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Rolling circle replication

February 16, 2024

Rolling circle replication (RCR) is a process of unidirectional nucleic acid replication that can rapidly synthesize multiple copies of circular molecules of DNA or RNA, such as plasmids, the genomes of bacteriophages, and the circular RNA genome of viroids. Some eukaryotic viruses also replicate their DNA or RNA via the rolling circle mechanism.

Rolling circle replication produces multiple copies of a single circular template.

As a simplified version of natural rolling circle replication, an isothermal DNA amplification technique, rolling circle amplification was developed. The RCA mechanism is widely used in molecular biology and biomedical nanotechnology, especially in the field of biosensing (as a method of signal amplification).[1]

Circular DNA replication edit

 
Illustration of rolling circle replication.

Rolling circle DNA replication is initiated by an initiator protein encoded by the plasmid or bacteriophage DNA, which nicks one strand of the double-stranded, circular DNA molecule at a site called the double-strand origin, or DSO. The initiator protein remains bound to the 5' phosphate end of the nicked strand, and the free 3' hydroxyl end is released to serve as a primer for DNA synthesis by DNA polymerase III. Using the unnicked strand as a template, replication proceeds around the circular DNA molecule, displacing the nicked strand as single-stranded DNA. Displacement of the nicked strand is carried out by a host-encoded helicase called PcrA (the abbreviation standing for plasmid copy reduced) in the presence of the plasmid replication initiation protein.

Continued DNA synthesis can produce multiple single-stranded linear copies of the original DNA in a continuous head-to-tail series called a concatemer. These linear copies can be converted to double-stranded circular molecules through the following process:

First, the initiator protein makes another nick in the DNA to terminate synthesis of the first (leading) strand. RNA polymerase and DNA polymerase III then replicate the single-stranded origin (SSO) DNA to make another double-stranded circle. DNA polymerase I removes the primer, replacing it with DNA, and DNA ligase joins the ends to make another molecule of double-stranded circular DNA.

As a summary, a typical DNA rolling circle replication has five steps:[2]

  1. Circular dsDNA will be "nicked".
  2. The 3' end is elongated using "unnicked" DNA as leading strand (template); 5' end is displaced.
  3. Displaced DNA is a lagging strand and is made double stranded via a series of Okazaki fragments.
  4. Replication of both "unnicked" and displaced ssDNA.
  5. Displaced DNA circularizes.

Virology edit

Replication of viral DNA edit

Some DNA viruses replicate their genomic information in host cells via rolling circle replication. For instance, human herpesvirus-6 (HHV-6)(hibv) expresses a set of "early genes" that are believed to be involved in this process.[3] The long concatemers that result are subsequently cleaved between the pac-1 and pac-2 regions of HHV-6's genome by ribozymes when it is packaged into individual virions.[4]

 
A model for HPV16 rolling circle replication.

Human Papillomavirus-16 (HPV-16) is another virus that employs rolling replication to produce progeny at a high rate. HPV-16 infects human epithelial cells and has a double stranded circular genome. During replication, at the origin, the E1 hexamer wraps around the single strand DNA and moves in the 3' to 5' direction. In normal bidirectional replication, the two replication proteins will disassociate at time of collision, but in HPV-16 it is believed that the E1 hexamer does not disassociate, hence leading to a continuous rolling replication. It is believed that this replication mechanism of HPV may have physiological implications into the integration of the virus into the host chromosome and eventual progression into cervical cancer.[5]

In addition, geminivirus also utilizes rolling circle replication as its replication mechanism. It is a virus that is responsible for destroying many major crops, such as cassava, cotton, legumes, maize, tomato and okra. The virus has a circular, single stranded, DNA that replicates in host plant cells. The entire process is initiated by the geminiviral replication initiator protein, Rep, which is also responsible for altering the host environment to act as part of the replication machinery. Rep is also strikingly similar to most other rolling replication initiator proteins of eubacteria, with the presence of motifs I, II, and III at is N terminus. During the rolling circle replication, the ssDNA of geminivirus is converted to dsDNA and Rep is then attached to the dsDNA at the origin sequence TAATATTAC. After Rep, along with other replication proteins, binds to the dsDNA it forms a stem loop where the DNA is then cleaved at the nanomer sequence causing a displacement of the strand. This displacement allows the replication fork to progress in the 3’ to 5’ direction which ultimately yields a new ssDNA strand and a concatameric DNA strand.[6]

Bacteriophage T4 DNA replication intermediates include circular and branched circular concatemeric structures.[7] These structures likely reflect a rolling circle mechanism of replication.

Replication of viral RNA edit

Some RNA viruses and viroids also replicate their genome through rolling circle RNA replication. For viroids, there are two alternative RNA replication pathways that respectively followed by members of the family Pospivirodae (asymmetric replication) and Avsunviroidae (symmetric replication).

