Regulation of DNA replication at the end of the mitochondrial D-loop involves the helicase TWINKLE and a conserved sequence element

E Jemt, Ö Persson, Y Shi, M Mehmedovic… - Nucleic acids …, 2015 - academic.oup.com
E Jemt, Ö Persson, Y Shi, M Mehmedovic, JP Uhler, M Dávila López, C Freyer
Nucleic acids research, 2015academic.oup.com
The majority of mitochondrial DNA replication events are terminated prematurely. The
nascent DNA remains stably associated with the template, forming a triple-stranded
displacement loop (D-loop) structure. However, the function of the D-loop region of the
mitochondrial genome remains poorly understood. Using a comparative genomics approach
we here identify two closely related 15 nt sequence motifs of the D-loop, strongly conserved
among vertebrates. One motif is at the D-loop 5′-end and is part of the conserved …
Abstract
The majority of mitochondrial DNA replication events are terminated prematurely. The nascent DNA remains stably associated with the template, forming a triple-stranded displacement loop (D-loop) structure. However, the function of the D-loop region of the mitochondrial genome remains poorly understood. Using a comparative genomics approach we here identify two closely related 15 nt sequence motifs of the D-loop, strongly conserved among vertebrates. One motif is at the D-loop 5′-end and is part of the conserved sequence block 1 (CSB1). The other motif, here denoted coreTAS, is at the D-loop 3′-end. Both these sequences may prevent transcription across the D-loop region, since light and heavy strand transcription is terminated at CSB1 and coreTAS, respectively. Interestingly, the replication of the nascent D-loop strand, occurring in a direction opposite to that of heavy strand transcription, is also terminated at coreTAS, suggesting that coreTAS is involved in termination of both transcription and replication. Finally, we demonstrate that the loading of the helicase TWINKLE at coreTAS is reversible, implying that this site is a crucial component of a switch between D-loop formation and full-length mitochondrial DNA replication.
Oxford University Press