M13 bacteriophage: Difference between revisions
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{{short description|Species of virus}} |
{{short description|Species of virus}} |
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{{Hatnote|Further information: Ff phages}} |
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{{original research|date=May 2012}} |
{{original research|date=May 2012}} |
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| species = Escherichia virus M13 |
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'''M13''' is one of the [[Ff phages]] (fd and f1 are others), a member of the family [[filamentous bacteriophage]] ([[inovirus]]). Ff phages are composed of circular single-stranded DNA ([[ssDNA]]), which in the case of the m13 phage is 6407 [[nucleotides]] long and is encapsulated in approximately 2700 copies of the [[Phage major coat protein|major coat protein p8]], and capped with about 5 copies each of four different minor coat proteins (p3 and p6 at one end and p7 and p9 at the other end).<ref name=":0">{{cite journal | vauthors = Smeal SW, Schmitt MA, Pereira RR, Prasad A, Fisk JD | title = Simulation of the M13 life cycle I: Assembly of a genetically-structured deterministic chemical kinetic simulation | journal = Virology | volume = 500 | pages = 259–274 | date = January 2017 | pmid = 27644585 | doi = 10.1016/j.virol.2016.08.017 | doi-access = free }}</ref><ref>{{cite journal |vauthors=[[Jasna Rakonjac|Rakonjac J]], Das B, Derda R |date=2016 |title=Editorial: Filamentous Bacteriophage in Bio/Nano/Technology, Bacterial Pathogenesis and Ecology |journal=Frontiers in Microbiology |volume=7 |pages=2109 |doi=10.3389/fmicb.2016.02109 |pmc=5179506 |pmid=28066406 |doi-access=free}}</ref><ref>{{cite journal | vauthors = Roux S, Krupovic M, Daly RA, Borges AL, Nayfach S, Schulz F, Sharrar A, Matheus Carnevali PB, Cheng JF, Ivanova NN, Bondy-Denomy J, Wrighton KC, Woyke T, Visel A, Kyrpides NC, Eloe-Fadrosh EA | display-authors = 6 | title = Cryptic inoviruses revealed as pervasive in bacteria and archaea across Earth's biomes | journal = Nature Microbiology | volume = 4 | issue = 11 | pages = 1895–1906 | date = November 2019 | pmid = 31332386 | pmc = 6813254 | doi = 10.1038/s41564-019-0510-x }}</ref> The minor coat protein p3 attaches to the receptor at the tip of the [[F pilus]] of the host ''[[Escherichia coli]]''. The life cycle is relatively short, with the early phage progeny exiting the cell ten minutes after infection. Ff phages are chronic phage, releasing their progeny without killing the host cells. The infection causes turbid plaques in ''E. coli'' lawns, of intermediate opacity in comparison to regular lysis plaques. However, a decrease in the rate of cell growth is seen in the infected cells. The replicative form of M13 is circular double-stranded DNA similar to [[plasmids]] that are used for many recombinant [[DNA]] processes, and the virus has also been used for [[phage display]], [[directed evolution]], [[nanostructures]] and [[nanotechnology]] applications.<ref>{{cite journal | vauthors = Khalil AS, Ferrer JM, Brau RR, Kottmann ST, Noren CJ, Lang MJ, Belcher AM | title = Single M13 bacteriophage tethering and stretching | journal = Proceedings of the National Academy of Sciences of the United States of America | volume = 104 | issue = 12 | pages = 4892–7 | date = March 2007 | pmid = 17360403 | pmc = 1829235 | doi = 10.1073/pnas.0605727104 | doi-access = free }}</ref><ref>{{cite journal | vauthors = Suthiwangcharoen N, Li T, Li K, Thompson P, You S, Wang Q | title = M13 bacteriophage-polymer nanoassemblies as drug delivery vehicles.|journal= Nano Research | date = May 2011 | volume = 4 | issue = 5 | pages = 483–93 |doi=10.1007/s12274-011-0104-2 | s2cid = 97544776}}</ref><ref>{{cite journal | vauthors = Esvelt KM, Carlson JC, Liu DR | title = A system for the continuous directed evolution of biomolecules | journal = Nature | volume = 472 | issue = 7344 | pages = 499–503 | date = April 2011 | pmid = 21478873 | pmc = 3084352 | doi = 10.1038/nature09929 | bibcode = 2011Natur.472..499E }}</ref> |