 
Rolling circle replication of viral RNA

In the family Pospiviroidae (PSTVd-like), the circular plus strand RNA is transcribed by a host RNA polymerase into oligomeric minus strands and then oligomeric plus strands.[8] These oligomeric plus strands are cleaved by a host RNase and ligated by a host RNA ligase to reform the monomeric plus strand circular RNA. This is called the asymmetric pathway of rolling circle replication. The viroids in the family Avsunviroidae (ASBVd-like) replicate their genome through the symmetric pathway of rolling circle replication.[9] In this symmetric pathway, oligomeric minus strands are first cleaved and ligated to form monomeric minus strands, and then are transcribed into oligomeric plus strands. These oligomeric plus strands are then cleaved and ligated to reform the monomeric plus strand. The symmetric replication pathway was named because both plus and minus strands are produced the same way.

Cleavage of the oligomeric plus and minus strands is mediated by the self-cleaving hammerhead ribozyme structure present in the Avsunviroidae, but such structure is absent in the Pospiviroidae.[10]

Rolling circle amplification edit

 
The molecular mechanism of Rolling Circle Amplification (RCA)

The derivative form of rolling circle replication has been successfully used for amplification of DNA from very small amounts of starting material.[1] This amplification technique is named as Rolling circle amplification (RCA). Different from conventional DNA amplification techniques such as polymerase chain reaction (PCR), RCA is an isothermal nucleic acid amplification technique where the polymerase continuously adds single nucleotides to a primer annealed to a circular template which results in a long concatemer ssDNA that contains tens to hundreds of tandem repeats (complementary to the circular template).[11]

There are five important components required for performing a RCA reaction:

  1. A DNA polymerase
  2. A suitable buffer that is compatible with the polymerase.
  3. A short DNA or RNA primer
  4. A circular DNA template
  5. Deoxynucleotide triphosphates (dNTPs)
 
The detection methods of RCA product

The polymerases used in RCA are Phi29, Bst, and Vent exo-DNA polymerase for DNA amplification, and T7 RNA polymerase for RNA amplification. Since Phi29 DNA polymerase has the best processivity and strand displacement ability among all aforementioned polymerases, it has been most frequently used in RCA reactions. Different from polymerase chain reaction (PCR), RCA can be conducted at a constant temperature (room temperature to 65C) in both free solution and on top of immobilized targets (solid phase amplification).

There are typically three steps involved in a DNA RCA reaction:

  1. Circular template ligation, which can be conducted via template mediated enzymatic ligation (e.g., T4 DNA ligase) or template-free ligation using special DNA ligases (i.e., CircLigase).
  2. Primer-induced single-strand DNA elongation. Multiple primers can be employed to hybridize with the same circle. As a result, multiple amplification events can be initiated, producing multiple RCA products ("Multiprimed RCA").
  3. Amplification product detection and visualization, which is most commonly conducted through fluorescent detection, with fluorophore-conjugated dNTP, fluorophore-tethered complementary or fluorescently-labeled molecular beacons. In addition to the fluorescent approaches, gel electrophoresis is also widely used for the detection of RCA product.

RCA produces a linear amplification of DNA, as each circular template grows at a given speed for a certain amount of time. To increase yield and achieve exponential amplification as PCR does, several approaches have been investigated. One of them is the hyperbranched rolling circle amplification or HRCA, where primers that anneal to the original RCA products are added, and also extended.[12] In this way the original RCA creates more template that can be amplified. Another is circle to circle amplification or C2CA, where the RCA products are digested with a restriction enzyme and ligated into new circular templates using a restriction oligo, followed by a new round of RCA with a larger amount of circular templates for amplification.[13]

Applications of RCA edit

 
illustration of immuno-RCA

RCA can amplify a single molecular binding event over a thousandfold, making it particularly useful for detecting targets with ultra-low abundance. RCA reactions can be performed in not only free solution environments, but also on a solid surface like glass, micro- or nano-bead, microwell plates, microfluidic devices or even paper strips. This feature makes it a very powerful tool for amplifying signals in solid-phase immunoassays (e.g., ELISA). In this way, RCA is becoming a highly versatile signal amplification tool with wide-ranging applications in genomics, proteomics, diagnosis and biosensing.

Immuno-RCA edit

Immuno-RCA is an isothermal signal amplification method for high-specificity & high-sensitivity protein detection and quantification. This technique combines two fields: RCA, which allows nucleotide amplification, and immunoassay, which uses antibodies specific to intracellular or free biomarkers. As a result, immuno-RCA gives a specific amplified signal (high signal-to-noise ratio), making it suitable for detecting, quantifying and visualizing low abundance proteic markers in liquid-phase immunoassays[14][15][16] and immunohistochemistry.

Immuno-RCA follows a typical immuno-adsorbent reaction in ELISA or immunohistochemistry tissue staining.[17] The detection antibodies used in immuno-RCA reaction are modified by attaching a ssDNA oligonucleotide on the end of the heavy chains. So the Fab (Fragment, antigen binding) section on the detection antibody can still bind to specific antigens and the oligonucleotide can serve as a primer of the RCA reaction.

