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“You’re late,” she said. “And your lab looks like an unmade bed. Vergil, it’s—”

“Kaput,” Vergil finished for her, throwing his smock across a stool.

“You left a bunch of test tubes on the counter in the share lab. I’m afraid they’re ruined.”

“Fuck ‘em.”

Hazel’s eyes widened. “My, aren’t you in a mood.”

“I’ve been shut down. I have to clear out all my extracurricular work, give it up, or Harrison will issue my walking papers.”

“That’s rather even-handed of them,” Hazel said, returning to her scan. Harrison had shut down one of her own extracurricular projects the month before. “What did you do?”

“If it’s all the same to you, I’d rather be alone.” Vergil glowered at her from across the counter. “You can finish that in the share lab.”

“I could, but—”

“If you don’t,” Vergil said darkly, “I’ll smear your little piece of agarose across the floor with my wingtips.”

Hazel glared at him for a moment and surmised he wasn’t kidding. She shut off the electrodes, picked up her equipment, and headed for the door. “My condolences,” she said.

“Sure.”

He had to have a plan. Scratching his stubbly chin, he tried to think of some way to cut his losses. He could sacrifice those parts of the experiment that were expendable—the E. coli cultures, for example. He had long since gone beyond them. He had kept them as memorials to his progress, and as a kind of reserve in case work had not gone well in the next steps. The work had gone well, however. It was not complete, but it was so close that he could taste success like a cool, clean swallow of wine.

Hazel’s side of the lab was neat and tidy. His was a chaos of equipment and containers of chemicals. One of his few concessions to lab safety, a white absorbent mat to catch spills, hung half-off the black counter, one corner pinned by a jar of detergent.

Vergil stood before the white idea board, rubbing his stubbly beard, and stared at the cryptic messages he had scrawled there the day before.

Little engineers. Make the world’s tiniest machines. Better than MABs! Little surgeons. War with tumors. Computers with hu-capac. (Computers=spec tumor HA!) size of volvox.

Clearly the ravings of a madman, and Hazel would have paid them no attention. Or would she? It was common practice to scribble any wild idea or inspiration or joke on the boards and just be prepared to have it erased by the next hurried genius. Still…

The notes could have aroused the curiosity of someone as smart as Hazel. Especially since his work on the MABs had been delayed.

Obviously, he had not been circumspect.

MABs—Medically Applicable Biochips—were to be the first practical product of the biochip revolution, the incorporation of protein molecular circuitry with silicon electronics. Biochips had been an area of speculation in the literature for years, but Genetron hoped to have the first working samples available for PDA testing and approval within three months.

They faced intense competition. In what was coming to be known as Enzyme Valley—the biochip equivalent of Silicon Valley—at least six companies had set up facilities in and around La Jolla. Some had started out as pharmaceutical manufacturers hoping to cash in on the products of recombinant DNA research. Nudged out of that area by older and more experienced concerns, they had switched to biochip research. Genetron was the first firm established specifically with biochips in mind.

Vergil picked up an eraser and rubbed out the notes slowly. Throughout his life, things had always conspired to frustrate him. Often, he brought disaster on himself—he was honest enough to admit that. But not once had he ever been able to carry something through to completion. Not in his work, not in his private life.

He had never been good at gauging the consequences of his actions.

He removed four thick spiral-bound notebooks from his locked desk drawer and added them to the growing pile of material to be smuggled out of the lab.

He could not destroy all the evidence. He had to save the white blood cell cultures—his special lymphocytes. But where could he keep them—what could he do outside the lab?

Nothing. There was no place he could go. Genetron had all the equipment he needed, and it would take months to establish another lab. During that time, all his work would literally disintegrate.

Vergil passed through the lab’s rear door into the interior hall and walked past an emergency shower stall. The incubators were kept in a separate room beyond the share lab. Seven refrigerator-sized gray enameled chests stood along one wall, electronic monitors silently and efficiently keeping track of temperatures and CO2 partial pressure in each unit. In the far corner, amid older incubators of all shapes and sizes (gleaned from lab bankruptcy sales), stood a buffed stainless steel and white enamel Forma Scientific model with his name and “Sole Use” scribbled on a piece of surgical tape affixed to the door. He opened the door and removed a rack of culture dishes.

Bacteria in each dish had developed uncharacteristic colonies—blobs of orange and green which resembled aerial maps of Paris or Washington D.C. Lines radiated from clusters and divided the colonies into sections, each section having its own peculiar texture and—so Vergil surmised—function. Since each bacterium in the cultures had the potential intellectual capacity of a mouse, it was quite possible the cultures had turned into simple societies and the societies had developed functional divisions. He hadn’t been keeping track lately, involved as he had been with altered B-cell lymphocytes.

They were like his children, all of them. And they had turned out to be exceptional.

He felt a rush of guilt and nausea as he turned on a gas burner and applied each dish of altered E. coli to the flame with a pair of tongs.

He returned to his lab and dropped the culture dishes into a sterilizing bath. That was the limit. He could not destroy anything more. He felt a hatred for Harrison that went beyond any emotion he had ever felt toward another human. Tears of frustration blurred his vision.

Vergil opened the lab Kelvinator and removed a spinner bottle and a white plastic pallet containing twenty-two test tubes. The spinner bottle was filled with a straw-colored fluid, lymphocytes in a serum medium. He had constructed a custom impellor to stir the medium more effectively, with less cell damage—a rod with several half-helical teflon “sails.”

The test tubes contained saline solution and special concentrated serum nutrients to support the cells while they were examined under a microscope.

He drew fluid from the spinner bottle and carefully added several drops to four of the tubes on the pallet. He then placed the bottle-back on its base. The impellor resumed spinning.

After warming to room temperature—a process he usually aided with a small fan to gently blow warmed air over the pallet—the lymphocytes in the tubes would become active, resuming their development after being subdued by the refrigerator’s chill.

They would continue learning, adding new segments to the revised portions of their DNA. And when, in the normal course of cell growth, the new DNA was transcribed to RNA, and the RNA served as a template for production of amino acids, and the amino acids were converted to proteins…

The proteins would be more than just units of cell structure; other cells would be able to read them. Or RNA itself would be extruded to be absorbed and read by other cells Or—and this third option had presented itself after Vergil inserted fragments of bacterial DNA into the mammalian chromosomes—segments of DNA itself could be removed and passed along.

Every time he thought of it, his head whirled with possibilities, thousands of ways for the cells to communicate with each other and develop their intellects.