Viral evolution

Viral evolution is a subfield of evolutionary biology and virology that is specifically concerned with the evolution of viruses.[1][2] Viruses have short generation times and many, in particular RNA viruses, have relatively high mutation rates (on the order of one point mutation or more per genome per round of replication). This elevated mutation rate, when combined with natural selection, allows viruses to quickly adapt to changes in their host environment. In addition, most viruses provide many offspring, so any mutated genes can be passed on to a large number of offspring in a short time. Although the chance of mutations and evolution can change depending on the type of virus(double stranded DNA, double stranded RNA, single strand DNA, etc.), viruses overall have high chances for mutations.

Viral evolution is an important aspect of the epidemiology of viral diseases such as influenza (influenza virus), AIDS (HIV), and hepatitis (e.g. HCV). The rapidity of viral mutation also causes problems in the development of successful vaccines and antiviral drugs, as resistant mutations often appear within weeks or months after the beginning of a treatment. One of the main theoretical models applied to viral evolution is the quasispecies model, which defines a viral quasispecies as a group of closely related viral strains competing within an environment.

Origins

Viruses are ancient. Studies at the molecular level have revealed relationships between viruses infecting organisms from each of the three domains of life and viral proteins that pre-date the divergence of life and thus the last universal common ancestor.[3] This indicates that some viruses emerged early in the evolution of life,[4] and that viruses have probably arisen multiple times.[5]

There are three classical hypotheses on the origins of viruses and how they evolved:

  • Virus-first hypothesis: This is the idea that viruses could have evolved from complex molecules of protein and nucleic acid before cells first appeared on earth.[1][2] This hypothesis also states that viruses contributed to the rise of cellular life.[6] This is supported by the idea that all viral genomes encode for proteins that do not have cellular homologs. The virus-first hypothesis has been dismissed by some scientists because it violates the definition of viruses, in that they require a host cell to replicate.[1]
  • Reduction hypothesis: This idea states that viruses may have once been small cells that parasitized larger cells. This is also known as the degeneracy hypothesis.[7][8] This hypothesis is supported by the discovery of giant viruses that have similar genetic material to parasitic bacteria. However, the regressive hypothesis does not explain why even the smallest of cellular parasites do not resemble viruses in any way.[6]
  • Escape hypothesis: This idea states that some viruses may have evolved from bits of DNA or RNA that "escaped" from the genes of a larger organism. It is also known as the vagrancy hypothesis.[9] This hypothesis doesn't explain how the presence of structures that are unique to viruses are not seen anywhere in cells. This hypothesis also did not explain the complex capsids and other structures of virus particles.[6]

Virologists are, however, beginning to reconsider and re-evaluate all three hypotheses.[10][11]

One of the problems for those studying viral origins and evolution is their high rate of mutation, particularly the case in RNA retroviruses like HIV/AIDS. A recent study based on comparisons of viral protein folding structures, however, is offering some new evidence. Fold Super Families (FSF's) are proteins that show similar folding structures independent of the actual sequence of amino acids, and have been found to show evidence of viral phylogeny. Thus viruses have been found to be capable of being divided into 4 FSFs; based upon the three realms of bacterioviruses, archaeoviruses, and eukaryoviruses, together with a fourth FSF that seems to indicate that it pre-dated the separation of the three realms. Thus viral proteomes still contain traces of ancient evolutionary history that can be studied today. The study of protein FSFs suggests the existence of ancient cellular lineages common to both cells and viruses before the appearance of the 'last universal cellular ancestor' that gave rise to modern cells. Evolutionary pressure to reduce genome and particle size may have eventually reduced viro-cells into modern viruses, whereas other coexisting cellular lineages eventually evolved into modern cells.[12] Furthermore, the long genetic distance between RNA and DNA FSF's suggests that the RNA world hypothesis may have new experimental evidence, with a long intermediary period in the evolution of cellular life.

