Biology:Human virome

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Short description: Total collection of viruses in and on the human body


The human virome is the total collection of viruses in and on the human body.[1][2][3] Viruses in the human body may infect both human cells and other microbes such as bacteria (as with bacteriophages).[4] Some viruses cause disease, while others may be asymptomatic. Certain viruses are also integrated into the human genome as proviruses or endogenous viral elements.[1]

Viruses evolve rapidly and hence the human virome changes constantly.[5] Every human being has a unique virome with a unique balance of species.[2][6] Lifestyle, age, geographic location, and even the season of the year can affect an individual's exposure to viruses, and one's susceptibility to any disease that might be caused by those viruses is also affected by pre-existing immunity and both viral and human genetics.[7]

The human virome is far from being completely explored and new viruses are discovered frequently. Unlike the roughly 40 trillion bacteria in a typical human microbiome,[8] an estimate of the number of viral particles in a healthy adult human is not yet available, although virions generally outnumber individual bacteria 10:1 in nature.[9] Studying the virome is thought to provide an understanding of microbes in general and how they affect human health and disease.

In January 2024, biologists reported the discovery of "obelisks", a new class of viroid-like elements, and "oblins", their related group of proteins, in the human microbiome.[10][11]

Methods and tools

Multiple methods are available for the isolation and study of human viruses:

  • Deep sequencing is a rapid DNA sequencing technique that is useful for characterizing virome richness, stability, gene function and the association with disease phenotypes.[1][3] This technology creates large amounts of sequence information and is capable of detecting rare components of a microbial community. Current methods combining the removal of human and bacterial DNA from samples, large scale sequencing, and bioinformatics are very efficient in the identification of unknown viruses.[12] Unlike other discovery methods, viruses do not need to be grown in cell cultures. Without any prior knowledge of genome sequence or growth methods, novel viruses can be discovered. Therefore, deep sequencing is well suited for rapid identification of an unknown or unexpected viruses involved in a disease outbreak or associated with conditions not thought to be caused by viruses. Deep sequencing also allows for large scale screenings with minimal hands on effort.[13] A systematic exploration of the viruses that infect humans (the human virome) is important and feasible with these methods.
  • Polymerase chain reaction is a tool to amplify and detect specific DNA sequences. It can be used to help characterize the virome, but it is limited by the need for at least partial DNA sequence information.
  • The human metagenome includes all organisms that live on or in the human body. Viruses contribute to the metagenome and establish chronic infection that infest chromosomes; this method will formulate new estimate of the number of genes that confer susceptibility to a given virus and specify alleles for some viruses.[14][15]
  • Large scale antibody studies with ELISA using donated blood could help to determine human exposure to particular viruses in different geographic regions.[7]

Diversity of human viruses

The human virome in healthy, asymptomatic adults. The histogram shows the number of individuals (y-axis) who were positive for a given number of different viral genera (x-axis).[16]

The diversity of human viruses is vast and continually expanding. As of now, there are 219 known species of viruses that can infect humans. This number continues to grow with three to four new species being discovered every year.

The human virome is not stable and may change over time. In fact, new viruses are discovered constantly.[7][17][18] With an increasing number of known viruses, diagnosis and treatment of novel viral-associated conditions will become easier as well.[19][20] Studying the virome could help improve drug development and limit antibiotic usage.[2][18][21]

One of the first studies that used high-throughput DNA sequencing to describe the diversity of eukaryotic dsDNA viruses in normal individuals included 706 samples from 102 subjects.[16] This study detected an average of 5.5 viral genera in each individual and these viruses included herpesviruses, papillomaviruses, polyomaviruses, adenoviruses, anelloviruses, parvoviruses, and circoviruses.[16]

The human virome in healthy, asymptomatic adults. The viral genera (y-axis) detected in each subject (x-axis) are represented by black bars. The virome of each individual is viewed by looking at the black bars in a given column.[16]

Each individual had a distinct viral profile, demonstrating the high interpersonal diversity of the virome. One to 15 viral genera (average 5.5) were detected in 92% of the 102 individuals sampled (Figure 2).[16] Figure 3 illustrates the viromes of the 102 individuals defined by sampling up to five major body habitats, showing that a broad range of viruses was detected in healthy people (Figure 3).[16]

The 102 individuals carried seven distinct families of human DNA viruses (Figure 4A).[16] Sequences were detected predominantly in the nose and skin, similarity to 17 papillomavirus genera(Figure 4B).[16] Roseoloviruses, predominantly HHV-7 and to a lesser extent HHV-6, were present among 98% of the individuals who provided mouth samples.[16]

