Nav: Home

Why did the passenger pigeon die out?

January 11, 2018

Why do species die out? This is the overarching question being asked by many leading researchers. Knowing more about what leads to a species' becoming extinct could enable us to do something about it. The passenger pigeon is a famous example and the species has been studied extensively.

The passenger pigeon (Ectopistes migratorius) was once found in huge numbers in North America. Records tell of passing flocks that darkened the skies for several days at a time. The species may have peaked at five billion individuals. A more conservative estimate is three billion.

Within a short time, the species disappeared completely.

"Given the huge size of the population, it's simply amazing that the species disappeared so quickly," says Tom Gilbert.

Gilbert is a professor at the University of Copenhagen's Centre for GeoGenetics, but he also has a part-time position as an adjunct professor at the Norwegian University of Science and Technology (NTNU).

The human role

The history of the passenger pigeon is interesting, partly because it can tell us something about how and why species become extinct.

Native Americans also relied on passenger pigeons for food. But at least in parts of the passenger pigeons' range, people had learned to harvest the species at a sustainable level that didn't threaten to eradicate it.

It was common in some parts of North America to only eat young pigeons that were hunted at night, since this did not seem to scare away the adult birds or prevent them from re-nesting.

But starting around 1500, a more aggressive variant of humans came to the continent with the arrival of Europeans. The hunt for passenger pigeons grew and culminated in a massive hunt for the species throughout the 1800s, before the species finally collapsed and disappeared.

So were the Europeans then really the ones to blame for the collapse?

Already headed to oblivion?

In 2014, a study in published in the scientific journal PNAS strongly suggested that humans were simply the final straw in destroying a species that was already vulnerable and headed to oblivion.

The researchers asserted that despite their enormous numbers, the passenger pigeons were already in trouble. The population of the species varied greatly, similar to lemmings, but over a longer period of time.

When the Europeans arrived, the species was already in a strong decline. The population was plummeting long before Europeans arrived, and perhaps Europeans even contributed to a short-term increase in numbers.

Studies of the genetic variation of the species using an investigative method called PSMC formed the background for these assertions. And now we have to concentrate a bit.

From one to many

All of an individual's genes are called a genome. You have a genome, your mom has her own genome, your dog has one and the neighbour's cat has yet another. These can be broken down into chromosomes and genes and base pairs, but you only have a single genome.

So, all of your chromosomes and genes are found in this one genome, but at the same time this genome is unique to just you and only you. Unless, that is, you have an identical twin or are a termite or belong to another species where the individuals are largely identical clones. (In the last case, it's remarkable that you can read this.)

Here is the crux of the matter:

The PSMC method can use the information in the genes of a single individual of a species to map the history of the species.

You should therefore be able to see how the species developed over many generations, and estimate how many individuals there were at any given time, all based on a single genome.

Humans partially off the hook

Using this method, researchers found that the number of passenger pigeons was in free fall even before the arrival of the Europeans.

Although the species might not have become extinct, it would have shrunk significantly in any case, maybe to only a few hundred thousand individuals.

People were just the final factor in their demise. We may have pushed the passenger pigeons off the cliff, but the species was already on its way there.

So - according to the researchers behind the study in PNAS - it wasn't just the Europeans' fault.

It sounds almost too good to be true that you can come up with something so definitive based on information from just one or a few individuals. And in this case it is - at least if we're to believe a new study that has recently been published in the journal Science.

Ineffective for passenger pigeons

The problem is that the PSMC method can't be used on passenger pigeons. The new research in Science provides completely different results.

Leading molecular biologist Beth Shapiro is the main author of the Science article, and Tom Gilbert is one of the study's contributors.

PSMC is based on the assumption that genetic variations occur relatively evenly all along the chromosomes that constitute the genome. That is, genetic changes are equally likely to occur at the ends of a chromosome as in the middle. But this turns out not to be the case for this species.

"Passenger pigeons don't have the variation patterns that we'd expect, because of the strong selection on genes that appear to have been important throughout the species' history. So it doesn't work to use PSMC in this case," said Gilbert.

In passenger pigeons, most of the genetic diversity was found at the ends of the chromosome. The middle of the chromosome showed little variation from one generation to the next as a result of the selection on these genes.

This fact may not sound revolutionary, but it yields completely different results if you try to read the history of the species based on the genome of a single individual.

You have to take into account that variations are greatest in certain parts of the chromosome rather than evenly distributed throughout. This makes the PSMC method unusable in this context.

Used another method

The researchers behind the article in Science didn't use the PSMC method. Instead, they used mitochondrial DNA from 41 passenger pigeons as their starting point. Now we have to concentrate again.

Your DNA is not your only inheritance. Mitochondrial DNA is a distinct, separate inheritance found in certain cells called mitochondria.

Regular DNA is a combination of the inheritance from your father and mother. But mitochondrial DNA is only transmitted from your mother. Variations in mitochondrial DNA also occur due to mutations, and happen relatively consistently over time.

This is a different point of departure for understanding how a species develops over time, and the results can be quite different from those generated using the PSMC method.

In addition, the study presented in Science analysed the entire genomes from four passenger pigeons and compared them with two genomes from band-tailed pigeons (Patagioenas fasciata), one of the closest relatives of the passenger pigeon.

