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Printable Handouts
Navigable Slide Index
- Introduction
- Overview
- Introduction to ROS production
- A closer look at mitochondrial bioenergetics
- Oxygen and its radicals
- Oxidative stress and damage
- Mitochondrial H2O2 signaling
- Oxidative eustress vs. oxidative distress
- Antioxidant defense systems
- Important considerations for H2O2 signaling
- Sites for mitochondrial O2●-/H2O2 production
- Which sites form the most O2●-/H2O2?
- Major sites for O2●-/H2O2 production: muscle
- Electron flow & ETC ROS production
- Major sites for ROS production: liver
- Reverse electron flow to PDH and OGDH
- The many sources of mitochondrial ROS
Topics Covered
- Mitochondrial bioenergetics
- Oxygen, its radicals, and oxidative distress vs. oxidative eustress
- Use of H2O2 as a mitokine
- Understanding mitochondrial ROS release
- Sites of ROS production and formation
Talk Citation
Mailloux, R.J. (2018, January 31). Controlling mitochondrial reactive oxygen species production for cell signaling 1 [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 22, 2024, from https://doi.org/10.69645/ZUTO1949.Export Citation (RIS)
Publication History
Financial Disclosures
- Dr. Ryan J. Mailloux has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Controlling mitochondrial reactive oxygen species production for cell signaling 1
Published on January 31, 2018
21 min
A selection of talks on Biochemistry
Transcript
Please wait while the transcript is being prepared...
0:00
Hello, my name is Ryan Mailloux,
and I'm an assistant professor of biochemistry at Memorial University of Newfoundland.
In this lecture, I'll be discussing
controlling mitochondrial reactive oxygen species production for cell signalling.
0:14
I will start this lecture with an introduction that focuses on giving a background
on how mitochondria combust carbon to make energy and reactive oxygen species.
This will be followed by a brief discussion on oxygen and its radicals,
and the difference between oxidative eustress, and oxidative distress
and how these two terms properly defined
the dichotomous nature of reactive oxygen species in biology.
This will then be followed by a few slides on
the signalling properties of reactive oxygen species,
focusing specifically on hydrogen peroxide.
I'll then start moving through the core of this lecture,
which is understanding mitochondrial ROS release.
In the first part of this discussion,
I will go through some of the basics of how mitochondria produce reactive oxygen species,
focusing on the 12 different ROS forming sites associated with energy metabolism.
After this, I'll go through controlling mitochondrial reactive oxygen species production
focusing on proton leaks,
supercomplex assemblies, and redox switches.
And then finally, I will discuss the implications of
redox switches in controlling mitochondrial reactive oxygen species signaling.
1:21
Mitochondria fulfill various essential functions of metabolism,
which includes meeting cellular energy demands through ATP production.
This is achieved via the combustion of carbon and the liberation of
electrons which are then used to produce ATP by oxidative phosphorylation.
Mitochondria are also the most important source of
cellular reactive oxygen species namely superoxide, and hydrogen peroxide,
the proximal reactive oxygen species generated by mitochondria,
and the most important oxy-radicals formed by biological systems.
Importantly, the formation of superoxide and hydrogen peroxide relies on
the same electron transfer pathways that mitochondria used to make ATP.
And although ROS are damaging at high levels,
it is now appreciated that low grade mitochondrial ROS production
specifically hydrogen peroxide,
is vital for regulating various cellular functions.
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