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'''M13''' is a [[filamentous phage|filamentous]] [[bacteriophage]] composed of circular single-stranded DNA ([[ssDNA]]) which is 6407 [[nucleotides]] long encapsulated in approximately 2700 copies of the [[Phage major coat protein|major coat protein P8]], and capped with 5 copies of two different minor coat proteins (P9, P6, P3) on the ends.<ref>{{cite journal | vauthors = Opella SJ, Stewart PL, Valentine KG | title = Protein structure by solid-state NMR spectroscopy | journal = Quarterly Reviews of Biophysics | volume = 19 | issue = 1–2 | pages = 7–49 | date = February 1987 | pmid = 3306759 | doi = 10.1017/S0033583500004017 }}</ref> The minor coat protein P3 attaches to the receptor at the tip of the [[F pilus]] of the host ''[[Escherichia coli]]''. |
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The life cycle of M13 is relatively short, with the early phage progeny exiting the cell ten minutes after infection. M13 is a chronic phage, releasing its progeny without killing the host cells. |
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The infection causes turbid plaques in ''E. coli'' lawns, of intermediary opacity in comparison to regular lysis plaques. However, a decrease in the rate of cell growth is seen in the infected cells. M13 [[plasmids]] are used for many recombinant [[DNA]] processes, and the virus has also been used for [[phage display]], [[directed evolution]], [[nanostructures]] and [[nanotechnology]] applications.<ref>{{cite journal | vauthors = Khalil AS, Ferrer JM, Brau RR, Kottmann ST, Noren CJ, Lang MJ, Belcher AM | title = Single M13 bacteriophage tethering and stretching | journal = Proceedings of the National Academy of Sciences of the United States of America | volume = 104 | issue = 12 | pages = 4892–7 | date = March 2007 | pmid = 17360403 | pmc = 1829235 | doi = 10.1073/pnas.0605727104 }}</ref><ref>{{cite journal | vauthors = Suthiwangcharoen N, Li T, Li K, Thompson P, You S, Wang Q | title = M13 bacteriophage-polymer nanoassemblies as drug delivery vehicles. Nano Research | date = May 2011 | volume = 4 | issue = 5 | pages = 483–93 |doi=10.1007/s12274-011-0104-2 }}</ref><ref>{{Cite journal|last1=Esvelt|first1=Kevin M.|last2=Carlson|first2=Jacob C.|last3=Liu|first3=David R.|date=2011-04-28|title=A System for the Continuous Directed Evolution of Biomolecules|journal=Nature|volume=472|issue=7344|pages=499–503|doi=10.1038/nature09929|issn=0028-0836|pmc=3084352|pmid=21478873|bibcode=2011Natur.472..499E}}</ref> |
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==Phage particles== |
==Phage particles== |
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The phage coat is primarily assembled from a 50 [[amino acid]] [[protein]] called |
The phage coat is primarily assembled from a 50 [[amino acid]] [[protein]] called p8, which is encoded by [[gene]] 8 in the phage [[genome]]. For a [[wild type]] M13 particle, it takes approximately 2700 copies of p8 to make the coat about 900 nm long. The coat's dimensions are flexible because the number of p8 copies adjusts to accommodate the size of the single stranded genome it packages.<ref>{{cite journal | vauthors = Sattar S, Bennett NJ, Wen WX, Guthrie JM, Blackwell LF, Conway JF, Rakonjac J | title = Ff-nano, short functionalized nanorods derived from Ff (f1, fd, or M13) filamentous bacteriophage | journal = Frontiers in Microbiology | volume = 6 | pages = 316 | date = 2015 | pmid = 25941520 | pmc = 4403547 | doi = 10.3389/fmicb.2015.00316 | doi-access = free }}</ref> The phage appear to be limited to approximately twice the natural DNA content. However, deletion of a phage protein (p3) prevents full escape from the host ''E. coli'', and phage that are 10-20X the normal length with several copies of the phage genome can be seen shedding from the ''E. coli'' host. |
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At one end of the filament are up to five copies of the surface exposed protein (p9) and a more buried companion protein (p7). If p8 forms the shaft of the phage, p9 and p7 form the "blunt" end that is seen in micrographs. These proteins are very small, containing only 33 and 32 amino acids respectively, though some additional residues can be added to the N-terminal portion of each which are then presented on the outside of the coat. At the other end of the phage particle are five copies of the surface exposed (p3) and its less exposed accessory protein (p6). These form the rounded tip of the phage and are the first proteins to interact with the ''E. coli'' host during infection. Protein p3 is also the last point of contact with the host as a new phage buds from the bacterial surface.