Fusion or Fission?

The closer one looks at these performances of matter in living organisms, the more impressive the show becomes.

—MAX DELBRUCK,
A Physicist Looks at Biology

Rosemary sits on her backless chair with her chin in hand, staring at the Macintosh. More martial columns of numbers parade down the screen. “It’s such a lot,” she says flatly, without taking her eyes from the screen. “And we’ve got to be so terribly careful. I mean, the amount of cross-checking, and double-checking, and triple-checking, to make absolutely sure there are no errors in the data …!”

Her office is quiet. Cactus finches probe cactus flowers in the photographs on the walls. Guppies hover in an aquarium on the window-sill. They too are souvenirs of evolution in action, although no one is watching them now. They come from the famous fish tanks in John Endler’s laboratory. Rosemary’s daughter Nicola got them from some of the grad students. “She wanted them, but then I of course ended up with them,” says Rosemary.

She and Peter have been climbing their mountain of numbers day and night, here in Eno Hall, and on a Macintosh in their house on Riverside Drive, a few minutes from the Princeton campus. They work together on the same desert island in the Galápagos and in the middle of civilization. She sometimes wonders if they could have done it when they were first married. But now they know how to work with each other, and they know how to work around each other. They interlock.

THEY CAN SEE in their numbers and computer-generated charts that since the flood, the crazy Niño of 1982–83, the adaptive landscape of the islands has changed dramatically. Tribulus has gone down, down, down. It was already in trouble before the first rains of El Niño. Rosemary and Peter suspect a fungus: some kind of rust that ate at its roots. Then of course the floodwaters drowned it, and green vines overwhelmed it, and Cacabus plants sprang up as if out of nowhere—great, sticky, hairy-leaved mats of Cacabus—and smothered it. After that came the droughts.

Cactus on the island is down too. First the cactus trees took up too much water in the great flood, then too little in the droughts. The cactus trees toppled under tangles of vines and more Cacabus. By 1990 there were hardly any Tribulus or cactus seeds to be found anywhere on the island, even for finches flipping hours of pebbles with their beaks. The cactus may be just beginning to come back now.

A pattern is emerging: a shift that the Grants had not seen clearly until they did the analysis. There have been fewer big, hard seeds on Daphne since the flood. But there have been more small, soft seeds—mostly from all that Cacabus. Rosemary and Peter have put these changes into hard numbers, and the changes are significant. In fact, the changes are enormous. For Darwin’s ground finches, life is seeds. If the pile of big seeds shoots down and the pile of little seeds shoots up, that is an upheaval, a catastrophe in the adaptive landscape, the fall and rise of alps. This is just what has happened on Daphne in the years since the flood. One adaptive peak has collapsed, and another peak has gone beetling skyward.

In spite of all this selection pressure, the cactus finches have not changed in the last ten years. By all the Grants’ measures, their beaks and bodies are the same now, on average, as they were before the flood. This too makes sense in terms of the adaptive landscape, because in evolutionary terms these birds have nowhere to go. “Flee as a bird to your mountain,” sings the psalmist. Cactus is this bird’s mountain. When this peak falls down, they have no peak nearby to which to flee. They are trapped on one falling alp.

Since the big Niño, selection pressure has been strong on fortis too. Among the fortis that saw the flood, not quite one in three were still alive by 1987. But the Grants’ tables show that the fortis did not die at random. The survivors in 1987 were eating a much greater proportion of small seeds than large seeds. This was partly a change in behavior, since individual fortis are flexible in their choice of foods. However, they are flexible only up to a point. The Grants can see from their data base that it was the fortis individuals with significantly deeper, wider beaks, the birds that were committed by their anatomy to the pile of big seeds, the eroding peak, who were doing most of the dying. The fortis with significantly shallower and narrower beaks were doing most of the surviving. So the average beak of the fortis generation that was born after the flood—the baby-boom generation—was better adapted to the brave new landscape of the 1980s.

