Pecking Order

Bird beaks are more than nature's ingenious designs. They're wonders of evolution, barometers of how species react to鈥攁nd sometimes even instigate鈥攃hanges in their environment.

Finches with their hefty seed-crackers; warblers with their forceps made slender for extracting small insects hidden among leaves and stems; raptors with their curved hooks for tearing; shorebirds with their probes, straight or curved, which help them extract foods buried on a beach or mudflat. Novice birders quickly learn that the wild diversity of bird beaks is among the most reliable means of quickly determining to what family, and often even what species, a bird belongs. When you鈥檙e faced with the bewildering array of avian life in a fall marsh or spring woodlot, that certitude is a comfort, something solid to rest on.

But it鈥檚 a bit misleading, too. Birds鈥 beaks are, in fact, always changing. They鈥檙e not static over the course of an individual bird鈥檚 lifetime, and they鈥檙e certainly not fixed as bird species respond to鈥攁nd instigate鈥攃hanges in their environment. Yes, the basic order taught in Birding 101 is there. But scientists have come to learn in recent years that bills are far from being blunt instruments. Rather, they鈥檙e delicate barometers of their surroundings. To examine in detail how they work is to be transported from simple satisfaction at the intricacies of efficient natural design to wonderment that evolution can get things so precisely right in so many ways.

鈥淏irds have had this explosion of variety in their beaks,鈥 says Margaret Rubega, a biologist at the University of Connecticut. 鈥淢ost vertebrate animals don鈥檛 have nearly as much variation in how their jaws work. But at every stage of the process of changing beak shape it has to work; at every stage in their evolution birds had to feed themselves successfully. The bird that ends up not fed ends up dead.鈥

 

Rubega began studying red-necked phalaropes in the early 1990s. Phalaropes are the black sheep of the sandpiper family: Females are larger and more colorful than males, and they take multiple mates. They feed in a distinctive manner, too, spinning like dervishes on the surface of a lake or ocean to concentrate the tiny crustaceans and other aquatic invertebrates they like to eat in a column of water, then grabbing the organisms with their long, straight bills. But the tip of a phalarope鈥檚 bill is a long way from its mouth. So how does the prey make that journey? The birds don鈥檛 lift their heads, which means whatever they鈥檙e ingesting has to be elevated against the force of gravity. And beaks are not formed like straws, so suction can鈥檛 explain what happens.

Using high-speed videography, Rubega was able to reveal what does occur. A feeding phalarope swiftly opens its bill after grabbing its prey. The food, embedded in a water droplet, races up between the bird鈥檚 jaws, often in as little as one two-hundredth of a second. How does it do that? Through surface tension, Rubega found鈥攖he same force that causes water to bead on a window. Water molecules are attracted both to one another and to the molecules lining a bird鈥檚 bill. As a phalarope opens and closes its bill, the molecules move closer together鈥攚hich has the result of pulling the droplet up into the bird鈥檚 mouth. (Recently, MIT researchers built a model phalarope bill, providing additional support for Rubega鈥檚 explanation, and coined the term 鈥渃apillary ratchet鈥 for the bird鈥檚 feat of biomechanical wizardry.)

Rubega observed that some birds, the star performers of the phalarope world, open their bills only a single time to raise a droplet; others need two or three tries. By looking at cross-section anatomy measurements of the birds鈥 beaks, she was able to correlate the efficiency of a bird鈥檚 feeding with its anatomy. Phalaropes have a complex series of humps on the inside of their upper jaws that increase the effect of surface tension because they give water molecules more surface area to hang onto; the more complex this topography is, the more efficiently a phalarope feeds.

鈥淲hen you look at the outside of the beak, which is what scientists generally measure, there鈥檚 no relationship to how well they do this transport, because that鈥檚 not what makes the difference,鈥 she says. 鈥淎ll that matters is the internal dimensions of their beak.鈥

One of Rubega鈥檚 graduate students, Gregor Yanega, photographed hummingbirds in action to learn how these long-billed birds, so well evolved to feed on nectar, manage to capture the insect prey whose protein they also need. The question was, as Rubega puts it, 鈥淗ow do they manage to snatch insects with that long, delicate tool? It鈥檚 as if they鈥檙e using a set of chopsticks instead of a catcher鈥檚 mitt.鈥

To their surprise, Yanega鈥檚 high-speed videos showed hummingbirds bending their jaws out to the sides in order to dramatically increase the size of their gape and angle the far end down to get it out of the way. In other words, they move their chopsticks out of the way in order to make better use of the catcher鈥檚 mitt that lies beyond. 