<ref name=":03">{{cite journal |vauthors=Smeal SW, Schmitt MA, Pereira RR, Prasad A, Fisk JD |date=January 2017 |title=Simulation of the M13 life cycle I: Assembly of a genetically-structured deterministic chemical kinetic simulation |journal=Virology |volume=500 |pages=259–274 |doi=10.1016/j.virol.2016.08.017 |pmid=27644585 |doi-access=free}}</ref><ref>{{Cite journal |last1=Moon |last2=Choi |last3=Jeong |last4=Sohn |last5=Han |last6=Oh |date=2019-10-11 |title=Research Progress of M13 Bacteriophage-Based Biosensors |journal=Nanomaterials |volume=9 |issue=10 |pages=1448 |doi=10.3390/nano9101448 |pmid=31614669 |pmc=6835900 |issn=2079-4991|doi-access=free }}</ref><ref>{{Cite journal |last1=Haase |first1=Maximilian |last2=Tessmer |first2=Lutz |last3=Köhnlechner |first3=Lilian |last4=Kuhn |first4=Andreas |date=2022-05-27 |title=The M13 Phage Assembly Machine Has a Membrane-Spanning Oligomeric Ring Structure |journal=Viruses |volume=14 |issue=6 |pages=1163 |doi=10.3390/v14061163 |pmid=35746635 |pmc=9228878 |issn=1999-4915|doi-access=free }}</ref> The production of phage particles causes a host cell to grow and divide, but it does not lead to lysis of the cell.<ref name=":03"/> |
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==Replication in ''E. coli''== |
==Replication in ''E. coli''== |
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Entry of the virus into a host cell is mediated by the p3 protein, specifically the N domains, binding to the primary and secondary receptors of the host cell.<ref>{{Cite journal |last1=Bennett |first1=Nicholas J. |last2=Gagic |first2=Dragana |last3=Sutherland-Smith |first3=Andrew J. |last4=Rakonjac |first4=Jasna |date=2011 |title=Characterization of a Dual-Function Domain That Mediates Membrane Insertion and Excision of Ff Filamentous Bacteriophage |url=http://dx.doi.org/10.1016/j.jmb.2011.07.002 |journal=Journal of Molecular Biology |volume=411 |issue=5 |pages=972–985 |doi=10.1016/j.jmb.2011.07.002 |pmid=21763316 |issn=0022-2836}}</ref> After the positive single strand DNA has entered the cell, it is duplicated to form the double stranded DNA that is then used to transcribe the mRNA that will build the proteins.<ref name=":03"/> |
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Below are steps involved with replication of M13 in ''E. coli''. |
Below are steps involved with replication of M13 in ''E. coli''. |
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* [[DNA Gyrase]], a [[type II topoisomerase]], acts on [[dsDNA|double-stranded DNA]] and catalyzes formation of [[DNA supercoil|negative supercoils]] in double-stranded DNA |
* [[DNA Gyrase]], a [[type II topoisomerase]], acts on [[dsDNA|double-stranded DNA]] and catalyzes formation of [[DNA supercoil|negative supercoils]] in double-stranded DNA |
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* Final product is parental replicative form (RF) DNA |
* Final product is parental replicative form (RF) DNA |
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* Transcription and translation of the viral genome begins with p2. |
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* |
* The phage protein, p2, nicks the (+) strand in the RF |
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* 3'-hydroxyl acts as a primer in the creation of new viral strand |
* 3'-hydroxyl acts as a primer in the creation of new viral strand |
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* |
* p2 circularizes displaced viral (+) strand DNA |
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* |
* A pool of progeny double-stranded RF molecules is produced |
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* Negative strand of RF is template of transcription |
* Negative strand of RF is template of transcription |
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* mRNAs are translated into the phage proteins |
* mRNAs are translated into the phage proteins |
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Phage proteins in the cytoplasm are |
Phage proteins in the cytoplasm are p2, p10 and p5, and they are part of the replication process of DNA. The other phage proteins are synthesized and inserted into the cytoplasmic or outer membranes. |
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* |
* p5 dimers bind newly synthesized single-stranded DNA and prevent conversion to RF DNA. The timing and attenuation of p5 translation is essential. |
