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Gene Expression
Three Important Points
to Remember
- Chromosomes are
made of DNA
- Segments of DNA
code for a protein
- Protein in turn,
relates to a trait (eye color, enzymes, hormones..)
How are Proteins Synthesized
from DNA
1. DNA is trancribed
into mRNA (messenger RNA)
2. mRNA leaves the nucleus and travels to the cytoplasm
3. Ribosomes in the cytoplasm use the code on mRNA to translate it into
amino acids
4. Amino acids form a chain - a protein
Sounds simple, huh?
Well, you're not getting off that easy, now we will break down each step
of the process.
Transcription
RNA is very similar
to DNA with the following exceptions:
- it is single stranded
- it has uracil instead
of thymine
- it has the sugar
ribose, instead of deoxyribose
The base-pair rule
is followed during transcription, except, instead of pairing thymine with
adenine, when creating an RNA strand, uracil is used
DNA Strand: T G C
A T C A G A
RNA Strand: A
C G U A G U C U
View the following
animation: Transcription
Transcription begins
on the area of DNA that contains the gene. Each gene has three regions:
1. Promotor - turns
the gene on or off
2. Coding region - has the information on how to construct the protein
3. Termination sequence - signals the end of the gene
RNA Polymerase is
responsible for reading the gene, and building the mRNA strand. It reads
only the 3' to 5' strand.
Still confused: Check
on these animations:
Transcription 2 - http://www.ncc.gmu.edu/dna/mRNAanim.htm
Transcription
3 - http://www.stolaf.edu/people/giannini/flashanimat/molgenetics/transcription.swf
Translation
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View the animation
of translation: Translation
1. The mRNA
travels to the cytoplasm
2. Amino acids exist freely in the cytoplasm, many of them you acquire
from your diet
3. Each 3 bases (codon) translates to a single amino acid. (See
codon chart)
4. The ribosome looks for the "start" codon - AUG, this
is where the chain begins
5. Transfer (tRNA), has an anticodon at one end and an amino acid
at the other, it binds to a complementary codon.
6. Another tRNA reads the next codon, the amino acid attached to
it binds with the amino acid on the previous tRNA using a peptide
bond. The first tRNA falls off.
7. This process continues until the "stop" codon is reached.
8. The amino acid chain folds into a 3 dimensional structure, now
a protein.
9. That protein can be an enzyme, a hormone, or any other structure
in the body that gives it traits and functionality.
Still confused?
Check out other animations:
Translation
2 - http://www.cat.cc.md.us/biotutorials/protsyn/translat.html
Translation
3 - http://www.stolaf.edu/people/giannini/flashanimat/molgenetics/translation.swf
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Test
for Understanding
A
DNA sequence has the following bases: T A C - A G A - T T A - G
G G - A T T
What amino acids does it code for? (You'll need to use the codon
chart)
Answer
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Image of Transcription
---> Translation
Tying it
altogether - the Lac Operon Gene
E. Coli bacteria
can synthesize lactase, which is an enzyme that breaks down lactose. Lactase
is only synthesized in the presence of lactose. If there is no lactose
in the environment, the gene is repressed. Since they live in the intestinal
tract of humans, they must live on whatever the host eats. When you drink
milk, you are provided your E. Coli bacteria with lactose.
- E. Coli
has three genes that code for lactase.
- It also has an
operator and a promotor.
- Without lactose,
the lac repressor binds to the operator site.
- With lactose, the
repressor is removed
- Once repressor
is removed, RNA polymerase binds to the promoter
- RNA is transcribed,
which is then translated, and becomes the lactase enzyme.
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View
movie on the lac operon.
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Here is
another movie that shows transcription and translation, however
it is a very large file (10.8 mb). It is not recommended for
view unless you have a very fast connection or plenty of time
to wait for it to load: transcription.mov
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Test Your Understanding
by labeling the parts of image below: See
answer.
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