The final result was that the new study ended up with completely different answers about the passenger pigeons and why the species met its demise.

Genetic diversity

The new study is interesting for several reasons. It tells us about the genetic diversity of the passenger pigeon, but also supports an entirely different explanation for the species' extinction.

Scientists previously believed that the larger the population of a species is, the more genetically diverse it will be. But this theory has turned out to be wrong, as the recent passenger pigeon research has shown.

According to the article in Science, the large population size appears to have enabled passenger pigeons to adapt and evolve more quickly and thus remove harmful mutations.

In species with fewer individuals, chance can cause a less beneficial mutation to persist, but chance plays less of a role in species with greater numbers of individuals.

"Mutations that provide a major evolutionary benefit would spread rapidly," says Gilbert.

The fact that beneficial mutations became incredibly dominant so quickly simply led to the disappearance of other genetic variants.

This in turn led to the genetic diversity in the passenger pigeon being surprisingly low in relation to the number of individuals. This may have made the species more vulnerable to changes.

But that was not why the passenger pigeon died out.

Our mistake

"The passenger pigeon died out because of people," is Gilbert's short version.

The passenger pigeon wasn't in trouble prior to Europeans arrival in North America. Nothing suggests that the species was struggling in any way.

Perhaps this isn't that surprising. In the 19th century passenger pigeons were so numerous that there were contests to shoot as many of them as possible during a certain period of time. In one competition, the winner had shot 30 000 birds.

If nothing else, the story of the passenger pigeon has contributed to a greater understanding that even prolific species can become extinct.

Something to learn

The large grasshopper Melanoplus spretus from the western United States suffered the same fate. It went from a population of several trillion to zero in a few decades, possibly because farmers destroyed its breeding grounds. In Norway and across the whole of the North Atlantic, the great auk (Pinguinus impennis) died out after people harvested them in large numbers.

People ate passenger pigeons in huge amounts, but they were also killed because they were perceived as a threat to agriculture. As Europeans migrated across North America, they thinned out and eliminated the large forests that the pigeons depended on. The pigeons lived primarily on acorns.

As the species was already dying out, 250,000 birds - the last big flock - were shot on a single day in 1896. That same year, the last passenger pigeon was observed in Louisiana. It was also shot.

The pigeons were probably dependent on a large flock size to reproduce. Their instincts didn't work when only a few individuals remained here and there.

The last passenger pigeon died in the Cincinnati Zoo in 1914.

Norwegian University of Science and Technology

Related Dna Articles:

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.
Self-healing DNA nanostructures
DNA assembled into nanostructures such as tubes and origami-inspired shapes could someday find applications ranging from DNA computers to nanomedicine.
DNA design that anyone can do
Researchers at MIT and Arizona State University have designed a computer program that allows users to translate any free-form drawing into a two-dimensional, nanoscale structure made of DNA.
DNA find
A Queensland University of Technology-led collaboration with University of Adelaide reveals that Australia's pint-sized banded hare-wallaby is the closest living relative of the giant short-faced kangaroos which roamed the continent for millions of years, but died out about 40,000 years ago.
DNA structure impacts rate and accuracy of DNA synthesis
DNA sequences with the potential to form unusual conformations, which are frequently associated with cancer and neurological diseases, can in fact slow down or speed up the DNA synthesis process and cause more or fewer sequencing errors.
Changes in mitochondrial DNA control how nuclear DNA mutations are expressed in cardiomyopathy
Differences in the DNA within the mitochondria, the energy-producing structures within cells, can determine the severity and progression of heart disease caused by a nuclear DNA mutation.
Switching DNA and RNA on and off
DNA and RNA are naturally polarised molecules. Scientists believe that these molecules have an in-built polarity that can be reoriented or reversed fully or in part under an electric field.
New DNA synthesis technique promises rapid, high-fidelity DNA printing
Today, DNA is synthesized as an organic chemist would, using toxic chemicals and error-prone steps that limit accuracy and thus length to about 200 base pairs.
The changing shape of DNA
The shape of DNA can be changed with a range of triggers including copper and oxygen - according to new research from the University of East Anglia.
More Dna News and Dna Current Events

Best Science Podcasts 2019

We have hand picked the best science podcasts for 2019. Sit back and enjoy new science podcasts updated daily from your favorite science news services and scientists.
Now Playing: TED Radio Hour

Rethinking Anger
Anger is universal and complex: it can be quiet, festering, justified, vengeful, and destructive. This hour, TED speakers explore the many sides of anger, why we need it, and who's allowed to feel it. Guests include psychologists Ryan Martin and Russell Kolts, writer Soraya Chemaly, former talk radio host Lisa Fritsch, and business professor Dan Moshavi.
Now Playing: Science for the People

#538 Nobels and Astrophysics
This week we start with this year's physics Nobel Prize awarded to Jim Peebles, Michel Mayor, and Didier Queloz and finish with a discussion of the Nobel Prizes as a way to award and highlight important science. Are they still relevant? When science breakthroughs are built on the backs of hundreds -- and sometimes thousands -- of people's hard work, how do you pick just three to highlight? Join host Rachelle Saunders and astrophysicist, author, and science communicator Ethan Siegel for their chat about astrophysics and Nobel Prizes.