Muscle Bio Week 3.docx

Full Transcript

Muscle Bio Week 3

***Week 3, Module 3: Fuel Delivery and Storage in Skeletal Muscle***

the metabolic rates seen in skeletal muscle are unmatched by any other
tissue in the body, and can increase by as much as 200-fold during
exercise. Therefore, the muscle cell (analogous to the F1 engine) is
necessarily different from regular cells (analogous to the standard car
engine) and is specifically designed to optimise fuel delivery to the
sites of cellular energy production (i.e., the mitochondria). This
allows the muscle cell to maintain a ***high rate of energy
production*** to fuel exercise.

Muscle cells (also known as ***myocytes***) must use both extracellular
(sourced outside of the cell, such as blood glucose or lipids) and
intracellular (sourced inside the cell, such as intramuscular glycogen,
lipids, phosphocreatine, and stored ATP) substrates to fuel energy
production.

*[Skeletal Muscle Structure: Key Terminology ]*

Muscle cells are also known as ***myocytes***. The cell membrane of a
muscle cell is known as the ***sarcolemma***, and the interior of the
cell, the cytoplasm, is known as the ***sarcoplasm***.

The sarcoplasm contains the usual subcellular structures (known
as ***organelles***):

- Nucleus, mitochondria, Golgi apparatus, lysosomes

- A specialised version of the endoplasmic reticulum known as
the ***sarcoplasmic reticulum***

In addition to these typical subcellular structures, muscle cells also
contain a number of specialised structures designed to enhance the
ability of muscle to produce and use energy for muscle contraction.

These structures include:

- ***Myofibrils*** that contain the contractile elements of the muscle
cell (i.e., the sarcomeres)

- ***T-tubules*** to enhance the function of the sarcoplasmic
reticulum

- ***Myoglobin** *(an oxygen storage and transport site)

- Stored ***glycogen*** (in the form of glycogen granules) and
stored ***triglycerides*** (in the form of lipid droplets)

- ***Multiple nuclei*** per cell (as opposed to typical cells that
contain a single nucleus)

[Mitochondria: The Site of Aerobic Energy Production ]

- During aerobic metabolism, ATP production occurs within the
mitochondria. This applies to both carb and fat sources of ATP. Both
sources are then converted in Acetyl-CoA to then be broken down into
fuel.

- How well aerobic ATP production occurs is dependent on the number
and size of the mitochondria, the capacity for oxygen transport to
the muscle (via capillaries and the bloodstream supplying the
muscle) and the storage of oxygen (determined by levels of cellular
myoglobin).

- Mitochondria within muscles are arranged in a continuous membrane
system, aka mitochondrial reticulum.

- They are the powerhouse of the cell

*Structural Features*

- Inner membrane: impermeable to ions and polar molecules unless
they\'ve got specific transporters

- Outer membrane: encases the mitochondria and \'pores\' for ions and
polar molecules

- Cristae: increases the surface area of the inner membrane.

- Intermembrane space: has enzymes related to the electron transport
chain

- Matrix: has enzymes of the Kreb Cycle and enzymes for fatty acid
oxidation

There are 2 different types of mitochondria within muscles:

1. ***Subsarcolemmal mitochondria*** account for \~10-15% of total
mitochondria, and are located near the sarcolemma (outer membrane of
the myocyte). Their location near the sarcolemma suggests they are
likely involved in ATP production for events occurring at the cell
membrane, such as membrane transport (e.g., transporting circulating
fatty acids into the cell)

2. ***Intermyofibrillar mitochondria*** are more abundant (85-90%) and
are embedded among the myofibrils. They have higher rates of aerobic
energy production than sarcolemmal mitochondria. This is because
intermyofibrillar mitochondria are believed to provide energy
primarily for the contractile apparatus (i.e., the sarcomeres),
hence being important for muscle contraction.

[Delivery of Extracellular Fuels to Skeletal Muscle ]

*Capillaries*

- Delivers nutrients to and removes waste products from cells,
including muscle cells.

- The capillary bed constitutes a vast surface that facilitates
exchange of oxygen, substrates and metabolites between blood and
skeletal muscle.** **While the muscle microvasculature is optimally
designed for the transfer of oxygen from the circulation to muscle
cells, it is less efficient for the transfer of substrates.

- Because of the lack of substantial oxygen stores in muscle, the
oxygen required to meet energy demands has to be supplied by the
circulation. By contrast, only a limited quantity of substrates is
supplied from the circulation during exercise, due to the
availability of intramuscular energy stores.

- At exercise intensities above 30% VO2max, there is more reliance
from the muscle on intracellular substrate stores, eg: glycogen.
These stores eventually exhaust during exercise = onset of fatigue
and diminished performance. These stores will replenish during rest
or lower energy demands.

