Reverse transcriptase explained

Symbol:RVT_1
Reverse transcriptase
(RNA-dependent DNA polymerase)
Pfam:PF00078
Pfam Clan:CL0027
Interpro:IPR000477
Prosite:PS50878
Scop:1hmv
Cdd:cd00304
RNA-directed DNA polymerase
Ec Number:2.7.7.49
Cas Number:9068-38-6
Go Code:0003964

A reverse transcriptase (RT) is an enzyme used to convert RNA genome to DNA, a process termed reverse transcription. Reverse transcriptases are used by viruses such as HIV and hepatitis B to replicate their genomes, by retrotransposon mobile genetic elements to proliferate within the host genome, and by eukaryotic cells to extend the telomeres at the ends of their linear chromosomes. Contrary to a widely held belief, the process does not violate the flows of genetic information as described by the classical central dogma, as transfers of information from RNA to DNA are explicitly held possible.[1] [2] [3]

Retroviral RT has three sequential biochemical activities: RNA-dependent DNA polymerase activity, ribonuclease H (RNase H), and DNA-dependent DNA polymerase activity. Collectively, these activities enable the enzyme to convert single-stranded RNA into double-stranded cDNA. In retroviruses and retrotransposons, this cDNA can then integrate into the host genome, from which new RNA copies can be made via host-cell transcription. The same sequence of reactions is widely used in the laboratory to convert RNA to DNA for use in molecular cloning, RNA sequencing, polymerase chain reaction (PCR), or genome analysis.

History

Reverse transcriptases were discovered by Howard Temin at the University of Wisconsin–Madison in Rous sarcoma virions[4] and independently isolated by David Baltimore in 1970 at MIT from two RNA tumour viruses: murine leukemia virus and again Rous sarcoma virus.[5] For their achievements, they shared the 1975 Nobel Prize in Physiology or Medicine (with Renato Dulbecco).

Well-studied reverse transcriptases include:

Function in viruses

The enzymes are encoded and used by viruses that use reverse transcription as a step in the process of replication. Reverse-transcribing RNA viruses, such as retroviruses, use the enzyme to reverse-transcribe their RNA genomes into DNA, which is then integrated into the host genome and replicated along with it. Reverse-transcribing DNA viruses, such as the hepadnaviruses, can allow RNA to serve as a template in assembling and making DNA strands. HIV infects humans with the use of this enzyme. Without reverse transcriptase, the viral genome would not be able to incorporate into the host cell, resulting in failure to replicate.

Process of reverse transcription or retrotranscription

Reverse transcriptase creates double-stranded DNA from an RNA template.

In virus species with reverse transcriptase lacking DNA-dependent DNA polymerase activity, creation of double-stranded DNA can possibly be done by host-encoded DNA polymerase δ, mistaking the viral DNA-RNA for a primer and synthesizing a double-stranded DNA by a similar mechanism as in primer removal, where the newly synthesized DNA displaces the original RNA template.

The process of reverse transcription, also called retrotranscription or retrotras, is extremely error-prone, and it is during this step that mutations may occur. Such mutations may cause drug resistance.

Retroviral reverse transcription

Retroviruses, also referred to as class VI ssRNA-RT viruses, are RNA reverse-transcribing viruses with a DNA intermediate. Their genomes consist of two molecules of positive-sense single-stranded RNA with a 5' cap and 3' polyadenylated tail. Examples of retroviruses include the human immunodeficiency virus (HIV) and the human T-lymphotropic virus (HTLV). Creation of double-stranded DNA occurs in the cytosol[9] as a series of these steps:

  1. Lysyl tRNA acts as a primer and hybridizes to a complementary part of the virus RNA genome called the primer binding site or PBS.
  2. Reverse transcriptase then adds DNA nucleotides onto the 3' end of the primer, synthesizing DNA complementary to the U5 (non-coding region) and R region (a direct repeat found at both ends of the RNA molecule) of the viral RNA.
  3. A domain on the reverse transcriptase enzyme called RNAse H degrades the U5 and R regions on the 5’ end of the RNA.
  4. The tRNA primer then "jumps" to the 3’ end of the viral genome, and the newly synthesised DNA strands hybridizes to the complementary R region on the RNA.
  5. The complementary DNA (cDNA) added in (2) is further extended.
  6. The majority of viral RNA is degraded by RNAse H, leaving only the PP sequence.
  7. Synthesis of the second DNA strand begins, using the remaining PP fragment of viral RNA as a primer.
  8. The tRNA primer leaves and a "jump" happens. The PBS from the second strand hybridizes with the complementary PBS on the first strand.
  9. Both strands are extended to form a complete double-stranded DNA copy of the original viral RNA genome, which can then be incorporated into the host's genome by the enzyme integrase.

