Monkeypox

Monkeypox is a rare, viral, smallpox-like disease from central and western Africa that was first diagnosed in laboratory primates in 1958. The first human cases were reported in 1970 in Africa. An outbreak in the Democratic Republic of Congo in 1997 was reported to have infected 88 people, with three deaths, all in children younger than 3 years.³⁹

In late May and early June 2003, the first cases of a febrile rash illness in people were reported from Wisconsin, Illinois, and Indiana. Most affected people had been in close contact with recently purchased ill prairie dogs (Cynonys ludovicianus) that had been held with a recent shipment of African rodents. The African rodents that spread the disease had been legally shipped from Ghana to the United States in April 2003 for the pet trade. The shipment included a number of species, and studies indicated that two rope squirrels (Funisciurus), a Gambian rat (Cricetomys), and three dormice (Dryomys) were carrying the monkeypox virus.³⁴ By early July, 71 nonfatal human cases from six states were reported to the Centers for Disease Control and Prevention (CDC).¹⁰ Before this event, nonendangered rodents from Africa were legally shipped into the United States for the pet trade with no regulatory controls. Subsequently, restrictions were placed on U.S. importation of African rodents.

Severe Acute Respiratory Syndrome

SARS was first recognized as a newly emerging human disease in November 2002 in Guangdong Province, China.⁹³ Symptoms included high fever, respiratory illness progressing to pneumonia, in some cases diarrhea, and death. The disease first spread to Hong Kong and thereafter across five continents and 25 countries via infected people.⁷¹ In April 2003, a new coronavirus was discovered to be the causative agent. In July 2003, the World Health Organization (WHO) listed the number of probable SARS cases in humans at 8437, with 813 deaths.⁸ Evidence of viral infection, often without signs, was also detected in palm civets (Paguma) farmed in the region.³³ The initial suggestion of a link between civets and SARS led to a government directive to cull more than 10,000 masked palm civets in the province despite the ambiguity of the disease link.⁹ Later, viral evidence was also detected in raccoon dogs (Nyctereutes) and ferret badgers (Melogale), as well as domestic cats. It now appears that the palm civet served as an artificial market-induced host or amplification host, along with a number of other possible species. Subsequent studies determined that three species of horseshoe bat (Rhinolophus)²⁸ were found to be the natural reservoir host for closely related SARS-like coronaviruses.^51,56

Bats have been found to be reservoir hosts for a number of viral pathogens, including Lyssa, Nipha,¹⁰¹ Hedra, and Ebola viruses. Their role in emerging disease spread appears to be significant.

Ebola Hemorrhagic Fever

Ebola hemorrhagic fever (Ebola) is named after the river in the Democratic Republic of Congo (DRC, formerly Zaire), where it was first identified. Chimpanzees and humans share 98% of their DNA, and gorillas and humans share 97%.⁸⁰ Therefore, bush meat in the form of nonhuman primates poses a particularly high risk of cross-species infection into humans. The first three known outbreaks of Ebola occurred between 1976 and 1979 in DRC and Sudan. Between 2000 and 2004, five human Ebola outbreaks were documented in western central Africa. Epidemiologic studies indicated that these outbreaks resulted from multiple introductions of virus from infected animal sources. The index cases were mainly hunters, and all were infected while handling dead animals, including gorilla (Gorilla), chimpanzee (Pan troglodytes), and duiker (Cephalophus).⁵³ Thereafter, outbreaks spread quickly among people, especially through caregivers, and were documented to almost wipe out entire villages.^31,52 In people, the symptoms are referable to multiple organ effects, with internal and external hemorrhaging. The Zaire subtype of Ebola virus has been known to have a case-fatality rate of almost 90%, and the Sudan subtype has a rate of approximately 50%.⁸²

Ebola has been linked to declines in western equatorial Africa great ape populations. There is evidence that other forest animals, such as the duiker, are also affected.⁵³ Data do not exist on total numbers of nonhuman primates and duikers that have died of the disease, but it is believed that Ebola rivals hunting as the major threat to ape populations.⁹² For some time, the natural reservoir host remained elusive.⁷⁵ Bats were long postulated as a potential reservoir host, as recently confirmed in three species of fruit bat.⁵⁴

The movement of nonhuman primates for use in biomedical research has also proved to be a source for the spread of Ebola-related viruses. In 1989, a closely related simian hemorrhagic fever was diagnosed in Reston, Virginia, in imported cynomolgus monkeys from the Philippines that died during quarantine. Named Ebola Reston, the disease was later found not to cause human disease.⁶²

Transmissible Spongiform Encephalopathies

The transmissible spongiform encephalopathies include chronic wasting disease of cervids, scrapie of sheep, bovine spongiform encephalopathy (BSE) of cattle, and Creutzfeldt-Jakob disease (CJD) of humans. They are caused by pathogenic prions, which are transmissible particles devoid of a nucleic acid genome and composed of a modified isoform of normal prion protein.⁷⁷ These prion proteins are extremely resistant to inactivation by ultraviolet light, ionizing radiation, steam sterilization, and almost all forms of traditional disinfection.

