Unexpected sequences and structures of mtDNA required for efficient transcription from the first heavy-strand promoter.

Akira Uchida,Markus Kastner,Jamie J Arnold,L James Maher,Divakaran Murugesapillai,Craig E Cameron,Mark C Williams,Shaan Prabhakar,Guinevere V Oliver,Maria F Lodeiro,Yao Wang

doi:10.7554/elife.27283

Akira Uchida, Markus Kastner + Show 9 more

Open Access

https://doi.org/10.7554/elife.27283

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Abstract

Human mtDNA contains three promoters, suggesting a need for differential expression of the mitochondrial genome. Studies of mitochondrial transcription have used a reductionist approach, perhaps masking differential regulation. Here we evaluate transcription from light-strand (LSP) and heavy-strand (HSP1) promoters using templates that mimic their natural context. These studies reveal sequences upstream, hypervariable in the human population (HVR3), and downstream of the HSP1 transcription start site required for maximal yield. The carboxy-terminal tail of TFAM is essential for activation of HSP1 but not LSP. Images of the template obtained by atomic force microscopy show that TFAM creates loops in a discrete region, the formation of which correlates with activation of HSP1; looping is lost in tail-deleted TFAM. Identification of HVR3 as a transcriptional regulatory element may contribute to between-individual variability in mitochondrial gene expression. The unique requirement of HSP1 for the TFAM tail may enable its regulation by post-translational modifications.

Highlights

In spite of the absolute requirement of mitochondrial function for life, more is known about generegulatory mechanisms in prokaryotes than is known about corresponding mechanisms in the mitochondria of humans or other mammalian species
Studies performed in cells and cell-free extracts have revealed the existence of three mitochondrial promoters: light-strand promoter (LSP), heavy-strand promoter 1 (HSP1) and HSP2 (Bogenhagen et al, 1984; Cantatore and Attardi, 1980; Chang and Clayton, 1984; Montoya et al, 1982, 1983)
The primary role of this upstream sequence is to bind mitochondrial transcription factor A (TFAM), a DNA binding, bending and wrapping protein related to mammalian high-mobility-group proteins (Malarkey and Churchill, 2012; Murugesapillai et al, 2017)

Summary

Introduction

In spite of the absolute requirement of mitochondrial function for life, more is known about generegulatory mechanisms in prokaryotes than is known about corresponding mechanisms in the mitochondria of humans or other mammalian species One reason for this knowledge gap is the inability to perform reverse-genetic analysis of mitochondrial DNA (mtDNA). We recently suggested that such a division of transcription would allow assembly of the core components of the ETC by activating HSP2. In this model, activation of complex I would not occur until LSP was activated, as ND6 mRNA is the sole mRNA transcribed from this promoter.

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