HSS2305 Lecture 6 on Mitochondria PDF

Summary

Lecture notes on mitochondria and aerobic metabolism, including sample questions and a case study about a healthy baby born at term that developed symptoms throughout the first 12 - 18 months of life.

Full Transcript

What “breathes” in
O2 and pyruvate,
“spits” out CO2 and
ATP, rhymes with
hypochondria and
Mitochondria!
confuses my
neighbour?
 HSS2305: Molecular
Mechanisms of Disease

Lecture 6 – Mitochondria and Aerobic Metabolism –
Today’s Outline
Sample Questions
Mitochondria and Aerobic
Metabolism!
Announcement
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Sample Questions
1. How many ATP molecules are used in the investment phase of glycolysis?
1. 0
2. 1
3. 36
4. 2
2. Oxidation is the:
1. Gain of electrons
2. Loss of electrons
3. Production of O2
4. Production of Oxygen Free Radicals
3. Glycolysis does not produce:
1. NADH
2. ATP
3. FADH2
4. Pyruvate
5. Glucose
4. What enzyme converts NADH to NADPH and vice versa?
1. Transhydrogenase
2. Hexokinase
3. NAD+ Kinase
4. NAMPT
Mitochondria
Singular: Mitochondrion
Plural: Mitochondria
Role:
“Powerhouse of the Cell”
Many others!!!
Today’s Case Study
Healthy baby born at term
No complications in the pregnancy
Met all developmental milestones up to
6 months
12 months of age
Lost basic motor skills such as:
Sucking
Head control
Walking
Talking
Irritable
Appetite loss
Seizures
18 months
Vision loss
Respiratory problems
MRI found brain lesions, particularly in the
midbrain and brainstem
 Origin of Mitochondria
The Origin of Mitochondria
Endosymbiotic theory:
Some organelles in eukaryotic
cells were once prokaryotic
microbes
Examples:
Mitochondria
Believed to have developed
from Alpha-proteobacteria
Chloroplasts
Believed to have developed
from Cyanobacteria
Evidence:
Same size as prokaryotic cells
Divide by binary fission
https://mmegias.webs.uvigo.es/02-english/5-celulas/1-
Contain DNA
endosimbiosis.php
 Mitochondria
Structure

2 Membranes:
1. Outer mitochondrial membrane
2. Inner mitochondrial membrane
1. Inner boundary membrane
2. Cristae
Contains Electron Transport
Chain (ETC) - ATP synthesis
machinery
2 Compartments:
1. Intermembrane space
2. Matrix
Contains circular mitochondrial
DNA, ribosomes, and enzymes
(ex. TCA Cycle)
 Mitochondria
Structure - Membranes
Mitochondria membranes are highly proteinaceous:
Outer membrane ~50% protein
Inner membrane ~75% protein
Facilitates transport:
Metabolites
Ions
Proteins
Ex. Porin
(a.k.a. voltage-dependent anion channel – VDAC)
Large pore-forming protein
a major metabolite channel
Most abundant protein in outer mitochondrial
membrane
Maintains outer membrane permeability: the
exchange of ions and small molecules, including NADH
, and ATP, across the mitochondrial outer membrane
Mitochondria
Structure – Inner Mitochondrial Membrane
Contains:
ETC
Cristae
Invaginations/folds
Inner membrane largely
impermeable
Except:
O2
CO2
H2O
Contains:
Uniport
Antiport systems for specific
metabolites
Regulated permeability key to
bioenergetics of a cell, most
importantly the electron transport
chain
 Mitochondria
Structure - MATRIX

Mitochondrial matrix
Inner most compartment
TCA cycle occurs here
Fat (β) -Oxidation
Contains:
Circular DNA molecule
(mitochondrial DNA -
mtDNA)
Ribosomes
Enzymes
Can synthesize RNA and proteins
 Mitochondria
Mitochondrial DNA (mtDNA)
Mitochondrial (mtDNA)
Encodes 13 proteins
All part of the ETC
Numerous copies within cell
2 copies of nuclear genes
>10 copies of mtDNA genes
Inherited primarily from mothers via
oocyte mitochondria
Can be used to track human
migration and evolution
the mitochondrial genome
mutates 5-10 times faster than
nuclear DNA
Single nucleotide
polymorphisms used to track
maternal ancestry
Note: Most mitochondrial proteins
(~1500) like Porin are not encoded by
mtDNA but by the nuclear DNA
 Mitochondria
Dynamic Organelles
Mitochondrial biogenesis:
Creation of new mitochondria
Mitophagy:
Selective degradation of old/dysfunctional
mitochondria via autophagy
Autophagy – lysosomal recycling of cellular
components
Mitochondria fusion:
Fuse with one another
Mitochondrial fission:
Split in two
Evidence suggests this could be induced by
endoplasmic reticulum (ER)
Fusion and fission is likely a major
determinant of Mitochondrial:
Number
Length
Degree of interconnection.

