Genetic history of endangered Australian songbird could inspire an encore

October 30, 2019

The genetic history of a critically endangered songbird shows its best chance of survival is to protect its rapidly disappearing habitat.

Researchers from The Australian National University (ANU) used DNA samples from museums around the world, dating back to the 1800s, to study the genetic impact of severe population decline on the regent honeyeater.

Their study shows that while the birds' genetic diversity remains intact, giving it a fighting chance, the best way to save the species from extinction is by protecting what little habitat it still has access to.

Dr Ross Crates and Dr George Olah from the Difficult Bird Research Group say while regent honeyeaters were common less than 60 years ago, they're now critically endangered.

"Best estimates suggest there may be as few as 250 left in the wild," Dr Crates said.

"The population has suffered a rapid decline due to the widespread loss of breeding habitat caused by land clearing, as well as competition with larger bird species for access to remaining habitat."

The birds can be found from northern Victoria to southern Queensland - an area of over 600,000km2.

Because of this massive distance, studying the birds is difficult. That's why the researchers hunted down DNA in museums.

"It's a real challenge to locate so few birds over such a huge area," Dr Crates said.

"Regent honeyeaters can travel hundreds of kilometres to find blossom nectar to feed on. We don't know where they will turn up and breed from one year to the next.

"If we are going to save this species from extinction, we need to know if there is anything we can do to help maintain genetic diversity in the remaining population."

The team compared the genetic makeup of the regent honeyeater when it was abundant and widespread, to the genetic makeup of the remaining population today.

"When populations become small and isolated, genetic diversity can be lost, reducing the survival of the remaining individuals. In some species, this can severely impact the chances of population recovery," Dr Olah said.

The team extracted DNA from tiny fragments of tissue from regent honeyeater specimens housed in museums. They also used blood samples collected by BirdLife Australia over the past 30 years.

They then sampled DNA from wild birds, and compared the patterns in the genetic data.

Despite the small numbers of birds left in the wild, the researchers found little genetic diversity has been lost over time.

"Birds in the north of the range are closely related to both their near neighbours and birds in the south of the range," Dr Crates said.

"This strongly suggests that small numbers of birds are travelling long distances to breed with each other."

The team says this is both "good news and bad news".

"The good news is the birds' long-distance movements are naturally helping to maintain genetic diversity in the population," Dr Crates said.

"The bad news is this means there's little we can actually do in terms of conservation action to help manage their genetic makeup.

"It means our best chance of saving regent honeyeaters from extinction is by protecting remaining breeding habitat, restoring as much lost breeding habitat as possible and protecting nests from predators."
The study has been published in PLOS ONE.

Australian National University

Related DNA Articles from Brightsurf:

A new twist on DNA origami
A team* of scientists from ASU and Shanghai Jiao Tong University (SJTU) led by Hao Yan, ASU's Milton Glick Professor in the School of Molecular Sciences, and director of the ASU Biodesign Institute's Center for Molecular Design and Biomimetics, has just announced the creation of a new type of meta-DNA structures that will open up the fields of optoelectronics (including information storage and encryption) as well as synthetic biology.

Solving a DNA mystery
''A watched pot never boils,'' as the saying goes, but that was not the case for UC Santa Barbara researchers watching a ''pot'' of liquids formed from DNA.

Junk DNA might be really, really useful for biocomputing
When you don't understand how things work, it's not unusual to think of them as just plain old junk.

Designing DNA from scratch: Engineering the functions of micrometer-sized DNA droplets
Scientists at Tokyo Institute of Technology (Tokyo Tech) have constructed ''DNA droplets'' comprising designed DNA nanostructures.

Does DNA in the water tell us how many fish are there?
Researchers have developed a new non-invasive method to count individual fish by measuring the concentration of environmental DNA in the water, which could be applied for quantitative monitoring of aquatic ecosystems.

Zigzag DNA
How the cell organizes DNA into tightly packed chromosomes. Nature publication by Delft University of Technology and EMBL Heidelberg.

Scientists now know what DNA's chaperone looks like
Researchers have discovered the structure of the FACT protein -- a mysterious protein central to the functioning of DNA.

DNA is like everything else: it's not what you have, but how you use it
A new paradigm for reading out genetic information in DNA is described by Dr.

A new spin on DNA
For decades, researchers have chased ways to study biological machines.

From face to DNA: New method aims to improve match between DNA sample and face database
Predicting what someone's face looks like based on a DNA sample remains a hard nut to crack for science.

Read More: DNA News and DNA Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to