Creation of double-stranded DNA also involves strand transfer, in which there is a translocation of short DNA product from initial RNA-dependent DNA synthesis to acceptor template regions at the other end of the genome, which are later reached and processed by the reverse transcriptase for its DNA-dependent DNA activity.[10]

Retroviral RNA is arranged in 5’ terminus to 3’ terminus. The site where the primer is annealed to viral RNA is called the primer-binding site (PBS). The RNA 5’end to the PBS site is called U5, and the RNA 3’ end to the PBS is called the leader. The tRNA primer is unwound between 14 and 22 nucleotides and forms a base-paired duplex with the viral RNA at PBS. The fact that the PBS is located near the 5’ terminus of viral RNA is unusual because reverse transcriptase synthesize DNA from 3’ end of the primer in the 5’ to 3’ direction (with respect to the newly synthesized DNA strand). Therefore, the primer and reverse transcriptase must be relocated to 3’ end of viral RNA. In order to accomplish this reposition, multiple steps and various enzymes including DNA polymerase, ribonuclease H(RNase H) and polynucleotide unwinding are needed.[11] [12]

The HIV reverse transcriptase also has ribonuclease activity that degrades the viral RNA during the synthesis of cDNA, as well as DNA-dependent DNA polymerase activity that copies the sense cDNA strand into an antisense DNA to form a double-stranded viral DNA intermediate (vDNA).[13] The HIV viral RNA structural elements regulate the progression of reverse transcription.[14]

In cellular life

Self-replicating stretches of eukaryotic genomes known as retrotransposons utilize reverse transcriptase to move from one position in the genome to another via an RNA intermediate. They are found abundantly in the genomes of plants and animals. Telomerase is another reverse transcriptase found in many eukaryotes, including humans, which carries its own RNA template; this RNA is used as a template for DNA replication.[15]

Initial reports of reverse transcriptase in prokaryotes came as far back as 1971 in France (Beljanski et al., 1971a, 1972) and a few years later in the USSR (Romashchenko 1977[16]). These have since been broadly described as part of bacterial Retrons, distinct sequences that code for reverse transcriptase, and are used in the synthesis of msDNA. In order to initiate synthesis of DNA, a primer is needed. In bacteria, the primer is synthesized during replication.[17]

Valerian Dolja of Oregon State argues that viruses, due to their diversity, have played an evolutionary role in the development of cellular life, with reverse transcriptase playing a central role.[18]

Structure

The reverse transcriptase employs a "right hand" structure similar to that found in other viral nucleic acid polymerases.[19] In addition to the transcription function, retroviral reverse transcriptases have a domain belonging to the RNase H family, which is vital to their replication. By degrading the RNA template, it allows the other strand of DNA to be synthesized.[20] Some fragments from the digestion also serve as the primer for the DNA polymerase (either the same enzyme or a host protein), responsible for making the other (plus) strand.[21]

Replication fidelity

There are three different replication systems during the life cycle of a retrovirus. The first process is the reverse transcriptase synthesis of viral DNA from viral RNA, which then forms newly made complementary DNA strands. The second replication process occurs when host cellular DNA polymerase replicates the integrated viral DNA. Lastly, RNA polymerase II transcribes the proviral DNA into RNA, which will be packed into virions. Mutation can occur during one or all of these replication steps.[22]

Reverse transcriptase has a high error rate when transcribing RNA into DNA since, unlike most other DNA polymerases, it has no proofreading ability. This high error rate allows mutations to accumulate at an accelerated rate relative to proofread forms of replication. The commercially available reverse transcriptases produced by Promega are quoted by their manuals as having error rates in the range of 1 in 17,000 bases for AMV and 1 in 30,000 bases for M-MLV.[23]

Other than creating single-nucleotide polymorphisms, reverse transcriptases have also been shown to be involved in processes such as transcript fusions, exon shuffling and creating artificial antisense transcripts.[24] [25] It has been speculated that this template switching activity of reverse transcriptase, which can be demonstrated completely in vivo, may have been one of the causes for finding several thousand unannotated transcripts in the genomes of model organisms.[26]

Template switching

Two RNA genomes are packaged into each retrovirus particle, but, after an infection, each virus generates only one provirus.[27] After infection, reverse transcription is accompanied by template switching between the two genome copies (copy choice recombination).[27] There are two models that suggest why RNA transcriptase switches templates. The first, the forced copy-choice model, proposes that reverse transcriptase changes the RNA template when it encounters a nick, implying that recombination is obligatory to maintaining virus genome integrity. The second, the dynamic choice model, suggests that reverse transcriptase changes templates when the RNAse function and the polymerase function are not in sync rate-wise, implying that recombination occurs at random and is not in response to genomic damage. A study by Rawson et al. supported both models of recombination. From 5 to 14 recombination events per genome occur at each replication cycle.[28] Template switching (recombination) appears to be necessary for maintaining genome integrity and as a repair mechanism for salvaging damaged genomes.[29]