In addition, the same viruses were prevalent in multiple body habitats within individuals. For instance, the beta- and gamma-papillomaviruses were the viruses most commonly found in the skin and the nose (anterior nares; see Figure 4A,B), which may reflect proximity and similarities in microenvironments that support infection with these viruses.[16]

The human virome in five body habitats. (A) All of the viruses detected in the five body habitats . Each virus is represented by a colored bar and labeled on the y-axis on the right side. The relative height of the bar reflects the percentage of subjects sampled at each body site in whom the virus was detected. In this panel, the bar representing roseoloviruses in the oral samples reflects the maximum bar height, because 98% of the individuals who were sampled in the mouth harbored roseoloviruses. (B) This panel shows papillomaviruses included in the category ‘Other papillomaviruses’. The largest bar height shown represents the unclassified papillomaviruses found in skin samples from 65% of subjects.[16]

The human blood virome

Whole-genome sequencing data of blood from 8,240 individuals without any clear infectious disease revealed 94 different viruses in 42% of the study participants. The sequences included 19 human DNA viruses, proviruses and RNA viruses (herpesviruses, anelloviruses, papillomaviruses, three polyomaviruses, adenovirus, HIV, HTLV, hepatitis B, hepatitis C, parvovirus B19, and influenza virus).[22] Of possible relevance to transfusion medicine, this study identified Merkel cell polyomavirus in 49 individuals, papillomavirus in blood of 13 individuals, parvovirus B19 in 6 individuals, and the presence of herpesvirus 8 in 3 individuals.[22]

Impact on human health

The human virome is a part of human bodies and will not always cause harm.[23] Many latent and asymptomatic viruses are present in the human body all the time. Viruses infect all life forms; therefore the bacterial, plant, and animal cells and material in the gut also carry viruses.[6] When viruses cause harm by infecting the cells in the body, a symptomatic disease may develop.

Contrary to common belief, harmful viruses may be in the minority, compared to benign viruses in the human body. It is much harder to identify viruses than it is to identify bacteria, therefore the understanding of benign viruses in the human body is very rudimentary.[2] The collection of all viruses in the human body which do not cause disease in healthy individuals is often referred to as the 'healthy human virome'.[23] The healthy virome consists of three distinct components: (i) viruses that systematically enter the human organism, primarily, with food, but do not replicate in humans; (ii) viruses infecting prokaryotes and, possibly, unicellular eukaryotes that comprise the healthy human microbiome; and (iii) viruses that actually replicate and persist in human cells.[23]

The health effects of viruses on an individual are dependent on the individual's immune system.[1][20]

The hygiene hypothesis

Recent research has linked the emerging idea of the hygiene hypothesis to viruses. This hypothesis attempts to explain some of the high incidences of diseases such as asthma[24] and eczema[25] in the Western world by Western societies' overuse of antibiotic and antiviral agents.

This overuse potentially disrupts not only the bacteria of the gut but also the viruses that have long lived in harmony with the human body and now play a role in regulation of human health.

The hypothesis generally refers to microorganisms, but is now being extended to include airborne viruses and common viral infections of childhood that are becoming increasingly less common.[26]

Effect of skin location

Diverse viruses colonize the human skin and differ by skin site.[27] This skin virome includes human viruses (i.e. human papillomavirus) and bacteriophages (bacterial viruses) that infect commensal skin bacteria such as Staphylococci.[28]

Virus communities differ by moisture levels and degree of protection from the external environment.[27]

Effect of diet

Many studies have demonstrated that the bacteria and viruses in the human gut (the gut microbiome) can be altered by changes in diet.[29] One study that focused on bacterial viruses, called bacteriophages, in the gut found a significant relationship between diet and the type of bacteriophages present.[30] This was done by comparing the distance between bacteriophage gut communities in individuals both before and after they started a controlled diet. The results were that the distance between the bacteriophage gut communities of individuals on the same diet was significantly smaller at the end of their dietary treatment than it was at the start, while there was no increase in community similarity for individuals on different diets over time.