鈥淲e were gobsmacked,鈥 says Rubega. 鈥淲e had to play the initial piece of tape back three or four times to convince ourselves that was really what we were seeing.鈥

Effective feeding is not the only purpose of beaks, whose shape, size, and color affect birds鈥 lives in many ways. A beak鈥檚 size can dictate the notes a bird can articulate while singing; its color can attract potential mates (in many species, bright bill colors signal a healthy immune system); its shape often reflects how a species builds its nests (generally, finer-beaked birds weave more neatly). But food supply is the driving architect of shape and size.

Andrew Gosler has been reminded of that every year since 1981, when he first began measuring the sizes of great tit bills as a continuation of one of the longest-running efforts in basic natural history. Gosler, a biology professor at the University of Oxford, was interested in looking at how birds interact with habitat in Wytham Woods, a tract of land deeded to the school in 1943. Generations of Oxford researchers have been closely monitoring the plot鈥檚 woodland populations of great and blue tits鈥攂oth relatives of chickadees鈥攕ince 1947.

As expected, Gosler found that male great tits, which are generally larger than females, have shorter and stouter bills. He was amazed to learn that the bill of an individual great tit can vary considerably in size. That occurs, Gosler realized, because bills have to work hard, and because their underlying bony structure is covered with a layer of keratin, a tough protein related to that which forms our fingernails. 鈥淭he keratin covering is continually growing, and is worn down by the food it eats and by bill-wiping behavior,鈥 he says. 鈥淪o what you see is a sort of dynamic stability between growth and wear.鈥

Over the years Gosler鈥檚 careful measurements revealed that great tit bills tend to be longer in summer, shorter in winter, which dovetails neatly with the birds鈥 needs. In summer, tits feed mainly on insects, which don鈥檛 produce much bill wear. As a result, bills grow longer and more pointed鈥攖he ideal form for probing leaf or bark crevices. In winter, tits concentrate on hard seeds, which cause a lot of wear. Bills grow shorter and stouter鈥攁nd, again, this form is ideal for the work they have to do. 鈥淚t鈥檚 not as if they turn from warblers into sparrows,鈥 Gosler says, 鈥渂ut their beaks are changing size all the time. These little birds are superbly adapted to what they do. It鈥檚 what you would expect from an evolutionary standpoint.鈥

How hard birds work their bills varies a great deal. Species that feed on fruits or soft-bodied insects don鈥檛 have to deal with much abrasion, while woodpeckers or birds that concentrate on hard seeds do. But the rate of bill growth echoes the rate of abrasion鈥攋ust as studies have found that the fingernails of people who bite their nails grow more quickly than those of people who don鈥檛.

Among the champion abraders鈥攁nd bill-growers鈥攁re Eurasian oystercatchers, the flashy black-and-white shorebirds that feed on rocky shores and mudflats in northern Europe. Bruno Ens of the SOVON Dutch Centre for Field Ornithology has been studying them intensively for more than three decades. 鈥淭heir bills grow twice the length in a year,鈥 he says, 鈥渟o if they didn鈥檛 abrade, oystercatcher bills would be enormous.鈥 That鈥檚 double the rate, he notes, at which fingernails grow.

Eurasian oystercatchers have three basic bill shapes so distinctive that ornithologists once suspected their bearers of belonging to different species. But that鈥檚 not the case. Rather, the form of an oystercatcher鈥檚 bill is closely shaped by the foods it eats. Some oystercatchers eat mainly marine worms; they have pointed bills that are ideal for probing in mudflats. Some hammer open cockles or mussels through brute force; they have blunt, screwdriver-shaped bills. Others feed on the same sorts of shellfish by stabbing a weak point鈥攕uch as the hinge where the shell halves meet鈥攁nd severing the muscle that holds the shell closed. Those birds have chisel-shaped bills.