In other words, while the cactus finches have gone down with their peak, the fortis have evolved. They have rolled with the adaptive landscape. The width of the fortis beak in the new generation, a generation of finches that is hopping around on the lava of Daphne Major at this moment, is measurably narrower than the beaks of the generation before them—down from 8.86 millimeters at the time of the flood to 8.74 millimeters now.

In these same years the Grants have seen a second oscillation, a change in the fate of the hybrids on the island. The mixed bloods were selected against in the first half of the watch, and they were selected for in the second half. Up until the flood, a male fortis that crossed with a female fuliginosa (a small beak) or a scandens (a cactus finch) was putting his young at a disadvantage. The hybrids did not prosper. Selection pressure was against intermarriage. But since the flood, selection has reversed. Now a cross with a fuliginosa or a scandens does the genes of fortis a favor.

By putting the two oscillations together, the Grants can begin to understand what is going on with the hybrids. Their misfit data are beginning to fit.

These two oscillations are driven by the same events. They are both governed by the same changes in the adaptive landscape. In an adaptive landscape that is wrinkling and rolling as fast as Daphne, a landscape in which the peaks are in geological upheaval, it can pay to be born different, to carry a beak 3, 4, or 5 millimeters away from the tried and true. Since the super-Niño, some of the old peaks have turned into valleys, and some of the old valleys are peaks. Now a hybrid has a chance of coming down on the summit of a new peak. It can luck onto a piece of the new shifting ground.

In this changing landscape the hybrids may have advantages not only because they are so variable in the dimensions the Grants are measuring. It is also possible that the influx of new genes that is the birthright of the hybrids could translate into a thousand subtle advantages too small for the Grants to measure: benefits that add up to greater physical vigor, even if the bird stays on the same adaptive peak as everybody else. “A hybrid could do all the things others do on an island,” Peter muses, “and just be a better piece of machinery generally.”

Thoughts like these send Peter back to a paper that two evolutionists, Richard Lewontin and L. C. Birch, published in 1966, “Hybridization as a Source of Variation for Adaptation to New Environments.”

Lewontin and Birch found their case in a fruit fly, Dacus tryoni, close cousin of the notorious Mediterranean fruit fly, or medfly. Dacus tryoni once lived solely on fruits in Australian tropical rain forests. That began to change in the 1850s, while Darwin was writing the book that became the Origin of Species. In those same years, farmers “down under” began planting orchards in Queensland. The flies moved out of the rain forest and became a pest in the new apple, pear, and guava orchards. Within a hundred years the flies had expanded their range as far south as Victoria, with sporadic outbreaks in Adelaide, Melbourne, and Gippsland, and in the capital of Australia’s Northern Territory, on the Timor Sea, the port called Darwin.

The farther the flies pressed from their original home in the rain forests, the cooler the weather they encountered. In fact their expansion carried them all the way from the tropical zone to the temperate zone. Lewontin and Birch studied historical records and maps and concluded that the flies had been blocked and slowed in their march across the continent chiefly by this change in climate. Laboratory tests confirmed that the strains of flies in the farthest reaches of their range were more resistant to cold than the flies back home in the rain forest, and there was a neat gradation of cold resistance among the flies in between. These were heritable changes, encoded in the flies’ genes, and all these adaptations had evolved in this species within a single century.

In terms of the adaptive landscape, tryoni was hopping from peak to peak, and as it got farther from the rain forest, each peak was colder and snowier than the one before. Actually the journey was harder on the flies than that, both colder and hotter, since tryoni’s migration from the tropics to the temperate zone exposed it to seasonal swings of temperature that were more and more extreme in both directions.

“Such a process of rapid evolution means rapid genetic change,” write Lewontin and Birch, “and such change, in turn, demands genetic variation on which natural selection can operate. But where did this genetic variation come from?”

Tryoni lives side by side with a second species of flies, Dacus neohumeralis. Tryoni and neohumeralis are sibling species, like Darwin’s finches. The flies share most of the same orchards. Mothers in the two species will even lay their eggs inside the very same apple, which means that tryoni and neohumeralis larvae often grow up side by side, like litter mates.