References

  1. 1.0 1.1 1.2 1.3 Wylie, Kristine M.; Weinstock, George M.; Storch, Gregory A. (1 October 2012). "Emerging view of the human virome". Translational Research 160 (4): 283–290. doi:10.1016/j.trsl.2012.03.006. PMID 22683423. 
  2. 2.0 2.1 2.2 2.3 Williams, S. C. P. (6 February 2013). "The other microbiome". Proceedings of the National Academy of Sciences 110 (8): 2682–2684. doi:10.1073/pnas.1300923110. PMID 23388628. Bibcode2013PNAS..110.2682W. 
  3. 3.0 3.1 Fontana, Judith M.; Alexander, Elizabeth; Salvatore, Mirella (2012). "Translational research in infectious disease: current paradigms and challenges ahead". Translational Research 159 (6): 430–453. doi:10.1016/j.trsl.2011.12.009. PMID 22633095. 
  4. Pride, David T; Salzman, Julia; Haynes, Matthew; Rohwer, Forest; Davis-Long, Clara; White, Richard A; Loomer, Peter; Armitage, Gary C et al. (8 December 2011). "Evidence of a robust resident bacteriophage population revealed through analysis of the human salivary virome". The ISME Journal 6 (5): 915–926. doi:10.1038/ismej.2011.169. PMID 22158393. 
  5. Woolhouse, M.; Scott, F.; Hudson, Z.; Howey, R.; Chase-Topping, M. (10 September 2012). "Human viruses: discovery and emergence". Philosophical Transactions of the Royal Society B: Biological Sciences 367 (1604): 2864–2871. doi:10.1098/rstb.2011.0354. PMID 22966141. 
  6. 6.0 6.1 Zimmer, Carl (8 February 2013). "Your Inner Lions: Get to Know Your Virome". National Geographic. http://phenomena.nationalgeographic.com/2013/02/08/your-inner-lions-get-to-know-your-virome/. 
  7. 7.0 7.1 7.2 Delwart, Eric; Racaniello, Vincent (14 February 2013). "A Roadmap to the Human Virome". PLOS Pathogens 9 (2): e1003146. doi:10.1371/journal.ppat.1003146. PMID 23457428. 
  8. Sender, R; Fuchs, S; Milo, R (January 2016). "Are We Really Vastly Outnumbered? Revisiting the Ratio of Bacterial to Host Cells in Humans". Cell 164 (3): 337–40. doi:10.1016/j.cell.2016.01.013. PMID 26824647. 
  9. "Meet the trillions of viruses that make up your virome | EarthSky.org" (in en-US). 11 October 2018. https://earthsky.org/human-world/trillions-of-viruses-human-virome. 
  10. Koumoundouros, Tessa (29 January 2024). "'Obelisks': Entirely New Class of Life Has Been Found in The Human Digestive System". ScienceAlert. Archived from the original on 29 January 2024. https://archive.ph/wip/WuR9D. Retrieved 29 January 2024. 
  11. Zheludev, Ivan N. (21 January 2024). "Viroid-like colonists of human microbiomes". bioRxiv. doi:10.1101/2024.01.20.576352. Archived from the original on 29 January 2024. https://archive.ph/wip/klBBX. Retrieved 29 January 2024. 
  12. Thurber, Rebecca V; Haynes, Matthew; Breitbart, Mya; Wegley, Linda; Rohwer, Forest (2009). "Laboratory procedures to generate viral metagenomes". Nature Protocols 4 (4): 470–483. doi:10.1038/nprot.2009.10. PMID 19300441. 
  13. Allander, T. (6 September 2005). "From The Cover: Cloning of a human parvovirus by molecular screening of respiratory tract samples". Proceedings of the National Academy of Sciences 102 (36): 12891–12896. doi:10.1073/pnas.0504666102. PMID 16118271. Bibcode2005PNAS..10212891A. 
  14. Virgin, Herbert W.; Wherry, E. John; Ahmed, Rafi (1 July 2009). "Redefining Chronic Viral Infection". Cell 138 (1): 30–50. doi:10.1016/j.cell.2009.06.036. PMID 19596234. 
  15. Kristensen, David M.; Mushegian, Arcady R.; Dolja, Valerian V.; Koonin, Eugene V. (2010). "New dimensions of the virus world discovered through metagenomics". Trends in Microbiology 18 (1): 11–19. doi:10.1016/j.tim.2009.11.003. PMID 19942437. 
  16. 16.00 16.01 16.02 16.03 16.04 16.05 16.06 16.07 16.08 16.09 16.10 Wylie, Kristine M.; Mihindukulasuriya, Kathie A.; Zhou, Yanjiao; Sodergren, Erica; Storch, Gregory A.; Weinstock, George M. (2014-01-01). "Metagenomic analysis of double-stranded DNA viruses in healthy adults". BMC Biology 12: 71. doi:10.1186/s12915-014-0071-7. ISSN 1741-7007. PMID 25212266. 
