After the flood last year I found a big tulip-tree limb that had been wind-thrown into Tinker Creek. The current dragged it up on some rocks on the bank, where receding waters stranded it. A month after the flood I discovered that it was growing new leaves. Both ends of the branch were completely exposed and dried. I was amazed. It was like the old fable about the corpse’s growing a beard; it was as if the woodpile in my garage were suddenly to burst greenly into leaf. The way plants persevere in the bitterest of circumstances is utterly heartening. I can barely keep from unconsciously ascribing a will to these plants, a do-or-die courage, and I have to remind myself that coded cells and mute water pressure have no idea how grandly they are flying in the teeth of it all.
In the lower Bronx, for example, enthusiasts found an ailanthus tree that was fifteen feet long growing from the corner of a garage roof. It was rooted in and living on “dust and roofing cinders.” Even more spectacular is a desert plant, Ibervillea sonorae—a member of the gourd family—that Joseph Wood Krutch describes. If you see this plant in the desert, you see only a dried chunk of loose wood. It has neither roots nor stems; it’s like an old gray knothole. But it is alive. Each year before the rainy season comes, it sends out a few roots and shoots. If the rain arrives, it grows flowers and fruits; these soon wither away, and it reverts to a state as quiet as driftwood.
Well, the New York Botanical Garden put a dried Ibervillea sonorae on display in a glass case. “For seven years,” says Joseph Wood Krutch, “without soil or water, simply lying in the case, it put forth a few anticipatory shoots and then, when no rainy season arrived, dried up again, hoping for better luck next year.” That’s what I call flying in the teeth of it all.
(It’s hard to understand why no one at the New York Botanical Garden had the grace to splash a glass of water on the thing. Then they could say on their display case label, “This is a live plant.” But by the eighth year what they had was a dead plant, which is precisely what it had looked like all along. The sight of it, reinforced by the label “Dead Ibervillea sonorae,” would have been most melancholy to visitors to the botanical garden. I suppose they just threw it away.)
The growth pressure of plants can do an impressive variety of tricks. Bamboo can grow three feet in twenty-four hours, an accomplishment that is capitalized upon, legendarily, in that exquisite Asian torture in which a victim is strapped to a mesh bunk a mere foot above a bed of healthy bamboo plants whose woodlike tips have been sharpened. For the first eight hours he is fine, if jittery; then he starts turning into a colander, by degrees.
Down at the root end of things, blind growth reaches astonishing proportions. So far as I know, only one real experiment has ever been performed to determine the extent and rate of root growth, and when you read the figures, you see why. I have run into various accounts of this experiment, and the only thing they don’t tell you is how many lab assistants were blinded for life.
The experimenters studied a single grass plant, winter rye. They let it grow in a greenhouse for four months; then they gingerly spirited away the soil—under microscopes, I imagine—and counted and measured all the roots and root hairs. In four months the plant had set forth 378 miles of roots—that’s about three miles a day—in 14 million distinct roots. This is mighty impressive, but when they get down to the root hairs, I boggle completely. In those same four months the rye plant created 14 billion root hairs, and those little strands placed end to end just about wouldn’t quit. In a single cubic inch of soil, the length of the root hairs totaled 6,000 miles.
Other plants use the same water power to heave the rock earth around as though they were merely shrugging off a silken cape. Rutherford Platt tells about a larch tree whose root had cleft a one-and-one-half-ton boulder and hoisted it a foot into the air. Everyone knows how a sycamore root will buckle a sidewalk, a mushroom will shatter a cement basement floor. But when the first real measurements of this awesome pressure were taken, nobody could believe the figures.
Rutherford Platt tells the story in The Great American Forest, one of the most interesting books ever written: “In 1875, a Massachusetts farmer, curious about the growing power of expanding apples, melons and squashes, harnessed a squash to a weightlifting device which had a dial like a grocer’s scale to indicate the pressure exerted by the expanding fruit. As the days passed, he kept piling on counterbalancing weight; he could hardly believe his eyes when he saw his vegetables quietly exerting a lifting force of 5 thousand pounds per square inch. When nobody believed him, he set up exhibits of harnessed squashes and invited the public to come and see. The Annual Report of the Massachusetts Board of Agriculture, 1875, reported: ‘Many thousands of men, women, and children of all classes of society visited it. Mr. Penlow watched it day and night, making hourly observations; Professor Parker was moved to write a poem about it; Professor Seelye declared that he positively stood in awe of it.’”