- The rate of carb and fat transport are at max during low intensity
exercise (40% VO2max) and can\'t be increased during high intensity
exercise. At higher intestines, the muscles rely on the
intracellular fuel stores, ie: glycogen and lipid stores in the
cell. No more than 20-30% of fuel in the muscle comes from
extracellular sources.

*T-Tubules*

- Tunnel-like extensions of the sarcolemma, extending from one side of
the cell layer to the other.

- Allows for the end of the cell to be reached.

- The first function of the t-tubules is to enable the movement of
electrical charge from the cell surface to the internal areas of
myofibres, triggering the release of calcium ions from the
sarcoplasmic reticulum. Without t-tubules, electrical conduction
into the interior of the cell would happen much more slowly, causing
delays between neural stimulation and muscle contraction - resulting
in slower, weaker contractions.

- The t-tubules also play a role in substrate metabolism and contains
a significant proportion of the insulin receptors and glucose
transporters.** **The t-tubule network therefore allows glucose to
be delivered in a targeted manner to the intracellular metabolic
machinery within a skeletal muscle cell.

- Substrates can be quickly carried to the centre of the muscle fibre
where there are proteins to transport glucose (and presumably other
substrates) across the t-tubule membrane to the site where it can be
immediately used for energy or stored.

[Intramuscular Fuel Stores ]

- Mitochondria can consume fuel faster than the supply from external
sources.

- For contraction to be sustained, the muscle then relies on its
internal stores.

- Metabolic fuels within the muscle are pools of glycogen granules and
lipid droplets.

*Glycogen*

- Glycogen is a branched chain polymer containing many glucose sub
units. A glycogen particle in a skeletal muscle can contain as much
as 50,000 glucose molecules.

- The amount of glycogen stored within the muscle is dependent on 3
things:

a. Training status

b. Basal metabolic rate

c. Nutritional habits.

- Muscle glycogen functions as an immediate reserve source of
available glucose for muscle cells. As muscle cells lack the
enzyme ***glucose-6-phosphatase***, which is required for glucose to
be transferred back to the circulation, the glycogen stored in
muscle is 'locked' inside the muscle cell for exclusive use, and is
not shared with other cells.

- Due to the reliance on glycogen in anaerobic glycolysis, the oxygen
demand is low.

- Glycogen availability is essential to power ATP resynthesis during
high-intensity exercise, which relies heavily on glycogenolysis (the
breakdown of glycogen into its component glucose molecules) to
liberate the energy needed for ATP resynthesis. Reductions in muscle
glycogen levels are associated with impaired exercise performance,
even when there is sufficient amount of other fuels available.

- Glycogen is often thought of as being uniformly distributed within
the muscle cell. However, glycogen is actually distributed within
the muscle fibre in ***distinct pools***, allowing glycogen to act
as a metabolic fuel for different processes involved in muscle
contraction:

a. ***Subsarcolemmal glycogen***: located
just [beneath] the sarcolemma (5-15% of glycogen
stores)

b. ***Intermyofibrillar glycogen***:
located [between] the myofibrils, mainly at the
level of the I-band close to mitochondria and sarcoplasmic
reticulum (\~75-85% of glycogen stores), and

c. ***Intramyofibrillar glycogen***:
located [within] the myofibril, mainly near the
Z-line of sarcomeres (5-15% of glycogen stores).

- Due to being so close to the site of contraction and able to sustain
high rates of ATP production, this is why it is the primary fuel for
moderate to intense exercise.

- The intramyofibrillar pool of glycogen influences calcium release
from the SR.

- impairments in muscle function during fatigue are associated with
defective calcium release from the sarcoplasmic reticulum, this pool
of glycogen plays a key role in limiting fatigue during exercise

*Intramuscular Triglycerides*

- Intramuscular triglycerides are mostly found in the cytoplasm of
oxidative (type I) muscle fibres as lipid droplets.

- These lipid droplets are located between the myofibrils and in close
proximity to the mitochondria, therefore providing a
readily-available source of fatty acids for energy production (via
oxidative phosphorylation).

- Lipid droplets in skeletal muscle are in direct contact with the
outer mitochondrial membrane, which is often marked by a 'dent' in
the mitochondria

- It seems likely that the fatty acids are transported across the
mitochondrial membrane within these areas of contact, allowing them
to be more quickly transported into energy production sites.\
In skeletal muscle cells, IMTGs represents a fuel that can be either
mobilised or stored depending on the cellular energy demand.

- When energy demands increase, such as during exercise, the
triglyceride can be broken down to glycerol and 3 fatty acid chains,
in a process called ***hydrolysis***. The free fatty acid chains can
then be used to fuel ATP production within the mitochondria.\
Conversely, when energy demands are low, free fatty acids (FFAs) can
be combined with glycerol to form IMTGs via a process known
as ***esterification***. This results in an increase in stored IMTGs
that can be used later when required.