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* RF DNA synthesis continues and amount of |
* RF DNA synthesis continues and amount of p5 reaches critical concentration |
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* DNA replication switches to synthesis of single-stranded (+) viral DNA |
* DNA replication switches to synthesis of single-stranded (+) viral DNA |
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* |
* p5-DNA structures from about 800 nm long and 8 nm in diameter |
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* |
* p5-DNA complex is substrate in phage assembly reaction |
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Unusually, the major coat protein can insert post-translation into membranes, even those lacking translocation structures, and even into [[liposome]]s with no protein content.<ref name="Rapoport-et-al-1996">{{cite journal | vauthors = Rapoport TA, Jungnickel B, Kutay U | title = Protein transport across the eukaryotic endoplasmic reticulum and bacterial inner membranes | journal = Annual Review of Biochemistry | volume = 65 | issue = 1 | pages = 271–303 | year = 1996 | pmid = 8811181 | doi = 10.1146/annurev.bi.65.070196.001415 | publisher = [[Annual Reviews (publisher)|Annual Reviews]] }}</ref> |
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==Research== |
==Research== |
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⚫ | [[George Smith (chemist)|George Smith]], among others, showed that fragments of EcoRI [[endonuclease]] could be fused in the unique Bam site of f1 filamentous phage and thereby expressed in gene 3 whose protein p3 was externally accessible. M13 does not have this unique Bam site in gene 3. M13 had to be engineered to have accessible insertion sites, making it limited in its flexibility in handling different sized inserts. Because the M13 phage display system allows great flexibility in the location and number of recombinant proteins on the phage, it is a popular tool to construct or serve as a scaffold for nanostructures.<ref name="pmid16178252">{{cite journal | vauthors = Huang Y, Chiang CY, Lee SK, Gao Y, Hu EL, De Yoreo J, Belcher AM | title = Programmable assembly of nanoarchitectures using genetically engineered viruses | journal = Nano Letters | volume = 5 | issue = 7 | pages = 1429–34 | date = July 2005 | pmid = 16178252 | doi = 10.1021/nl050795d | bibcode = 2005NanoL...5.1429H }}</ref> For example, the phage can be engineered to have a different protein on each end and along its length. This can be used to assemble structures like gold or cobalt oxide nano-wires for batteries<ref>{{cite journal | vauthors = Nam KT, Kim DW, Yoo PJ, Chiang CY, Meethong N, Hammond PT, Chiang YM, Belcher AM | display-authors = 6 | title = Virus-enabled synthesis and assembly of nanowires for lithium ion battery electrodes | journal = Science | volume = 312 | issue = 5775 | pages = 885–8 | date = May 2006 | pmid = 16601154 | doi = 10.1126/science.1122716 | bibcode = 2006Sci...312..885N | s2cid = 5105315 }}</ref> or to pack carbon nanotubes into straight bundles for use in photovoltaics.<ref>{{cite journal | vauthors = Dang X, Yi H, Ham MH, Qi J, Yun DS, Ladewski R, Strano MS, Hammond PT, Belcher AM | display-authors = 6 | title = Virus-templated self-assembled single-walled carbon nanotubes for highly efficient electron collection in photovoltaic devices | journal = Nature Nanotechnology | volume = 6 | issue = 6 | pages = 377–84 | date = April 2011 | pmid = 21516089 | doi = 10.1038/nnano.2011.50 | bibcode = 2011NatNa...6..377D }}</ref> The M13 capsid is also the first intact virus structure to ever be solved entirely by [[Solid-state nuclear magnetic resonance|solid state NMR]].<ref>{{cite journal | vauthors = Morag O, Sgourakis NG, Baker D, Goldbourt A | title = The NMR–Rosetta capsid model of M13 bacteriophage reveals a quadrupled hydrophobic packing epitope | journal = Proceedings of the National Academy of Sciences | volume = 112 | issue = 4 | pages = 971-976 | date = January 2015 | pmid = 25587134 | doi = 10.1073/pnas.1415393112 | pmc = 4313819 }}</ref> |
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George Smith, among others, showed that fragments of EcoRI [[endonuclease]] could be fused in the unique Bam site of f1 filamentous phage and thereby expressed in gene III whose protein pIII was externally accessible. M13 does not have this unique Bam site in gene III. |
