Preprint
Upstream alternative polyadenylation in SCN5A produces a short transcript isoform encoding a mitochondria-localized NaV1.5 N-terminal fragment that influences cardiomyocyte respiration
bioRxiv
Cold Spring Harbor Laboratory
08/10/2024
DOI: 10.1101/2024.08.09.607406
PMCID: PMC11360925
PMID: 39211120
Abstract
SCN5A
encodes the cardiac voltage-gated Na+ channel, NaV1.5, that initiates action potentials.
SCN5A
gene variants cause arrhythmias and increased heart failure risk. Mechanisms controlling NaV1.5 expression and activity are not fully understood. We recently found a well-conserved alternative polyadenylation (APA) signal downstream of the first
SCN5A
coding exon. This yields a
SCN5A-short
transcript isoform expressed in several species (e.g. human, pig, and cat), though rodents lack this upstream APA. Reanalysis of transcriptome-wide cardiac APA-seq and mRNA-seq data shows reductions in both upstream APA usage and short/full-length
SCN5A
mRNA ratios in failing hearts. Knock-in of the human
SCN5A
APA sequence into mice is sufficient to enable expression of
SCN5A
-short transcript, while significantly decreasing expression of full-length
SCN5A
mRNA. Notably,
SCN5A
-short transcript encodes a novel protein (NaV1.5-NT), composed of an N-terminus identical to NaV1.5 and a unique C-terminus derived from intronic sequence. AAV9 constructs were able to achieve stable NaV1.5-NT expression in mouse hearts, and western blot of human heart tissues showed bands co-migrating with NaV1.5-NT transgene-derived bands. NaV1.5-NT is predicted to contain a mitochondrial targeting sequence and localizes to mitochondria in cultured cardiomyocytes and in mouse hearts. NaV1.5-NT expression in cardiomyocytes led to elevations in basal oxygen consumption rate, ATP production, and mitochondrial ROS, while depleting NADH supply. Native PAGE analyses of mitochondria lysates revealed that NaV1.5-NT expression resulted in increased levels of disassembled complex V subunits and accumulation of complex I-containing supercomplexes. Overall, we discovered that APA-mediated regulation of
SCN5A
produces a short transcript encoding NaV1.5-NT. Our data support that NaV1.5-NT plays a multifaceted role in influencing mitochondrial physiology: 1) by increasing basal respiration likely through promoting complex V conformations that enhance proton leak, and 2) by increasing overall respiratory efficiency and NADH consumption by enhancing formation and/or stability of complex I-containing respiratory supercomplexes, though the specific molecular mechanisms underlying each of these remain unresolved.
Details
- Title: Subtitle
- Upstream alternative polyadenylation in SCN5A produces a short transcript isoform encoding a mitochondria-localized NaV1.5 N-terminal fragment that influences cardiomyocyte respiration
- Creators
- Nathan H. Witmer - University of IowaJared M. McLendon - University of IowaColleen S. Stein - University of IowaJin-Young YoonElena Berezhnaya - Temple UniversityJohn W. Elrod - Temple UniversityBarry L. London - University of IowaRyan L. Boudreau - University of Iowa
- Resource Type
- Preprint
- Publication Details
- bioRxiv
- DOI
- 10.1101/2024.08.09.607406
- PMID
- 39211120
- PMCID
- PMC11360925
- NLM abbreviation
- bioRxiv
- eISSN
- 2692-8205
- Publisher
- Cold Spring Harbor Laboratory
- Language
- English
- Date posted
- 08/10/2024
- Academic Unit
- Molecular Physiology and Biophysics; Iowa Neuroscience Institute; Pharmaceutical Sciences and Experimental Therapeutics; Cardiovascular Medicine; Fraternal Order of Eagles Diabetes Research Center; Internal Medicine
- Record Identifier
- 9984699519602771
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