Difference between revisions of "Viruses as Pest Control: the coevolution of the Myxoma virus and its long-eared hosts"

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==Evolution of the host==
 
==Evolution of the host==
The highly lethal Myxoma virus placed the rabbit population under extreme selective pressure. The virus killed the vast majority of the susceptible rabbit population, leaving only resistant rabbits behind. These resistant rabbits reproduced and created resistant offspring. Over time, the population became more resistant to myxomatosis.<br>Australia was not the only country to use myxomatosis to mitigate their rabbit infestation; the United Kingdom and France also experimented with viral pest control. Initially, the virus devastated rabbit populations, but rabbits soon developed immunity. Researchers compared the DNA of European rabbits collected before the Myxoma outbreaks with modern resistant populations. They discovered that the genomes had changed identically across all three locations, allowing the scientists to determine which genes conferred immunity to myxomatosis <ref>Davis, Josh. "Darwin's rabbit is revealing how the animals became immune to myxomatosis". Natural History Museum. Retrieved 14 August 2019.</ref>.
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The highly lethal Myxoma virus placed the rabbit population under extreme selective pressure. The virus killed the vast majority of the susceptible rabbit population, leaving only somewhat resistant rabbits behind. These resistant rabbits reproduced and created resistant offspring. Over time, the population became more resistant to myxomatosis.<br>Australia was not the only country to use myxomatosis to mitigate their rabbit infestation; the United Kingdom and France also experimented with viral pest control. Initially, the virus devastated rabbit populations, but rabbits soon developed immunity. Researchers compared the DNA of European rabbits collected before the Myxoma outbreaks with modern resistant populations. They discovered that the genomes had changed identically across all three locations, allowing the scientists to determine which genes conferred immunity to myxomatosis <ref>Davis, Josh. "Darwin's rabbit is revealing how the animals became immune to myxomatosis". Natural History Museum. Retrieved 14 August 2019.</ref>.
  
 
==Coevolution of the parasite==
 
==Coevolution of the parasite==

Revision as of 07:17, 26 April 2020

By Ilana Richter
Authored for BIOL 238 Microbiology, taught by Joan Slonczewski, 2018, Kenyon College.

Background

European colonists introduced rabbits to Australia at the end of the 1700s [1]. European rabbits (Otyctolagus cuniculus) are native to southern Europe and northern Africa, but is considered an invasive pest species around the world. The rabbit population in Australia grew exponentially due to the lack of natural predators and warm climate that enabled year-round breeding. Australia was home to an estimated 10 billion rabbits by the 1920s [2]. The Australian rabbit population caused widespread vegetation depletion, leading to soil erosion [3]. The rabbits caused massive destruction of crops and pastures for livestock, resulting in a significant loss of agricultural productivity and harming the economy. Rabbits competed for resources with native herbivores, and themselves became food for the increasing population of native predators. These factors heavily contributed to the decline of native Australian biodiversity decline [4]. Australian farmers attempted to use various chemical pesticides, but those also proved detrimental to the ecosystem. In the 1950s, scientists proposed using the recently-discovered Myxoma virus to curb the rabbit population. This experiment in biological warfare ultimately failed to eliminate the rabbit infestation, but became an important experiment on the coevolution of a pathogen and its host.

Myxoma virus

The Myxoma virus is a poxvirus that lives commensally inside lagomorphs in South America and California [5]. The virus is vectored by mosquitoes and fleas, but it can also be spread through direct contact with an infected animal [6]. Myxoma virions are enveloped and rectangular. Like many poxviruses, they contain a bioconcave core [7]. Myxoma has a non-segemented genome consisting of a single molecule of linear double-stranded DNA [8]. Virons replicate within the cytoplasm of the host cell and reproduce by budding out of the host cell's membrane. The Myxoma virus infects fibroblasts, lymphocytes, and mucosal cells [9].

Myxoma virus, TEM, colorized blue. Credit: David Gregory & Debbie Marshall.

Pathology

The Myxoma virus produces extracellular proteins that specifically suppress or evade a rabbit’s immune response [10]. Most lagomorphs are susceptible to the virus, but the virus is easily targeted by the immune systems of other species. The reservoir hosts of the virus (American rabbits) do not usually exhibit symptoms, except for occasional benign skin tumors. However, infected European rabbits contract the deadly disease myxomatosis. An effect of this severe immunosuppression is opportunistic infection by gram-negative bacteria. This disease manifests as development of lesions and tumors, fever, swelling, hemorrhage, respiratory malfunction, blindness, and death [11].

