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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
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:
# Circular dsDNA will be "nicked".
# The
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.
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.
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. 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. 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.
The derivative form of rolling circle replication has been successfully used for amplification of DNA from very small amounts of starting material. This amplification technique is named as Rolling circle amplification (RCA). Different from conventional DNA amplification techniques such as 
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:
# 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
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.
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.
DNA replication systems used with small circular DNA molecules
''Genomes 2'', T. Brown et al., at
MicrobiologyBytes: Viroids and Virusoids
*http://mcmanuslab.ucsf.edu/node/246 __FORCETOC__ DNA replication
viroid
Viroids are small single-stranded, circular RNAs that are infectious pathogens. Unlike viruses, they have no protein coating. All known viroids are inhabitants of angiosperms (flowering plants), and most cause diseases, whose respective economi ...
s. Some eukaryotic viruses also replicate their DNA or RNA via the rolling circle mechanism.
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
Molecular biology is the branch of biology that seeks to understand the molecular basis of biological activity in and between cells, including biomolecular synthesis, modification, mechanisms, and interactions. The study of chemical and physi ...
and biomedical nanotechnology, especially in the field of biosensing
A biosensor is an analytical device, used for the detection of a chemical substance, that combines a biological component with a physicochemical detector.
The ''sensitive biological element'', e.g. tissue, microorganisms, organelles, cell recep ...
(as a method of signal amplification).
Circular DNA 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:
# Circular dsDNA will be "nicked".
# The 3' end
Directionality, in molecular biology and biochemistry, is the end-to-end chemical orientation of a single strand of nucleic acid. In a single strand of DNA or RNA, the chemical convention of naming carbon atoms in the nucleotide pentose-sugar-r ...
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 fragment
Okazaki fragments are short sequences of DNA nucleotides (approximately 150 to 200 base pairs long in eukaryotes) which are synthesized discontinuously and later linked together by the enzyme DNA ligase to create the lagging strand during DNA ...
s.
# Replication of both "unnicked" and displaced ssDNA.
# Displaced DNA circularizes.
Virology
Replication of viral DNA
SomeDNA virus
A DNA virus is a virus that has a genome made of deoxyribonucleic acid (DNA) that is replicated by a DNA polymerase. They can be divided between those that have two strands of DNA in their genome, called double-stranded DNA (dsDNA) viruses, and ...
es replicate their genomic information in host cells via rolling circle replication. For instance, ''human herpesvirus-6
Human herpesvirus 6 (HHV-6) is the common collective name for '' human betaherpesvirus 6A'' (HHV-6A) and '' human betaherpesvirus 6B'' (HHV-6B). These closely related viruses are two of the nine known herpesviruses that have humans as their prim ...
'' (HHV-6)(hibv) expresses a set of "early genes" that are believed to be involved in this process. The long concatemers
A concatemer is a long continuous DNA molecule that contains multiple copies of the same DNA sequence linked in series. These polymeric molecules are usually copies of an entire genome linked end to end and separated by ''cos'' sites (a protein bi ...
that result are subsequently cleaved between the pac-1 and pac-2 regions of HHV-6's genome by ribozymes
Ribozymes (ribonucleic acid enzymes) are RNA molecules that have the ability to catalyze specific biochemical reactions, including RNA splicing in gene expression, similar to the action of protein enzymes. The 1982 discovery of ribozymes demons ...
when it is packaged into individual virions.
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.
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.
Bacteriophage T4
Escherichia virus T4 is a species of bacteriophages that infect ''Escherichia coli'' bacteria. It is a double-stranded DNA virus in the subfamily '' Tevenvirinae'' from the family Myoviridae. T4 is capable of undergoing only a lytic lifecycle ...
DNA replication intermediates include circular and branched circular concatemeric structures. These structures likely reflect a rolling circle mechanism of replication.
Replication of viral RNA
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).
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. 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. 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.
Rolling circle amplification
The derivative form of rolling circle replication has been successfully used for amplification of DNA from very small amounts of starting material. This amplification technique is named as Rolling circle amplification (RCA). Different from conventional DNA amplification techniques such as polymerase chain reaction (PCR)
The polymerase chain reaction (PCR) is a method widely used to rapidly make millions to billions of copies (complete or partial) of a specific DNA sample, allowing scientists to take a very small sample of DNA and amplify it (or a part of it) ...
, 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).
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)
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:
# 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 beacon
Molecular beacons, or molecular beacon probes, are oligonucleotide hybridization probes that can report the presence of specific nucleic acids in homogenous solutions. Molecular beacons are hairpin-shaped molecules with an internally quenched fluo ...
s. 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. 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.
Applications of 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
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 and immunohistochemistry. Immuno-RCA follows a typical immuno-adsorbent reaction in ELISA or immunohistochemistry tissue staining. 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:
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
Aptamers are short sequences of artificial DNA, RNA, XNA, or peptide that bind a specific target molecule, or family of target molecules. They exhibit a range of affinities ( KD in the pM to μM range), with little or no off-target bindin ...
based immuno-RCA
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. The process is illustrated in the figure on the right.
Other applications of RCA
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, 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. In addition to the amplification function in biosensing applications, RCA technique can be applied to the construction of DNA nanostructures and DNAhydrogels
A gel is a semi-solid that can have properties ranging from soft and weak to hard and tough. Gels are defined as a substantially dilute cross-linked system, which exhibits no flow when in the steady-state, although the liquid phase may still dif ...
as well. The products of RCA can also be use as templates for periodic assembly of nanospecies or proteins, synthesis of metallic nanowire
A nanowire is a nanostructure in the form of a wire with the diameter of the order of a nanometre (10−9 metres). More generally, nanowires can be defined as structures that have a thickness or diameter constrained to tens of nanometers or less ...
s and formation of nano-islands.
See also
* Selector-techniqueReferences
{{reflistExternal links
DNA replication systems used with small circular DNA molecules
''Genomes 2'', T. Brown et al., at
NCBI
The National Center for Biotechnology Information (NCBI) is part of the United States National Library of Medicine (NLM), a branch of the National Institutes of Health (NIH). It is approved and funded by the government of the United States. The ...
BooksMicrobiologyBytes: Viroids and Virusoids
*http://mcmanuslab.ucsf.edu/node/246 __FORCETOC__ DNA replication