developed survival strategies too. But the pests that have gained the most advantage are the weeds.
‘In residential Sydney there would not be a single area of remnant bushland not infested by introduced plants,’ says Michelle Leishman, a Macquarie University plant biologist.
Over 20 years Leishman and her colleagues have shown how the city’s vast stretches of impermeable concrete coupled with the stormwater system have helped weeds such as lantana and the small- and large-leafed privet infiltrate pockets of bushland.
As rains wash over backyards and roadways they collect chemicals such as nitrogen and phosphorus which enter the stormwater system where they are piped to the edges of bushland. The nutrient-rich water seeps into the soil and creates the perfect environment for the many exotic species that ‘live fast, and die young,’ Leishman says.
Native plants prefer low-fertility soil and struggle to cope with the nutrients.
But development has encroached beyond land. The erection of piers, wharves and sea walls in and around Sydney Harbour, the country’s largest urbanised estuary, has provided perfect conditions for invasive marine species, according to Emma Johnston from the Sydney Institute of Marine Science at UNSW. Artificial structures that block sunlight and are positioned vertically favour weedy species transported into the harbour by ships, she says.
Laboratory experiments have also shown that some invasive species, such as lace coral, have huge potential to evolve tolerance to pollutants in the ocean better than native varieties.
Over two to three generations many invertebrates will increase their tolerance to contaminants by five to ten times, Johnston says. ‘Rapid evolution is not uncommon, especially to contaminants.’
Johnston has noticed a similar trend in the offspring of native barnacles. Offspring whose parents were collected from Port Kembla or Port Botany showed a greater tolerance to copper than the young of Clyde River barnacles. ‘But we need multiple generations to express the same traits to show there has been rapid evolution,’ she says.
When Charles Darwin wrote On the Origin of Species, he thought evolution would be a process that occurred over tens of thousands of years, says Angela Moles. ‘Now there are lots of examples of proven evolution happening within ten generations.’
Moles’ student, Joanna Buswell, has shown that 70 per cent of introduced terrestrial plant species in New South Wales have changed their morphology, altering their leaf or stem size to become more suited to Australian conditions.
Now Moles is trying to determine whether these changes are underpinned by genetic mutations that would suggest they were becoming new species. ‘I absolutely think that’s where they’re going to go,’ she says. ‘Whether they are there yet, we don’t know.’
A short walk in the Australian bush
Planet of the vines
Planet of the vines
William Laurance
Gaze out over a tropical rainforest and the scene looks idyllic – a kaleidoscope of trees festooned with colourful vines, orchids, ferns and lichens. Don’t be fooled. Myriad ecological battles are being fought beneath this tranquil surface. And none is more embittered than that between trees and their ancient enemies, the vines.
Biologists like myself who study these jungle ecosystems are now seeing a shift in this war. Until a decade or so ago the two adversaries were evenly matched, but vines now seem to be on the march. If that continues, the face of our forests – and of our planet – could be changed irrevocably. We are left scrabbling to unearth the root cause.
If the forest were a financial system, trees would be its old money. Deeply rooted, they grow slowly, investing heavily over time in woody trunks and branches to support their leaves, and providing homes for a zoo of other species. Vines, on the other hand, would be the flashy junk-bond traders. Representing up to half of the plant species in a typical rainforest and producing up to 40 per cent of all leaves, they are down-and-dirty competitors. They invest almost nothing in supportive tissue, instead taking advantage of the trees’ investments to scramble up to the top of the forest and produce great flushes of leaves that bask brazenly in the full sun.
Francis Putz, a biologist at the University of Florida in Gainesville, highlighted this fraught relationship in a 1980 paper entitled ‘Lianas vs trees’. Lianas, or woody vines, can grow to be hundreds of metres long, with stems over half a metre across. Trees pay a high price
for their presence. Lianas can strangle and deform a tree’s branches, their dense foliage robs trees of life-giving sunlight, and their roots scarf up vital nutrients and water. Trees bearing lianas usually grow more slowly, reproduce less and die sooner than those without. Once lianas reach the canopy, they often climb laterally, effectively roping trees together so that, when one falls, it can drag down others. This is why loggers hate them: if they don’t cut every liana linked to a tree before felling it, another may be yanked down on top of them. ‘Loggers call them “widow-makers”,’ says Putz.
