{{short description|Type of DNA molecule}}

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 binding nucleotide sequence that occurs once in each copy of the genome). Concatemers are frequently the result of rolling circle replication, and may be seen in the late stage of infection of bacteria by phages. As an example, if the genes in the phage DNA are arranged ABC, then in a concatemer the genes would be ABCABCABCABC and so on (assuming synthesis was initiated between genes C and A). They are further broken by ribozymes.<ref>{{cite journal|title=Cloning human herpes virus 6A genome into bacterial artificial chromosomes and study of DNA replication intermediates|first1=Ronen |last1=Borenstein |first2=Niza |last2=Frenkel|journal=Proceedings of the National Academy of Sciences|volume=106 |issue= 45|pages=19138–19143|doi=10.1073/pnas.0908504106 |year=2009|pmc=2767366 |pmid=19858479|bibcode=2009PNAS..10619138B|doi-access=free}}</ref> <!--The concatemer may be then cut into fragments.The cut fragments need not be of a genome length but, will possess all the genes.For example, the concatemer ABCABCABCABC can be cut as, A BCA BCAB CAB C or AB CABCA BCA BC and in many other ways.-->

During active infection, some species of viruses have been shown to replicate their genetic material via the formation of concatemers.<ref>{{cite journal|last=Arbuckle|first=Jesse|title=The molecular biology of human herpesvirus-6 latency and telomere integration|journal=Microbes and Infection|volume=13|issue=8–9|doi=10.1016/j.micinf.2011.03.006|pmid=21458587|pmc=3130849|year=2011|pages=731–741}}</ref> In the case of ''human herpesvirus-6'', its entire genome is made over and over on a single strand. These long concatemers are subsequently cleaved between the pac-1 and pac-2 regions by ribozymes when the genome is packaged into individual virions.

Bacteriophage T4 replicating DNA was labeled with tritiated thymidine and examined by autoradiography.<ref name="pmid4580243">{{cite journal |vauthors=Bernstein H, Bernstein C |title=Circular and branched circular concatenates as possible intermediates in bacteriophage T4 DNA replication |journal=J. Mol. Biol. |volume=77 |issue=3 |pages=355–61 |date=July 1973 |pmid=4580243 |doi= 10.1016/0022-2836(73)90443-9}}</ref> The observed DNA replication intermediates included circular and branched circular concatemeric structures that likely arose by rolling circle replication.

When assembling concatemers from synthetic oligonucleotides, increasing salt concentration to 200 mM was found to be a major optimizing factor due to its ability to enhance ionic strength, which hastened the formation of concatemers.<ref>{{cite journal |last1=Sun |first1=Lu |last2=Åkerman |first2=Björn |title=Characterization of self-assembled DNA concatemers from synthetic oligonucleotides |journal=Computational and Structural Biotechnology Journal |date=August 2014 |volume=11 |issue=18 |pages=66–72 |doi=10.1016/j.csbj.2014.08.011 |pmid=25379145 |pmc=4212282 }}</ref>

== Mechanism/ replication == In addition to rolling circle replication, many DNA viruses employ recombination-dependent replication to produce concatemers. In this mechanism, replication is initiated at multiple sites, followed by strand invasion and homologous recombination, which join replication forks and generate long tandem repeats. Some viruses initiate multiple consecutive reinitiation events at genomic termini, which lead to overlapping replication rounds that effectively result in concatemer formation.<ref>{{cite journal |last1=Lo Piano |first1=Ambra |last2=Martinez-Jimenez |first2=Maria I. |last3=Zecchi |first3=Lisa |last4=Ayora |first4=Silvia |date=Sep 2011 |title=Recombination-dependent concatameric DNA replication |url=https://pubmed.ncbi.nlm.nih.gov/21708194/ |journal=Virus Research |volume=160 |issue=1-2 |publisher= |pages=1-14 |doi=10.1016/j.virusres.2011.06.009 |pmc= |pmid=21708194 |access-date=6 Mar 2026 |name-list-style=vanc}}</ref>

Concatemers, especially when unresolved, can contribute to genomic instability and rearrangements. Tandem duplication, unequal, crossover, and insertion/deletion may occur. Over time, concatemers may seed new tandem repeat arrays or satellite DNA, and in viruses, variation in concatemer length can drive genetic diversity.{{cn|date=March 2026}}

== Mitochondria == In yeast S. cerevisiae concatamers are an essential part of the process for packaging DNA. We know this because of experiments done on the yeast S cerevisiae cells.<ref name=":0">{{Cite journal|title=DNA recombination protein-dependent mechanism of homoplasmy and its proposed functions|url=https://www.sciencedirect.com/science/article/pii/S1567724906002376|journal=Mitochondrion|date=2007-02-01|issn=1567-7249|pages=17–23|volume=7|series=Mitochondria and Life|issue=1|doi=10.1016/j.mito.2006.11.024|first=Takehiko|last=Shibata|first2=Feng|last2=Ling|url-access=subscription}}</ref>

-There are two ways that concatamers are formed, rolling circle replication and crossing over. <ref name=":0" />

-Mhr1 is a protein that starts the rolling circle replication for mitochondrial DNA in the yeast. <ref name=":0" />

-CCE1 is a protein that helps with crossing over.<ref name=":0" />

-If the gene for Mhr1 is overexpressed there will be more concatamers, if it is disrupted by a mutation there will be less concatamers.<ref name=":0" />

-If both the MHR1 gene and CCE1 genes are disrupted by mutations concatamers won’t be able to form and the cell will have no mitochondrial DNA.<ref name=":0" /> Mitochondrial DNA won't form without concatamers. That proves that they are necessary for mitochondrial DNA.

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== Rolling Circle DNA Replication == One of the ways concatamers are formed is through rolling circle replication. In rolling circle replication the outer strand of DNA is cut at an origin. That strand is peeled off of it’s complementary strand. As it is fully peeled off, DNA replicase will attach nucleotides to the inner strand to replace the peeled strand. Once the strand is fully peeled DNA replicase can bind nucleotides so that it will have a complementary strand. After the process, there will be two strands of DNA with their complements.<ref>{{Cite book|title=Rolling Circle Amplification (RCA)|url=http://link.springer.com/10.1007/978-3-319-42226-8|publisher=Springer International Publishing|date=2016|location=Cham|isbn=978-3-319-42224-4|doi=10.1007/978-3-319-42226-8|language=en|editor-first=Vadim V.|editor-last=Demidov}}</ref> alt=Diagram explaining rolling circle replication|thumb|550x550px|Rolling Circle Replication|none ==References== {{Reflist}}

==Bibliography== * Oxford Dictionary of Biochemistry and Molecular Biology, 2nd ed. R. l., eds. Oxford University Press, 2006. p.&nbsp;138.

Category:Repetitive DNA sequences

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