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M13 had to be engineered to have accessible insertion sites, making it limited in its flexibility in handling different sized inserts. |
|||
⚫ | Because the M13 phage display system allows great flexibility in the location and number of recombinant proteins on the phage, it is a popular tool to construct or serve as a scaffold for nanostructures.<ref name="pmid16178252">{{cite journal | vauthors = Huang Y, Chiang CY, Lee SK, Gao Y, Hu EL, De Yoreo J, Belcher AM | title = Programmable assembly of nanoarchitectures using genetically engineered viruses | journal = Nano Letters | volume = 5 | issue = 7 | pages = 1429–34 | date = July 2005 | pmid = 16178252 | doi = 10.1021/nl050795d | bibcode = 2005NanoL...5.1429H }}</ref> For example, the phage can be engineered to have a different protein on each end and along its length. This can be used to assemble structures like gold or cobalt oxide nano-wires for batteries<ref>{{cite journal | vauthors = Nam KT, Kim DW, Yoo PJ, Chiang CY, Meethong N, Hammond PT, Chiang YM, Belcher AM | display-authors = 6 | title = Virus-enabled synthesis and assembly of nanowires for lithium ion battery electrodes | journal = Science | volume = 312 | issue = 5775 | pages = 885–8 | date = May 2006 | pmid = 16601154 | doi = 10.1126/science.1122716 | bibcode = 2006Sci...312..885N }}</ref> or to pack carbon nanotubes into straight bundles for use in photovoltaics.<ref>{{cite journal | vauthors = Dang X, Yi H, Ham MH, Qi J, Yun DS, Ladewski R, Strano MS, Hammond PT, Belcher AM | display-authors = 6 | title = Virus-templated self-assembled single-walled carbon nanotubes for highly efficient electron collection in photovoltaic devices | journal = Nature Nanotechnology | volume = 6 | issue = 6 | pages = 377–84 | date = April 2011 | pmid = 21516089 | doi = 10.1038/nnano.2011.50 | bibcode = 2011NatNa...6..377D }}</ref> |
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== See also == |
== See also == |
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== Further reading == |
== Further reading == |
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{{refbegin}} |
{{refbegin}} |
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* {{cite book | title = Phage Display: A Laboratory Manual | edition = 1st | |
* {{cite book | title = Phage Display: A Laboratory Manual | edition = 1st | vauthors = Barbas CF, Burton DR, Silverman GJ | publisher = Cold Spring Harbor Laboratory Press | date = October 2004 | isbn = 978-0-87969-740-2 }} |
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* {{cite book | pmid = 8220775 | vauthors = Messing J | publication-date = 1993 | year = 1993 | editor = Griffin H.G. | editor2 = Griffin A.M. | title = DNA Sequencing Protocols. Methods in Molecular Biology™ |
* {{cite book | pmid = 8220775 | vauthors = Messing J | publication-date = 1993 | year = 1993 | editor = Griffin H.G. | editor2 = Griffin A.M. | title = DNA Sequencing Protocols. Methods in Molecular Biology™ | volume = 23 | pages = 9–22 | doi = 10.1385/0-89603-248-5:9 | chapter = M13 Cloning Vehicles | publisher = Humana Press | isbn = 0-89603-248-5 | chapter-url = http://www.blogsua.com/pdf/dna-sequencing-protocols.pdf | chapter-format = large 21mb file | url-status = usurped | archive-url = https://web.archive.org/web/20120219073524/http://www.blogsua.com/pdf/dna-sequencing-protocols.pdf | archive-date = 2012-02-19 }} |
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{{refend}} |
{{refend}} |
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{{Taxonbar}} |
{{Taxonbar|from=Q625347}} |
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{{DEFAULTSORT:M13 Bacteriophage}} |
{{DEFAULTSORT:M13 Bacteriophage}} |
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[[Category:Inoviridae]] |
[[Category:Inoviridae]] |
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[[Category:Bacteriophages]] |
Latest revision as of 03:03, 14 November 2024
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|
Escherichia virus M13 | |
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Blue: Coat Protein pIII; Brown: Coat Protein pVI; Red: Coat Protein pVII; Limegreen: Coat Protein pVIII; Fuchsia: Coat Protein pIX; Purple: Single Stranded DNA | |
Virus classification | |
(unranked): | Virus |
Realm: | Monodnaviria |
Kingdom: | Loebvirae |
Phylum: | Hofneiviricota |