The only thing that seems to hold these flies apart is sex. Tryoni copulates around sundown, and neohumeralis copulates from mid-morning to mid-afternoon. So the two species are isolated from each other by time though not by space. They look and act so much alike that at least one observer had labeled them as only subspecies. But Lewontin and Birch reason, as the Grants do with Darwin’s finches, that “the clear sexual isolation and the maintenance of their separate identities in nature” warrants calling each of them a separate species.

Tryoni has some bright yellow markings, whereas neohumeralis is plain dull brown. Lewontin and Birch point out that intermediate forms turn up fairly often in collections: flies with a little mosaic of the yellow and the brown. Careful studies proved that these intermediates are, in fact, what they seem to be: hybrids, products of rare crosses between tryoni and neohumeralis. So the separation between the species is not absolute, any more than it is among Darwin’s finches. One fly likes the lights on, one fly likes the lights off, but every once in a while a pair of them gets together anyway.

“This gene exchange has not been sufficient to merge the species,” write Lewontin and Birch, “presumably because of selection against hybrids, but has been sufficient to incorporate foreign species genes into the gene pool of each.”

They are two species as closely related as Darwin’s finches. They often pass genes back and forth, like the finches. They are held apart by natural selection, as the finches were during the first half of the Grants’ study.

To test this hypothesis, Lewontin and Birch performed an experiment in the laboratory. They collected flies of both species and bred them in the lab. Then they set up population cages at three temperatures—20°, 25°, and 31.5° C (68°, 77°, and 89° F)—cool, warm, and hot for these flies.

Lewontin and Birch allowed populations of each species to evolve for two years at each of these temperatures. They witnessed the evolution of a new, combined strain that was more fit than either species is separately. There were marked and rapid genetic changes.

“The introduction of genes from another species can serve as the raw material for an adaptive evolutionary advance even though the original hybridization is disadvantageous,” Lewontin and Birch conclude. “How often this has happened in nature is another question.”

PETER AND ROSEMARY have just seen it happen in nature—on some of the most remote islands in the world. A new vista is opening before them. They are looking at a very broad event, whose action has encompassed the whole of their watch in the Galápagos.

“Under some circumstances,” Peter says, “the populations are maintained as separate entities, because any hybridization that occurs, however rarely, is penalized. The offspring are not as fit. Their chances of surviving to reproduce are not very good. Then comes the rare event.” A terrible drought, or a plague, or a once-in-a-century flood shakes up the island, transforms the adaptive landscape so that the peaks and the valleys are no longer where they were before. The whole adaptive landscape gets shaken like a rug and thrown down again in haphazard new wrinkles and folds. Now the birds that fall in what used to be a valley may find themselves perched on a new, rising peak. Suddenly they are at an advantage. “That causes a very, very slow fusion of the populations,” Peter says. “That’s the direction in which hybridization is pulling.

“But before that goes very far, I think the pendulum will swing back the other way. And at the very least arrest, and at the most reverse, the process.”

“At times, we think now, hybrids are at a disadvantage,” Peter says, “and at times, at an advantage. In the last ten years, the hybrids were at an advantage. But in the ten years before that, the hybrid birds were at a disadvantage. So our mental model is one of oscillation, an oscillation of hybrid superiority and inferiority.”

They see a sort of vast, invisible pendulum swinging back and forth in Darwin’s islands, an oscillation with two phases, each phase lasting a decade or more. “Put the two together, and it is very unlikely that the fusion will go to completion before the wheel of fortune is, so to speak, reversed.”

Peter Boag and Peter Grant have projected the consequences of this kind of action for fortis and fuliginosa. The Grants summarize those results in a paper for the Proceedings of the Royal Society of London. “At the observed rate of interbreeding,” the Grants write, with “no hybrid advantage and no selection, it would take more than fifty generations, or more than two hundred years, to eliminate the morphological differences between them.”