Evolution

Time-line of paleoviruses in the human lineage[13]

Viruses do not form fossils in the traditional sense, because they are much smaller than the finest colloidal fragments forming sedimentary rocks that fossilize plants and animals. However, the genomes of many organisms contain endogenous viral elements (EVEs). These DNA sequences are the remnants of ancient virus genes and genomes that ancestrally 'invaded' the host germline. For example, the genomes of most vertebrate species contain hundreds to thousands of sequences derived from ancient retroviruses. These sequences are a valuable source of retrospective evidence about the evolutionary history of viruses, and have given birth to the science of paleovirology.[13]

The evolutionary history of viruses can to some extent be inferred from analysis of contemporary viral genomes. The mutation rates for many viruses have been measured, and application of a molecular clock allows dates of divergence to be inferred.[14]

Viruses evolve through changes or in their RNA (or DNA), some quite rapidly, and the best adapted mutants quickly outnumber their less fit counterparts. In this sense their evolution is Darwinian.[15] The way viruses reproduce in their host cells makes them particularly susceptible to the genetic changes that help to drive their evolution.[16] The RNA viruses are especially prone to mutations.[17] In host cells there are mechanisms for correcting mistakes when DNA replicates and these kick in whenever cells divide.[17] These important mechanisms prevent potentially lethal mutations from being passed on to offspring. But these mechanisms do not work for RNA and when an RNA virus replicates in its host cell, changes in their genes are occasionally introduced in error, some of which are lethal. One virus particle can produce millions of progeny viruses in just one cycle of replication, therefore the production of a few "dud" viruses is not a problem. Most mutations are "silent" and do not result in any obvious changes to the progeny viruses, but others confer advantages that increase the fitness of the viruses in the environment. These could be changes to the virus particles that disguise them so they are not identified by the cells of the immune system or changes that make antiviral drugs less effective. Both of these changes occur frequently with HIV.[18]

Phylogenetic tree showing the relationships of morbilliviruses of different species[19]

Many viruses (for example, influenza A virus) can "shuffle" their genes with other viruses when two similar strains infect the same cell. This phenomenon is called genetic shift, and is often the cause of new and more virulent strains appearing. Other viruses change more slowly as mutations in their genes gradually accumulate over time, a process known as genetic drift.[20]

Through these mechanisms new viruses are constantly emerging and present a continuing challenge in attempts to control the diseases they cause.[21][22] Most species of viruses are now known to have common ancestors, and although the "virus first" hypothesis has yet to gain full acceptance, there is little doubt that the thousands of species of modern viruses have evolved from less numerous ancient ones.[23] The morbilliviruses, for example, are a group of closely related, but distinct viruses that infect a broad range of animals. The group includes measles virus, which infects humans and primates; canine distemper virus, which infects many animals including dogs, cats, bears, weasels and hyaenas; rinderpest, which infected cattle and buffalo; and other viruses of seals, porpoises and dolphins.[24] Although it is not possible to prove which of these rapidly evolving viruses is the earliest, for such a closely related group of viruses to be found in such diverse hosts suggests the possibility that their common ancestor is ancient.[25]

Transmission

Viruses have been able to continue their infectious existence due to evolution. Their rapid mutation rates and natural selection has given viruses the advantage to continue to spread. One way that viruses have been able to spread is with the evolution of virus transmission. The virus can find a new host through:[26]

  • Droplet transmission- passed on through body fluids (sneezing on someone)
    • An example is the influenza virus[27]
  • Airborne transmission- passed on through the air (brought in by breathing)
    • An example would be how viral meningitis is passed on[28]
  • Vector transmission- picked up by a carrier and brought to a new host
    • An example is viral encephalitis[29]
  • Waterborne transmission- leaving a host, infecting the water, and being consumed in a new host
    • Poliovirus is an example for this[30]
  • Sit-and-wait-transmission- the virus is living outside a host for long periods of time
    • The smallpox virus is also an example for this[30]

There are also some ideas behind the idea that virulence, or the harm that the virus does on its host, depends on a few factors. These factors also have an effect on how the level of virulence will change over time. Viruses that transmit through vertical transmission (transmission to the offspring of the host) will evolve to have lower levels of virulence. Viruses that transmit through horizontal transmission (transmission between members of the same species that don't have a parent-child relationship) will usually evolve to have a higher virulence.[31]