The typical antibody mediated immuno-RCA procedure is as follows:

 
Illustration of aptamer based immuno-rca

1. A detection antibody recognizes a specific proteic target. This antibody is also attached to an oligonucleotide primer.

2. When circular DNA is present, it is annealed, and the primer matches to the circular DNA complementary sequence.

3. The complementary sequence of the circular DNA template is copied hundreds of times and remains attached to the antibody.

4. RCA output (elongated ssDNA) is detected with fluorescent probes using a fluorescent microscope or a microplate reader.

Aptamer based immuno-RCA[18] edit

In addition to antibody mediated immuno-RCA, the ssDNA RCA primer can be conjugated to the 3' end of a DNA aptamer as well. The primer tail can be amplified through rolling circle amplification. The product can be visualized through the labeling of fluorescent reporter.[19] The process is illustrated in the figure on the right.

Other applications of RCA edit

Various derivatives of RCA were widely used in the field of biosensing. For example, RCA has been successfully used for detecting the existence of viral and bacterial DNA from clinical samples,[20][21] which is very beneficial for rapid diagnostics of infectious diseases. It has also been used as an on-chip signal amplification method for nucleic acid (for both DNA and RNA) microarray assay.[1]

In addition to the amplification function in biosensing applications, RCA technique can be applied to the construction of DNA nanostructures and DNA hydrogels as well. The products of RCA can also be use as templates for periodic assembly of nanospecies or proteins, synthesis of metallic nanowires[22] and formation of nano-islands.[1]