Applications

Antiviral drugs

As HIV uses reverse transcriptase to copy its genetic material and generate new viruses (part of a retrovirus proliferation circle), specific drugs have been designed to disrupt the process and thereby suppress its growth. Collectively, these drugs are known as reverse-transcriptase inhibitors and include the nucleoside and nucleotide analogues zidovudine (trade name Retrovir), lamivudine (Epivir) and tenofovir (Viread), as well as non-nucleoside inhibitors, such as nevirapine (Viramune).

Molecular biology

Reverse transcriptase is commonly used in research to apply the polymerase chain reaction technique to RNA in a technique called reverse transcription polymerase chain reaction (RT-PCR). The classical PCR technique can be applied only to DNA strands, but, with the help of reverse transcriptase, RNA can be transcribed into DNA, thus making PCR analysis of RNA molecules possible. Reverse transcriptase is used also to create cDNA libraries from mRNA. The commercial availability of reverse transcriptase greatly improved knowledge in the area of molecular biology, as, along with other enzymes, it allowed scientists to clone, sequence, and characterise RNA.

See also

External links

Notes and References

  1. Crick F . Central dogma of molecular biology . Nature . 227 . 5258 . 561–3 . August 1970 . 4913914 . 10.1038/227561a0 . 4164029 . 1970Natur.227..561C .
  2. Book: Sarkar S . The Philosophy and History of Molecular Biology: New Perspectives . 1996 . Kluwer Academic Publishers . Dordrecht . 187–232.
  3. Danchin É, Pocheville A, Rey O, Pujol B, Blanchet S . Epigenetically facilitated mutational assimilation: epigenetics as a hub within the inclusive evolutionary synthesis . Biological Reviews . 2019 . 94 . 1 . 259–282 . 10.1111/brv.12453 . 6378602. 67861162 . free .
  4. Temin HM, Mizutani S . RNA-dependent DNA polymerase in virions of Rous sarcoma virus . Nature . 226 . 5252 . 1211–3 . June 1970 . 4316301 . 10.1038/2261211a0 . 4187764 .
  5. Baltimore D . RNA-dependent DNA polymerase in virions of RNA tumour viruses . Nature . 226 . 5252 . 1209–11 . June 1970 . 4316300 . 10.1038/2261209a0 . 4222378 .
  6. Ferris AL, Hizi A, Showalter SD, Pichuantes S, Babe L, Craik CS, Hughes SH . Immunologic and proteolytic analysis of HIV-1 reverse transcriptase structure . Virology . 175 . 2 . 456–64 . April 1990 . 1691562 . 10.1016/0042-6822(90)90430-y .
  7. Konishi A, Yasukawa K, Inouye K . Improving the thermal stability of avian myeloblastosis virus reverse transcriptase α-subunit by site-directed mutagenesis . Biotechnology Letters . 34 . 7 . 1209–15 . July 2012 . 22426840 . 10.1007/s10529-012-0904-9 . 2433/157247 . 207096569 . free .
  8. Autexier C, Lue NF . The structure and function of telomerase reverse transcriptase . Annual Review of Biochemistry . 75 . 1 . 493–517 . June 2006 . 16756500 . 10.1146/annurev.biochem.75.103004.142412 .
  9. http://www.bio-medicine.org/biology-definition/Retrovirus/ Bio-Medicine.org - Retrovirus
  10. Book: Telesnitsky A, Goff SP . Skalka MA, Goff SP . Reverse transcriptase. 1st . Cold Spring Harbor. New York . 1993 . Strong-stop strand transfer during reverse transcription . 49. 978-0-87969-382-4 .
  11. Book: Bernstein A, Weiss R, Tooze J . Molecular Biology of Tumor Viruses . 2nd. Cold Spring Harbor Laboratory . Cold Spring Harbor, N.Y. . 1985 . RNA tumor viruses .
  12. Moelling K, Broecker F . The reverse transcriptase-RNase H: from viruses to antiviral defense . Annals of the New York Academy of Sciences . 1341 . 1. 126–35 . April 2015 . 25703292 . 10.1111/nyas.12668 . 2015NYASA1341..126M . 42378727 .
  13. Web site: Gary E. . Kaiser . vanc . The Life Cycle of HIV . Doc Kaiser's Microbiology Home Page . https://web.archive.org/web/20100726222939/http://student.ccbcmd.edu/courses/bio141/lecguide/unit3/viruses/hivlc.html . 2010-07-26 . dead . Community College of Baltimore Count . January 2008 .