All this is very jolly. Unless perhaps I were strapped down above a stand of growing, sharpened bamboo, I am unlikely to feel the faintest queasiness about either the growth pressure of plants, or their fecundity. Even when the plants get in the way of human “culture,” I don’t mind. When I read how many thousands of dollars a city like New York has to spend to keep underground water pipes free of ailanthus, ginkgo, and sycamore roots, I cannot help but give a little cheer. After all, water pipes are almost always an excellent source of water. In a town where resourcefulness and beating the system are highly prized, these primitive trees can fight city hall and win.
But in the animal world things are different, and human feelings are different. While we’re in New York, consider the cockroaches under the bed and the rats in the early morning clustered on the porch stoop. Apartment houses are hives of swarming roaches. Or again, in one sense you could think of Manhattan’s land as high-rent, high-rise real estate; in another sense you could see it as an enormous breeding ground for rats, acres and acres of rats. I suppose that the rats and the cockroaches don’t do so much actual damage as the roots do; nevertheless, the prospect does not please. Fecundity is anathema only in the animal. “Acres and acres of rats” has a suitably chilling ring to it that is decidedly lacking if I say, instead, “acres and acres of tulips.”
The landscape of earth is dotted and smeared with masses of apparently identical individual animals, from the great Pleistocene herds that blanketed grasslands to the gluey gobs of bacteria that clog the lobes of lungs. The oceanic breeding grounds of pelagic birds are as teeming and cluttered as any human Calcutta. Lemmings blacken the earth and locusts the air. Grunion run thick in the ocean, corals pile on pile, and protozoans explode in a red tide stain. Ants take to the skies in swarms, mayflies hatch by the millions, and molting cicadas coat the trunks of trees. Have you seen the rivers run red and lumpy with salmon?
Consider the ordinary barnacle, the rock barnacle. Inside everyone of those millions of hard white cones on the rocks—the kind that bruises your heel as you bruise its head—is of course a creature as alive as you or I. Its business in life is this: when a wave washes over it, it sticks out twelve feathery feeding appendages and filters the plankton for food. As it grows, it sheds its skin like a lobster, enlarges its shell, and reproduces itself without end. The larvae “hatch into the sea in milky clouds.” The barnacles encrusting a single half mile of shore can leak into the water a million million larvae. How many is that to a human mouthful? In sea water they grow, molt, change shape wildly, and eventually, after several months, settle on the rocks, turn into adults, and build shells. Inside the shells they have to shed their skins. Rachel Carson was always finding the old skins; she reported: “Almost every container of sea water that I bring up from the shore is flecked with white, semitransparent objects…. Seen under the microscope, every detail of structure is perfectly represented…. In the little cellophane-like replicas I can count the joints of the appendages; even the bristles, growing at the bases of the joints, seem to have been slipped intact out of their casings.” All in all,
rock barnacles may live four years.
My point about rock barnacles is those million million larvae “in milky clouds” and those shed flecks of skin. Sea water seems suddenly to be but a broth of barnacle bits. Can I fancy that a million million human infants are more real?
What if God has the same affectionate disregard for us that we have for barnacles? I don’t know if each barnacle larva is of itself unique and special, or if we the people are essentially as interchangeable as bricks. My brain is full of numbers; they swell and would split my skull like a shell. I examine the trapezoids of skin covering the back of my hands like blown dust motes moistened to clay. I have hatched, too, with millions of my kind, into a milky way that spreads from an unknown shore.
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 she 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 alive, awake, and hungry from a mummy case, which they crawl over like worms and feed on till it’s 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 agley. The clothes moth, whose caterpillar eats wool, sometimes goes into a molting frenzy that 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 diminuti
on 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 astonished.”
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.
An Annie Dillard Reader Page 37