Class: | Faserviricetes |
Order: | Tubulavirales |
Family: | Inoviridae |
Genus: | Inovirus |
Species: | Escherichia virus M13
|
M13 is one of the Ff phages (fd and f1 are others), a member of the family filamentous bacteriophage (inovirus). Ff phages are composed of circular single-stranded DNA (ssDNA), which in the case of the m13 phage is 6407 nucleotides long and is encapsulated in approximately 2700 copies of the major coat protein p8, and capped with about 5 copies each of four different minor coat proteins (p3 and p6 at one end and p7 and p9 at the other end).[1][2][3] The minor coat protein p3 attaches to the receptor at the tip of the F pilus of the host Escherichia coli. The life cycle is relatively short, with the early phage progeny exiting the cell ten minutes after infection. Ff phages are chronic phage, releasing their progeny without killing the host cells. The infection causes turbid plaques in E. coli lawns, of intermediate opacity in comparison to regular lysis plaques. However, a decrease in the rate of cell growth is seen in the infected cells. The replicative form of M13 is circular double-stranded DNA similar to plasmids that are used for many recombinant DNA processes, and the virus has also been used for phage display, directed evolution, nanostructures and nanotechnology applications.[4][5][6]
Phage particles
[edit]The phage coat is primarily assembled from a 50 amino acid protein called p8, which is encoded by gene 8 in the phage genome. For a wild type M13 particle, it takes approximately 2700 copies of p8 to make the coat about 900 nm long. The coat's dimensions are flexible because the number of p8 copies adjusts to accommodate the size of the single stranded genome it packages.[7] The phage appear to be limited to approximately twice the natural DNA content. However, deletion of a phage protein (p3) prevents full escape from the host E. coli, and phage that are 10-20X the normal length with several copies of the phage genome can be seen shedding from the E. coli host.
At one end of the filament are up to five copies of the surface exposed protein (p9) and a more buried companion protein (p7). If p8 forms the shaft of the phage, p9 and p7 form the "blunt" end that is seen in micrographs. These proteins are very small, containing only 33 and 32 amino acids respectively, though some additional residues can be added to the N-terminal portion of each which are then presented on the outside of the coat. At the other end of the phage particle are five copies of the surface exposed (p3) and its less exposed accessory protein (p6). These form the rounded tip of the phage and are the first proteins to interact with the E. coli host during infection. Protein p3 is also the last point of contact with the host as a new phage buds from the bacterial surface.[8][9][10] The production of phage particles causes a host cell to grow and divide, but it does not lead to lysis of the cell.[8]
Replication in E. coli
[edit]Entry of the virus into a host cell is mediated by the p3 protein, specifically the N domains, binding to the primary and secondary receptors of the host cell.[11] After the positive single strand DNA has entered the cell, it is duplicated to form the double stranded DNA that is then used to transcribe the mRNA that will build the proteins.[8]
Below are steps involved with replication of M13 in E. coli.
- Viral (+) strand DNA enters cytoplasm
- Complementary (-) strand is synthesized by bacterial enzymes
- DNA Gyrase, a type II topoisomerase, acts on double-stranded DNA and catalyzes formation of negative supercoils in double-stranded DNA
- Final product is parental replicative form (RF) DNA
- Transcription and translation of the viral genome begins with p2.
- The phage protein, p2, nicks the (+) strand in the RF
- 3'-hydroxyl acts as a primer in the creation of new viral strand
- p2 circularizes displaced viral (+) strand DNA
- A pool of progeny double-stranded RF molecules is produced
- Negative strand of RF is template of transcription
- mRNAs are translated into the phage proteins
Phage proteins in the cytoplasm are p2, p10 and p5, and they are part of the replication process of DNA. The other phage proteins are synthesized and inserted into the cytoplasmic or outer membranes.
- p5 dimers bind newly synthesized single-stranded DNA and prevent conversion to RF DNA. The timing and attenuation of p5 translation is essential.
