Life for the hermaphroditic slug begins as the first warmth of spring rouses it from the torpor of winter. Only now will it lay its egg masses into the brackish water, where, a week or so later, they hatch out as larvae. The larvae spend the next few weeks swimming here and there in the planktonic layers of the coastal marshes, all the while searching for the green filaments of a single species of seaweed, the alga Vaucheria litorea, to which they home and firmly attach. Having found the right alga, they complete their metamorphosis to tiny slugs, when they immediately begin to feed, rasping through the algal walls and sucking out the contents of its cells. Vaucheria is a green alga, which, like the green leaves of trees, is packed with tiny bun-shaped organelles, known as chloroplasts, which capture the bountiful energy of sunlight. This process, known as photosynthesis, is fundamental to the cycles of life, enabling plants to convert sunlight into chemical energy that can be stored, and further shared, by the animals that feed on plants. In essence, all of the familiar life forms we see around us depend on photosynthesis, without which our world would be a very different place. There would be no oxygen in the atmosphere, no trees or flowering plants, no fish to swim in the oceans, and no birds, mammals or people.

Photosynthesis began perhaps as long ago as 3 billion years, when some early bacteria, known as cyanobacteria from their blue-green colour, evolved on our exceedingly young, and volatile, planet. A good deal later, through the evolutionary process known as symbiosis, these pioneering photosynthetic microbes were incorporated into early nucleated life forms, formerly known as protozoa but today called protists, which became the forerunners of the green algae and plants. But the cyanobacterial forerunners never went away. They still thrive in the planktonic regions of the oceans, and their ancestral forms also survive, though somewhat whittled down in their genomes, within the tissues of algae and plants as the tiny cellular inclusions known as chloroplasts. All of Elysia ’s rasping and sucking are directed at these chloroplasts, which it somehow separates out from the other contents of the algal cells, before secreting them away into special cells lining its gut. Soon the gut expands, branching out into various tiny channels all over the body of the growing slug, so that the precious chloroplasts end up in a confluent layer immediately beneath its skin. Thus replete, the slug abandons its mouth to become exclusively solar-powered for the remainder of its life, deriving all of the energy it needs from the algal chloroplasts, which, like a myriad fairy lights within its leaf-shaped body, have switched on the illumination and turned it green.

However, we are far from done with the Elysian mystery. The ingested chloroplasts must now continue to gather the energy of sunlight throughout the slug’s life, and this in turn would normally rely on a continuous supply of proteins, which would be coded by the algal nucleus. How then, since the chloroplasts are no longer connected to the algal nucleus, do they continue to survive and function throughout the nine months of the slug’s day-to-day life cycle?

In fact, we now know that, at some time during the previous evolution of Elysia chlorotica, key genes have been transferred from the nucleus of the alga to the nucleus of the slug.³ Much remains to be discovered about this natural genetic engineering, but there is gathering evidence that it is made possible by viruses that inhabit the slug’s nucleus and tissues. One very interesting discovery about these viruses is that they possess a special chemical, the enzyme known as reverse transcriptase, which usually tells us that we are dealing with a retrovirus. I shall explain a good deal more about these curious organisms, the retroviruses, in subsequent chapters, but let it suffice for the present to know that this enzyme, reverse transcriptase, enables a retrovirus to invade the nucleus. Exactly how such viruses might have made possible the union of such disparate kingdoms as the plants and animals within the sea slug is not presently known. Indeed, precious little is really known about these viruses, which appear rather ancient in the lineages of retroviruses, though they are seen to assemble, on occasion, in the nuclei of the slug’s cells, and from there to make their way as seemingly harmless visitors in the various spaces and compartments of the internal organs and tissues, including, it would appear, the captured chloroplasts. However, there is a final twist to the tale.

