Iteron

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Iterons are directly repeated DNA sequences which play an important role in regulation of plasmid copy number in bacterial cells. It is one among the three negative regulatory elements found in plasmids which control its copy number. The others include antisense RNAs and ctRNAs. Iterons complex with cognate replication (Rep) initiator proteins to achieve the required regulatory effect. [1] [2]

Contents

Regulation of Replication

Iterons have an important role in plasmid replication. An iteron-containing plasmid origin of replication can be found containing about five iterons about 20 base pairs in length total. These iterons provide a saturation site for initiator receptor proteins and promote replication thus increasing plasmid copy number in a given cell. [1]

Limiting Factors of Initiation

There are 4 main limiting factors leading to no initiation of replication in iterons: [1]

Four main limiting factors leading to no initiation of replication in iterons Screen Shot 2015-12-02 at 6.30.31 PM.png
Four main limiting factors leading to no initiation of replication in iterons

Transcriptional auto-repression is thought to reduce initiator synthesis by repressing the formation of the Rep proteins. Since these proteins work to promote binding of replication machinery, replication can be halted in this form. Another factor used to stop replication is known as dimerization. It works to dimerize these Rep proteins and as a result monomers of these proteins are no longer in a high enough concentration to initiate replication. [2] Another limiting factor, titration, occurs after replication and works to prevent saturation by distributing monomers to daughter origins so that no are fully saturated. Finally, handcuffing refers to pairing origins leading to inactivation. This is mediated by monomers and inactivation is due to steric hindrance between the origins. [1] [2]

Another less prevalent limitation thought to be present in these iterons is the presence of extra repeats. If a plasmid contains an extra supply of iterons outside of the saturation site it has been shown this can decrease plasmid copy number. In contrast, removing these extra iterons will increase copy number. [1]

Replicon Structure

Plasmids are known to have very similar structure when under control of Iterons. This structure consists of an origin of replication upstream of a gene that codes for a replication initiator protein. The iterons themselves are known to cover about half of the origin of replication. [2] Usually, iterons on the same plasmid are highly conserved, whereas comparing iterons on different plasmids still exhibit homology yet are not as highly conserved. This suggests that iterons could be evolutionarily related. [3]

Replication Initiator Proteins

Representation of the molecular structure of protein RepA, a known rep protein used in iterons PDB 1hkq EBI.jpg
Representation of the molecular structure of protein RepA, a known rep protein used in iterons

The replication initiator protein (Rep) plays a key role in initiation of replication in plasmids. In its monomer form, Rep binds an iteron and promotes replication. The protein itself is known to contain two independent N-terminal and C-terminal globular domains that subsequently bind to two domains of the iteron. The dimer version of the protein is generally inactive in iteron binding, however it is known to bind to the repE operator. This operator contains half of the iteron sequence making it able to bind the dimer and promote gene expression. [2] [4]

Plasmids containing iterons are all organized very similarly in structure. [2] The gene for Rep proteins is usually found directly downstream of the origin of replication. [5] This means that the iterons themselves are known to regulate the synthesis of the rep proteins. [6] [7]

Related Research Articles

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<span class="mw-page-title-main">Toxin-antitoxin system</span> Biological process

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<span class="mw-page-title-main">SeqA protein</span>

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In cellular biology, the plasmid copy number is the number of copies of a given plasmid in a cell. To ensure survival and thus the continued propagation of the plasmid, they must regulate their copy number. If a plasmid has too high of a copy number, they may excessively burden their host by occupying too much cellular machinery and using too much energy. On the other hand, too low of a copy number may result in the plasmid not being present in all of their host's progeny. Plasmids may be either low, medium or high copy number plasmids; the regulation mechanisms between low and medium copy number plasmids are different. Low copy plasmids require either a partitioning system or a toxin-antitoxin pair such as CcdA/CcdB to ensure that each daughter receives the plasmid. For example, the F plasmid, which is the origin of BACs is a single copy plasmid with a partitioning system encoded in an operon right next to the plasmid origin. The partitioning system interacts with the septation apparatus to ensure that each daughter receives a copy of the plasmid. Many biotechnology applications utilize mutated plasmids that replicate to high copy number. For example, pBR322 is a medium copy number plasmid from which several high copy number cloning vectors have been derived by mutagenesis, such as the well known pUC series. This delivers the convenience of high plasmid DNA yields but the additional burden of the high copy number restricts the plasmid size. Larger high copy plasmids (>30kb) are disfavoured and also prone to size reduction through deletional mutagenesis.

References

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  4. Tsukasa Fueki, and Kazuo Yamaguchi1j (2001). "The structure and function of the replication initiator protein (Rep) of pSC101: an analysis based on a novel positive-selection system for the replication-deficient mutants". The Journal of Biochemistry . 130 (3): 399–405. doi:10.1093/oxfordjournals.jbchem.a002999. PMID   11530016.{{cite journal}}: CS1 maint: numeric names: authors list (link)
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