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  18. 18.0 18.1 Dalke, Kate. "The Human Virome". Genome News Network. http://www.genomenewsnetwork.org/articles/06_03/virome.shtml. 
  19. "Pathogenic simian immunodeficiency virus infection is associated with expansion of the enteric virome.". Cell 151 (2): 253–66. Oct 12, 2012. doi:10.1016/j.cell.2012.09.024. PMID 23063120. 
  20. 20.0 20.1 Foxman, Ellen F.; Iwasaki, Akiko (1 April 2011). "Genome–virome interactions: examining the role of common viral infections in complex disease". Nature Reviews Microbiology 9 (4): 254–264. doi:10.1038/nrmicro2541. PMID 21407242. 
  21. Pennisi, E. (24 March 2011). "Going Viral: Exploring the Role Of Viruses in Our Bodies". Science 331 (6024): 1513. doi:10.1126/science.331.6024.1513. PMID 21436418. Bibcode2011Sci...331.1513P. 
  22. 22.0 22.1 Moustafa, Ahmed; Xie, Chao; Kirkness, Ewen; Biggs, William; Wong, Emily; Turpaz, Yaron; Bloom, Kenneth; Delwart, Eric et al. (2017-03-22). "The blood DNA virome in 8,000 humans". PLOS Pathogens 13 (3): e1006292. doi:10.1371/journal.ppat.1006292. ISSN 1553-7374. PMID 28328962. 
  23. 23.0 23.1 23.2 Koonin, Eugene V; Dolja, Valerian V; Krupovic, Mart (2021). "The healthy human virome: from virus–host symbiosis to disease". Current Opinion in Virology 47: 86–94. doi:10.1016/j.coviro.2021.02.002. PMID 33652230. https://www.sciencedirect.com/science/article/pii/S1879625721000122. 
  24. Butler, Christopher C (September 2013). "Asthma prevalence and humoral immune response in Somali immigrants in the US: implications for the hygiene hypothesis.". Primary Care Respiratory Journal: Journal of the General Practice Airways Group 22 (3): 262–264. doi:10.4104/pcrj.2013.00081. PMID 23959045. 
  25. Strachan, David P (June 10, 2014). "Siblings, Asthma, Rhinoconjunctivitis And Eczema: A Worldwide Perspective From The International Study Of Asthma And Allergies In Childhood.". Clinical and Experimental Allergy 45 (1): 126–136. doi:10.1111/cea.12349. PMID 24912652. 
  26. Daley, D (October 2014). "The evolution of the hygiene hypothesis: the role of early-life exposures to viruses and microbes and their relationship to asthma and allergic diseases.". Current Opinion in Allergy and Clinical Immunology 14 (5): 390–396. doi:10.1097/ACI.0000000000000101. PMID 25102107. 
  27. 27.0 27.1 Hannigan, Geoffrey D.; Meisel, Jacquelyn S.; Tyldsley, Amanda S.; Zheng, Qi; Hodkinson, Brendan P.; SanMiguel, Adam J.; Minot, Samuel; Bushman, Frederic D. et al. (2015-10-30). "The Human Skin Double-Stranded DNA Virome: Topographical and Temporal Diversity, Genetic Enrichment, and Dynamic Associations with the Host Microbiome" (in en). mBio 6 (5): e01578–15. doi:10.1128/mBio.01578-15. ISSN 2150-7511. PMID 26489866. 
  28. Grice, Elizabeth A.; Kong, Heidi H.; Conlan, Sean; Deming, Clayton B.; Davis, Joie; Young, Alice C.; Program, NISC Comparative Sequencing; Bouffard, Gerard G. et al. (2009-05-29). "Topographical and Temporal Diversity of the Human Skin Microbiome" (in en). Science 324 (5931): 1190–1192. doi:10.1126/science.1171700. ISSN 0036-8075. PMID 19478181. Bibcode2009Sci...324.1190G. 
  29. Focà, Alfredo; Liberto, Maria Carla; Quirino, Angela; Marascio, Nadia; Zicca, Emilia; Pavia, Grazia (2015-01-01). "Gut Inflammation and Immunity: What Is the Role of the Human Gut Virome?". Mediators of Inflammation 2015: 326032. doi:10.1155/2015/326032. ISSN 0962-9351. PMID 25944980. 
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Further reading

  • David Pride, "The Viruses inside You: Trillions of viruses make up the human virome. Some can harm us, but some could help us, if we can figure out how to use them", Scientific American, vol. 323, no. 6 (December 2020), pp. 46–53.




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