Biology 1001 Unit 9: DNA to Protein PDF

Summary

Notes/presentation from a biology unit on the process of transcription and translation, from DNA to proteins. The topic includes details of the process and significance of the genetic code.

Full Transcript

Biology 1001

SECTION 9

From Gene to Protein
All information for this section can be found in CHAPTER 17

*BEGIN reading at BASIC PRINCIPLES OF TRANSCRIPTION AND
TRANSLATION (p 359-364)
17.2 Transcription is the DNA-directed synthesis of RNA: A closer look (p 364-
367) – ONLY the first section (Molecular components of transcription) (p 364-5)
17.3 Eukaryotic cells modify RNA after transcription (p 367-369)
17.4 Translation is the RNA-directed synthesis of a polypeptide: A closer look (p 369-
378)
Possible Exam Figures
Figure 17.4 Overview: the roles of transcription and translation in the flow of
genetic
information. (p 361)
Figure 17.5 The triplet code. (p 362)
Figure 17.15 Translation: the basic concept. (p 370)
Figure 17.17 An aminoacyl-tRNA synthetase joining a specific amino acid to a
tRNA. (p 371)
Figure 17.25 A summary of transcription and translation in a eukaryotic cell. (p
379)
 We already know that genes control an organism’s
phenotypic traits :
◼ The colour of Mendel’s pea flowers, the white eyes of Thomas Hunt
Morgan’s mutant fruit flies, the white hair of the Kermode bear,
 i.e. what it looks like, and its physiology

 But how do genes determine an organism’s
characteristics?

 What does a gene actually say???
 Concept 17.1 – Genes specify proteins via
transcription and translation

Current knowledge of how GENES work:
 Genes are sequences of DNA that contain the
instructions for making proteins
 The instructions are not used directly but copied out on
RNA molecules
 Messenger RNA carries the instructions to the protein-
making machinery in the cytoplasm of the cell
 Proteins are produced
 And PROTEINS control the traits (characteristics) of
living organisms
 PROTEINS are the link between our DNA and our
CHARACTERISTICS

 DNA dictates the
synthesis of
proteins, via
intermediary RNA
molecules

 And look what
proteins do!
In 1956, Francis Crick summarized the cellular flow of genetic
information in his CENTRAL DOGMA

 Crick said that

 Cells are governed by a
molecular chain of command

 DNA RNA Protein

 Proteins run all the metabolic
processes of life

 This is still almost 100% true
GENE EXPRESSION culminates in the production of PROTEINS

 Gene Expression proceeds in two stages

 1. TRANSCRIPTION – imagine that you transcribe
one book into another, using in different fonts but the
same language (nucleic acid letters)
 Using a DNA template to produce RNA script
 2. TRANSLATION – you translate into another
language (nucleic acid into a sequence of aminoacids)
 Using mRNA (messenger RNA) as an
instruction to produce a polypeptide
 NOTE: In some cases, we stop at p.1 - the end product
of transcription is rRNA (ribosomal RNA) or tRNA
(transfer RNA).

 These are used as is, (i.e. not translated into a protein
product), so in these cases, gene expression stops at
transcription
 Basic Mechanisms of Transcription and Translation are Similar,
but Not Identical in Bacteria and Eukarya

 Bacteria  Eukarya

 No nuclear membrane – DNA in the  Nuclear membrane separates
nucleoid region transcription and translation in space
and time
 Translation can begin while
transcription is still in progress

 And mRNA is processed after
transcription, before export out of the
 mRNA is translated without any
nucleus
additional processing
The link between nucleic acids and proteins

 Is the GENETIC CODE

 Cells use the genetic code to translate DNA/RNA
sequences into proteins

 The code was cracked by scientists in the 1960s
Using logic to work out the GENETIC CODE

 In DNA there are 4 nucleotides A, T, G, C
4 “letters” available
to write the code
 In RNA there are 4 nucleotides A, U, G, C

 IN PROTEINS there are 20 different AAs

 How might 4 LETTERS be arranged to spell
20 different WORDS?