https://www.youtube.com/watch?v=CIXY-Ns5vks
Mitochondria
Roles and Importance of the
Mitochondria for Human Health

For example:

1. Cellular Respiration (ATP)
→ ENERGY
2. Cataplerosis
→ ANABOLISM
3. Calcium homeostasis
→ SIGNAL TRANSDUCTION
4. Apoptosis
→ CELL LIFE CYCLE
 Roles Of Mitochondria:
1. Carbohydrate Metabolism in the Mitochondria

2
 Glycolysis
Glycolysis http://cfcc.edu/faculty/dnorris/pdf/glycolysis.jpg

Investment Phase
Metabolizes monosaccharides
Primarily glucose
Produces:
Net 2 ATPs/glucose
2 NADH/glucose
2 Pyruvate/glucose
Anaerobic pathway
Or to fermentation
Requires no O2
Pyruvate
Catabolized aerobically or
anaerobically
Occurs in the cytosol
Payoff Phase

https://www.youtube.com/watch?v=8Kn6BVGqKd8 Or to fermentation
 Roles Of Mitochondria:
1. Carbohydrate Metabolism in the Mitochondria
Pyruvate Entry
Glycolysis produces Pyruvate (Pyruvic acid)
Pyruvate must be transformed and
transported into mitochondrial matrix by
Pyruvate Dehydrogenase (PDH)
Pyruvate dehydrogenase (PDH)
Multienzyme complex
Highly regulated
A switch regulating Carbohydrate vs Fat
Metabolism
Pyruvate transported and converted to
Acetyl-CoA
1. Decarboxylated to form a 2 carbon
acetyl group
2. Acetyl group transferred to
coenzyme A (HS-COA) to produce
Acetyl CoA
Overall Reaction:

Pyruvate + HS-CoA + NAD+ → acetyl CoA + CO2 + NADH + H+
PDH
 Roles Of Mitochondria:
1. Carbohydrate (fatty acid) Metabolism in the
Mitochondria
TCA/Krebs/Citric Acid Cycle
Glycolysis

PDH

β (Fat)-Oxidation
In mitochondrial matrix
Accepts:
Acetyl-CoA
From Pyruvate via PDH
Fatty Acid Oxidation
Per Acetyl-COA Produces:
1 ATP
Reducing Equivalents:
3 NADH + 1 NADH from PDH for
Pyruvate
1 FADH2
 Roles Of Mitochondria:
1. Carbohydrate Metabolism in the Mitochondria
TCA/Krebs/Citric Acid Cycle
Glycolysis

PDH

β (Fat)-Oxidation
Stepwise cycle
1. Acetyl-CoA (2 Carbons) is condensed
with oxaloacetate (OAA; 4 C) to form
citrate (citric acid; 6 C).
2. 2 Carbons lost to CO2, eventually
regenerating the OAA
3. 4 pairs of electrons (carried via NADH
and FADH2) are removed
4. NADH and FADH2 transported to the
electron transport chain
 Roles Of Mitochondria:
1. Carbohydrate (fatty acid) Metabolism in the
Mitochondria
Oxidative Phosphorylation
Electron Transport Chain: Intermembrane
Electrons from: space
NADH (via Complex I) Matrix
FADH2 (via Complex II)
Pass through electron transport chain I
Complexes pumps H+ in the matrix to the
intermembrane space across the inner II
membrane
III
Generates proton gradient and
mitochondrial membrane potential
Uses O2 at Complex IV IV
ATP-synthase (Complex V)
Potential Energy from H + Forms ATP
Chemiosmosis
NADH
2 or 3 ATP
FADH2
2 ATP
ATP SYNTHASE (V)
Inner membrane
1 molecule of glucose → 36 molecules of ATP
Membrane Potential: -ve +ve
(in theory)
 Roles Of Mitochondria:
1. Carbohydrate (fatty acid) Metabolism in the Mitochondria
Oxidative Phosphorylation
*not every proton transported outside
the mitochondrion necessarily makes it
back into the matrix
Net: 6 ATP

