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<applet load='3jyt' size='350' color='white' frame='true' align='right' caption='Reverse Transcriptase' scene='Reverse_transcriptase/Initial/1' />
<StructureSection load='3dlk' size='340' side='right' caption='HIV-1 reverse transcriptase P66 subunit (grey) and P51 subunit (green) complex with sulfate [[3dlk]]' scene=''>
Being the protein that gives their name to Retroviruses, Reverse Transcriptase is, in company of [[Hiv protease|Protease]] and [[Hiv integrase|Integrase]], the most important part of the protein system involved in the process of infection of viruses like HIV, MuLV and AMV, and has the unusual property of transcribing ssRNA into dsDNA going against the Central Dogma of Molecular Biology.
Since its discovery in 1970, the study of its properties and mechanisms of action have been of high interest among the scientific community due to the unique properties that makes it an important medical target enzyme and important tool for genetic engineering applications like RT-PCR in the construction of cDNA libraries.


<scene name='Reverse_transcriptase/Presentation/1'><< CBI Molecular Playground Model >></scene>
==Introduction==
[[Reverse transcriptase]] (RT) or '''RNA-dependent DNA polymerase''' transcribes single-stranded RNA into double-stranded [[DNA]].  HIV-1 RT is from the human immunodeficiency virus and is a heterodimer of P66 and P51 subchains. P15 is its RNAse H domain. There are two types of inhibitors for RT: '''NNRTIs''' are the non-nucleoside inhibitors, and '''NRTIs''' are the nucleoside inhibitors. Being the protein that gives their name to Retroviruses, Reverse Transcriptase is, along with [[Hiv protease|Protease]] and Integrase, the most important part of the protein system involved in the process of infection and reproduction for viruses like HIV, MuLV and AMV. RT has the unusual property of transcribing ssRNA into dsDNA going against the Central Dogma of Molecular Biology.
Since its discovery in 1970, the study of its properties and mechanisms of action have been of high interest among the scientific community due to the unique properties that makes it an important medical target enzyme and important tool for genetic engineering applications like RT-PCR in the construction of cDNA libraries.  See also <br />
*[[Transcription and RNA Processing]]<br />
*[[HIV-1 Reverse Transcriptase in Complex with Nevirapine]]<br />
*[[Efavirenz]]<br />
*[[Emtricitabine]]<br />
*[[Efavirenz/emtricitabine/tenofovir]]<br />
*[[Phl p 2]]<br />
*[[Tenofovir disoproxil]]<br />
*[[AZT-resistant HIV-1 reverse transcriptase]]<br />
*[[Catalytic Subunit of T. Castaneum TERT Polymerase]].<br />
*[[Telomerase Reverse Transcriptase]]<br />
*[[Reverse Transcriptase (Hebrew)]]<br />


Reverse Transcriptase is one of the [[CBI Molecules]] being studied in the  [http://www.umass.edu/cbi/ University of Massachusetts Amherst Chemistry-Biology Interface Program] at UMass Amherst (see [[UMass Chem 423 Student Projects 2011-2#HIV Reverse Transcriptase|HIV Reverse Transcriptase (UMass Chem 423 Student Projects 2011-2)]]) and on display at the [http://www.molecularplayground.org/ Molecular Playground]. <scene name='Reverse_transcriptase/Presentation/3' caption='The hand-like two-enzymes-in-one protein that amazingly makes DNA from RNA'>-- CBI Molecular Playground Model --</scene>
{{Clear}}
==Structure==
==Structure==
This ''hand-like'' <scene name='Reverse_transcriptase/Chains/1'>heterodimer</scene> protein that has an usual length of 1000 residues (560 in Chain A and 440 for B), the third of them involved in alpha helical and almost a quarter in beta sheets, showing &alpha;+&beta; <scene name='Reverse_transcriptase/Secondary/1'>secondary structure</scene> domains; <scene name='Reverse_transcriptase/Chaina/1'>Chain A</scene> has an usual weight of 66KDa whereas <scene name='Reverse_transcriptase/Chainb/1'>Chain B</scene> is around 51KDa, those monomers are derived from the same gen but p51 lacks the aminoacids of one active site and has a different tertiary structure conformation compared with p66, for this reason is totally inactive.  [http://www.sciencemag.org.silk.library.umass.edu:2048/cgi/content/abstract/sci;256/5065/1783?maxtoshow=&HITS=10&hits=10&RESULTFORMAT=&andorexacttitleabs=and&andorexactfulltext=and&searchid=1&FIRSTINDEX=0&volume=256&firstpage=1783&resourcetype=HWCIT]
 
