Twelve birds lie belly-up in a wooden drawer at the Berkeley Museum of Vertebrate Zoology. Bloated with stuffing, their ruddy brown chests resemble a row of sweet potatoes. Slate-blue heads and thin white tails protrude in perfect alignment, except for one bird that cranes its neck to face its neighbor. A pea-sized bulge of white cotton sits where its eye should be. A slip of paper tied to its foot reads, “Ectopistes migratorius. Manitoba. 1884.” This is the passenger pigeon, once the most abundant bird in North America. When Europeans first landed on the continent, they encountered billions of the birds. By 1914 they were extinct.

That may be about to change. Today scientists are meeting in Washington, D.C. to discuss a plan to bring the passenger pigeon back from extinction. The technical challenges are immense, and the ethical questions are slippery. But as genetic technology races ahead, a scenario that’s hard to imagine is becoming harder to dismiss out of hand.

About 1,500 passenger pigeons inhabit museum collections. They are all that’s left of a species once perceived as a limitless resource. The birds were shipped in boxcars by the tons, sold as meat for 31 cents per dozen, and plucked for mattress feathers. But in a mere 25 years, the population shrank from billions to thousands as commercial hunters decimated nesting flocks. Martha, the last living bird, took her place under museum glass in 1914.

Ben Novak doesn’t believe the story should end there. The 26-year-old genetics student is convinced that new technology can bring the passenger pigeon back to life. “This whole idea that extinction is forever is just nonsense,” he says. Novak spent the last five years working to decipher the bird’s genes, and now he has put his graduate studies on hold to pursue a goal he’d once described in a junior high school fair presentation: de-extinction.

Novak is not alone in his mission. An organization called Revive and Restore is enlisting the support of preeminent scientists—and even the National Geographic Society, which is hosting the TEDx meeting on the topic today, to investigate putting the passenger pigeon back in the sky. The group has chosen Novak to spearhead the project.

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When the bird from the Berkeley drawer flew over Manitoba in 1884, it didn’t travel alone. Passenger pigeons were named for their passage up and down eastern North America in flocks several hundred million strong. To sustain long, strenuous flights, the birds devoured forests and left destruction in their wake. Ornithologist J.M. Wheaton described one flock as a rolling cylinder filled with leaves and grass. “The noise was deafening and the sight confusing to the mind,” he wrote in 1882. It was easy to tell where the pigeons had roosted: The trees were crippled, their branches cracked off and picked clean of nuts and acorns. For miles, the ground was coated with a layer of feces more than an inch thick.

But the same flocking behavior also led to the bird’s demise. Their nesting sites in the northeastern U.S. were densely packed—as many as 100 nests per tree, each containing a single egg. Pigeon hatchlings were a smorgasbord for predators. Each helpless lump of fat, as heavy as its parents but lacking their aerial skill, would wallow in the nest for a day, then flutter to the ground.

Even before Europeans arrived, hunters shot nests with arrows or knocked them down with poles. But in the mid 19th century, the railroad and the telegraph turned the pigeon into a national commodity. Professional trackers followed the flocks and descended on nest sites. Their tactics were brutal and effective: Firing into the trees brought down thousands of birds in one afternoon. Setting a match to the combustible birch bark forced terrified chicks to fling themselves from their nests. By the late 1850s, flocks were shrinking. By 1889, the population was in the thousands.

Novak remembers learning about the pigeon in school. “I just fell in love with the story of it,” he said. “This absolutely bigger-than-life story of the most abundant bird on the planet going extinct so quickly.” But he wasn’t convinced that animals like the passenger pigeon were gone forever. “I thought that was too absolute.”

As a student at Montana State University Novak studied ecology and evolution with the hope of bringing back extinct animals, but his focus soon shifted toward more modest population studies. “You’re kind of steered away from the science fiction when you go to school,” he says. When he started graduate school at the Ancient DNA Center of McMaster University in Ontario, Novak hoped to analyze genes from the bird that had captivated him as a kid. All he needed were samples from a museum specimen.