Their estimate is conservative. If they factor in the hybrid advantage that the Grants have seen since the flood, then the change would take less time—somewhere between one hundred and two hundred years. If they factor in the increasing rate of interbreeding, it would take less time yet.

In the two decades they have been watching, the Grants have seen the pendulum swing toward drought, toward flood, and back again. They have seen the adaptive landscape heave in slow motion like whitecaps in an invisible sea. When the landscape returns to something like its condition before the great flood, when the land dries out and the cactus and the Tribulus come back into their own, the flow of genes between the species should dry up too. Then, as the Grants write, the hybrids that have flourished in this present interval, in the landscape as it stands now, will be at a disadvantage again, they will be weeded out by natural selection, “and the three species will persist as three separate species, until the next extraordinary El Niño event occurs. Over the past 500 years El Niño events classified as ‘strong’ have occurred one to three times a century.”

The Grants need to watch longer and study more to be sure. But this is the view that seems to be opening before them. Whenever the adaptive landscape heaves and flings about, like a sea under heavy winds, the hybrids among Darwin’s finches will be favored. They will intermingle their genes. But when the landscape returns to the pattern it held before the storm, the birds will settle back to their old peaks, and the sharing of genes will slow again.

THE GRANTS HAVE BEGUN to think about how far all this goes beyond the Galápagos. “Hybridization,” as they have written this sabbatical in an article for the journal Science, “provides favorable conditions for major and rapid evolution to occur.” There are a total of 9,672 species of birds in the world today. Back in 1975 a German ornithologist, W. Meise, estimated that about 2 percent of the younger, more recent species hybridize regularly, and about 3 percent more hybridize occasionally. In 1989 a Russian ornithologist, E. N. Panov, compiled a more extensive list, including every species of bird that has ever been seen, even once, to hybridize. As the Grants note, “No other class of organisms of comparable size is known so comprehensively.” And the new numbers look interesting.

The total number of bird species in the world is almost 10,000. Almost 1,000 of them, the Grants write, “are known to have bred in nature with another species and produced hybrid offspring … roughly one out of every ten species.”

Among some orders of birds the incidence is even higher. Hybridization seems to be quite common among grouse and partridges, also among woodpeckers, hummingbirds, and many species of hawks and herons. It is highest of all among ducks and geese. Of the 161 species of ducks and geese in the world, 67 species have been known to hybridize. In other words, as the Grants note, almost one out of every two species of ducks and geese has been seen to interbreed in the wild.

Not so long ago, hybridization among birds was thought to be very rare. In 1965 Ernst Mayr, one of the finest ornithologists and evolutionists of this century, wrote, “On the basis of my examination of random collections, I estimate that perhaps one out of 60,000 wild birds is a hybrid.” His estimate may be correct for old and well-established species. But now it seems possible that the interbreeding of birds is more common among younger lineages, where, in Darwin’s phrase, we find the manufactory of species still in action. And the process may be important for evolution, the Grants write, “because it produces novel combinations of genes, as well as new alleles [variant forms of the same gene], thereby creating favorable genetic conditions for rapid and major evolutionary change to occur.”

It may seem improbable that the crossing of lines could do so much to shape the tree of life. But the power of intercrossing “is not hypothetical,” to recycle the phrase with which Darwin introduced the power of natural selection. Among plants the intercrossing of species can create new species, and it can do so literally overnight. “As many as forty percent of plant species may have arisen in this way,” the Grants write. That is a huge number of species. Somewhere between a third and a half of all the green things on this earth, and at least half of the world’s flowering plants, arrived by the mixing of genes from separate species.