See also edit

References edit

  1. ^ a b c d Ali, M. Monsur; Li, Feng; Zhang, Zhiqing; Zhang, Kaixiang; Kang, Dong-Ku; Ankrum, James A.; Le, X. Chris; Zhao, Weian (2014). "Rolling circle amplification: a versatile tool for chemical biology, materials science and medicine". Chemical Society Reviews. 43 (10): 3324–41. doi:10.1039/C3CS60439J. PMID 24643375.
  2. ^ Demidov, Vadim V, ed. (2016). Rolling Circle Amplification (RCA) - Toward New Clinical | Vadim V. Demidov | Springer. Springer. doi:10.1007/978-3-319-42226-8. ISBN 9783319422244. S2CID 30024718.
  3. ^ Arbuckle, Jesse (2011). "The molecular biology of human herpesvirus-6 latency and telomere integration". Microbes and Infection. 13 (8–9): 731–741. doi:10.1016/j.micinf.2011.03.006. PMC 3130849. PMID 21458587.
  4. ^ Borenstein, Ronen; Frenkel, Niza (2009). "Cloning human herpes virus 6A genome into bacterial artificial chromosomes and study of DNA replication intermediates". Proceedings of the National Academy of Sciences. 106 (45): 19138–19143. Bibcode:2009PNAS..10619138B. doi:10.1073/pnas.0908504106. PMC 2767366. PMID 19858479.
  5. ^ Kusumoto-Matsuo, Rika; Kanda, Tadahito; Kukimoto, Iwao (2011-01-01). "Rolling circle replication of human papillomavirus type 16 DNA in epithelial cell extracts". Genes to Cells. 16 (1): 23–33. doi:10.1111/j.1365-2443.2010.01458.x. ISSN 1365-2443. PMID 21059156. S2CID 30493728.
  6. ^ Rizvi, Irum; Choudhury, Nirupam Roy; Tuteja, Narendra (2015-02-01). "Insights into the functional characteristics of geminivirus rolling-circle replication initiator protein and its interaction with host factors affecting viral DNA replication". Archives of Virology. 160 (2): 375–387. doi:10.1007/s00705-014-2297-7. ISSN 0304-8608. PMID 25449306. S2CID 16502010.
  7. ^ Bernstein H, Bernstein C (July 1973). "Circular and branched circular concatenates as possible intermediates in bacteriophage T4 DNA replication". J. Mol. Biol. 77 (3): 355–61. doi:10.1016/0022-2836(73)90443-9. PMID 4580243.
  8. ^ Daròs, José-Antonio; Elena, Santiago F.; Flores, Ricardo (June 2006). "Viroids: an Ariadne's thread into the RNA labyrinth". EMBO Reports. 7 (6): 593–598. doi:10.1038/sj.embor.7400706. ISSN 1469-221X. PMC 1479586. PMID 16741503.
  9. ^ Tsagris, Efthimia Mina; Martínez de Alba, Ángel Emilio; Gozmanova, Mariyana; Kalantidis, Kriton (2008-11-01). "Viroids". Cellular Microbiology. 10 (11): 2168–2179. doi:10.1111/j.1462-5822.2008.01231.x. ISSN 1462-5822. PMID 18764915.
  10. ^ Flores, Ricardo; Gas, María-Eugenia; Molina-Serrano, Diego; Nohales, María-Ángeles; Carbonell, Alberto; Gago, Selma; De la Peña, Marcos; Daròs, José-Antonio (2009-09-14). "Viroid Replication: Rolling-Circles, Enzymes and Ribozymes". Viruses. 1 (2): 317–334. doi:10.3390/v1020317. PMC 3185496. PMID 21994552.
  11. ^ Ali, M. Monsur; Li, Feng; Zhang, Zhiqing; Zhang, Kaixiang; Kang, Dong-Ku; Ankrum, James A.; Le, X. Chris; Zhao, Weian (2014-05-21). "Rolling circle amplification: a versatile tool for chemical biology, materials science and medicine". Chemical Society Reviews. 43 (10): 3324–3341. doi:10.1039/c3cs60439j. ISSN 1460-4744. PMID 24643375.
  12. ^ Lizardi, Paul M.; Huang, Xiaohua; Zhu, Zhengrong; Bray-Ward, Patricia; Thomas, David C.; Ward, David C. (July 1998). "Mutation detection and single-molecule counting using isothermal rolling-circle amplification". Nature Genetics. 19 (3): 225–232. doi:10.1038/898. ISSN 1546-1718. PMID 9662393. S2CID 21007563.