This ''hand-like'' <scene name='Reverse_transcriptase/Chains/2'>heterodimer</scene> protein has an usual length of 1000 residues (560 in Chain A (shown in red) and 440 for B (shown in green)), a third of them involved in alpha helices and almost a quarter involved in beta sheets, showing &alpha;+&beta; <scene name='Reverse_transcriptase/Secondary/2'>secondary structure</scene> domains. <scene name='Reverse_transcriptase/Chaina/2'>Chain A</scene> has an usual weight of 66KDa whereas <scene name='Reverse_transcriptase/Chainb/2'>Chain B</scene> is around 51KDa. These monomers are derived from the same gene, but p51 lacks the amino acids of one active site and has a different tertiary structure conformation compared to p66. Because of this, p51 is enzymatically inactive<ref>PMID: 1377403</ref>.
There are five distinct structures within the p66 subchain that are used to describe the functions of RT: the fingers (residues 1–85 and 118–155), the palm (residues 86–117 and 156–236), the thumb (residues 237–318), the connection (319–426), and the RNase H (residues 427-end). The palm contains the main active site (residues 110, 185-186)<ref>PMID: 19022262</ref>.
{{Clear}}


==Function==
==Function==
As a RNA-dependent DNA Polymerase, is able to recognize the initial RNA, transcribe it to ssDNA, cleave the remaining RNA and then build up the dsDNA, to do this the protein has two active catalytic zones. Chain A has the <scene name='Reverse_transcriptase/Fingers/1'>Polymerase active site</scene> that consist of two ''finger-like'' domains, one of them recognizes the initial nucleic acid by h-bonds interactions with phosphate groups of the side chains, then both domains make a conformational change closing the recognition hole to allow the second domain with the support a  <scene name='Reverse_transcriptase/Magnesium/1'>Magnesium ion</scene> coordination system, begin the transcription process adding the specific DNA nucleotides; this change is allowed by a <scene name='Reverse_transcriptase/Flexible/1'>flexible zone</scene> between the two previous domains that is used as a common pharmaceutical target site in order to prevent this change and by this way inhibit the activity, but this one is the only zone of the Chain A that has non-conserved aminoacids giving the virus more drug resistance. [http://consurfdb.tau.ac.il/chain_selection.php?pdb_ID=1JLB]
As the same rate that the polymerization process occurs, the other active site known as the <scene name='Reverse_transcriptase/Rnase/1'>Ribonuclease H domain</scene>, cleaves the RNA releasing the ssDNA that comes again trough the Polymerase active site to become dsDNA (all this with a <scene name='Reverse_transcriptase/Magnesium2/1'>second Magnesium</scene> coordinative system, that allows non-specific recognition, just with phosphates). Finally Chain B despite of the similar aminoacid sequence with Chain A has no enzyme activity, possibly its function is to stabilize and communicate both active sites, this varying the length between them in order to synchronize both functions.
This seems to be the most general idea of the mechanism of action of Reverse Transcriptase, however the process remains unclear and new approaches are being reported. [http://www.nature.com/nature/journal/v453/n7192/full/nature06941.html]


One of the principal issues about this protein comparative with the usual DNA polymerase (besides to the similarity with the Klenow fragment), is the lack of a correction mechanism (usually made by DNA PolIII in the [[User:Karl E. Zahn/RB69 DNA polymerase (GP43)|DNA Polymerase]]) that increase the quota of errors, producing more mutations and by this way giving more facultative and resistance abilities to the virus.
As a RNA-dependent DNA Polymerase, Reverse Transcriptase is able to recognize the initial RNA, transcribe it to ssDNA, cleave the remaining RNA and then build up the dsDNA. To do this the protein has two active catalytic zones. Chain A has the <scene name='Reverse_transcriptase/Fingers/4'>Polymerase active site</scene> that consist of two ''finger-like'' domains: one of them recognizes the initial nucleic acid by h-bond interactions with phosphate groups of the side chains, then both domains make a conformational change closing the recognition hole to allow the second domain with the support a  <scene name='Reverse_transcriptase/Magnesium/2'>Magnesium ion</scene> coordination system to begin the transcription process adding the specific DNA nucleotides. This change is allowed by a <scene name='Reverse_transcriptase/Flexible/2'>flexible zone</scene> between the two previous domains; it is used as a common pharmaceutical target site in order to prevent the change and therefore inhibit activity. This zone is the only zone of Chain A that has non-conserved aminoacids, giving the virus more drug resistance<ref>[http://dx.doi.org/10.1002/ijch.201200096 ConSurf: Using Evolutionary Data to Raise Testable Hypotheses about Protein Function DOI: 10.1002/ijch.201200096]</ref>
[http://consurfdb.tau.ac.il/chain_selection.php?pdb_ID=1JLB Link to Consurf Data Base for PDB Entry: 1JLB].
 