- RF DNA synthesis continues and amount of p5 reaches critical concentration
- DNA replication switches to synthesis of single-stranded (+) viral DNA
- p5-DNA structures from about 800 nm long and 8 nm in diameter
- p5-DNA complex is substrate in phage assembly reaction
Unusually, the major coat protein can insert post-translation into membranes, even those lacking translocation structures, and even into liposomes with no protein content.[12]
Research
[edit]George Smith, among others, showed that fragments of EcoRI endonuclease could be fused in the unique Bam site of f1 filamentous phage and thereby expressed in gene 3 whose protein p3 was externally accessible. M13 does not have this unique Bam site in gene 3. M13 had to be engineered to have accessible insertion sites, making it limited in its flexibility in handling different sized inserts. Because the M13 phage display system allows great flexibility in the location and number of recombinant proteins on the phage, it is a popular tool to construct or serve as a scaffold for nanostructures.[13] For example, the phage can be engineered to have a different protein on each end and along its length. This can be used to assemble structures like gold or cobalt oxide nano-wires for batteries[14] or to pack carbon nanotubes into straight bundles for use in photovoltaics.[15] The M13 capsid is also the first intact virus structure to ever be solved entirely by solid state NMR.[16]
See also
[edit]References
[edit]- ^ Smeal SW, Schmitt MA, Pereira RR, Prasad A, Fisk JD (January 2017). "Simulation of the M13 life cycle I: Assembly of a genetically-structured deterministic chemical kinetic simulation". Virology. 500: 259–274. doi:10.1016/j.virol.2016.08.017. PMID 27644585.
- ^ Rakonjac J, Das B, Derda R (2016). "Editorial: Filamentous Bacteriophage in Bio/Nano/Technology, Bacterial Pathogenesis and Ecology". Frontiers in Microbiology. 7: 2109. doi:10.3389/fmicb.2016.02109. PMC 5179506. PMID 28066406.
- ^ Roux S, Krupovic M, Daly RA, Borges AL, Nayfach S, Schulz F, et al. (November 2019). "Cryptic inoviruses revealed as pervasive in bacteria and archaea across Earth's biomes". Nature Microbiology. 4 (11): 1895–1906. doi:10.1038/s41564-019-0510-x. PMC 6813254. PMID 31332386.
- ^ Khalil AS, Ferrer JM, Brau RR, Kottmann ST, Noren CJ, Lang MJ, Belcher AM (March 2007). "Single M13 bacteriophage tethering and stretching". Proceedings of the National Academy of Sciences of the United States of America. 104 (12): 4892–7. doi:10.1073/pnas.0605727104. PMC 1829235. PMID 17360403.
- ^ Suthiwangcharoen N, Li T, Li K, Thompson P, You S, Wang Q (May 2011). "M13 bacteriophage-polymer nanoassemblies as drug delivery vehicles". Nano Research. 4 (5): 483–93. doi:10.1007/s12274-011-0104-2. S2CID 97544776.
- ^ Esvelt KM, Carlson JC, Liu DR (April 2011). "A system for the continuous directed evolution of biomolecules". Nature. 472 (7344): 499–503. Bibcode:2011Natur.472..499E. doi:10.1038/nature09929. PMC 3084352. PMID 21478873.
- ^ Sattar S, Bennett NJ, Wen WX, Guthrie JM, Blackwell LF, Conway JF, Rakonjac J (2015). "Ff-nano, short functionalized nanorods derived from Ff (f1, fd, or M13) filamentous bacteriophage". Frontiers in Microbiology. 6: 316. doi:10.3389/fmicb.2015.00316. PMC 4403547. PMID 25941520.
- ^ a b c Smeal SW, Schmitt MA, Pereira RR, Prasad A, Fisk JD (January 2017). "Simulation of the M13 life cycle I: Assembly of a genetically-structured deterministic chemical kinetic simulation". Virology. 500: 259–274. doi:10.1016/j.virol.2016.08.017. PMID 27644585.
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Further reading
[edit]- Barbas CF, Burton DR, Silverman GJ (October 2004). Phage Display: A Laboratory Manual (1st ed.). Cold Spring Harbor Laboratory Press. ISBN 978-0-87969-740-2.
- Messing J (1993). "M13 Cloning Vehicles" (PDF). In Griffin H.G., Griffin A.M. (eds.). DNA Sequencing Protocols. Methods in Molecular Biology™. Vol. 23. Humana Press. pp. 9–22. doi:10.1385/0-89603-248-5:9. ISBN 0-89603-248-5. PMID 8220775. Archived from the original on 2012-02-19.
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