The great leap backward ———————–

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The Manitoban pigeon lying in its drawer at Berkeley holds a vast library in its feet. Every cell in its fleshy toe pads contains the 1.5 billion base pairs of DNA that spell out the bird’s identity, from the color of its eggs to the sound of its voice. But this DNA has seen better days. It has been broken apart by enzymes and oxygen, zapped with ultraviolet radiation and contaminated by other organisms. “Whenever you touch it, your DNA gets in the sample,” said evolutionary biologist Beth Shapiro of the University of California, Santa Cruz. “If it sits next to other birds, their DNA gets in the sample.”

But in the last decade, a set of techniques known as next-generation sequencing has offered a better way to work with less-than-perfect DNA. New machines can analyze hundreds of thousands of short fragments at the same time, speeding up the tedious sequencing process and bringing down its cost. “In the past 10 years, sequencing has gotten approximately 500,000 times more efficient,” said biostatistician Steven Salzberg of Johns Hopkins University. “Nothing in the history of civilization or technology has ever gotten that much more efficient that fast.”

Using next-generation sequencing, scientists identified the passenger pigeon’s closest living relative: Patagioenas fasciata, the ubiquitous band-tailed pigeon of the American west. This was an important step. The short, mangled DNA fragments from the museums’ passenger pigeons don’t overlap enough for a computer to reassemble them, but the modern band-tailed pigeon genome could serve as a scaffold. Mapping passenger pigeon fragments onto the band-tailed sequence would suggest their original order.

Eager to crack the pigeon’s genome, Novak sent requests to 30 different museums for a toe fragment, and was rejected by all of them. He resigned himself to a thesis focusing on the mastodon, but he continued his pigeon research on the side. In 2011, Chicago’s Field Museum of Natural History offered him a sample. He sent the pigeon DNA to a Toronto lab for sequencing, using $2,500 he borrowed from a friend.

Meanwhile, others were taking note of the revolution in biotechnology, including writer and activist Stewart Brand, best known for the Whole Earth Catalog, the late-1960s counter-culture guidebook. More recently Brand founded the Long Now Foundation, a nonprofit that aims to “provide a counterpoint to today's accelerating culture and help make long-term thinking more common.” Brand saw reversing extinction as a conservation method of the future. He and his wife, Ryan Phelan, founder of the consumer genomics company DNA Direct, created a branch of the Long Now Foundation called Revive and Restore. They chose the iconic passenger pigeon as the first experiment.

Revive and Restore hosted a meeting at Harvard University in February of 2012. Attendees included experts like Beth Shapiro, biologist David Blockstein with the National Council for Science and the Environment, and renowned Harvard molecular geneticistGeorge Church. Shapiro was skeptical of the project’s goal from the start, but she decided to add her expertise—and her concerns—to the conversation.

When Novak heard about the meeting, he contacted Church, Phelan and Brand to see if he could contribute. Recognizing his passion, Brand and Phelan invited Novak to help coordinate the project, and he abandoned his graduate program to begin formulating a step-by-step vision of de-extinction. His official title, according to the organization’s website, was “passenger pigeon reviver.”

When Novak describes his revival scenario, his eyes shine with enthusiasm, but his tone is that of a matter-of-fact classroom lecture. With a wry smile, he presents de-extinction as if the futuristic science were already the stuff of textbooks.

Here is Novak’s plan in broad strokes: Sequence the band-tailed and passenger pigeon genomes and find the significant differences between them. Edit the DNA from a band-tailed pigeon germ cell – the type that develops into sperm or eggs – to match that of the passenger pigeon. Implant this cell into the egg of another pigeon, perhaps a rock pigeon, which is easy to work with in the lab. Hope that the germ cell will migrate into the gonads of the developing chick. Allow the chick to grow up, and breed two such birds to create a passenger pigeon.

