Pilgrim at Tinker Creek (18 page)

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Authors: Annie Dillard

Tags: #Essays

BOOK: Pilgrim at Tinker Creek
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I have seen the mantis’s abdomen dribbling out eggs in wet bubbles like tapioca pudding glued to a thorn. I have seen a film of a termite queen as big as my face, dead white and featureless, glistening with slime, throbbing and pulsing out rivers of globular eggs. Termite workers, who looked like tiny longshoremen unloading the
Queen Mary
, licked each egg as fast as it was extruded to prevent mold. The whole world is an incubator for incalculable numbers of eggs, each one coded minutely and ready to burst.

The egg of a parasite chalcid wasp, a common small wasp, multiplies unassisted, making ever more identical eggs. The female lays a single fertilized egg in the flaccid tissues of its live prey, and that one egg divides and divides. As many as two thousand new parasitic wasps will hatch to feed on the host’s body with identical hunger. Similarly—only more so—Edwin Way Teale reports that a lone aphid, without a partner, breeding “unmolested” for one year, would produce so many living aphids that, although they are only a tenth of an inch long, together they would extend into space twenty-five hundred
light-years
. Even the average goldfish lays five thousand eggs, which she will eat as fast as the lays, if permitted. The sales manager of Ozark Fisheries in Missouri, which raises commercial goldfish for the likes of me, said, “We produce, measure,
and sell our product by the ton.” The intricacy of Ellery and aphids multiplied mindlessly into tons and light-years is more than extravagance; it is holocaust, parody, glut.

The pressure of growth among animals is a kind of terrible hunger. These billions must eat in order to fuel their surge to sexual maturity so that they may pump out more billions of eggs. And what are the fish on the bed going to eat, or the hatched mantises in the Mason jar going to eat, but each other? There is a terrible innocence in the benumbed world of the lower animals, reducing life there to a universal chomp. Edwin Way Teale, in
The Strange Lives of Familiar Insects
—a book I couldn’t live without—describes several occasions of meals mouthed under the pressure of a hunger that knew no bounds.

You remember the dragonfly nymph, for instance, which stalks the bottom of the creek and the pond in search of live prey to snare with its hooked, unfolding lip. Dragonfly nymphs are insatiable and mighty. They clasp and devour whole minnows and fat tadpoles. Well, a dragonfly nymph, says Teale, “has even been seen climbing up out of the water on a plant to attack a helpless dragonfly emerging, soft and rumpled, from its nymphal skin.” Is this where I draw the line?

It is between mothers and their offspring that these feedings have truly macabre overtones. Look at lacewings. Lacewings are those fragile green insects with large, rounded transparent wings. The larvae eat enormous numbers of aphids, the adults mate in a fluttering rush of instinct, lay eggs, and die by the millions in the first cold snap of fall. Sometimes, when a female lays her fertile eggs on a green leaf atop a slender stalked thread, she is hungry. She pauses in her laying, turns around, and eats her eggs one by one, then lays some more, and eats them, too.

Anything can happen, and anything does; what’s it all
about? Valerie Eliot, T. S. Eliot’s widow, wrote in a letter to the London
Times:
“My husband, T. S. Eliot, loved to recount how late one evening he stopped a taxi. As he got in the driver said: ‘You’re T. S. Eliot.’ When asked how he knew, he replied: ‘Ah, I’ve got an eye for a celebrity. Only the other evening I picked up Bertrand Russell, and I said to him, “Well, Lord Russell, what’s it all about,” and, do you know, he couldn’t tell me.’” Well, Lord God, asks the delicate, dying lacewing whose mandibles are wet with the juice secreted by her own ovipositor, what’s it all about? (“And do you know…”)

Planarians, which live in the duck pond, behave similarly. They are those dark laboratory flatworms that can regenerate themselves from almost any severed part. Arthur Koestler writes, “During the mating season the worms become cannibals, devouring everything alive that comes their way, including their own previously discarded tails which were in the process of growing a new head.” Even such sophisticated mammals as the great predator cats occasionally eat their cubs. A mother cat will be observed licking the area around the umbilical cord of the helpless newborn. She licks, she licks, she licks until something snaps in her brain, and she begins eating, starting there, at the vulnerable belly.