  14. Krupkin M, Jackson LN, Ha B, Puglisi EV . Advances in understanding the initiation of HIV-1 reverse transcription . Curr Opin Struct Biol . 65 . 175–183 . Dec 2020 . 32916568 . 10.1016/j.sbi.2020.07.005 . 9973426 . 221636459 .
  15. Book: Krieger M, Scott MP, Matsudaira PT, Lodish HF, Darnell JE, Zipursky L, Kaiser C, Berk A . Molecular cell biology . W.H. Freeman and CO . New York . 2004 . 978-0-7167-4366-8 . registration .
  16. Romashchenko AG, etal . Otdelenie ot preparatov DNK-polimeraz I RNK-zavisimoy DNK-polimeraz; oshistka i svoystva fermenta . . 1977 . 233 . 734–737.
  17. Hurwitz J, Leis JP . RNA-dependent DNA polymerase activity of RNA tumor viruses. I. Directing influence of DNA in the reaction . Journal of Virology . 9 . 1 . 116–29 . January 1972 . 4333538 . 356270 . 10.1128/JVI.9.1.116-129.1972.
  18. News: Arnold . Carrie . vanc . Could Giant Viruses Be the Origin of Life on Earth? . https://web.archive.org/web/20140718130943/http://news.nationalgeographic.com/news/2014/07/140716-giant-viruses-science-life-evolution-origins/ . dead . July 18, 2014 . 29 May 2016 . National Geographic . 17 July 2014.
  19. Hansen JL, Long AM, Schultz SC . Structure of the RNA-dependent RNA polymerase of poliovirus . Structure . 5 . 8 . 1109–22 . August 1997 . 9309225 . 10.1016/S0969-2126(97)00261-X . free .
  20. Schultz SJ, Champoux JJ . RNase H activity: structure, specificity, and function in reverse transcription . Virus Research . 134 . 1–2 . 86–103 . June 2008 . 18261820 . 2464458 . 10.1016/j.virusres.2007.12.007 .
  21. Sarafianos SG, Marchand B, Das K, Himmel DM, Parniak MA, Hughes SH, Arnold E . Structure and function of HIV-1 reverse transcriptase: molecular mechanisms of polymerization and inhibition . Journal of Molecular Biology . 385 . 3 . 693–713 . January 2009 . 19022262 . 2881421 . 10.1016/j.jmb.2008.10.071 .
  22. Book: Bbenek K, Kunkel AT. Skalka MA, Goff PS . Reverse transcriptase . Cold Spring Harbor Laboratory Press . New York . 1993 . The fidelity of retroviral reverse transcriptases . 85 . 978-0-87969-382-4 .
  23. Web site: Promega kit instruction manual . 1999 . https://web.archive.org/web/20061121205121/http://www.promega.com/pnotes/71/7807_22/7807_22_core.pdf . 2006-11-21 . dead .
  24. Houseley J, Tollervey D . Apparent non-canonical trans-splicing is generated by reverse transcriptase in vitro . PLOS ONE . 5 . 8 . e12271 . August 2010 . 20805885 . 2923612 . 10.1371/journal.pone.0012271 . 2010PLoSO...512271H . free .
  25. Zeng XC, Wang SX . Evidence that BmTXK beta-BmKCT cDNA from Chinese scorpion Buthus martensii Karsch is an artifact generated in the reverse transcription process . FEBS Letters . 520 . 1–3 . 183–4; author reply 185 . June 2002 . 12044895 . 10.1016/S0014-5793(02)02812-0 . 24619868 . free .
  26. Response to "The Reality of Pervasive Transcription" . 2011 . van Bakel H, Nislow C, Blencowe BJ, Hughes TR . PLOS Biology . 9 . 7 . e1001102 . 10.1371/journal.pbio.1001102 . 3134445 . free .
  27. Rawson JM, Nikolaitchik OA, Keele BF, Pathak VK, Hu WS . Recombination is required for efficient HIV-1 replication and the maintenance of viral genome integrity . Nucleic Acids Research . 46 . 20 . 10535–10545 . November 2018 . 30307534 . 6237782 . 10.1093/nar/gky910 .
  28. Cromer D, Grimm AJ, Schlub TE, Mak J, Davenport MP . Estimating the in-vivo HIV template switching and recombination rate . AIDS . 30 . 2 . 185–92 . January 2016 . 26691546 . 10.1097/QAD.0000000000000936 . 20086739 . free .
  29. Hu WS, Temin HM . Retroviral recombination and reverse transcription . Science . New York, N.Y. . 250 . 4985 . 1227–33 . November 1990 . 1700865 . 10.1126/science.1700865 . 1990Sci...250.1227H .