By transferring oystercatcher chicks from parents that feed in one way to foster parents that do so in another, the researchers learned that such behavior, and bill shape, travels in families. Place the offspring of hammerers in the care of stabbers, in other words, and the youngster will learn to stab. Genetically, any oystercatcher can grow up to feed in any way鈥攂ut it鈥檚 likely to do just as its parents do.

Once it does, it鈥檚 likely to keep doing what it knows, although the scientists have also proven experimentally that an adult oystercatcher can switch techniques if needed鈥攕ay, when food supplies change. Its bill shape will also change while the bird goes through an awkward period of learning the new technique. As with a golfer trying to master a new swing, the transition is an inefficient, not-very-graceful process. 鈥淚t takes about two weeks to change,鈥 says Ens. 鈥淭hey can change, but we don鈥檛 think they do that very often. Usually they perfect their technique and get stuck on it.鈥

 

Given enough time and reliable food supplies, oystercatchers could split into three separate species specializing in different foods. That鈥檚 what appears to have happened鈥攐r is still happening鈥攚ith crossbills. These birds use their eponymous bills to bite between the scales of conifer cones, then move their lower jaws to the side to spread apart the cone scales, reaching the seeds hidden underneath. This takes a lot more energy than actually cracking the seeds, says Craig Benkman, an ecologist at the University of Wyoming.

鈥淐onifer scales are like shingles on a roof,鈥 he says. 鈥淲hen crossbills are working on closed cones, they really have to exert a lot of force. Their bills are really over-powered for the seeds themselves. They鈥檙e engineered to get to the seeds.鈥

Over time, crossbill populations have come to specialize in particular seeds鈥攕uch as those of black spruce or ponderosa pine鈥攁nd their bills have taken on shapes that allow them to open those specific cones as readily as possible. In North America ornithologists have identified populations that specialize in at least seven different conifers; by weighing those food preferences and other characteristics, such as differing call types, they鈥檝e proposed that there may be 10 species of red crossbills on this continent alone.

As crossbills have specialized, they鈥檝e shaped the cones of the trees they feed on. Because getting to conifer seeds is hard work, crossbills seek out cones with thinner scales. They eat a lot of seeds, and over time their appetites have prompted conifer species to produce cones with ever-thicker scales so that some seeds are left to allow the trees to reproduce. By examining fossils, Benkman and his students have estimated how long it has taken trees to alter their cones. In Newfoundland the scales of spruce cones have grown up to 15 percent thicker in the 9,000 years since spruce, and crossbills, arrived there. On the island of Hispaniola, which has hosted crossbills for much longer, pine cone scales have become 53 percent thicker over more than half a million years.

Evidence shows this can happen even more quickly. Mauro Galetti, a conservation biologist at Universidade Estadual Paulista in S茫o Paulo, has been studying how fragmented areas in Brazil鈥檚 Atlantic forest respond to the removal of certain animal species. In a healthy patch of Atlantic forest, such large-billed birds as toucans and the pheasant-sized guans known locally as jacutingas feed preferentially on the largest fruits of trees, like the palm trees Euterpe edulis, which locals call palmitos. Unlike crossbills, these birds don鈥檛 destroy the plants鈥 seeds; rather, they efficiently and widely disperse them through the forest in their droppings.

When those birds vanish due to hunting and habitat destruction, there are no animals left that can disperse the larger seeds. Galetti has shown that palmitos in areas lacking large-billed birds produce substantially smaller seeds than those in pristine areas; furthermore, they鈥檙e much less successful at having their seeds dispersed widely through adjacent areas. He has been able to show that this has happened in historical time鈥攚ithin the past two centuries. 鈥淭he disappearance of animals from the forest is definitely affecting the evolution of this plant,鈥 he says.

Galetti鈥檚 work is a reminder that people aren鈥檛 separate from the ongoing processes of evolution. We鈥檝e got a heavy hand on evolution鈥檚 tiller these days. And it explains, too, why many ecologists feel such a sense of urgency at teasing out the intricacies of how the physiology of birds interacts with the environment. As Margaret Rubega notes, the feeding behavior of about three-quarters of the world鈥檚 birds has never been closely studied.

鈥淓very time we put a high-speed camera on a bird,鈥 she says, 鈥渨e see something no one鈥檚 seen before.鈥