At the end of the slug’s life cycle, when spring is stirring the torpid animals back into life, and soon after the eggs for the future generation have been laid, the adult slugs begin to sicken and die. All of a sudden the viruses that previously appeared innocuous now teem and swarm throughout its tissues and organs. This is no chance observation since viruses are found to be multiplying in every dying slug, and virulent pathological changes throughout the tissues would point to an aggressive viral attack.⁴ These viruses are not invaders coming in out of the oceans since exactly the same pattern is seen in slugs that have been maintained in aquaria, in artificial sea water. It is hard to draw any conclusion other than that this attack is brought about by the very retroviruses that appear to inhabit the slug’s own genetic make-up, those same enigmatic viruses that enabled the genetic transfer of the chloroplast genes from the alga, and made possible the solar-powered life cycle. If so, we appear to be witnessing a programmed annihilation of the entire adult population, as if the viruses that had previously enabled the slug’s somewhat idyllic life cycle had now switched behaviour and were acting out some more brutal pattern of programming, culling the now-redundant adults after they had laid the eggs for the start of a new generation.

If the circumstantial evidence is indeed correct, we are looking at an illuminating example of a powerful evolutionary mechanism known as “aggressive symbiosis”. A chance discovery amid perilous circumstances led to my proposing this concept many years ago – though I little realised back then that it would play such a major role in the future direction of my professional life.

Those extreme circumstances began on 14 May 1993 with an ambulance screaming westwards through the dry desert roads of New Mexico, heading for the Indian Health Service Hospital in Gallup. The ambulance crew had radioed ahead so that, as the ambulance reversed back into the admissions bay, the emergency medical staff, under the direction of Dr Bruce Tempest, were already waiting by the entrance to lift the occupant, a young Navajo male, onto a gurney and rush him to the emergency area, where he was subjected to an emergency chest x-ray even as cardiopulmonary resuscitation began. The chest x-ray showed a bizarre picture – instead of the normal, slightly feathery transparency of healthy lungs, the young man’s chest showed a solid opaque white. The air sacs had been flooded with some pathological process, whether fluid or pneumonic exudates, leaving no room at all for air to get through. In effect, he was drowning in his own body’s secretions. Resuscitation was unsuccessful and the young man was pronounced dead right there in the emergency room.

In such tragic circumstance arrived a new or “emerging” plague into the Four Corners States of New Mexico, Arizona, Utah and Colorado. Although it began in the territory of the Navajo Nation, it soon manifested in the non-Navajo areas of the other states, and spread far and wide throughout the rest of America. But the epicentre was always focused on the desert areas of New Mexico and Arizona, where it terrified the local community, often infecting previously fit young people who could be reduced from rude good health to death, with whited-out lungs, in 24 hours. When I first arrived in New Mexico, the plague was still rampant, with the entire intensive care unit at the University Hospital in Albuquerque devoted to looking after newly diagnosed cases. Through intensive modern investigation and devoted medical management by the medical staff in various cities and hospitals, the death rate had been clawed back from an initial 70% to something closer to 50%. My purpose in coming to New Mexico was to examine new, or “emerging plagues”, and particularly those caused by viruses, such as Ebola and HIV-1, as part of the researches for my book, Virus X,⁵ and so the emergence of this all-American plague afforded me a rare opportunity to examine the most intensive modern medical and scientific response, in day-to-day detail. I found that the investigation of the plague, and the medical management of its victims, was still at its height, and I was duly grateful to my hard-pressed and dedicated colleagues, who allowed me to sit in with them in their clinical meetings and scientific experiments.