Cytosolic
NADH → 2 ATP/NADH
* (actually between 1.5-2 ATP/NADH rather
than 2.5-3 due to cost of going from cytosol to
matrix)

Mitochondrial
NADH → 3 ATP/NADH
Net: 30 ATP

* (actually between 2.5-3 ATP/NADH)

Mitochondrial
FADH2 → 2 ATP/FADH2
* (actually between 1.5-2 ATP/FADH2)
* (some reports indicate 32 ATP/Glucose)
ATP Synthase

http://youtu.be/xbJ0nbzt5Kw http://youtu.be/3y1dO4nNaKY
 ATP: ENERGY CURRENCY

Adenosine-5'-TriPhosphate (ATP)
Molecular unit of currency → intracellular energy
ATP + H2O → ADP + Pi (~7.3 kcal/mole free energy)
Powers most of the energy-consuming activities of cells
active transport of molecules and ions
nerve impulses
maintenance of cell volume by osmosis
adding phosphate groups (phosphorylation) to many different
proteins, e.g., to alter their activity in cell signaling.
muscle contraction
beating of cilia and flagella (including sperm)
bioluminescence
 ATP: OTHER FUNCTIONS
Cell Signalling:
Substrate in signal transduction
pathways by kinases that
phosphorylate proteins and lipids
Used by adenylyl cyclase to produce
the second messenger molecule
cyclic AMP
Anabolism:
monomer used in the synthesis of
RNA and, after conversion to
deoxyATP (dATP), DNA
Roles Of Mitochondria:
2. Cataplerosis
Anabolic molecules
produced in
mitochondria
Cataplerosis
Specifically metabolic
intermediates from TCA
cycle used for anabolism
Ex.
Citrate
For Fatty Acids,
Lipids and Sterols
ɑ-Ketogluterate
For some amino
acids
Succinyl-CoA
For Heme groups
Malate
For some amino
acids
 Roles Of Mitochondria:
3. Calcium regulation
Free calcium (Ca2+)
Intracellular signalling molecule
Mitochondria can transiently store calcium
“cytosolic buffers" for calcium
1. Porin/VDAC on the outer membrane allows Ca2+ into the
intermembrane space
2. Calcium uniporter, in the inner membrane, transports Ca 2+ into
the matrix
Driven by the mitochondrial membrane potential
Intermembrane space highly +ve
Release of calcium back into cytosol occurs via a sodium-
calcium (Na+-Ca2+) exchanger in the inner membrane
Roles Of Mitochondria:
4. Apoptosis

Reactive Oxygen Species (ROS)

Impaired calcium
homeostasis
Abnormal
fission/fusion
Insufficient ATP
production
Release of
mitochondrial ROS
Roles Of Mitochondria:
4. Apoptosis

Apoptosis = programmed cell death
 Roles Of Mitochondria:
4. Apoptosis

Intrinsic Apoptotic Pathway:
De-phosphorylated Bad associates with the
Bcl-2 proteins
Bcl-2 dissociates from the Bax proteins
Dissociation of Bax generated pores in the
mitochondrial membrane which permit the
influx of ions
Cytochrome c is released through the pores
and activates Apaf-1
Activated Apaf-1 activates the caspase
pathway and initiates programmed cell
death pathways
Roles Of Mitochondria:
4. Apoptosis

https://www.youtube.com/watch?v=hqhxnWty5jc
Brief Review of Mitochondria

Structure Roles (examples)
2 membranes 1. Carbohydrate
Outer and Inner metabolism
2 compartments TCA Cycle (Matrix)
Intermembrane space ETC (Inner
Matrix mitochondrial
Contains mtDNA membrane)
Site of Aerobic 2. Cataplerosis
Respiration
Dynamic 3. Calcium Regulation
Created, degraded, 4. Apoptosis
fused, fizzed
Case study
Healthy baby born at term
No complications in the pregnancy
Met all developmental milestones up to
6 months
12 months of age
Lost basic motor skills such as:
Sucking
Head control
Walking
Talking
Irritable
Appetite loss
Seizures
18 months
Vision loss
Respiratory problems
MRI found brain lesions, particularly in the
midbrain and brainstem
Case study
What might be wrong with
this child?

