Muscle Bio Week 8.docx

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***Week 8, Module 8: Basics of Gene Transcription and Protein
Synthesis***  

- Info needed to synthesise proteins is coded in the sequence of bases
(or nucleotides) that make up the DNA code within a cell\'s nucleus.

- DNA of the nucleus controls every aspect of the cell\'s structure
and function, eg: the nucleus can accelerate the rate of glycolysis
in the cell by increasing the synthesis of glycolytic enzymes within
the cytoplasm.

- Skeletal muscle cells are special when compared to many other cells
within the body -- one example being they are multi-nucleated cells.
When we consider this means that muscle cells have more of the
'blueprints' required to make proteins (encoded in the nuclei), this
helps to explain the adaptability (plasticity) and regenerating
qualities of skeletal muscle.

- New proteins are made by activating genes encoded in the DNA that
resides in the nucleus of the cell.

- when exercise is repeated over time, repeated 'bursts' of gene
activation (expression), coupled with the translation of gene
transcripts (messenger RNA or mRNA) into specific proteins,
culminate in the adaptations associated with either endurance or
resistance training. These internal, molecular level changes is what
underpins the external adaptations that we see.

*DNA, RNA and Protein*

[DNA]

- Deoxyribonucleic acid

- Double helix structure. Comprised of the nucleotide bases: Adenine,
Cytosine, Thymine and Guanine.

- Located in the nucleus of each cell. Mitochondria also contain DNA
that encodes 13 mitochondrial specific proteins.

- The genetic code is called a '***triplet code***' because a sequence
of three nucleotide bases (ACG, or AAA, or TAG) specifies the
identity of a single amino acid.

- The information within this code contains the blueprint for \~30,000
genes, and allows the synthesis of somewhere from 100,000 to 200,000
different proteins. On average, each gene consists of 3000 bases,
but this varies greatly and some genes contain as many as 2.4
million bases

[RNA]

- Ribonucleic acid

- Molecules essential for the regulation and expression of genes

- Single stranded.

- Used to copy genetic info from DNA

3 types of RNA

1. Messenger RNA (mRNA): copies genetic info from DNA, this process is
called transcription. The copied DNA is then given to the cytosol in
the cell, to the ribosomes, where they specify which amino acids
need to join together to make new proteins.

2. Transfer RNA (tRNA): links the mRNA and amino acid sequence by
carrying amino acids to the cellular 'factory' where new proteins
are made (ribosomes). The tRNA does this by containing the amino
acid linked to a three-nucleotide sequence (codon), which is
complementary and specific to the codon on the mRNA.

3. Ribosomal RNA (rRNA):  combine to form two subunits of a ribosome,
known as the large and small subunits. During translation, an mRNA
strand is 'sandwiched' between the small and large subunits, and the
ribosome catalyses the formation of a peptide bond between the two
amino acids that are contained in the rRNA.

[Transcription from DNA to mRNA]

- Transcription happens in the nucleus. It\'s the process of copying
part of DNA to make an RNA molecule.

- Transcription means to copy or rewrite.

- The forming of mRNA in this process is catalysed by the enzyme RNA
polymerase. This enzyme reads the DNA and transfers the genetic code
of target genes to an mRNA molecule using ribonucleotides to the
mRNA.

- Only one strand of DNA is copied and RNA formed is referred to as
the primary gene transcription.

- RNA is made up of guanine, cytosine, adenine and uracil.

- Guanine will bind to Cytosine, Cytosine will bind
to Guanine, Adenine will bind to Uracil, and Uracil bind to Adenine

[Translation from mRNA to Protein ]

- This occurs on the ribosomes residing within the cytosol and is the
site of protein synthesis.

- The mRNA is converted into a sequence of amino acids to form a
polypeptide chain.

- The meaning of 'translate' is to present the same information in a
different language; in this case, a message written in the language
of nucleic acids (the mRNA) is translated by ribosomes and tRNA into
the language of proteins (sequences of amino acids)

Translation has 3 phases:

1. Initiation: the translation of an mRNA into a peptide chain is
\'initiated\' by the formation of a complex containing a tRNA
carrying the Methionine amino acid (which is the first amino acid in
all proteins), a protein known as an initiation factor, and another
type of high-energy phosphate molecule known as GTP (guanine
triphosphate).Once formed, this complex then binds with other
initiation factors, and attaches to the ribosome so that translation
can begin.

2. Elongation: the process whereby the peptide chain is \'elongated\'
via the addition of more amino acids to the growing peptide chain.
The first phase of the process involves the tRNAs bringing each
amino acid to the ribosome, and the second involves the movement of
the ribosome along the mRNA strand, so that the mRNA code can
continue to be read and the peptide chain can grow.

3. Termination: The translation process is terminated when a \'stop\'
codon (UAA, UAG, or UGA) on the mRNA strand is encountered within
the ribosome. This process culminates with the release of a
newly-formed polypeptide (i.e., protein) chain from the ribosome.

*Control of Gene Expression and Protein Synthesis*

- As a physiological stress, exercise can affect the degree of
expression of genes (and therefore levels of specific proteins)
within skeletal muscle. A gene can be induced (its product
increases) or it can be repressed (its product decreases). The steps
below correspond to the numbered picture on the right:

1. Transcription of DNA to RNA

- Most important control point of gene expression.

- Exercise enhances transcription of genes encoding structural
proteins, transport proteins and enzymes.

2. Conversion of primary RNA to mRNA (RNA processing)

- Once RNA is copied to a new strand from DNA, it can undergo
alteration. This leads to a new stand of mRNA and the synthesis
of a different protein.

3. mRNA transport from the nucleus into the cytosol

4. mRNA stability (delay of degradation by ribonucleases)

- Lifespan of mRNA varies between minutes to hours. This lifespan
can be viewed as another level of control and how long it
survives if dictated by the degradative enzymes called
ribonucleases.

- How long the molecules last can be regulated by proteins that
stabilise mRNA, whilst others destabilise it.

- The long the mRNA is in the cell, the more proteins it can make.

5. Translation of mRNA to protein

- Levels of a certain protein within the cell are clearly
dependent on whether or not the mRNA encoding that protein is
translated at the ribosome. 

- It is important to consider, however, that abundance of a given
protein can occur without any apparent increase in its
corresponding mRNA. 

- This suggests that either the rate at which existing mRNA are
translated is increased, or that there is a decrease in the
rate at which the given protein is degraded within the cell.

6. Protein stability

- Proteins are more stabile than mRNA, but can also be degraded.
This refers to the ratio of protein synthesis to protein
breakdown.

- Protein degradation is carried out by 3 major enzymes known as
proteases: calpain (calcium activated neutral protease) system,
autophagy-lysosomal system and ubiquitin proteasome pathway. The
activation of these enzymes increases in catabolic conditions,
including diseased states such as cancer or AIDS.

7. Post translational modification of proteins

- Similar to how RNA can be altered following transcription to
produce alternate mRNA 'codes', proteins can also undergo
alterations after being translated from mRNA. This can change
the resultant protein structure or function.