Traditionally, evolutionists have thought of this kind of intermixing and rapid evolution as the more or less exclusive property of the plant kingdom. Mayr concluded that hybridization was unlikely to play much of an evolutionary role among higher animals. Yet that may not be true. Certainly it is rarer among animals than plants, but among birds and many other groups of animals, it seems, hybridization is widespread. It is common in toads of the large genus Bufo and in many families of insects. It is extensive among fish, which usually spread their sperm and eggs in the water to be fertilized outside their bodies, rather like plants. Mayr himself cites “occasional or extensive hybridization” among lampreys, trout, salmon, whitefish, catfish, pike, goodeid killifish, live-bearers (including John Endler’s guppies), silver-sides, perch, sunfish, and more.

For plants the advantage of all this interbreeding is obvious. Mayr has put it succinctly: “Plants cannot move. A seed germinates where it drops and must succeed or die.” So as the plants’ pollen is swept from one plant to another by winds and insects, hybridization is not only inevitable but also desirable, because so many myriads of seeds will fall and sprout in adaptive landscapes that are different from those of their parents. Here natural selection favors great genetic variability, and hybridization is one way to generate it fast. Cross a tree with star-shaped leaves and a tree with spear-shaped leaves, and you can get generations of hybrid leaves with shapes like splayed hands, pyramids, hearts, and arrowheads. That is only the variation that catches the eye—imagine the variation beneath the surface.

Because the Grants are watching so closely, they can see that even on the same desert island, on a lump of rock that looks to the casual eye as changeless as the moon, the adaptive landscape varies with extraordinary energy from decade to decade. So the birds that are bound to this little island, breeding where their line has bred for generations, may often need as great an infusion of fresh variation as plants whose seeds drift hundreds of miles on the wind.

The Grants are looking at a pattern that was once dismissed as insignificant in the tree of life. The pattern is known as reticulate evolution, from the Latin reticulum, diminutive for net. The finches’ lines are not so much lines or branches at all. They are more like twiggy thickets, full of little networks and delicate webbings. This sort of reticulate evolution doesn’t bind lineages together forever; eventually they part ways or fuse. But it may be a general and hitherto neglected feature of the origin of species.

Ever since the Grants and their team published the first news of hybrids among Darwin’s finches, evolutionists have been talking and writing about this new view the finches are helping to open up, the implications of a reticulate tree of life.

“Instead of thinking of the evolutionary chart of the finches as a well-developed family tree with clean branches heading off in distinct directions,” writes the evolutionist David Steadman, who is an authority on the fossil remains of Darwin’s finches, “I find it useful to think of it as a young bush in which branches are so tangled, untrimmed, and interrelated that evolutionary directions remain jumbled and tentative.” He writes, “It is as if, like young adults, they are experimenting with different adult identities, some aspects of which they will keep and some they will discard.”

“In the short term,” writes another evolutionist, Jeremy Searle, “they are not following entirely independent evolutionary pathways.” A novel gene that evolves in one species can spread to others. Life would be so much simpler if lines of animals would only keep to themselves, Searle writes, only half-jokingly. That should not be too much to ask: it is the zoologist’s standard working criterion of a good species. But “things are not so easy for zoologists,” Searle concludes. “It is disappointing that even Darwin’s finches do not seem to quite fit the bill.”

A third evolutionist, Robert Holt, is also greatly struck by this blending of competing lines. “Species that are competitors over ecological time,” Holt writes, “may be mutualists over evolutionary time, each providing a store of genetic variation that can be tapped by the other.

“Maybe we should all be grateful that Mother Nature is a bit slovenly when it comes to reproduction, for this may ultimately permit the unfolding of the bountiful diversity of life on Earth.”

The apparent fixity of species once seemed the greatest argument against evolution, just as the apparent fixity of the earth once seemed a commonsense argument against Copernicanism. Now the satisfying and reassuring sameness that once encouraged Aesop and other fable spinners to speak of The Fox, The Owl, The Wolf, The Whale, and The Crow seems more illusory than ever before. “All is flux,” said the Greek philosopher Heraclitus; “everything flows.” The forms and instincts of living things, the invisible borders among them, and the very coasts and landscapes they inhabit are all more fluid and in more flux than even Heraclitus could have imagined.

Chapter 13

Fusion or Fission?