What would be the
molecular processes through
which these symptoms
manifested?
 Case study
Leigh’s Syndrome/Disease
Progressive neurometabolic disorder affects infants between the age of
three months and two years
1 in 77,000 births
At least 26 causative/contributory enzymatic defects have been identified
Pyruvate dehydrogenase (PDH) deficiency, and respiratory chain
enzyme (ETC) defects - Complexes I, II, IV, and V
Deficient ATP production, severe mitochondrial defects, cellular
apoptosis
No cure, prognosis is poor → live anywhere from a few years to the mid-
teens
Mitochondrial Diseases
https://www.youtube.com/watch?v=XX7irov3uKw
Mitochondrial Diseases
Refers to a group of disorders
The result of a genetic mutation in the mitochondrial
DNA or Nuclear-encoded mitochondrial proteins
(nuclear DNA), resulting in mitochondrial failure
Insufficient ATP production
Impaired Ca2+ homeostasis
Abnormal cell signalling and function
Increased cell death
~ 1 in 6000 people have some form of mitochondrial
disease
Symptoms can range from mild to severe
Currently no cure for these diseases**, research
underway
Mitochondrial Diseases
Leigh Syndrome French Canadian Type
First described in Saguenay-Lac-
Saint-Jean
Estimated ~ 1 in 2000 live births
~1 in 23 harbour mutation
May be a founder effect
Characterized by:
Chronic metabolic acidosis
Hypotonia
Facial dysmorphism
Delayed development
Caused by:
Mutation in LRPPRC
Protein involved in the stability of
mitochondrially-encoded mRNAs
https://rarediseases.info.nih.gov/diseases/8370/leigh-syndrome-french-canadian-type
Mitochondrial Diseases
What influences severity of Mitochondrial Diseases?
Heteroplasmy = presence of > 1 type of mtDNA
within a cell or individual
 Mitochondrial diseases:
mtDNA 3 parent IVF

http://www.wellcome.ac.uk/About-us/Policy/Spotlight-issues/Mitochondrial-diseases/
 Mitochondrial
diseases:
mtDNA 3 parent IVF
Successfully conducted in mice since 1990
2008 – Newcastle University, successfully
transferred pronuclear DNA between day 1
single cell human embryo
Embryos develop normally to blastocyst
stage with minimal carryover of maternal
mtDNA
2009 – successfully conducted on primates
resulting in offspring with no detectable
carryover of maternal mtDNA
Feb 2015 – approved for use in UK, go into
effect Oct 2015
2017 First baby was born from mother with
mitochondrial disease

http://www.geneticsandsociety.org/article.p
hp?id=6527#1a
 Mitochondrial diseases:
mtDNA 3 parent IVF
Mitochondrial Replacement Therapy (MRT) remains illegal in
Canada

Assisted Human Reproduction Act (2004)
no person can knowingly "alter the genome of a cell of a
human being or in vitro embryo such that the alteration is
capable of being transmitted to descendants."
fines of up to $500,000, or a jail sentence of up to 10
years, or both

http://www.cbc.ca/news/health/why-canada-isn-t-ready-to-talk-about-3-parent-
babies-1.2956257
 Mitochondrial diseases:
mtDNA 3 parent IVF
Potential benefits:
Parents can have children that are genetically related to
them
Children potentially born free from mitochondrial
disorders
This protection will be carried on in all future descendants
 Mitochondrial diseases:
mtDNA 3 parent IVF
What are the ethical
considerations of this
treatment option?
Identity of offspring?
Designer babies? Slippery
slope?
Status/rights of donor
mother?
Long term adverse effects of
treatment may not be
immediately apparent. Is it OK
to implement an experiment
treatment on future
generations?
 Mitochondrial diseases:
mtDNA 3 parent IVF - Unregulated MRT
Dr. John Zhang
2016
Performed MRT with
woman suffering from
Leigh’s syndrome
Mother previously had 4
miscarriages and 2
children die as a result of
the disease
Procedure illegal in US
Performed procedure in
Mexico
https://www.washingtonpost.com/national/health-science/this-fertility-doctor-is-pushing-
the-boundaries-of-human-reproduction-with-little-regulation/2018/05/11/ea9105dc-1831-
11e8-8b08-027a6ccb38eb_story.html
Questions?
Next Lecture
Interactions Between Cells and Environment (Ch. 7)