transcription-g10 (1).pdf

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Transcription
Objectives
At the end of the topic lesson, the learners should have:

-diagrammed the steps in transcription and translation.
What are proteins?
They are composed of amino acids
linked together by peptide bonds.
Roles and functions of proteins:
channels in membranes –
control the movement of
molecules in and out of the cell
structural molecules – for
example, making up hair or
muscle in animals
hormones – to regulate the
activity of cells
antibodies – in the immune
system
enzymes – to act as catalysts in
biological systems.
Protein synthesis
Protein synthesis refers to the
biological process whereby
amino acids are assembled by
peptide bonding into specific
polypeptide sequences in
accord with genetic blueprints
encoded by deoxyribonucleic
acid (DNA).
Steps in protein synthesis:
Transcription
Translation
DNA and RNA
DNA (deoxyribonucleic acid)
and RNA (ribonucleic acid)
work together to produce
proteins from genetic codes.
Genetic codes are found in
DNA or RNA which is made up
of nucleotide bases usually in
three’s (triplet) that code for the
amino acids making up the
proteins.
Seatwork: 15 minutes
Contrast DNA and RNA according to their type of sugar, structure,
stability under certain conditions, functions, and nitrogenous
bases.
½ crosswise paper
Worth 20 points
Open notes
Can access the internet
A short summary of the difference between
DNA and RNA.
RNA
RNA (Ribonucleic Acid), unlike the double
stranded DNA, is a nucleic acid polymer with a
single strand.
It is composed of the four nucleotides adenine,
uracil (replaced thymine in DNA), guanine and
cytosine which are represented by their first letter
A, U, G, C. (The only difference with DNA is the
Uracil).
RNA is the first intermediate in converting the
information from the DNA into proteins which is
important for proper cellular function.
Thymine vs Uracil
The main distinction between thymine
and uracil lies in their chemical
structure.
Thymine has a methyl group (CH3)
attached to its ring structure, whereas
uracil does not have this methyl group.
This structural difference is responsible
for the various roles of thymine in DNA
and uracil in RNA.
Uracil is the demethylated form of
thymine.
Stability
Thymine, with its methyl group, improves
the stability and structural reliability of
DNA.
The methyl group helps protect the DNA
molecule from chemical damage and
enzymatic destruction.
It also plays a character in holding errors
in DNA replication and maintaining the
overall structure of the DNA double helix.
Stability under
alkaline conditions
Due to its deoxyribose sugar, which
contains one less oxygen-
containing hydroxyl group, DNA is a
more stable molecule than RNA,
which is useful for a molecule
which has the task of keeping
genetic information safe.
RNA, containing a ribose sugar, is
more reactive than DNA and is not
stable in alkaline conditions.
Functions
RNA falls into three major
categories:

Messenger RNA (mRNA)
Ribosomal RNA (rRNA)
Transfer RNA (tRNA)
mRNA
mRNA copies the genetic code from
the DNA into a form that can be read
and used to make proteins. mRNA
transmits genetic information from
the nucleus to the cell’s cytoplasm.
rRNA
rRNA is situated in the cytoplasm of
a cell, where we can find the
ribosomes. rRNA leads the
translation of mRNA into proteins.
tRNA
tRNA transfers amino acids to the
ribosome that matches to each
three-nucleotide codon of rRNA.
The amino acids then can be
combined together and processed
to make polypeptides and proteins.
1. Messenger RNA (mRNA)
- transcribes the DNA nucleotide bases to RNA nucleotide
bases
2. Ribosomal RNA (rRNA)
- binds the mRNA and tRNA to ensure that codons are
translated correctly
3. Transfer RNA (tRNA)
- translates the mRNA codons into the correct amino acids
Transcription
Transcription in protein
synthesis is the process where
RNA is made from the DNA by
copying the base sequence of
the double stranded DNA into a
piece of a single stranded
nucleic acid.
This transcription process is
catalyzed by the enzyme RNA
Polymerase.
Location
Transcription of DNA to form RNA takes
place in the cell’s nucleus.
This process uses DNA as a model to
make an RNA (mRNA) molecule.
During transcription, a strand of mRNA
is made that corresponds to a strand of
DNA.
Just like DNA replication, transcription
also occurs in three major steps:
initiation, elongation and termination.
Why does it happen in the
nucleus?
Initiation
Initiation is the start of transcription.
It transpires when the enzyme RNA
polymerase binds to a specific region
of a gene which is called the
promoter with the help of proteins
called ‘transcription factors’.
This signals the DNA double strand to
unwind and open so the RNA
polymerase enzyme can ‘‘read’’ the
bases found in one of the DNA
strands.
 With the open strands, one is
considered as the template strand
(anti-sense strand) and this will be
used to generate the mRNA. The
other is called the non-template
strand (sense strand).
After reading the bases, the RNA
polymerase enzyme is now ready to
make a strand of mRNA with a
complementary sequence of bases.
Elongation
Elongation is the adding of nucleotides
to the mRNA strand. RNA polymerase
reads the opened DNA strand and forms
the mRNA molecule with the use of
complementary base pairs.
There is a short time during this process
when the newly formed RNA is bound to
the opened DNA. During this process of
elongation, an adenine (A) in the DNA
binds to an uracil (U) in the RNA.
 RNA polymerase does not need a
primer during this process. It simply
initiates the mRNA synthesis from
the starting point and then moves
downstream reading the anti-sense
strand from 3’ to 5’ and generating
the mRNA from the 5’ to 3’ end as it
goes.
Unlike helicase enzyme in DNA
replication, RNA polymerase zips
DNA back up as it goes keeping only
10-20 bases exposed one at a time.
Termination
Termination is the last step of the
transcription process. This happens
when RNA polymerase enzyme
reaches a stop or termination
sequence in the gene.
When the stop sequence or stop
codon is reached, the enzyme
detaches from the gene. The mRNA
strand is now produced and it
detaches from DNA.
 It carries with it the
information encoded in the
gene.
By the end of transcription,
the DNA segment is
transcribed to form the
mRNA molecule.
The template strand shown
with the sequence T-A-C-T-A-
G-A-G-C-A-T-T transcribes to
form the mRNA A-U-G-A-U-
C-U-C-G-U-A-A.
Remember!
Remember to take note of
the transcription pattern:
Thymine to Adenine,
Adenine to Uracil, Cytosine
to Guanine, Guanine to
Cytosine.
Uracil is being synthesized
instead of Thymine as
compared during DNA
replication.
Transcribe your DNA to RNA
Identify the correct mRNA sequence from the given DNA
template sequence.
Answers
1. AUG ACU AGC UGG GGG UAU UAC UUU UAG

2. AUG GCG AGG CGG CAG CUG UUA UGG UGA

3. AUG GUG GGG GCA UAC CGA CCC UUA UAG

4. AUG AGA GGG UUU UUU AUG GUG GGG UAG

5. AUG GAG UGU GAU GCG UAC AAC CCC UAA
What will happen to the
transcribed mRNA?
 For a protein-coding gene, the messenger RNA carries the
information needed to build a polypeptide. The messenger
RNA (mRNA) is the RNA form of the gene that leaves the
nucleus through the nuclear pore and moves to the
cytoplasm where proteins are made.
Take note, transcription is the process wherein the DNA
sequence of a gene is "rewritten" using RNA nucleotides.
Now, it’s ready to be translated.