Myxomatosis presentation in European rabbit. Credit: Richard Harvey.

Experimental use in Australia

Conventional methods of rabbit elimination had failed to solve the problem. Poisoning rabbits and burning their warrens were expensive and laborious options, and ultimately incapable of destroying rabbits at a higher rate than they could reproduce [12]. The desperate government of New South Wales offered a £25,000 reward for “any method of success not previously known in the Colony for the effectual extermination of rabbits.” Over one thousand proposals were submitted [13]. The idea of using a biological control agent was unconventional yet promising, and Myxoma was a perfect candidate. The Myxoma virus only affects rabbits, but it had an incredibly high mortality rate.
Preliminary safety tests were performed in 1933, and myxomatosis positive rabbits were successfully released in Australia in 1950 [14]. The experiment immediately saw dramatic results. The Myxoma virus eliminated over 80% of the rabbit population over two years. [15]. Myxomatosis has a mortality rate of 99.8% upon release. Australia’s agricultural industry rapidly recovered. Mosquitoes do not live in arid deserts, so the virus could not spread across the entire country, but the program was still initially hailed as a resounding success [16]. However, the rabbit population soon began to recover. The rabbit population rebounded to almost 300 million by 1991 [17]. What had changed?

Myxomatosis trials, Wardang Island, South Australia, 1938. Credit: National Archives of Australia A1200, L44186.

Evolution of the host

The highly lethal Myxoma virus placed the rabbit population under extreme selective pressure. The virus killed the vast majority of the susceptible rabbit population, leaving only somewhat resistant rabbits behind. These resistant rabbits reproduced and created resistant offspring. Over time, the population became more resistant to myxomatosis.
Australia was not the only country to use myxomatosis to mitigate their rabbit infestation; the United Kingdom and France also experimented with viral pest control. Initially, the virus devastated rabbit populations, but rabbits soon developed immunity. Researchers compared the DNA of European rabbits collected before the Myxoma outbreaks with modern resistant populations. They discovered that the genomes had changed identically across all three locations, allowing the scientists to determine which genes conferred immunity to myxomatosis [18].

Coevolution of the parasite

A pathogen that has just been introduced to a species is often extremely lethal. This level of virulence is unsustainable, because if the parasite kills its host before it can spread to a new host, the parasite will also die. Evidence shows that such pathogens quickly evolve to become less virulent and more transmissible in a new host [19] At first, this was the case with myxomatosis. The strain of Myxoma that was introduced to Australia was almost 100% lethal to infected rabbits. Within a few years, it had mutated into multiple strains with far lower mortality rates. This supported the belief that parasites evolve to become less virulent or even benign over time ex: the Myxoma virus lives within the bodies of American rabbits without causing them any harm. However, the Australian myxomatosis experiment provides strong evidence that nature does not necessarily conform to this pattern[20]. As rabbit populations evolved resistance to the milder strains, the virus coevolved to become more virulent again. By the 1990s, the virus had evolved the ability to totally deactivate the host’s immune system. As the rabbits gained resistance, the disease evolved, and the rabbits were no longer resistant to its new form. This pattern was repeated in European populations[21]. Instead of continuing to decrease in virulence, the Myxoma virus seems to have stabilized at a very high mortality rate (~75%).