 Nucleotide code words of 1 letter - could only
translate into 4 AAs (one letter – one AA)

 Nucleotide words of 2 letters - could translate
into 4x4 = 16 AAs (4 possibilities in the 1st
position, each having 4 possibilities in 2nd
position)

Nucleotide words of 3 letters - … ?
 If nucleotides are grouped in 3s

, they can be used to spell 64 different words (4 3 )

 More than enough to specify each of the 20 amino acids in
proteins

 SCIENTISTS CONCLUDED THAT

 The DNA language (written using bases A, G, C, and T) must be
written in words three nucleotides long

 TRANSCRIBED into CODONS (again 3 bases long) on the mRNA
(written using bases A, G, C, and U)

 CODONS can then be TRANSLATED into the 20 amino acids that
make up proteins
By mid-1960s the code had been cracked

 All 64 mRNA
codons had been
deciphered

 Codons for all the
20 different
amino acids were
identified
 You do not need to memorize the Table – it will
Fig. 17.6 The Codon Table be given, but have to know how to read it)
for mRNA

We have 64 triplets and
only 20 AA to code:

1.No ambiguity
(no two AA are described
by the same triplet)

2. Redundancy
(all except Met and Trp
described by more than
one (64 combination for
only 20 Aas…)

3. Punctuation
(one Start and 3 Stop
signs)
Punctuation is important because it ensures the correct
reading frame

 Imagine a message sequence:
thebigdogatetheredhat

 Correct reading frame (i.e.: start in the right place, stop in
the right place):
the big dog ate the red hat

 Incorrect reading frame – one off from the beginning:
heb igd oga tet her edh at

◼ Conclusion - Start and Stop codons are vital
 Universality of the Genetic Code

 The genetic code is pretty much universal

 It is shared by all organisms

 from the prokaryotes, to the most complex
plants and animals
◼ With only very minor exceptions
Universality of the Genetic Code has:

1. Evolutionary significance:

 A language shared by all living things must have been
established very early in the history of life

 Early enough to be present in the common ancestor of all
living organisms
 2. Practical significance: BIOTECHNOLOGY

 If the same code can be transcribed and translated
to give the same protein product in all organisms

=> Then genes can be moved between organisms,
and the same protein products should still be
expressed

 GENE TRANSFER TECHNOLOGY has
many applications

 E.g. use of bacteria to express proteins with
medicinal use. E.g.: Golden rice

◼ Insulin
◼ Human growth hormone

Fig. 20.4
Quote from 1958 Nobel Laureate George Beadle and wife Muriel
Beadle

“Deciphering the DNA code has revealed
a language much older than hieroglyphics,
a language as old as life itself,
a language that is the most living language of all-
even if its letters are invisible
and its words are buried deep in the cells of our bodies.”(1966)
 Fig. 17.5 – The triplet code. The flow of information

DNA RNA PROTEIN

 1. DNA template strand acts
as a transcription template

 2. mRNA is transcribed as the
exact complement of the DNA
template sequence, except that
URACIL substitutes for
THYMINE.

 3. Each group of three bases on the
mRNA = a codon

 4. Each codon is specific for a
particular amino acid
Concept 17.2 - Transcription is the DNA-directed synthesis of RNA

Some transcription facts

 Transcription = production of RNA (the “on-site instructions”) ,
from DNA (the “blueprint”)
 RNA acts as an expendable, short-lived copy of the DNA
blueprint

 The nucleotides in DNA are A, T, G, and C

 The nucleotides in RNA are A, U, G and C

 They pair up like this
Some transcription facts – cont.:
 Gene - Definition = a region of DNA producing a functional
product – either a polypeptide, or an RNA molecule (e.g.
rRNA , tRNA)

 Genes are found on both strands of the double helix.

Strand A
Strand B
 Some transcription facts – cont.

 For each gene, only one of the two DNA strands istranscribed

 The strand transcribed = TEMPLATE STRAND

 The one that isn’t transcribed = the non-template strand
 Some transcription facts: directionality

RNA is synthesized in an antiparallel
direction to the DNA strand:

 DNA is transcribed from 3’ to 5’end

 while RNA is built 5’to 3’ -
nucleotides are always added at the
3’ end of the mRNA as it grows
Molecules involved in Transcription

 DNA and RNA

 RNA polymerase - the main
enzyme responsible in RNA
synthesis

 FUNCTIONS of RNA polymerase –

 opens up the two DNA strands

 Works along the template strand in the 3’
to 5’ direction

 Joins up RNA nucleotides (A, U, G and
C) complementary to the sequence of
DNA nucleotides on the template strand
Fig. 17.8 - The stages of transcription

