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Printable Handouts
Navigable Slide Index
- Introduction
- Mitochondrial (mt) biogenesis
- Activation of gene expression
- Transcription factors contributing to mt biogenesis
- PGC-1alpha domains and functions
- PGC-1 family of coactivators of mt biogenesis
- Estrogen-related receptor (ERRalpha)
- PGC-1alpha and ERRs interact physically
- PGC-1alpha enhances ERRalpha activity
- PGC-1alpha as an ERRalpha ligand
- PGC-1alpha induces ERRalpha expression
- ERRalpha regulates its own expression
- PGC-1alpha and ERRalpha activity and expression
- PGC-1alpha and ERRalpha: similar expression
- Context of ERRalpha function
- Mitochondrial biogenesis induction by PGC-1alpha
- PGC-1alpha and increased mtDNA copy number
- Genes induced by PGC-1alpha
- PGC-1alpha activity requires nuclear receptors
- ERRs in mediating PGC-1alpha function (1)
- ERRs in mediating PGC-1alpha function (2)
- ERRalpha and gene induction by PGC-1alpha (1)
- ERRalpha recruits PGC-1alpha at target genes
- Activation of promoters via ERREs
- ERRalpha and gene induction by PGC-1alpha (2)
- PGC-1alpha-mediated mt biogenesis
- ERRalpha is a downstream effector of PGC-1alpha
- VP16-ERRalpha induces mt biogenesis
- PGC-1beta and ERRalpha induce mt genes
- Activity of ERRalpha - summary
- ERRalpha knock-out mice (by Vincent Giguere)
- Assessing ERRalpha function in mt biogenesis
- mt genes expression in ERRalpha-/- BAT
- Interaction of ERRalpha with mt genes in BAT
- mtDNA replication factors in ERRalpha-null BAT
- Mitochondrial mass in BAT of ERRalpha-null mice
- Lipid accumulation in BAT of ERRalpha-null mice
- O2 consumption in BAT of ERRalpha-null mice
- Adaptive thermogenesis
- Adaptive thermogenesis of ERRalpha-null mice
- PGC-1, UCP1, DIO2 levels and cold exposure
- ERRalpha-null mice at mild cold temperatures
- BAT of ERRalpha-null mice - summary
- Role of ERRalpha in vivo - summary
- Acknowledgments
Topics Covered
- Mitochondrial biogenesis
- Transcriptional regulation of mitochondrial biogenesis
- The roles of transcriptional coactivators of the PGC-1 family and of the orphan nuclear receptor Estrogen-Related Receptor alpha (ERRa) in the regulation of mitochondrial biogenesis
- Physiologic function of ERR-alpha-dependent mitochondrial biogenesis
Talk Citation
Kralli, A. (2016, November 28). Regulation of mitochondrial biogenesis by transcriptional coactivators and estrogen-related receptor alpha [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 22, 2024, from https://doi.org/10.69645/FAUJ2668.Export Citation (RIS)
Publication History
Financial Disclosures
- Dr. Anastasia Kralli has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Regulation of mitochondrial biogenesis by transcriptional coactivators and estrogen-related receptor alpha
A selection of talks on Cell Biology
Transcript
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0:00
The mitochondrial content of a cell is regulated by tissue specific endocrine and
physiologic signals so that it closely
matches the specific energetic needs faced by a cell.
This talk will focus on the transcriptional networks that communicate
tissue and physiologic state specific signals
to the regulation of mitochondrial biogenesis,
with an emphasis on recently identified components of the network,
namely the transcriptional coactivators,
PGC-1 alpha and PGC-1 beta,
and the PGC-1 effector estrogen related receptor alpha.
0:35
Biogenesis of mitochondria is a complex process,
requiring the coordinated transcription with close to
a thousand nuclear genes encoding mitochondrial proteins,
which I will loosely refer to as mitochondrial genes,
as well as their application and transcription of the mitochondrial DNA genome,
the biosynthesis of mitochondrial membranes,
and the import and assembly of the newly made proteins
and lipids to a functional and dynamic organelle.
The seemingly distinct processes have to be coregulated.
To a large extent, this coregulation is managed at the level of
transcriptional controlling the nucleus,
which determines the expression levels of mitochondrial components,
as well as directs the expression of regulators
of particular aspects of mitochondrial biogenesis.
For example, regulators of mitochondrial DNA replication and transcription,
as discussed by Richard Scarpulla in this series.
Besides determining the appropriate mitochondrial mass for the cell,
transcriptional regulation in the nucleus is also
specifying the structural and functional properties of the organelle.
Close to 60 percent of mitochondrial proteins are
differentially expressed in different tissues or in response to physiologic signals.
This differential expression reflects the role of mitochondria not just for
substrate oxidation and ATP production but also for other processes,
such as apoptosis, ion homeostasis,
signaling via production of reactive oxygen species,
thermogenesis, or steroid biosynthesis.
Elucidating the transcriptional networks that control mitochondrial biogenesis and
function is important for understanding
the mechanisms that may underlie mitochondrial diseases,
as well as for enabling strategies that may counteract such diseases.
Before reviewing the transcriptional regulators of mitochondrial biogenesis,
I will give you a brief and basic introduction to
the principles that govern regulation of gene expression.
Transcription factors recognize and bind directly to
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