Resistance mutation

Resistance to a drug

A resistance mutation is a mutation in a virus gene that allows the virus to become resistant to treatment with a particular antiviral drug. The term was first used in the management of HIV, the first virus in which genome sequencing was routinely used to look for drug resistance. At the time of infection, a virus will infect and begin to replicate within a preliminary cell. As subsequent cells are infected, random mutations will occur in the viral genome.[1] When these mutations begin to accumulate, antiviral methods will kill the wild type strain, but will not be able to kill one or many mutated forms of the original virus. At this point a resistance mutation has occurred because the new strain of virus is now resistant to the antiviral treatment that would have killed the original virus.[1] Resistance mutations are evident and widely studied in HIV due to its high rate of mutation and prevalence in the general population. Resistance mutation is now studied in bacteriology and parasitology.

Mechanisms

Resistance mutations can occur through several mechanisms from single nucleotide substitutions to combinations of amino acid substitutions, deletions and insertions.[1] Over time, these new genetic lines will persist if they become resistant to treatments being used against them. It has been shown that pathogens will favor and become more resistant to treatment in common host genotypes through frequency-dependent selection.[2] Further, strict adherence to a retroviral regimen correlates to a strong decrease in retroviral resistance mutations.[3] There are five classes of drug that are used to treat HIV infection, and resistance mutations can effect the efficacy of these treatments as well.

In Other Viruses

Resistance mutations are found and become problematic in many viruses other than HIV. Notable examples of such viruses include the herpes simplex virus and hepatitis B virus.[9] In the herpes virus, drugs mainly target the viral DNA polymerase. As a result, mutations in the viral DNA polymerase that make it resistant to these drugs are selected for, which ultimately can cause complete resistance of the treatment. In hepatitis B, nucleoside and nucleotide analogs are used to cause early termination of viral transcription. Mutations in viral reverse transcriptase can cause the enzyme to not incorporate these nonfunctional analogs, in favor for their natural counterparts. If this mutation occurs, transcription will not be halted, and viral proteins can be created.

Research Applications

References

  1. 1 2 3 4 Clavel, François. "Mechanisms of HIV Drug Resistance: A Primer" (PDF). Physicians' Research Network. Physicians Research Network Inc. Retrieved 6 February 2016.
  2. Bangham, Jenny; Obbard, Darren; Kim, Kang-Wook; Haddril, Penelope; Jiggins, Francis (22 August 2007). "The Age and Evolution of an Antiviral Resistance Mutation in Drosophila melanogaster". Proceedings: Biological Sciences. 274 (1621): 2027–2034. PMC 1914336Freely accessible. PMID 17550883. doi:10.1098/rspb.2007.0611.
  3. Harrigan, P.; Hogg, Robert; Dong, Winnie; Yip, Benita; Wynhoven, Brian; Woodward, Justin; Broome, Chanson; Broome, Zabrina; Mo, Theresa; Alexander, Chris; Montaner, Julio (1 February 2005). "Predictors of HIV Drug-Resistance Mutations in a Large Antiretroviral-Naive Cohort Initiating Triple Antiretroviral Therapy". The Journal of Infection Diseases. 151 (3): 339–347.
  4. Briz, Verónica; Poveda, Eva; Soriano, Vincent (2006-04-01). "HIV entry inhibitors: mechanisms of action and resistance pathways". The Journal of Antimicrobial Chemotherapy. 57 (4): 619–627. ISSN 0305-7453. PMID 16464888. doi:10.1093/jac/dkl027.
  5. Maga, Giovanni; Radi, Marco; Gerard, Marie-Aline; Botta, Maurizio; Ennifar, Eric (2010-03-30). "HIV-1 RT Inhibitors with a Novel Mechanism of Action: NNRTIs that Compete with the Nucleotide Substrate". Viruses. 2 (4): 880–899. ISSN 1999-4915. PMC 3185657Freely accessible. PMID 21994659. doi:10.3390/v2040880.
  6. Hare, C. Bradley; Mellors, John; Krambrink, Amy; Su, Zhaohui; Skiest, Daniel; Margolis, David M.; Patel, Sheran S.; Barnas, Douglas; Frenkel, Lisa; Coombs, Robert W.; Aweeka, Francesca; Morse, Gene D.; Haas, David W.; Boltz, Valerie; Palmer, Sarah; Coffin, John; Havlir, Diane V. (August 2008). "Detection of Nonnucleoside Reverse‐Transcriptase Inhibitor–Resistant HIV‐1 after Discontinuation of Virologically Suppressive Antiretroviral Therapy". Clinical Infectious Diseases. 47 (3): 421–424. PMC 2586907Freely accessible. PMID 18558886. doi:10.1086/589867.
  7. Hicks, Charles; Gulick, Roy M. (2009-04-01). "Raltegravir: The First HIV Type 1 Integrase Inhibitor". Clinical Infectious Diseases. 48 (7): 931–939. ISSN 1058-4838. PMID 19231980. doi:10.1086/597290.
  8. van Maarseveen, Noortje; Boucher, Charles (2006-01-01). Geretti, Anna Maria, ed. Resistance to protease inhibitors. London: Mediscript. ISBN 9780955166907. PMID 21249774.
  9. Strasfeld, Lynne; Chou, Sunwen (2010-06-01). "Antiviral Drug Resistance: Mechanisms and Clinical Implications". Infectious disease clinics of North America. 24 (2): 413–437. ISSN 0891-5520. PMC 2871161Freely accessible. PMID 20466277. doi:10.1016/j.idc.2010.01.001.
  10. He, Xiaohong; Wang, Fang; Huang, Bin; Chen, Peisong; Zhong, Liangying (2015-06-15). "Detection and analysis of resistance mutations of hepatitis B virus". International Journal of Clinical and Experimental Medicine. 8 (6): 9630–9639. ISSN 1940-5901. PMC 4538069Freely accessible. PMID 26309637.
  11. Rhee, Soo-Yon; Jordan, Michael R.; Raizes, Elliot; Chua, Arlene; Parkin, Neil; Kantor, Rami; Zyl, Gert U. Van; Mukui, Irene; Hosseinipour, Mina C. "HIV-1 Drug Resistance Mutations: Potential Applications for Point-of-Care Genotypic Resistance Testing". PLOS ONE. 10 (12): e0145772. PMC 4696791Freely accessible. PMID 26717411. doi:10.1371/journal.pone.0145772.
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