Muscle Bio Week 9.docx

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***Week 9, Module 9: Introduction to Cell Signalling and Exercise***

- Contraction of skeletal muscle disrupts homeostasis. An appropriate
response is developed and adaptations then occur to help minimise
future disruptions to homeostasis.

- Following exercise and ***muscle contraction***, both extracellular
(e.g., hormones, mechanical load) and intracellular (e.g., changes
in the cellular concentrations of AMP, ATP, oxygen, and reactive
oxygen species) ***signals*** are rapidly '***sensed***' by skeletal
muscle. This leads to intracellular ***signal transduction*** or the
activation of "signalling cascades", which communicate the exercise
signal within the muscle cell and ultimately lead to altered gene
expression, and eventually translation to protein and functional
adaptation of the cell. This process is termed "***regulated
transcription***".

- Importantly, the default state of transcription in humans is "off",
which means that unless transcription is turned on, gene expression
cannot occur. Once activated by muscle contraction and the sensing
of primary signals, any signalling cascades result in the activation
of transcription factors, which can bind to specific DNA sequences
and activate transcription, thereby ***regulating gene expression***

*Cell Signalling Basics*

- Cell signalling is an important communication mechanism within the
cells.

- It links the incoming info of what is disturbing homeostasis with
then how to appropriately respond to it. Be generating the right
response, it will then lead to adaptations to prevent disruption in
the future.

Phosphorylation

- This is the addition of a phosphate group to a protein on a
phosphate accepting amino acid. In humans this normally happens on
the amino acids serine, threonine and tyrosine.

- Phosphorylation is a form of post translational modification as the
protein is altered after it has been synthesised/translated.

- Kinases, which aid in the transfer of phosphate to another molecule,
belong to a group of enzymes called phosphotransferases.
Phosphotransferases aid in the addition of the phosphate from an
inorganic phosphate (e.g., ATP) to the acceptor molecule

- Many molecules are energy donors that serve to supply the phosphate
group, including ATP. Phosphorylation prepares molecules for the
tasks they need to perform

Dephosphorylation

- Occurs when this phosphate group \"falls off\" or is removed once
the protein has done what it needs to do

- Phosphatases act to remove the phosphate from the phosphorylated
molecules

- Phosphorylation plays an important role in cell signalling, by
altering (increasing or decreasing) the rate of activity of enzymes.
This begins a cascade of events (e.g., protein A phosphorylates
protein B, protein B phosphorylates protein C, etc.), eventually
leading to changes in gene expression and therefore protein content

*Linking Exercise Signals to Physiological Adaptation*

Primary Signals, Signalling Cascades and Gene/Protein Expression

- The signal transduction process associated with exercise is as
follows:

1. Muscle contraction during exercise results in a range of
metabolic (breakdown of metabolic fuels) and mechanical (muscle
stretch or damage) stimuli within the contracting muscle

2. For example, increased turnover of ATP lead to increases in ADP
and AMP, oxidation of metabolic fuels in the mitochondria
produce reactive oxygen species (ROS), and normal contractile
function results in the release of calcium from the sarcoplasmic
reticulum

3. All of these metabolic by-products activate signalling molecules
(or sensors), including protein kinases and phosphatases

4. From there, these sensors are integrated into signal
transduction pathways that activate transcription factors and
transcriptional co-regulators, ultimately leading to changes in
the expression and/or repression of specific genes, and the
accumulation of specific proteins (and hence adaptation) over
time

Timing of Cellular Responses to Exercise

-  the process of transcription (i.e., creating more mRNA) occurs
transiently following exercise. A given bout of exercise elicits a
rapid increase in relative mRNA expression of a given gene, which is
typically greatest at 3--12 hours after exercise and generally
returns to basal levels within 24 hours.

- mRNA response following excessive exercise is decreased, explaining
the concept of diminishing returns and why progressive overload is
important. However, a single bout of exercise only isn\'t enough to
stimulate structural or functional changes

- In response to single exercise bouts, elevated rates of
post-exercise protein synthesis cause relatively modest increases in
protein content, whereas repeated exercise bouts results in the
gradual accumulation of proteins in response to repeated \'pulses\'
of increased gene (mRNA) expression. 

- Long-term adaptations to training are therefore due to the
cumulative effects of each individual exercise session, whereby
changes in protein content or enzyme function can result in improved
exercise performance and whole muscle metabolism