Sequencing the two genomes is within reach. In March 2013, Novak joined Shapiro in her lab at UC Santa Cruz; he hopes to finish both genomes in about a year. But after that, the going could get rough. Because the last common ancestor of the two species flew about 30 million years ago, their genomes will likely differ at millions of locations, Shapiro says. Scientists will have to figure out which variations correspond to meaningful physical differences. “It’s not impossible,” she said. “It’s just a long time’s worth of work.” Even in humans, mapping traits to genes is a murky discipline.

According to Steven Salzberg, that’s not even the biggest barrier. Modifying the genome of one species to match another would be an unprecedented feat of engineering. The most promising method comes from Church’s lab, where scientists have developed a technology called Multiplex Automated Genome Engineering that can make fine-scale alterations to bacterial genomes. Novak hopes Church can make similar modifications at crucial points along the band-tailed pigeon chromosome. But Salzberg cautions that animal genomes are much more complicated than bacterial ones. At the same time, he’s not ready to write off this phase of the project just yet: “If I had to bet, I’d say someday we’ll figure it out.”

Getting from a strand of passenger pigeon DNA to a living bird is the last big step, Novak says. He will need specialized germ cells, which scientists know how to extract from chicken embryos, but not pigeons. He is investigating a work-around: extracting stem cells form band-tailed pigeons instead, and stimulating them to become germ cells. This feat has never been achieved in birds. However, Novak says, “Someone could make a major breakthrough in next two years.”

A final nesting place ———————

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Surmounting such technical challenges is only phase one of Revive and Restore’s plan. Novak hopes to set up a sanctuary of lab-generated pigeon chicks in the bird’s original breeding territory. He would then train homing pigeons to pass over the nest site, showing the chicks their ancestral migration route. Novak says passenger pigeons would restore balance to forest ecosystems, clearing brush and fertilizing soil.

This strategy doesn’t make sense to Blockstein, who says “quote-unquote” before every mention of de-extinction. He doubts that any small population could survive long enough to reach its original numbers. If it did, he fears the bird would become a pest to farmers, consuming commercial berries and grain. Stanford University bioethicist Hank Greely shares this concern. “You’re re-introducing to the same geographic region,” he said. “But not to the same environment.”

No governing body exists to make decisions about re-introducing an extinct species. Once the science is within reach, Novak says he will work with wildlife management authorities to set up a legal framework.

Beyond the ecological risks, Revive and Restore has a bigger “why” question to answer. The argument that extinction is forever underlies important protections like the Endangered Species Act, Greely says. Why try to rewrite the passenger pigeon’s iconic cautionary tale?

One possible answer: to do it responsibly before someone does it recklessly. The genomic tools of de-extinction may soon be cheap enough for students and DIY types to try on their own, Brand told an audience at the 2012 Aspen Environmental Forum. “I would like to see some kind of framework of how we think about that, before it goes totally amateur.” If an organized effort like Revive and Restore tackles a high-profile and tightly controlled project, it might bring scientists and the public into an important conversation, he argued.

Shapiro, who is no de-extinctionist, sees value in an ambitious goal that unifies scientific disciplines. As Novak strategizes decades into the future, Shapiro still plans to focus on the more down-to-earth population genetics work that has been the focus of her lab. Revive and Restore will pay Novak’s salary while he works with Shapiro, but the project is not supporting her research financially. “I’m thrilled to be along for the ride,” she said. “I will do what I can to bring some enthusiasm and hopefully also some sanity to the problem.”

In Novak’s mind, reviving the pigeon is not just about turning back the clock, but also demonstrating the exhilarating pace of science. “It’s actually going to get people more interested in the idea of conservation, because of how cool it is,” Novak said. Greely doesn’t dismiss this argument. He believes “a sense of wonder” is one of the most compelling cases for de-extinction.

If Novak can convince the public and potential funding sources of that value, the passenger pigeon might do more than ride a wave of new technology; it might propel science forward. Whether or not we ever see another living passenger pigeon, its genetic code remains alive. The birds in their dark museum drawers may be more powerful now than when they swarmed by the billions.