As the same rate that the polymerization process occurs, the other active site known as the <scene name='Reverse_transcriptase/Rnase/2'>Ribonuclease H domain</scene> cleaves RNA, releasing the ssDNA that comes again through the Polymerase active site to become dsDNA (all this with a <scene name='Reverse_transcriptase/Magnesium2/2'>second Magnesium</scene> coordinative system, that allows non-specific recognition, just with phosphates). Finally, Chain B, despite the similar aminoacid sequence with Chain A, has no enzymatic activity; its function is possibly to stabilize and interact with both active sites by varying the length between them in order to synchronize both functions.
This is the most general idea of the mechanism of action of Reverse Transcriptase; however the process remains unclear and new approaches are being reported <ref> PMID:
18464735</ref>.
 
One of the principal issues about this protein compared to usual DNA polymerase (besides to the similarity with the Klenow fragment), is the lack of a correction mechanism (usually made by DNA PolIII in the [[User:Karl E. Zahn/RB69 DNA polymerase (GP43)|DNA Polymerase]]); this deficiency increases the number of errors, producing more mutations and therefore giving more facultative and resistance ability to the virus.
{{Clear}}
 
== 3D Structures of Reverse transcriptase ==
[[Reverse transcriptase 3D structures]]
 
</StructureSection>


==See Also==
==See Also==
Line 20: Line 47:
* Molecule of the Month (09/2002) at [http://www.pdb.org/pdb/static.do?p=education_discussion/molecule_of_the_month/pdb33_1.html RCSB Protein Data Bank]
* Molecule of the Month (09/2002) at [http://www.pdb.org/pdb/static.do?p=education_discussion/molecule_of_the_month/pdb33_1.html RCSB Protein Data Bank]
* List of Reverse Transcriptase articles at [http://www.proteopedia.org/wiki/index.php/Category:Reverse_transcriptase Proteopedia] and at [http://www.pdb.org/pdb/static.do?p=education_discussion/molecule_of_the_month/pdb33_report.html RCSB Protein Data Bank]
* List of Reverse Transcriptase articles at [http://www.proteopedia.org/wiki/index.php/Category:Reverse_transcriptase Proteopedia] and at [http://www.pdb.org/pdb/static.do?p=education_discussion/molecule_of_the_month/pdb33_report.html RCSB Protein Data Bank]
* <scene name='Reverse_transcriptase/Presentation/1'>Model</scene> of Reverse Transcriptase as one of the [[CBI Molecules|CBI Molecules]] on the [http://www.molecularplayground.org Molecular Playground]  
* Model of Reverse Transcriptase as one of the [[CBI Molecules|CBI Molecules]] on the [http://www.molecularplayground.org Molecular Playground]  
 
* See [[Transcription]] for additional Proteopedia articles on the subject.
* For additional information, see: [[Human Immunodeficiency Virus]]
* For additional information, see: [[Transcription and RNA Processing]]
<br />
==References==
==References==
 
<references />
*[1] Kohistaedt, L.A. ''et al''. Science. 256, 1783-1790 (1992) | doi:10.1126/science.1377403
[[Category:Topic Page]]
*[2] Consurf Server Data Base. Evolutionary conservation profile for Reverse Transcriptase PDB file 1JLB <!--accessed November 28, 2009-->
*[3] Abbondanzieri, E.A. ''et al''. Nature 453, 184-189 (2008) | doi:10.1038/nature06941

Latest revision as of 14:05, 21 January 2024


Introduction

Reverse transcriptase (RT) or RNA-dependent DNA polymerase transcribes single-stranded RNA into double-stranded DNA. HIV-1 RT is from the human immunodeficiency virus and is a heterodimer of P66 and P51 subchains. P15 is its RNAse H domain. There are two types of inhibitors for RT: NNRTIs are the non-nucleoside inhibitors, and NRTIs are the nucleoside inhibitors. Being the protein that gives their name to Retroviruses, Reverse Transcriptase is, along with Protease and Integrase, the most important part of the protein system involved in the process of infection and reproduction for viruses like HIV, MuLV and AMV. RT has the unusual property of transcribing ssRNA into dsDNA going against the Central Dogma of Molecular Biology.