  13. ^ Dahl, Fredrik; Banér, Johan; Gullberg, Mats; Mendel-Hartvig, Maritha; Landegren, Ulf; Nilsson, Mats (2004-03-30). "Circle-to-circle amplification for precise and sensitive DNA analysis". Proceedings of the National Academy of Sciences. 101 (13): 4548–4553. Bibcode:2004PNAS..101.4548D. doi:10.1073/pnas.0400834101. ISSN 0027-8424. PMC 384784. PMID 15070755.
  14. ^ Schweitzer, Barry; Roberts, Scott; Grimwade, Brian; Shao, Weiping; Wang, Minjuan; Fu, Qin; Shu, Quiping; Laroche, Isabelle; Zhou, Zhimin (April 2002). "Multiplexed protein profiling on microarrays by rolling-circle amplification". Nature Biotechnology. 20 (4): 359–365. doi:10.1038/nbt0402-359. ISSN 1087-0156. PMC 2858761. PMID 11923841.
  15. ^ Zhou, Long; Ou, Li-Juan; Chu, Xia; Shen, Guo-Li; Yu, Ru-Qin (2007). "Aptamer-Based Rolling Circle Amplification: A Platform for Electrochemical Detection of Protein". Analytical Chemistry. 79 (19): 7492–7500. doi:10.1021/ac071059s. PMID 17722881.
  16. ^ Björkesten, Johan; Patil, Sourabh; Fredolini, Claudia; Lönn, Peter; Landegren, Ulf (2020-05-29). "A multiplex platform for digital measurement of circular DNA reaction products". Nucleic Acids Research. 48 (13): gkaa419. doi:10.1093/nar/gkaa419. ISSN 0305-1048. PMC 7367203. PMID 32469060.
  17. ^ Gusev, Y.; Sparkowski, J.; Raghunathan, A.; Ferguson, H.; Montano, J.; Bogdan, N.; Schweitzer, B.; Wiltshire, S.; Kingsmore, S. F. (July 2001). "Rolling circle amplification: a new approach to increase sensitivity for immunohistochemistry and flow cytometry". The American Journal of Pathology. 159 (1): 63–69. doi:10.1016/S0002-9440(10)61674-4. ISSN 0002-9440. PMC 1850404. PMID 11438455.
  18. ^ Zhao, Weian; Ali, M. Monsur; Brook, Michael A.; Li, Yingfu (2008-08-11). "Rolling Circle Amplification: Applications in Nanotechnology and Biodetection with Functional Nucleic Acids". Angewandte Chemie International Edition. 47 (34): 6330–6337. doi:10.1002/anie.200705982. ISSN 1521-3773. PMID 18680110.
  19. ^ Zhou, Long; Ou, Li-Juan; Chu, Xia; Shen, Guo-Li; Yu, Ru-Qin (2007-10-01). "Aptamer-Based Rolling Circle Amplification: A Platform for Electrochemical Detection of Protein". Analytical Chemistry. 79 (19): 7492–7500. doi:10.1021/ac071059s. ISSN 0003-2700. PMID 17722881.
  20. ^ Chen, Xiaoyou; Wang, Bin; Yang, Wen; Kong, Fanrong; Li, Chuanyou; Sun, Zhaogang; Jelfs, Peter; Gilbert, Gwendolyn L. (2014-05-01). "Rolling Circle Amplification for Direct Detection of rpoB Gene Mutations in Mycobacterium tuberculosis Isolates from Clinical Specimens". Journal of Clinical Microbiology. 52 (5): 1540–1548. doi:10.1128/JCM.00065-14. ISSN 0095-1137. PMC 3993705. PMID 24574296.
  21. ^ Liu, Yang; Guo, Yan-Ling; Jiang, Guang-Lu; Zhou, Shi-Jie; Sun, Qi; Chen, Xi; Chang, Xiu-Jun; Xing, Ai-Ying; Du, Feng-Jiao (2013-06-04). "Application of Hyperbranched Rolling Circle Amplification for Direct Detection of Mycobacterium Tuberculosis in Clinical Sputum Specimens". PLOS ONE. 8 (6): e64583. Bibcode:2013PLoSO...864583L. doi:10.1371/journal.pone.0064583. ISSN 1932-6203. PMC 3672175. PMID 23750210.
  22. ^ Guo, Maoxiang; Hernández-Neuta, Iván; Madaboosi, Narayanan; Nilsson, Mats; Wijngaart, Wouter van der (2018-02-12). "Efficient DNA-assisted synthesis of trans-membrane gold nanowires". Microsystems & Nanoengineering. 4: 17084. doi:10.1038/micronano.2017.84. ISSN 2055-7434.