References

  1. "Rabbits – fact sheet". www.environment.nsw.gov.au. Retrieved 2020-04-21.
  2. Zukerman, Wendy. “Australia's Battle with the Bunny.” ABC Science, ABC, 8 Apr. 2009, www.abc.net.au/science/articles/2009/04/08/2538860.htm.
  3. "Environmental Damage caused by Rabbits" (PDF). Archived from the original (PDF) on 18 December 2012.
  4. Cooke, Brain D. 2012. "Rabbits: manageable environmental pests or participants in new Australian ecosystems?". Wildlife Research. 39 (4): 280. doi:10.1071/WR11166
  5. Silvers, L., Barnard, D., Knowlton, F., Inglis, B., Labudovic, A., Holland, M., Janssens, P., Van Leeuween, B., and Kerr, P. 2010. Host-specificity of myxoma virus: Pathogenesis of South American and North American strains of myxoma virus in two lagomorph species. Veterinary Microbiology 141: 289-300.
  6. Fenner, Frank. 1952. "The mechanism of the transmission of myxomatosis in the European rabbit (Oryctolagus cuniculus) by the mosquito Aedes aegypti". Australian Journal of Experimental Biology and Medical Science. 30 (2): 130. doi:10.1038/icb.1952.13
  7. Padgett, B., Wright, M., Jayne, A., and Walker, D. "Electron microscope structure of myxoma virus and some reactivable derivatives." Journal of Bacteriology. 1964; 87(2): 454-460.
  8. Cameron, C., Hota-Mitchell, S., Chen, L., Barrett, J., Cao, J., Macaulay, C., Willer, D., Evans, D., and McFadden, D. "The Complete DNA Sequence of Myxoma Virus." Virology. 1999; 264(2): 298-318.
  9. Kerr, Peter. 2013. "Viral Infections of Rabbits". Veterinary Clinics of North America: Exotic Animal Practice. 16 (2): 437–468. doi:10.1016/j.cvex.2013.02.002
  10. Stanford, M., Werden, S., and McFadden, G. "Myxoma virus in the European rabbit: interactions between the virus and its susceptible host." Veterinary Research 2007; 38: 299-318.
  11. Kerr, Peter. 2013. "Viral Infections of Rabbits". Veterinary Clinics of North America: Exotic Animal Practice. 16 (2): 437–468. doi:10.1016/j.cvex.2013.02.002
  12. Zukerman, Wendy. “Australia's Battle with the Bunny.” ABC Science, ABC, 8 Apr. 2009, www.abc.net.au/science/articles/2009/04/08/2538860.htm.
  13. Andrews, Stefan. 2017. “In 1950, a Disease Called Myxomatosis Was Introduced to Rabbits for Population Control in Australia and It Wiped out 500 Million Rabbits in Two Years.” The Vintage News. www.thevintagenews.com/2017/03/30/in-1950-a-disease-called-myxomatosis-was-introduced-to-rabbits-for-population-control-in-australia-and-it-wiped-out-500-million-rabbits-in-two-years/.
  14. “The Virus That Stunned Australia's Rabbits.” CSIRO, Internet Archive- Wayback Machine, 25 Feb. 2011, web.archive.org/web/20111125204128/www.csiro.au/science/Myxomatosis-History.
  15. Andrews, Stefan. 2017. “In 1950, a Disease Called Myxomatosis Was Introduced to Rabbits for Population Control in Australia and It Wiped out 500 Million Rabbits in Two Years.” The Vintage News. www.thevintagenews.com/2017/03/30/in-1950-a-disease-called-myxomatosis-was-introduced-to-rabbits-for-population-control-in-australia-and-it-wiped-out-500-million-rabbits-in-two-years/.
  16. Zukerman, Wendy. “Australia's Battle with the Bunny.” ABC Science, ABC, 8 Apr. 2009, www.abc.net.au/science/articles/2009/04/08/2538860.htm.
  17. Andrews, Stefan. 2017. “In 1950, a Disease Called Myxomatosis Was Introduced to Rabbits for Population Control in Australia and It Wiped out 500 Million Rabbits in Two Years.” The Vintage News. www.thevintagenews.com/2017/03/30/in-1950-a-disease-called-myxomatosis-was-introduced-to-rabbits-for-population-control-in-australia-and-it-wiped-out-500-million-rabbits-in-two-years/.
  18. Davis, Josh. "Darwin's rabbit is revealing how the animals became immune to myxomatosis". Natural History Museum. Retrieved 14 August 2019.
  19. Read, Andrew F., and Peter J. Kerr. “Infographic: Evolving Virulence.” TheScientist, The Scientist Magazine, 30 Sept. 2017, www.the-scientist.com/multimedia/infographic-evolving-virulence-30813.
  20. Yong, Ed. “The Next Chapter in a Viral Arms Race.” The Atlantic, Atlantic Media Company, 14 Aug. 2017, www.theatlantic.com/science/archive/2017/08/rabbit-virus-arms-race/536796/.
  21. Yong, Ed. “The Next Chapter in a Viral Arms Race.” The Atlantic, Atlantic Media Company, 14 Aug. 2017, www.theatlantic.com/science/archive/2017/08/rabbit-virus-arms-race/536796/.