The songbirds that are common in gardens all across the world have a surprisingly distant origin. They all evolved from a common ancestor that emerged from what is now Australia around 24m

years ago. How they managed to leave this isolated part of the world and spread all over the planet has long been a mystery to scientists. But a new study suggests they began spreading just

as the islands in and around Indonesia were being formed, creating a pathway for them to cross what had previously been thousands of kilometres of open ocean. Songbirds are a tremendously

diverse group of small perching birds, made up of over 5,000 known species distributed across the world. Common examples include the European robin (Erithacus rubecula) and the North

evolutionary spread, it remained unclear how this diverse and cosmopolitan family arose from a single ancestral species on an isolated continent. However, a recent study by researchers at

the University of Kansas and published in the journal Nature Communications sheds new light on this question. Using genetic and fossil data, the authors reconstructed the evolutionary

“family tree” for songbirds. They then linked this to information on different species’ geographic locations to understand how early songbirds spread between different continents over the

course of millions of years. This confirmed that songbirds originated in Australia just over 30m years ago. But the most eye-catching finding is that songbirds started to spread out of

Australia much more recently than previously thought. This process appears to have started approximately 24m years ago, at the same time as the formation of Wallacea, a group of islands

bridging the ocean-filled gap between Australia and Asia. So this may explain how songbirds were able to leave Australia and radiate across the rest of the world, by island-hopping their way

to Asia. SECRETS IN THE DNA To gain these novel insights, the researchers first collected DNA from many songbird species across the world. DNA molecules are the building blocks of life and

bear the imprint of our evolutionary past. Close relatives tend to have more similar DNA to each other than to distant relatives. So by comparing DNA between songbird species that are

related by different amounts, it is possible to reconstruct their evolutionary past and generate a family tree for the entire songbird group. By mapping the geographic location of living

species onto this family tree, the authors were then able to reconstruct where and when new songbird species evolved. The first songbirds originated in the landmass that would eventually

become Australia. More surprisingly, though, the first major burst of evolution within songbirds coincided with a period of tectonic collision when islands began forming in the waters north

of Australia. This provided the first land link between Australasia and the south-eastern tip of Asia (Sundaland). These novel insights have at least three interesting implications. The

first is that it resolves the longstanding question of how and when songbirds arrived in Asia. Previous attempts to date the spread of the birds from Australia pointed to a much earlier

time, when the landmass was isolated by thousands of kilometres of open ocean. We now know that the islands of Wallacea provided the first plausible corridor out of Australia, resulting in

waves of songbird expansion through Asia to the rest of the globe. This colonisation of previously uninhabited regions seems to have then triggered the evolution of many new songbird

species, as the group began to adapt to these novel environments and habitats. GAME OF CHANCE This leads to the second important conclusion: the role of chance in evolution. Paleontologist

Stephen J. Gould argued that if the tape of life were rewound and allowed to run again from the start, chances are we would see a very different set of evolutionary outcomes. Features of

songbird evolution appear to support this message. Without the chance collision of two tectonic plates millions of years ago, songbirds may have never left Australia and the world’s garden

bird feeders may now be playing host to a very different set of species than they do today. The third and perhaps most striking conclusion is that the common ancestor of all modern songbird

species is likely to have lived just over 30m years ago. In evolutionary terms, this is surprisingly recent, especially compared to the probable age of the ancestor of all birds (about 95m

years). When you consider that songbirds account for over half of all bird species on Earth (over 5,000 species), the relatively recent origins of songbirds mean they evolved into new

species at an even faster rate than previously thought. By resolving these issues, the study has also set the stage for new and important questions about evolution. Perhaps the most

intriguing question now is why a once-small group of Australian songbirds went on to become such a diverse and widespread component of life on Earth.