External links edit

February 16, 2024
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This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Rolling circle replication news newspapers books scholar JSTOR November 2017 Learn how and when to remove this template message Rolling circle replication RCR is a process of unidirectional nucleic acid replication that can rapidly synthesize multiple copies of circular molecules of DNA or RNA such as plasmids the genomes of bacteriophages and the circular RNA genome of viroids Some eukaryotic viruses also replicate their DNA or RNA via the rolling circle mechanism Rolling circle replication produces multiple copies of a single circular template As a simplified version of natural rolling circle replication an isothermal DNA amplification technique rolling circle amplification was developed The RCA mechanism is widely used in molecular biology and biomedical nanotechnology especially in the field of biosensing as a method of signal amplification 1 Contents 1 Circular DNA replication 2 Virology 2 1 Replication of viral DNA 2 2 Replication of viral RNA 3 Rolling circle amplification 4 Applications of RCA 4 1 Immuno RCA 4 1 1 Aptamer based immuno RCA 18 4 2 Other applications of RCA 5 See also 6 References 7 External linksCircular DNA replication edit nbsp Illustration of rolling circle replication Rolling circle DNA replication is initiated by an initiator protein encoded by the plasmid or bacteriophage DNA which nicks one strand of the double stranded circular DNA molecule at a site called the double strand origin or DSO The initiator protein remains bound to the 5 phosphate end of the nicked strand and the free 3 hydroxyl end is released to serve as a primer for DNA synthesis by DNA polymerase III Using the unnicked strand as a template replication proceeds around the circular DNA molecule displacing the nicked strand as single stranded DNA Displacement of the nicked strand is carried out by a host encoded helicase called PcrA the abbreviation standing for plasmid copy reduced in the presence of the plasmid replication initiation protein Continued DNA synthesis can produce multiple single stranded linear copies of the original DNA in a continuous head to tail series called a concatemer These linear copies can be converted to double stranded circular molecules through the following process First the initiator protein makes another nick in the DNA to terminate synthesis of the first leading strand RNA polymerase and DNA polymerase III then replicate the single stranded origin SSO DNA to make another double stranded circle DNA polymerase I removes the primer replacing it with DNA and DNA ligase joins the ends to make another molecule of double stranded circular DNA As a summary a typical DNA rolling circle replication has five steps 2 Circular dsDNA will be nicked The 3 end is elongated using unnicked DNA as leading strand template 5 end is displaced Displaced DNA is a lagging strand and is made double stranded via a series of Okazaki fragments Replication of both unnicked and displaced ssDNA Displaced DNA circularizes Virology editReplication of viral DNA edit Some DNA viruses replicate their genomic information in host cells via rolling circle replication For instance human herpesvirus 6 HHV 6 hibv expresses a set of early genes that are believed to be involved in this process 3 The long concatemers that result are subsequently cleaved between the pac 1 and pac 2 regions of HHV 6 s genome by ribozymes when it is packaged into individual virions 4 nbsp A model for HPV16 rolling circle replication Human Papillomavirus 16 HPV 16 is another virus that employs rolling replication to produce progeny at a high rate HPV 16 infects human epithelial cells and has a double stranded circular genome During replication at the origin the E1 hexamer wraps around the single strand DNA and moves in the 3 to 5 direction In normal bidirectional replication the two replication proteins will disassociate at time of collision but in HPV 16 it is believed that the E1 hexamer does not disassociate hence leading to a continuous rolling replication It is believed that this replication mechanism of HPV may have physiological implications into the integration of the virus into the host chromosome and eventual progression into cervical cancer 5 In addition geminivirus also utilizes rolling circle replication as its replication mechanism It is a virus that is responsible for destroying many major crops such as cassava cotton legumes maize tomato and okra The virus has a circular single stranded DNA that replicates in host plant cells The entire process is initiated by the geminiviral replication initiator protein Rep which is also responsible for altering the host environment to act as part of the replication machinery Rep is also strikingly similar to most other rolling replication initiator proteins of eubacteria with the presence of motifs I II and III at is N terminus During the rolling circle replication the ssDNA of geminivirus is converted to dsDNA and Rep is then attached to the dsDNA at the origin sequence TAATATTAC After Rep along with other replication proteins binds to the dsDNA it forms a stem loop where the DNA is then cleaved at the nanomer sequence causing a displacement of the strand This displacement allows the replication fork to progress in the 3 to 5 direction which ultimately yields a new ssDNA strand and a concatameric DNA strand 6 Bacteriophage T4 DNA replication intermediates include circular and branched circular concatemeric structures 7 These structures likely reflect a rolling circle mechanism of replication Replication of viral RNA edit Some RNA viruses and viroids also replicate their genome through rolling circle RNA replication For viroids there are two alternative RNA replication pathways that respectively followed by members of the family Pospivirodae asymmetric replication and Avsunviroidae symmetric replication nbsp Rolling circle replication of viral RNAIn the family Pospiviroidae PSTVd like the circular plus strand RNA is transcribed by a host RNA polymerase into oligomeric minus strands and then oligomeric plus strands 8 These oligomeric plus strands are cleaved by a host RNase and ligated by a host RNA ligase to reform the monomeric plus strand circular RNA This is called the asymmetric pathway of rolling circle replication The viroids in the family Avsunviroidae ASBVd like replicate their genome through the symmetric pathway of rolling circle replication 9 In this symmetric pathway oligomeric minus strands are first cleaved and ligated to form monomeric