High-volume food production needs prompted the livestock industry to begin feeding ruminant protein to cattle, possibly derived from scrapie-infected sheep. It is believed that this practice led to the outbreak of BSE in the United Kingdom, which then spread to continental Europe, Canada and, more recently, the United States. It was likely through the ingestion of prion-infected meat from cattle that a new emerging disease of people was discovered in 1996, variant Creutzfeldt-Jakob disease (vCJD).

From October 1996 to November 2002, 129 cases of vCJD were reported in the United Kingdom, 6 in France, and 1 each in Canada, Ireland, Italy, and the United States.¹¹ The World Organization for Animal Health (OIE) has listed more than 184,296 cases of BSE in UK cattle alone as of September 2005. As confirmed, 13 species of zoo animals, including Bovidae and Felidae, have died as a result of infection with the BSE agent.²⁵

Chronic wasting disease (CWD) is a prion disease of wild and farmed cervids in North America.⁹⁷ It was first recognized in a research herd of mule deer (Odocoileus hemionus) in Colorado in 1967. In 1985, it was diagnosed first in elk (Cervus elaphus) and then in mule deer in a limited region of Colorado. It is believed that the increase in deer and elk farming and the movement of animals for that industry in the United States and Canada provided a means for spread. It has since been diagnosed in multiple states and regions both in captive and free-ranging cervids. Conversion of human prion protein by CWD-associated prions has been demonstrated in an in vitro cell-free experiment¹⁵ but, to date, investigations have not identified evidence for CWD transmission to humans.¹⁴

Avian Influenza

Avian influenza is an infectious disease of birds caused by type A strains of the influenza virus. Wild birds, predominantly ducks, geese, and shore birds, are the reservoir species for the low-pathogenic strains of avian influenza A virus (LPAI) in nature.⁹⁵ In these species, it does not usually cause illness. The virus is subtyped on the basis of the antigenic properties of hemagglutinin (HA, or H) and neuraminidase (NA, or N) glycoproteins; 16 HA and 9 NA subtypes have been demonstrated. Viruses containing subtypes H5 and H7 have been observed to become highly pathogenic avian influenza (HPAI) in poultry. HPAI has been isolated primarily from commercially raised birds, including chickens, turkeys, quail, guinea fowl, and ostrich (Struthio camelus). Influenza A viruses of the H5 and H7 subtypes have also been detected in a variety of mammals, including humans. The H5N1 influenza A viruses have been detected in birds, pigs, cats, leopards, tigers,⁴⁴ and people in Asia.⁶⁴

Live bird markets that sell a wide variety of domestic and wild bird species to the public provide the perfect conditions for genetic mixing and spread of flu viruses.⁹⁴ In addition, traditional poultry livestock practices that bring people into close contact with domestic fowl and promote the mixing of wild and domestic waterfowl also provide opportunities for domestic wildlife viral exchange and spread into humans. Such an occurrence may have been the cause of the avian flu (H5N1) outbreak in Hong Kong in 1997 and again in late 2003-2004 throughout Asia. Once established in poultry in Asia, a combination of intensive production methods and high-volume poultry movement, in addition to poor sanitation and hygiene, allowed the disease to spread.

In 2005, the H5N1 HPAI was isolated from migratory waterfowl on Quinghai Lake, China,²¹ and from a wild whooper swan in Mongolia.¹ However, it remains unclear whether migratory waterfowl are effective carriers of the disease or rapidly succumb to the infection before they spread the disease, as may have happened in Mongolia. Calls for mass culling of wild birds have been countered by conservation groups and the FAO.⁴

Of greater concern should be the global trade in domestic and wild birds. An illegal shipment of two crested hawk-eagles (Spizaetus nipalensis), smuggled into Europe from Thailand, was seized at the Brussels International Airport in October 2004. Both birds appeared clinically normal, and both were positive for the H5N1 HPAI.⁹¹

The threat posed by avian influenza goes beyond the food supply to becoming a lethal virus that is easily spread among people, a global pandemic. Such a scenario portends grave risk to the economies of nations and to the health of people. The report of the U.S. National Intelligence Council identified a global pandemic as the single most important threat to the global economy.³⁸ As of December 2005, WHO confirmed 142 human cases, with 74 resulting in death. These tragic statistics pale compared with the greater human disease threat. Genetic reassortment of the H5N1 precursor viruses that caused the initial human outbreak in Hong Kong in 1997 may be traced to outbreaks in poultry in China and seven other east Asian countries between 2003 and early 2004. This same virus has been fatal to humans in the region.⁵⁵ The fear is that the H5N1 viruses will gain the ability to spread efficiently among people, causing a global pandemic.

There is good reason for concern. In the 20th century, there have been three global pandemics, all believed to have originated from birds.⁷³ The most severe was the 1918 Spanish influenza pandemic virus (H1N1), which was estimated to have killed 20 to 50 million people worldwide. Pandemic influenza may originate through at least two mechanisms: (1) reassortment between an animal virus and a human virus that yields a new virus; and (2) direct spread and adaptation of a virus from animals to humans.¹⁶ The characterization of the reconstructed 1918 Spanish influenza pandemic virus⁸⁴ showed that the direct spread and adaptation of the avian influenza virus caused the pandemic.