The 2-micron plasmid residing within the host budding yeast Saccharomyces cerevisiae nucleus serves as a model system for understanding the mechanism of segregation and stable maintenance of circular endogenously present extrachromosomal DNA in eukaryotic cells. The plasmid is maintained at a high average copy number (40–60 copies per yeast cell) through generations despite there is no apparent benefit to the host. Notably, the segregation mechanism of 2-micron plasmid shares significant similarities with those of bacterial low-copy-number plasmids and episomal forms of viral genomes in mammalian cells. These similarities include formation of a complex where the plasmid- or viral encoded proteins bind to a plasmid- or viral genome-borne locus, respectively and interaction of the complex with the host proteins. These together form a partitioning system that ensures stable symmetric inheritance of both these genomes from mother to daughter cells. Recent studies with substantial evidence showed that the 2-micron plasmid, like episomes of viruses such as Epstein–Barr virus, relies on tethering itself to the host chromosomes in a non-random fashion for equal segregation. This review delves into the probable chromosome hitchhiking mechanisms of 2-micron plasmid during its segregation, highlighting the roles of specific plasmid-encoded proteins and their interactions with host proteins and the chromosomes. Understanding these mechanisms provides broader insights into the genetic stability and inheritance of extrachromosomal genetic elements across diverse biological systems.
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The image depicts an artistic representation of the lift-out and sectioning step with a focused ion beam (FIB), which is referred to as serial lift-out. A block of vitreously frozen biological material (in this case, a single C. elegans L1 larva) is attached (or "welded") to a micromanipulator needle. The underside of the block is then attached to a rectangular mesh copper EM grid, and a section of ~1 µm is cut away from it with the FIB. This procedure is repeated, yielding an array of sections that can be further thinned to ~200 nm for cryo-ET and further structural analysis. Image hand drawn (ink), digitised and coloured with Adobe Fresco (iPad). Read more in 'Cryo-electron tomography: en route to the molecular anatomy of organisms and tissues' by Plitzko and colleagues on pp 2415-2425 of this issue of Biochemical Society Transactions. Image courtesy of JM Plitzko
Chromosome hitchhiking: a potential strategy adopted by the selfish yeast plasmids to ensure symmetric inheritance during cell division
Deepanshu Kumar, Santanu Kumar Ghosh; Chromosome hitchhiking: a potential strategy adopted by the selfish yeast plasmids to ensure symmetric inheritance during cell division. Biochem Soc Trans 19 December 2024; 52 (6): 2359–2372. doi: https://doi.org/10.1042/BST20231555
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