I knew that scientists working in the Special Pathogens’ Branch of the Centers for Disease Control in Atlanta – the world-famous plague hunters – had discovered that the Four-Corners’ epidemic was caused by a hitherto unknown virus. Here then was the opportunity to see for myself where such emerging viruses came from in nature, and why they behaved as aggressively as they so often did when they encountered a new host, such as our human species. In Albuquerque I would spend some time observing the doctors in the University Hospital, fighting to save the lives of infected patients. Here they did me the great courtesy of allowing me to interview victims and their relatives, with the normal medical confidentiality, and to witness for myself the harrowing experience of contracting an emerging plague virus. I travelled to Atlanta to observe the work of the virologists and geneticists at the Centers for Disease Control, where they had first realised that they were dealing with a newly emerging virus, which was a member of the genus of viruses known as the “hantaviruses”, using molecular techniques only 13 days after the onset of the epidemic. It took them six more months to see the actual virus, which would subsequently be called the Sin Nombre hantavirus – the hantavirus with no name. I sat in on the online discussions between the virologists and the epidemiologists at CDC and the internists and medical investigators in Albuquerque. I found myself gazing with curiosity at images of the new virus taken with the electron microscope, which looked as innocuous as minuscule balls of cotton wool. I moved on to California, where I interviewed virologists who had investigated the first African outbreak of Ebola and who had been intimately involved with the investigation of the emerging virus we now know as HIV-1, the cause of the AIDS pandemic. It was towards the end of my exploration of the Sin Nombre outbreak, and after I had collected a great many interviews with the scientists investigating it, that I returned to Albuquerque to talk toTerry Yates, one more interview as I supposed among many, when I wanted to look at what the biologists had discovered about the animal source of the virus.

I knew by then that the virus that was so lethal in people had come from the commonest rodent in America, the humble deer mouse, the equivalent of the common field mouse back in the UK. And in that conversation, I sensed the ground shift beneath my feet, as I listened with a growing astonishment to the slightly built and dark-haired Yates as he explained, with a fast and engaging Kentuckian accent, his own take on plague viruses, and hantaviruses in particular.

‘We’re interested,’ he told me, ‘in the co-evolutionary potential of the hantavirus as it evolves in direct parallel with the host.’

His reply surprised me. Like most doctors, I thought of viruses as nothing more than parasites. I was taught modern Darwinian evolution as part of the core biology that underpins our understanding of medicine. Lay people often confuse viruses with bacteria but they are radically different organisms. Most viruses are a lot smaller than bacteria, so small in fact that most are completely invisible even under the highest magnifications of the light microscope. Only through more subtle detective work, using immunological probes, or molecular chemistry, or, ultimately, the vast magnification of the electron microscope, can we bring them into focus. In their genetic arrangements viruses also differ markedly from bacteria. Their DNA is usually packaged in the linear clusters we call genes, rather like our own, while the DNA of bacteria is packaged in a single ring. Viruses are also the ultimate masters of evolution through mutation. They mutate with astonishing speed, something like a thousand times faster than bacteria, which in turn mutate approximately a thousand times faster than we do. Mutation of this order is an important consideration for medicine since it is one of the ways in which bacteria and viruses become resistant to antibacterial and antiviral drugs. For example, it is the key to understanding resistance to therapy in conditions such as AIDS and tuberculosis, where the phenomenal mutational capacity of the HIV-1 virus and the tuberculosis bacterium means that we are obliged to prescribe a cocktail of different drugs to control them.

In this conversation with Terry Yates, I discovered that many different species of rodents around the world appeared to have hantaviruses that infected them. The first hantavirus ever discovered came from a rodent in Korea – it emerged close to the Hantaan River, which gave its name to the genus of viruses as well as to the human illness the virus caused, which is known as Hantaan fever. So when Yates told me he was looking into the evolutionary aspects of the hantaviruses, I presumed that he was talking about mutation. I knew nothing about the co-evolution of a virus in parallel with its host. Indeed, I was still thinking along the conventional medical and evolutionary lines when I asked him another question.

‘What do you perceive as a virus?’

‘That’s a good question. Some people will argue that viruses are not life. I disagree with that, certainly. Perhaps a more pertinent question to me is not “what is a virus?” but “what is a species as far as a virus goes?” Are there species of viruses analogous to mammalian species? Basically I am only recently into viruses. I...