A DNA mass conservation mechanism underpins cellular mtDNA number regulation
Hussan, J. R.; Kobro-Flatmoen, A.; Ruoff, P.; Omholt, S. W.
Show abstract
The nucleoid, which houses mtDNA within the mitochondrial matrix, is a phase-separation-driven biomolecular condensate capable of carrying out a broad spectrum of complex functions, including DNA replication, transcription, and repair. Here, we show by data-driven computational modelling that the concept of a tightly regulated intranucleoid deoxynucleoside triphoshate (dNTP) pool explains the observation that the number of mtDNA base pairs per cell is conserved in human hybrid cell lines regardless of the size of the introduced mitochondrial genome. This concept is then used to address the enigmatic observation that the synthesis rate of the short DNA strand called 7S DNA, which is part of the triple-stranded displacement loop (D-loop) found in the main noncoding region of mtDNA, increases dramatically during the cell cycle. Collectively, our quantitative analyses suggest that the mammalian mtDNA replisome uses a strictly controlled intranucleoid dNTP pool based predominantly on the synthesis and degradation of 7S DNA. One potential evolutionary explanation for this mechanism is that it offers an energetic advantage by enabling greater reliance on the salvage pathway for mtDNA replication.
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