See also

References

  1. 1 2 3 Mahy & Van Regenmortel 2009, p. 24
  2. 1 2 Villarreal, L.P. (2005). Viruses and the Evolution of Life. ASM Press. ISBN 978-1555813093.
  3. Mahy & Van Regenmortel 2009, p. 25
  4. Mahy & Van Regenmortel 2009, p. 26
  5. Dimmock, N.J. (2007). Introduction to Modern Virology. Blackwell. p. 16. ISBN 1-4051-3645-6.
  6. 1 2 3 Nasir, Arshan; Kim, Kyung Mo; Caetano-Anollés, Gustavo (2012-09-01). "Viral evolution". Mobile Genetic Elements. 2 (5): 247–252. doi:10.4161/mge.22797. ISSN 2159-2543. PMC 3575434. PMID 23550145.
  7. Leppard, Dimmock & Easton 2007, p. 16
  8. Sussman, Topley & Wilson 1998, p. 11
  9. Sussman, Topley & Wilson 1998, pp. 11–12
  10. Mahy & Van Regenmortel 2009, p. 362–378
  11. Forterre P (June 2010). "Giant viruses: conflicts in revisiting the virus concept". Intervirology. 53 (5): 362–78. doi:10.1159/000312921. PMID 20551688.
  12. Nasir, Anshan; Caetano-Anollés, Gustavo (4 September 2015). "A phylogenomic data-driven exploration of viral origins and evolution". Science Advances. 1 (8): e1500527. doi:10.1126/sciadv.1500527. PMC 4643759. PMID 26601271.
  13. 1 2 Emerman M, Malik HS (February 2010). Virgin SW, ed. "Paleovirology—modern consequences of ancient viruses". PLoS Biology. 8 (2): e1000301. doi:10.1371/journal.pbio.1000301. PMC 2817711. PMID 20161719.
  14. Lam TT, Hon CC, Tang JW (February 2010). "Use of phylogenetics in the molecular epidemiology and evolutionary studies of viral infections". Critical Reviews in Clinical Laboratory Sciences. 47 (1): 5–49. doi:10.3109/10408361003633318. PMID 20367503.
  15. Leppard, Dimmock & Easton 2007, p. 273
  16. Leppard, Dimmock & Easton 2007, p. 272
  17. 1 2 Domingo E, Escarmís C, Sevilla N, Moya A, Elena SF, Quer J, Novella IS, Holland JJ (June 1996). "Basic concepts in RNA virus evolution". The FASEB Journal. 10 (8): 859–64. doi:10.1096/fasebj.10.8.8666162. PMID 8666162.
  18. Boutwell CL, Rolland MM, Herbeck JT, Mullins JI, Allen TM (October 2010). "Viral evolution and escape during acute HIV-1 infection". The Journal of Infectious Diseases. 202 (Suppl 2): S309–14. doi:10.1086/655653. PMC 2945609. PMID 20846038.
  19. Barrett, Pastoreti & Taylor 2006, p. 24
  20. Chen J, Deng YM (2009). "Influenza virus antigenic variation, host antibody production and new approach to control epidemics". Virology Journal. 6: 30. doi:10.1186/1743-422X-6-30. PMC 2666653. PMID 19284639.
  21. Fraile A, García-Arenal F (2010). "The coevolution of plants and viruses: resistance and pathogenicity". Advances in Virus Research. Advances in Virus Research. 76: 1–32. doi:10.1016/S0065-3527(10)76001-2. ISBN 9780123745255. PMID 20965070.
  22. Tang JW, Shetty N, Lam TT, Hon KL (September 2010). "Emerging, novel, and known influenza virus infections in humans". Infectious Disease Clinics of North America. 24 (3): 603–17. doi:10.1016/j.idc.2010.04.001. PMID 20674794.
  23. Mahy & Van Regenmortel 2009, pp. 70–80
  24. Barrett, Pastoreti & Taylor 2006, p. 16
  25. Barrett, Pastoreti & Taylor 2006, pp. 24–25
  26. "Evolution from a virus's view". evolution.berkeley.edu. Retrieved 2017-11-27.
  27. "Key Facts About Influenza (Flu)". Seasonal Influenza (Flu). Center for Disease Control. 2017-10-16. Retrieved 2017-12-05.
  28. "Meningitis, Viral". Center for Disease Control. 2017-12-04. Retrieved 2017-12-05.
  29. "Encephalitis". PubMed Health. National Library of Medicine. Retrieved 2017-12-05.
  30. 1 2 "Smallpox". Center for Disease Control. 2017-07-13. Retrieved 2017-12-05.
  31. "Virus Evolution". public.wsu.edu. Retrieved 2017-11-27.

Bibliography

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