minus strands and then are transcribed into oligomeric plus strands These oligomeric plus strands are then cleaved and ligated to reform the monomeric plus strand The symmetric replication pathway was named because both plus and minus strands are produced the same way Cleavage of the oligomeric plus and minus strands is mediated by the self cleaving hammerhead ribozyme structure present in the Avsunviroidae but such structure is absent in the Pospiviroidae 10 Rolling circle amplification edit nbsp The molecular mechanism of Rolling Circle Amplification RCA The derivative form of rolling circle replication has been successfully used for amplification of DNA from very small amounts of starting material 1 This amplification technique is named as Rolling circle amplification RCA Different from conventional DNA amplification techniques such as polymerase chain reaction PCR RCA is an isothermal nucleic acid amplification technique where the polymerase continuously adds single nucleotides to a primer annealed to a circular template which results in a long concatemer ssDNA that contains tens to hundreds of tandem repeats complementary to the circular template 11 There are five important components required for performing a RCA reaction A DNA polymerase A suitable buffer that is compatible with the polymerase A short DNA or RNA primer A circular DNA template Deoxynucleotide triphosphates dNTPs nbsp The detection methods of RCA productThe polymerases used in RCA are Phi29 Bst and Vent exo DNA polymerase for DNA amplification and T7 RNA polymerase for RNA amplification Since Phi29 DNA polymerase has the best processivity and strand displacement ability among all aforementioned polymerases it has been most frequently used in RCA reactions Different from polymerase chain reaction PCR RCA can be conducted at a constant temperature room temperature to 65C in both free solution and on top of immobilized targets solid phase amplification There are typically three steps involved in a DNA RCA reaction Circular template ligation which can be conducted via template mediated enzymatic ligation e g T4 DNA ligase or template free ligation using special DNA ligases i e CircLigase Primer induced single strand DNA elongation Multiple primers can be employed to hybridize with the same circle As a result multiple amplification events can be initiated producing multiple RCA products Multiprimed RCA Amplification product detection and visualization which is most commonly conducted through fluorescent detection with fluorophore conjugated dNTP fluorophore tethered complementary or fluorescently labeled molecular beacons In addition to the fluorescent approaches gel electrophoresis is also widely used for the detection of RCA product RCA produces a linear amplification of DNA as each circular template grows at a given speed for a certain amount of time To increase yield and achieve exponential amplification as PCR does several approaches have been investigated One of them is the hyperbranched rolling circle amplification or HRCA where primers that anneal to the original RCA products are added and also extended 12 In this way the original RCA creates more template that can be amplified Another is circle to circle amplification or C2CA where the RCA products are digested with a restriction enzyme and ligated into new circular templates using a restriction oligo followed by a new round of RCA with a larger amount of circular templates for amplification 13 Applications of RCA edit nbsp illustration of immuno RCARCA can amplify a single molecular binding event over a thousandfold making it particularly useful for detecting targets with ultra low abundance RCA reactions can be performed in not only free solution environments but also on a solid surface like glass micro or nano bead microwell plates microfluidic devices or even paper strips This feature makes it a very powerful tool for amplifying signals in solid phase immunoassays e g ELISA In this way RCA is becoming a highly versatile signal amplification tool with wide ranging applications in genomics proteomics diagnosis and biosensing Immuno RCA edit Immuno RCA is an isothermal signal amplification method for high specificity amp high sensitivity protein detection and quantification This technique combines two fields RCA which allows nucleotide amplification and immunoassay which uses antibodies specific to intracellular or free biomarkers As a result immuno RCA gives a specific amplified signal high signal to noise ratio making it suitable for detecting quantifying and visualizing low abundance proteic markers in liquid phase immunoassays 14 15 16 and immunohistochemistry Immuno RCA follows a typical immuno adsorbent reaction in ELISA or immunohistochemistry tissue staining 17 The detection antibodies used in immuno RCA reaction are modified by attaching a ssDNA oligonucleotide on the end of the heavy chains So the Fab Fragment antigen binding section on the detection antibody can still bind to specific antigens and the oligonucleotide can serve as a primer of the RCA reaction The typical antibody mediated immuno RCA procedure is as follows nbsp Illustration of aptamer based immuno rca1 A detection antibody recognizes a specific proteic target This antibody is also attached to an oligonucleotide primer 2 When circular DNA is present it is annealed and the primer matches to the circular DNA complementary sequence 3 The complementary sequence of the circular DNA template is copied hundreds of times and remains attached to the antibody 4 RCA output elongated ssDNA is detected with fluorescent probes using a fluorescent microscope or a microplate reader Aptamer based immuno RCA 18 edit In addition to antibody mediated immuno RCA the ssDNA RCA primer can be conjugated to the 3 end of a DNA aptamer as well The primer tail can be amplified through rolling circle amplification The product can be visualized through the labeling of fluorescent reporter 19 The process is illustrated in the figure on the right Other applications of RCA edit Various derivatives of RCA were widely used in the field of biosensing For example RCA has been successfully used for detecting the existence of viral and bacterial DNA from clinical samples 20 21 which is very beneficial for rapid diagnostics of infectious diseases It has also been used as an on chip signal amplification method for nucleic acid for both DNA and RNA microarray assay 1 In addition to the amplification function in biosensing applications RCA technique can be applied to the construction of DNA nanostructures and DNA hydrogels as well The products