Although mothers devouring their own offspring is patently the more senseless, somehow the reverse behavior is the more appalling. In the death of the parent in the jaws of its offspring I recognize a universal drama that chance occurrence has merely telescoped, so that I can see all the players at once. Gall gnats, for instance, are common small flies. Sometimes, according to Teale, a gall gnat larva, which does not resemble the adult in the least, and which has certainly not mated, nevertheless produces within its body eggs, live eggs, which then hatch within its soft tissues. Sometimes the eggs hatch alive even within the quiescent body of
the pupa. The same incredible thing occasionally occurs within the fly genus
Miastor
, again to both larvae and pupae. “These eggs hatch within their bodies and the ravenous larvae which emerge immediately begin devouring their parents.” In this case, I know what it’s all about, and I wish I didn’t. The parents die, the next generation lives,
ad majorem gloriam
, and so it goes. If the new generation hastens the death of the old, it scarcely matters; the old has served its one purpose, and the direct processing of proteins is tidily all in the family. But think of the invisible swelling of ripe eggs inside the pupa as wrapped and rigid as a mummified Egyptian queen! The eggs burst, shatter her belly, and emerge a live, awake, and hungry from a mummy case which they crawl over like worms and feed on till its gone. And then they turn to the world.

 

“To prevent a like fate,” Teale continues, “some of the ichneumon flies, those wasplike parasites which deposit their eggs in the body tissues of caterpillars, have to scatter their eggs while in flight at times when they are unable to find their prey and the eggs are ready to hatch within their bodies.”

You are an ichneumon. You mated and your eggs are fertile. If you can’t find a caterpillar on which to lay your eggs, your young will starve. When the eggs hatch, the young will eat any body in which they find themselves, so if you don’t kill them by emitting them broadcast over the landscape, they’ll eat you alive. But if you let them drop over the fields you will probably be dead yourself, of old age, before they even hatch to starve, and the whole show will be over and done, and a wretched one it was. You feel them coming, and coming, and you struggle to rise….

Not that the ichneumon is making any conscious choice. If she were, her dilemma would be truly the stuff of tragedy;
Aeschylus need have looked no further than the ichneumon. That is, it would be the stuff of real tragedy if only Aeschylus and I could convince you that the ichneumon is really and truly as alive as we are, and that what happens to it matters. Will you take it on faith?

Here is one last story. It shows that the pressures of growth gang aft a-gley. The clothes moth, whose caterpillar eats wool, sometimes goes into a molting frenzy which Teale blandly describes as “curious”: “A curious paradox in molting is the action of a clothes-moth larva with insufficient food. It sometimes goes into a ‘molting frenzy,’ changing its skin repeatedly and getting smaller and smaller with each change.” Smaller and smaller…can you imagine the frenzy? Where shall we send our sweaters? The diminution process could, in imagination, extend to infinity, as the creature frantically shrinks and shrinks and shrinks to the size of a molecule, then an electron, but never can shrink to absolute nothing and end its terrible hunger. I feel like Ezra: “And when I heard this thing, I rent my garment and my mantle, and plucked off the hair of my head and of my beard, and sat down astonied.”

II

I am not kidding anyone if I pretend that these awesome pressures to eat and breed are wholly mystifying. The million million barnacle larvae in a half mile of shore water, the rivers of termite eggs, and the light-years of aphids ensure the living presence, in a scarcely concerned world, of ever more rock barnacles, termites, and aphids.

It’s chancy out there. Dog whelks eat rock barnacles, worms invade their shells, shore ice razes them from the rocks and grinds them to a powder. Can you lay aphid eggs faster
than chickadees can eat them? Can you find a caterpillar, can you beat the killing frost?

As far as lower animals go, if you lead a simple life you probably face a boring death. Some animals, however, lead such complicated lives that not only do the chances for any one animal’s death at any minute multiply greatly, but so also do the
varieties
of the deaths it might die. The ordained paths of some animals are so rocky they are preposterous. The horsehair worm in the duck pond, for instance, wriggling so serenely near the surface, is the survivor of an impossible series of squeaky escapes. I did a bit of research into the life cycles of these worms, which are shaped exactly like hairs from a horse’s tail, and learned that although scientists are not exactly sure what happens to any one species of them, they think it might go something like this:

You start with long strands of eggs wrapped around vegetation in the duck pond. The eggs hatch, the larvae emerge, and each seeks an aquatic host, say a dragonfly nymph. The larva bores into the nymph’s body, where it feeds and grows and somehow escapes. Then if it doesn’t get eaten it swims over to the shore where it encysts on submersed plants. This is all fairly improbable, but not impossibly so.

