Nuclear control of electron transport chain gene expression

Rowe, Glenn C.

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Introduction
Talk outline
Mitochondria are the powerhouse of the cell
Subunits of the ETC
Nuclear and mitochondrial encoded genes
Nuclear-encoded transcriptional regulators
Discovery of PGC1α
Discovery of PGC1ß and PRC
PGC1 family of co-activators
PGC-1s as a transcriptional regulator
Overexpression of PGC1α and ETC genes
Overexpression of PGC1ß and ETC genes
Overexpression of PRC increases ETC levels
Loss of PGC1α and ß decreases ETC levels
PGC1 DKO decreases ETC activity
PGC1 DKO myotubes and OXPHOS levels
PGC1 DKO cells have impaired respiration
NRF-1
Overexpression of NRF-1 increases ETC levels
NRF2/GABP
Deletion of NRF-2 decreases ETC levels
Deletion of NRF-2 decreases respiration
Estrogen-related receptors (ESRRs)
ESRRs domains
Overexpression of ESRRα and ETC genes
Identification of ESRRα binding sites
Overexpression of ESRRγ and ETC genes
Overexpression of ESRRγ increases respiration
ESRRs and NRFs regulate OXPHOS genes
YY1 identified downstream of PGC-1α
YY1
YY1 binding motifs
YY1 binds to promoter of genes involved in ETC
Effects of YY-1 loss on ETC level and respiration
The mitochondria encoded ETC subunits
Mitochondrial encoded ETC subunits
Nuclear-encoded transcriptional factors
Mitochondrial transcirption factors
Mitochondrial transcription factors and NRFs
Loss of PGC1α & ß and mitochondrial ETC
Coordinated transcriptional regulation of ETC
Summary
Thank you

Topics Covered

Introduction to the roles of mitochondria
Subunits of the electron transport chain (ETC) in nuclear & mitochondrial genomes
Transcription of the electron transport chain subunits
Peroxisome proliferator-activated receptor gamma coactivators (PGC-1s)
Nuclear respiratory factors (NRFs)
Estrogen-related receptor (ESRRs)
Mitochondrial transcription factors (Tfam and mtTFB)
Yin-Yang (YY-1)
Coordinated transcriptional regulation of ETC genes
Summary/Closing Statements

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Mitochondrial Biogenesis

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Talk Citation

Rowe, G.C. (2019, June 30). Nuclear control of electron transport chain gene expression [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 3, 2024, from https://doi.org/10.69645/OEPU2415.
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Publication History

Published on June 30, 2019

Financial Disclosures

Dr. Glenn C. Rowe has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.

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Nuclear control of electron transport chain gene expression

Dr. Glenn C. Rowe – University of Alabama at Birmingham, USA

Published on June 30, 2019 23 min

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Transcript

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0:00

Today we will talk about a nuclear control of the electron transport chain gene expression.

0:09

The talk outline will be a summary of an introduction, followed by a summary of the subunits involved in the electron transport chain, and the transcription of the electron transport chain subunits. We will also talk about the peroxisomes proliferator-activated receptor gamma co-activators, which we will refer to as PGC-1s, nuclear respiratory factors, NRFs, and estrogen-related receptors or ESRRs. We'll also talk about the mitochondrial transcription factors, which are also nuclear-encoded, and we'll talk briefly about the Yin-Yang 1 transcription factor.

0:52

Just a reminder, the mitochondria are the powerhouse of the cell; they convert dietary inputs into ATP. They are the location where the Krebs/Citric Acid Cycle occur. They're also the place where the process of oxidative phosphorylation occurs to produce ATP, using the complexes on the electron transport chain.

1:14

There are five complexes that make up the electron transport chain, and these complexes are encoded by both nuclear and mitochondrial genomes. The mitochondrial genome encodes for seven components of Complex I, one of Complex III, three of Complex IV, and two of Complex V; whilst the nuclear genome encodes for 39 subunits of Complex I, 10 of Complex III, 4 of Complex II, 10 of Complex IV, and 14 of Complex V. This requires coordinated expression of

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Nuclear control of electron transport chain gene expression

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Nuclear control of electron transport chain gene expression