There are obvious reasons why some vines are becoming more prevalent. Humans have introduced invasive species, such as the rubber vine to northern Australia and kudzu to the southeastern US, that smother native forests, grasslands and waterways. Most vines are light-loving and increase rapidly in forests that have been fragmented by agriculture or selectively logged. Small, regenerating trees on the edge of disturbed forests provide ideal trellises for climbing quickly into the canopy. A decade ago, my colleagues and I revealed much higher liana abundances in fragmented than in intact Amazonian forests. Trees in these areas are beleaguered, dying two to three times as fast as normal.
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But vines are also proliferating in undisturbed forests. Oliver Phillips of the University of Leeds in the UK and his colleagues revealed in 2002 that lianas had increased sharply at the expense of trees at sites across western Amazonia. Something similar has been seen in nearly a dozen other intact forests in Central and South America. ‘It was controversial at first,’ says Phillips, ‘but few doubt it now.’
What’s happening? A likely cause is that tropical forests around the globe are becoming more dynamic, with trees dying and regenerating more rapidly – conditions that strongly favour vines. It is possible that global warming is intensifying windstorms that increase tree fall in the affected areas, yet there is little evidence for such an effect.
Instead, a more subtle driver seems to be at play: rapidly rising levels of atmospheric carbon dioxide. CO2 fuels photosynthesis, and the more there is, the faster plants grow. Faster growth creates more competition among plants for light, space and nutrients, which in turn drives higher rates of tree death and regeneration. Rising CO2 could also favour vines directly. Several studies over the past few years suggest that vines, with high photosynthetic rates, an abundance of energy-producing leaves and little costly supportive tissue, are primed to take advantage of rising CO2.
This isn’t to imply we know everything about the onslaught of vines. So far the trend has been spotted in undisturbed forests only in the Americas. Long-term studies are needed elsewhere to ensure this isn’t a coincidence of geography. I wonder, too, about the fate of remote forests I have studied in the Congo basin. Vines there are naturally abundant because of disturbance by forest elephants. Yet elephant populations are collapsing from overhunting. Might vine numbers in these forests actually begin to decline?
Most evidence, however, suggests Earth is heading for a viney future. This worries ecologists like Stefan Schnitzer at the University of Wisconsin-Milwaukee. ‘Vines can change forests in a lot of ways,’ he says. ‘They hit big, slow-growing trees far harder than smaller, faster-growing species, meaning they can probably change the entire composition of the forest.’
It’s not just trees that are at risk. Ainhoa Magrach, a postdoctoral colleague of mine at James Cook University in Cairns, has found that plants that live on trees, such as ferns, tend to be excluded in regions where vines are dense. These ferns are little islands of biodiversity, sustaining many animals in the rainforest canopy. A few species have mutualisms with aggressive ants that attack encroaching vines, but most are not so lucky.
The biggest worry is that proliferating vines could reduce carbon storage. Forests lock up billions of tonnes of carbon in woody tissue, and when vines kill or suppress trees some of that carbon is released into the atmosphere. Studies in Panama and Amazonia suggest rampaging vines capture just a small fraction of the carbon they cause trees to release. That could induce a positive feedback, with still more greenhouse gases and a warmer future for us all. If that goes too far, we really could be heading for a planet of the vines.
Antarctic ice: Going, going …
They’re taking over!
Is there room for organics?
James Mitchell Crow
Western Australia at harvest time is a place of smoke and fire. By day, the signs are subtle: you need to come back in the relative cool of the night to witness the flames. Some fires burn in long orange-red stripes across the vast dark fields. Others are towering pyres. Death is in the air, but nobody is mourning. The fires are killing the seeds of multi-herbicide-resistant weeds, carefully collected during harvesting. Next year’s weeds, nipped in the bud.
The WA weed fires are a recently established ritual. Twenty years ago, the farmers simply sprayed weedkiller to keep their fields weed-free, often diluting the chemical to save a few dollars. The weeds soon became immune to these chemical treatments, forcing the farmers to find new ways to control them.
Seed burning is one form of non-chemical ‘harvest weed seed control’, a grassroots movement pioneered by farmers. If anyone could be said to lead this movement, though, it’s Stephen Powles. Softly spoken, yet forthright and direct, there’s a pragmatic air to Powles that speaks to his deep farming roots. Powles grew up on a New South Wales dairy farm. Today, he is an academic expert in weeds, researching them for 30 years. Powles directs the Australian Herbicide Resistance Initiative (AHRI) at the University of Western Australia.