Now the coincidences begin. First, presumably, the water level of the duck pond has to drop. This exposes the vegetation so that the land host organism can get at it without drowning. Horsehair worms have various land hosts, such as crickets, beetles, and grasshoppers. Let’s say ours can only make it if a grasshopper comes along. Fine. But the grasshopper had best hurry, for there is only so much fat stored in the encysted worm, and it might starve. Well, here comes just the right species of grasshopper, and it is obligingly feeding on shore vegetation. Now I have not observed any extensive grazing of grasshoppers
on any grassy shores, but obviously it must occur. Bingo, then, the grasshopper just happens to eat the encysted worm.

The cyst bursts. The worm emerges in all its hideous length, up to thirty-six inches, inside the body of the grasshopper, on which it feeds. I presume that the worm must eat enough of its host to stay alive, but not so much that the grasshopper will keel over dead far from water. Entomologists have found tiger beetles dead and dying on the water whose insides were almost perfectly empty except for the white coiled bodies of horsehair worms. At any rate, now the worm is almost an adult, ready to reproduce. But first it’s got to get out of this grasshopper.

Biologists don’t know what happens next. If at the critical stage the grasshopper is hopping in a sunny meadow away from a duck pond or ditch, which is entirely likely, then the story is over. But say it happens to be feeding near the duck pond. The worm perhaps bores its way out of the grasshopper’s body, or perhaps is excreted. At any rate, there it is on the grass, drying out. Now the biologists have to go so far as to invoke a “heavy rain,” falling from heaven at this fortuitous moment, in order to get the horsehair worm back into the water where it can mate and lay more seemingly doomed eggs. You’d be thin, too.

Other creatures have it just about as easy. A blood fluke starts out as an egg in human feces. If it happens to fall into fresh water it will live only if it happens to encounter a certain species of snail. It changes in the snail, swims out, and now needs to find a human being in the water in order to bore through his skin. It travels around in the man’s blood, settles down in the blood vessels of his intestine, and turns into a sexually mature blood fluke, either male or female. Now it has to find another fluke, of the opposite sex, who also just happens to have traveled the same circuitous
route and landed in the same unfortunate man’s intestinal blood vessels. Other flukes lead similarly improbable lives, some passing through as many as four hosts.

But it is for gooseneck barnacles that I reserve the largest measure of awe. Recently I saw photographs taken by members of the
Ra
expedition. One showed a glob of tar as big as a softball, jetsam from a larger craft, which Heyerdahl and his crew spotted in the middle of the Atlantic Ocean. The tar had been in the sea for a long time; it was overgrown with gooseneck barnacles. The gooseneck barnacles were entirely incidental, but for me they were the most interesting thing about the whole expedition. How many gooseneck barnacle larvae must be dying out there in the middle of vast oceans for every one that finds a glob of tar to fasten to? You’ve seen gooseneck barnacles washed up on the beach; they grow on old ship’s timber, driftwood, strips of rubber—anything that’s been afloat in the sea long enough. They do not resemble rock barnacles in the least, although the two are closely related. They have pinkish shells extending in a flattened oval from a flexible bit of “gooseneck” tissue that secures them to the substratum.

I have always had a fancy for these creatures, but I’d always assumed that they lived near shores, where chance floating holdfasts are more likely to occur. What are they doing—what are the larvae doing—out there in the middle of the ocean? They drift and perish, or, by some freak accident in a world where anything can happen, they latch and flourish. If I dangled my hand from the deck of the
Ra
into the sea, could a gooseneck barnacle fasten there? If I gathered a cup of ocean water, would I be holding a score of dying and dead barnacle larvae? Should I throw them a chip? What kind of a world is this, anyway? Why not make fewer barnacle larvae and give them a decent chance? Are we dealing in life, or in death?

 

I have to look at the landscape of the blue-green world again. Just think: in all the clean beautiful reaches of the solar system, our planet alone is a blot; our planet alone has death. I have to acknowledge that the sea is a cup of death and the land is a stained altar stone. We the living are survivors huddled on flotsam, living on jetsam. We are escapees. We wake in terror, eat in hunger, sleep with a mouthful of blood.

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