 1. Initiation.
 With establishment of the transcription initiation complex complete,
transcription can start.
 RNA Polymerase starts to unwind the DNA
Fig. 17.8 - The stages of transcription

 2. Elongation
 RNA polymerase moves downstream along the DNA, unwinding it
and synthesizing RNA.

 Double helix is re-formed as RNA polymerase moves on
◼ Note directionality
If a protein is needed in large amounts
 Several RNA polymerase molecules can be transcribing the same
gene at the same time!
Fig. 17.8 - The stages of transcription.

3. Termination

 When the end of the gene is reached, RNA polymerase must
stop transcribing and detach.

 Method of detaching is different in Prokaryotes and Eukaryotes
 mRNA production - Summary
 Three stages - Initiation Elongation Termination

 Transcription starts at the start point, within the
PROMOTER region of the gene

 RNA polymerase adds nucleotides to the growing
mRNA at the 3’ end

 till a TERMINATION signal is reached and
transcription is stopped

 These stages of mRNA production apply to
PROKARYOTES and EUKARYOTES
 but after the RNA transcript is produced there are
differences
What happens AFTER the termination of the transcription

Prokaryote mRNA needs no additional processing

 It is ready to translate straight away

 And because Prokaryotes have no nuclearmembrane
◼ mRNA is in contact with translation machinery of the cell as
soon as it is transcribed

 Result - translation can begin before transcription is complete

PROKARYOTES
Advantage: simultaneous transcription and translation can
produce lots of protein from a single gene
Concept 17.3 – Eukaryotic Cells Modify RNA After
Transcription

Unlike the prokaryotes

Eukaryotes produce pre-mRNA
which is processed to mRNA

- done still inside nucleus (i.e.
within the nuclear membrane)

- Ony then exported into
cytoplasm
 What does the processing involve?
1. Both ends of the mRNA are modified

 5’ end is capped with modified guanine nucleotide (= “ 5’ cap“ )
 3’ end has lots of adenines added to the AAUAAA already
present (= “poly-A tail“)

Cap Tail

5’ untranslated region 3’ untranslated region
What the 5’ cap and the poly-A tail: are good for?

 A) Help with exporting of mRNA from nucleus to
cytoplasm (may be recognized by the transporters?)

 B) Protect mRNA from early attack by hydrolytic
enzymes – how?

 C) Help ribosomes in cytoplasm attach to the right end of
the mRNA (5’ end) for correct translation (see the next
subsection)
What else can we see in that Figure 17.11?

Only a small part of the mRNA
includes the protein-coding segments

Cap Tail

5’ untranslated region 3’ untranslated region

And even in this region,
big chunks between the start and stop codons
also don’t code for the polypeptide
2. Eukaryotic genes have long non-coding stretches called INTRONS
that do not code for proteins and MUST BE REMOVED inside the
nucleus, before translation outside the nucleus

RNA transcript coding
for -globin, which is
146 amino acids long,
therefore mRNA
needs 146 codons
(438 bases)

 Introns are intervening sequences that must be cut out. They will stay
in the nucleus and be broken down to nucleotide monomers

 Exons are the bits you want

 Exons are the regions that will be expressed and contribute to the final
polypeptide. They will exit the nucleus
 Introns are removed by splicing

 Splicing is achieved by
spliceosomes
◼ Large complexes made of protein
and small RNA molecules

 The small RNA molecules
◼ participate in spliceosome
assembly
◼ Bind onto the mRNA and
Fig. 17.13
identify the introns to be cut
out
◼ and catalyse the splicing
reaction
 In other words – they act as
enzymes!
 Why do we have introns?

 Some of them may be a by-product of “alternative RNA splicing”

Depending on what is cut out (i.e. what you consider intron) one gene
can encode more than one polypeptide

 If I have a word “Catastrophe” I could use its portion to describe also
“at”, “Cat”, “strophe” (the first section of an ancient Greek choral ode) etc.

◼ Results from the Human Genome Project suggest that alternative
RNA splicing is one reason why humans are more complex than
roundworms (nematodes) despite having practically the same
number of genes as a nematode!! (i.e. we use some genes to produce
several different products)
 Why do we have introns?