of RCA can also be use as templates for periodic assembly of nanospecies or proteins synthesis of metallic nanowires 22 and formation of nano islands 1 See also editSelector techniqueReferences edit a b c d Ali M Monsur Li Feng Zhang Zhiqing Zhang Kaixiang Kang Dong Ku Ankrum James A Le X Chris Zhao Weian 2014 Rolling circle amplification a versatile tool for chemical biology materials science and medicine Chemical Society Reviews 43 10 3324 41 doi 10 1039 C3CS60439J PMID 24643375 Demidov Vadim V ed 2016 Rolling Circle Amplification RCA Toward New Clinical Vadim V Demidov Springer Springer doi 10 1007 978 3 319 42226 8 ISBN 9783319422244 S2CID 30024718 Arbuckle Jesse 2011 The molecular biology of human herpesvirus 6 latency and telomere integration Microbes and Infection 13 8 9 731 741 doi 10 1016 j micinf 2011 03 006 PMC 3130849 PMID 21458587 Borenstein Ronen Frenkel Niza 2009 Cloning human herpes virus 6A genome into bacterial artificial chromosomes and study of DNA replication intermediates Proceedings of the National Academy of Sciences 106 45 19138 19143 Bibcode 2009PNAS 10619138B doi 10 1073 pnas 0908504106 PMC 2767366 PMID 19858479 Kusumoto Matsuo Rika Kanda Tadahito Kukimoto Iwao 2011 01 01 Rolling circle replication of human papillomavirus type 16 DNA in epithelial cell extracts Genes to Cells 16 1 23 33 doi 10 1111 j 1365 2443 2010 01458 x ISSN 1365 2443 PMID 21059156 S2CID 30493728 Rizvi Irum Choudhury Nirupam Roy Tuteja Narendra 2015 02 01 Insights into the functional characteristics of geminivirus rolling circle replication initiator protein and its interaction with host factors affecting viral DNA replication Archives of Virology 160 2 375 387 doi 10 1007 s00705 014 2297 7 ISSN 0304 8608 PMID 25449306 S2CID 16502010 Bernstein H Bernstein C July 1973 Circular and branched circular concatenates as possible intermediates in bacteriophage T4 DNA replication J Mol Biol 77 3 355 61 doi 10 1016 0022 2836 73 90443 9 PMID 4580243 Daros Jose Antonio Elena Santiago F Flores Ricardo June 2006 Viroids an Ariadne s thread into the RNA labyrinth EMBO Reports 7 6 593 598 doi 10 1038 sj embor 7400706 ISSN 1469 221X PMC 1479586 PMID 16741503 Tsagris Efthimia Mina Martinez de Alba Angel Emilio Gozmanova Mariyana Kalantidis Kriton 2008 11 01 Viroids Cellular Microbiology 10 11 2168 2179 doi 10 1111 j 1462 5822 2008 01231 x ISSN 1462 5822 PMID 18764915 Flores Ricardo Gas Maria Eugenia Molina Serrano Diego Nohales Maria Angeles Carbonell Alberto Gago Selma De la Pena Marcos Daros Jose Antonio 2009 09 14 Viroid Replication Rolling Circles Enzymes and Ribozymes Viruses 1 2 317 334 doi 10 3390 v1020317 PMC 3185496 PMID 21994552 Ali M Monsur Li Feng Zhang Zhiqing Zhang Kaixiang Kang Dong Ku Ankrum James A Le X Chris Zhao Weian 2014 05 21 Rolling circle amplification a versatile tool for chemical biology materials science and medicine Chemical Society Reviews 43 10 3324 3341 doi 10 1039 c3cs60439j ISSN 1460 4744 PMID 24643375 Lizardi Paul M Huang Xiaohua Zhu Zhengrong Bray Ward Patricia Thomas David C Ward David C July 1998 Mutation detection and single molecule counting using isothermal rolling circle amplification Nature Genetics 19 3 225 232 doi 10 1038 898 ISSN 1546 1718 PMID 9662393 S2CID 21007563 Dahl Fredrik Baner Johan Gullberg Mats Mendel Hartvig Maritha Landegren Ulf Nilsson Mats 2004 03 30 Circle to circle amplification for precise and sensitive DNA analysis Proceedings of the National Academy of Sciences 101 13 4548 4553 Bibcode 2004PNAS 101 4548D doi 10 1073 pnas 0400834101 ISSN 0027 8424 PMC 384784 PMID 15070755 Schweitzer Barry Roberts Scott Grimwade Brian Shao Weiping Wang Minjuan Fu Qin Shu Quiping Laroche Isabelle Zhou Zhimin April 2002 Multiplexed protein profiling on microarrays by rolling circle amplification Nature Biotechnology 20 4 359 365 doi 10 1038 nbt0402 359 ISSN 1087 0156 PMC 2858761 PMID 11923841 Zhou Long Ou Li Juan Chu Xia Shen Guo Li Yu Ru Qin 2007 Aptamer Based Rolling Circle Amplification A Platform for Electrochemical Detection of Protein Analytical Chemistry 79 19 7492 7500 doi 10 1021 ac071059s PMID 17722881 Bjorkesten Johan Patil Sourabh Fredolini Claudia Lonn Peter Landegren Ulf 2020 05 29 A multiplex platform for digital measurement of circular DNA reaction products Nucleic Acids Research 48 13 gkaa419 doi 10 1093 nar gkaa419 ISSN 0305 1048 PMC 7367203 PMID 32469060 Gusev Y Sparkowski J Raghunathan A Ferguson H Montano J Bogdan N Schweitzer B Wiltshire S Kingsmore S F July 2001 Rolling circle amplification a new approach to increase sensitivity for immunohistochemistry and flow cytometry The American Journal of Pathology 159 1 63 69 doi 10 1016 S0002 9440 10 61674 4 ISSN 0002 9440 PMC 1850404 PMID 11438455 Zhao Weian Ali M Monsur Brook Michael A Li Yingfu 2008 08 11 Rolling Circle Amplification Applications in Nanotechnology and Biodetection with Functional Nucleic Acids Angewandte Chemie International Edition 47 34 6330 6337 doi 10 1002 anie 200705982 ISSN 1521 3773 PMID 18680110 Zhou Long Ou Li Juan Chu Xia Shen Guo Li Yu Ru Qin 2007 10 01 Aptamer Based Rolling Circle Amplification A Platform for Electrochemical Detection of Protein Analytical Chemistry 79 19 7492 7500 doi 10 1021 ac071059s ISSN 0003 2700 PMID 17722881 Chen Xiaoyou Wang Bin Yang Wen Kong Fanrong Li Chuanyou Sun Zhaogang Jelfs Peter Gilbert Gwendolyn L 2014 05 01 Rolling Circle Amplification for Direct Detection of rpoB Gene Mutations in Mycobacterium tuberculosis Isolates from Clinical Specimens Journal of Clinical Microbiology 52 5 1540 1548 doi 10 1128 JCM 00065 14 ISSN 0095 1137 PMC 3993705 PMID 24574296 Liu Yang Guo Yan Ling Jiang Guang Lu Zhou Shi Jie Sun Qi Chen Xi Chang Xiu Jun Xing Ai Ying Du Feng Jiao 2013 06 04 Application of Hyperbranched Rolling Circle Amplification for Direct Detection of Mycobacterium Tuberculosis in Clinical Sputum Specimens PLOS ONE 8 6 e64583 Bibcode 2013PLoSO 864583L doi 10 1371 journal pone 0064583 ISSN 1932 6203 PMC 3672175 PMID 23750210 Guo Maoxiang Hernandez Neuta Ivan Madaboosi Narayanan Nilsson Mats Wijngaart Wouter van der 2018 02 12 Efficient DNA assisted synthesis of trans membrane gold nanowires Microsystems amp Nanoengineering 4 17084 doi 10 1038 micronano 2017 84 ISSN 2055 7434 External links editDNA replication systems used with small circular DNA molecules Genomes 2 T Brown et al at NCBI Books MicrobiologyBytes Viroids and Virusoids http mcmanuslab ucsf edu node 246 Retrieved from https en wikipedia org w index php title Rolling circle replication amp oldid 1177568296, wikipedia, wiki, book, books, library,

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