Since its discovery in 1970, the study of its properties and mechanisms of action have been of high interest among the scientific community due to the unique properties that makes it an important medical target enzyme and important tool for genetic engineering applications like RT-PCR in the construction of cDNA libraries. See also

Reverse Transcriptase is one of the CBI Molecules being studied in the University of Massachusetts Amherst Chemistry-Biology Interface Program at UMass Amherst (see HIV Reverse Transcriptase (UMass Chem 423 Student Projects 2011-2)) and on display at the Molecular Playground.

Structure

This hand-like protein has an usual length of 1000 residues (560 in Chain A (shown in red) and 440 for B (shown in green)), a third of them involved in alpha helices and almost a quarter involved in beta sheets, showing α+β domains. has an usual weight of 66KDa whereas is around 51KDa. These monomers are derived from the same gene, but p51 lacks the amino acids of one active site and has a different tertiary structure conformation compared to p66. Because of this, p51 is enzymatically inactive[1].

There are five distinct structures within the p66 subchain that are used to describe the functions of RT: the fingers (residues 1–85 and 118–155), the palm (residues 86–117 and 156–236), the thumb (residues 237–318), the connection (319–426), and the RNase H (residues 427-end). The palm contains the main active site (residues 110, 185-186)[2].

Function

As a RNA-dependent DNA Polymerase, Reverse Transcriptase is able to recognize the initial RNA, transcribe it to ssDNA, cleave the remaining RNA and then build up the dsDNA. To do this the protein has two active catalytic zones. Chain A has the that consist of two finger-like domains: one of them recognizes the initial nucleic acid by h-bond interactions with phosphate groups of the side chains, then both domains make a conformational change closing the recognition hole to allow the second domain with the support a coordination system to begin the transcription process adding the specific DNA nucleotides. This change is allowed by a between the two previous domains; it is used as a common pharmaceutical target site in order to prevent the change and therefore inhibit activity. This zone is the only zone of Chain A that has non-conserved aminoacids, giving the virus more drug resistance[3]

Link to Consurf Data Base for PDB Entry: 1JLB.

As the same rate that the polymerization process occurs, the other active site known as the cleaves RNA, releasing the ssDNA that comes again through the Polymerase active site to become dsDNA (all this with a coordinative system, that allows non-specific recognition, just with phosphates). Finally, Chain B, despite the similar aminoacid sequence with Chain A, has no enzymatic activity; its function is possibly to stabilize and interact with both active sites by varying the length between them in order to synchronize both functions.

This is the most general idea of the mechanism of action of Reverse Transcriptase; however the process remains unclear and new approaches are being reported [4].

One of the principal issues about this protein compared to usual DNA polymerase (besides to the similarity with the Klenow fragment), is the lack of a correction mechanism (usually made by DNA PolIII in the DNA Polymerase); this deficiency increases the number of errors, producing more mutations and therefore giving more facultative and resistance ability to the virus.

3D Structures of Reverse transcriptase

Reverse transcriptase 3D structures


HIV-1 reverse transcriptase P66 subunit (grey) and P51 subunit (green) complex with sulfate 3dlk

Drag the structure with the mouse to rotate

See AlsoSee Also


ReferencesReferences

  1. Kohlstaedt LA, Wang J, Friedman JM, Rice PA, Steitz TA. Crystal structure at 3.5 A resolution of HIV-1 reverse transcriptase complexed with an inhibitor. Science. 1992 Jun 26;256(5065):1783-90. PMID:1377403 doi:[http://dx.doi.org/10.1126/science.1377403 http://dx.doi.org/10.1126/science.1377403
  2. 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. J Mol Biol. 2009 Jan 23;385(3):693-713. doi: 10.1016/j.jmb.2008.10.071. Epub 2008, Nov 3. PMID:19022262 doi:http://dx.doi.org/10.1016/j.jmb.2008.10.071
  3. ConSurf: Using Evolutionary Data to Raise Testable Hypotheses about Protein Function DOI: 10.1002/ijch.201200096
  4. Abbondanzieri EA, Bokinsky G, Rausch JW, Zhang JX, Le Grice SF, Zhuang X. Dynamic binding orientations direct activity of HIV reverse transcriptase. Nature. 2008 May 8;453(7192):184-9. PMID:18464735 doi:10.1038/nature06941

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