‘Until recently, Australia had the world’s biggest problems with herbicide-resistant weeds,’ he says. That Australia no longer tops this list is a credit to Powles and his team’s work alongside farmers. The 1990s were the most alarming time. During that decade, weeds resistant to farmers’ two main classes of chemical herbicides spread quickly across the grain belt, threatening yields. To protect their crops, Australian farmers started hunting for non-chemical means to keep the weeds down, helped by AHRI researchers. Intercepting and destroying the weeds while they are still seeds, burning or mechanically crushing them, is proving particularly effective.
The success of these chemical-free weed treatments could be considered a nod toward organic farming, although Powles is at pains to point out that these ‘organic’ approaches were developed on conventional farms, and they are still combined with careful applications of herbicides that do still work, such as glyphosate and paraquat. Australian wheat farmers are simply using every trick and tool they can come up with to keep food production high.
But are all of these tools – in particular, the synthetic herbicides, fertilisers and pesticides the farmers use – really necessary? Avoiding any use of synthetic herbicides, pesticides and fertilisers is the fundamental tenet of organic food production. Could this approach ever offer a sustainable, secure way to feed the world’s rapidly growing population?
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It’s hard to pinpoint the exact moment when the organic farming movement began. The first shoots seemed to spring up in the 1940s and early 1950s in multiple places from the US to Europe. In the UK, the Soil Association was established in 1946 over concerns that intensive, industrialised agriculture was damaging soil, the environment and the nutritional value of food. In 1967, its first organic standards were drawn up. More recently, these groups have campaigned vociferously against genetically modified crops.
The Soil Association is one of many organic advocacy groups to claim that GM crops aren’t needed to feed our growing global population. In fact, never mind GM, it says we don’t even need synthetic fertilisers, pesticides or herbicides. All it takes is organic farming, according to their recent position statement Feeding the Future: How organic farming can help feed the world. It’s an optimistic view given that certified organic agriculture is currently a niche activity accounting for less than 1 per cent of the world’s farmland. In some areas, most farming is by necessity organic.
These include Africa, where people are simply too poor to afford chemicals, and Cuba. Havana has become a poster-child for organic supply – with any available land reclaimed for organic food crops – but the story of organics in the countryside is one born of necessity. In the early 1990s, Cuba’s supply of Soviet fuel, fertilisers and pesticides was abruptly cut off. But the idea the island feeds itself purely by organic means is a myth – best guesses suggest that between 40–50 per cent of Cuba’s food is imported.
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It is early evening when I call organic farmer Raoul Adamchack at his California home to ask his views on this question. One of his children answers the phone – ‘Dad, there’s some English journalist on the phone for you’ – and we talk over the comforting background clatter and hum of a family preparing dinner.
Adamchak is a committed organic farmer. ‘I started in the mid-70s, which was a very environmentally conscious time,’ he recalls. Agent Orange was still fresh in the memory, and the battle to ban the environmentally damaging pesticide DDT was still raging. ‘The idea, for me, of applying pesticides that would affect my health, or the health of beneficial insects, or the health of my customers, seemed so alien that organic farming seemed like the way to go. And I’ve been doing it more or less ever since.’
Today, Adamchak runs the organic market garden at the University of California Davis, teaching students organic vegetable production. He speaks passionately and candidly about the challenges of organic farming. ‘It’s not easy,’ he says. ‘You lose some of your crop to pests that you just aren’t able to deal with.’
He comes across as a very pleasant man, and having been invited via phone line into his home, I find myself reluctant to challenge him on the standard organic doctrine that we should forget GM and let organic feed the world.
Talking to Powles in an earlier phone call, I’d had no such worries. I hadn’t got the feeling he was a man who would argue strongly for organic farming, despite his battles with weed killer resistance. Powles had dispatched the question with typical efficiency: ‘The serious analyses say that if we were to have widespread organic farming, we would have a 30 per cent reduction in food production.’ In 2012, for example, an analysis in the journal Nature compared 66 recent studies and reported that organic crop yields were, on average, 25 per cent less than at conventional farms. To maintain current levels of food production on an organic-only planet we’d have to expand farmland at the cost of natural habitat – hardly an ecologically sound solution.