 Other introns may be not our DNA , but “parasitic DNA”/”selfish
DNA”/”Genomic outlaws” – pieces of DNA that at some point in the
past brought by viruses or picked from environment –inserted
themselves into DNA of our ancestors and get replicated during each
cell division ever since.

 So why we have not got rid of them?

 Either our cells don’t have mechanisms to get rid of them
 Or there may be redeeming benefits:

 Possible usefulness during meiosis:
 Introns provide spaces between the coding regions
making crossing over easier and less likely to disrupt
a functional gene sequence – if the break happens in
an intron – no damage to the exon genes
Fig. 17.4 Overview of the roles of transcription and translation inthe flow of
genetic information

Transcription is now complete
And we are here
 Concept 17.4 - Translation is the RNA-directed
synthesis of a polypeptide: A closer look

 Translation = changing from one language to another
◼ from

 Language of Nucleotides
◼ ACGAAAGGU
 into

 Language of Amino Acids:
◼ Thr –Lys -Gly
Building a polypeptide
 Translation – the players

1. mRNA
◼ Which exits the nucleus after secondary processing

mRNA
2. Transfer RNA (tRNA)
– a molecule with two special sites

 Amino Acid attachment site
 Anticodon that matches a specific mRNA codon

Fig. 17.16 - The structure of transfer RNA (tRNA)
3. Enzymes called Aminoacyl-tRNA synthetases:

attach the right amino acids to their tRNA molecules

Figure 17.17
 There are 20 different
amino acids

 and 20 aminoacyl-tRNA
synthetase enzymes

 each aminoacyl-tRNA
synthetase enzyme has an
ACTIVE SITE

 specific for one amino acid
and

 and all the different tRNAs
with anticodons for that
particular amino acid
Using ATP, the enzyme (generic name = aminoacyl-tRNA-
synthetase) links tTNA and its amino acid together
Charged tRNAs are now ready for the process of translation

 Ribosomes are the next requirement
◼ Protein synthesis is very important so …
◼ Most cells contain 1000s of Ribosomes
 Prokaryotes and Eukaryotes both have Ribosomes

 Composed of ~2/3 RIBOSOMAL RNA (rRNA) and 1/3
PROTEINS
◼ Proteins mainly on the outside

 Come as two sub-units (large and small) that lock together
over the mRNA
 Bacterial and Eukaryotic ribosomes are quite similar
 But they do have some minor differences:

 Eukaryotic ribosomes are a
bit larger
 There are some minor
differences in molecular
composition
 This is very useful: some
antibiotics e.g. tetracycline,
streptomycin target bacterial
ribosomes without harming
human ones …
Recap - MAKING A RIBOSOME in a Eukaryotic cell

In Eukaryotes,
 rRNA is transcribed in the
NUCLEOLUS

 Production of ribosomal proteins
takes place in the cytoplasm (outside
the nucleus)

 Ribosomal proteins are then
IMPORTED into the nucleus

 RIBOSOMAL SUBUNITS are
ASSEMBLED in the NUCLEOLUS

 And exported to the cytoplasm,
where they do their work
 RIBOSOME STRUCTURE
 All ribosomes have a large and
a small subunit
 Made of rRNA (2/3) and protein
(1/3)
 With proteins on the outside

 Ribosomes have 3 sites - A, P
and E

 and an exit tunnel
(for the polypeptide to
grow through)
Fig. 17.18 Anatomy of a
functioning ribosome
Most of the work done by the ribosome is actually done by
the rRNA

 Ribosomal RNA is responsible for

1) positioning the mRNA and
tRNAs correctly

2) positioning the amino acids so
that they can be added to the
polypeptide chain as it grows

3) catalyzing peptide bond formation

 A ribosome can be thought of as one
huge RIBOZYME!
Building a Polypeptide: Step 1 - Initiation

Small ribosomal
subunit
Initiator tRNA with All come
methionine attached together
The mRNA

And:
 mRNA attaches to the small
subunit,
 the initiator tRNA binds to the
START codon on the mRNA,
 ensuring the correct READING
FRAME
 Large ribosomal subunit attaches over the mRNA
 Putting the tRNA in the P site

The process is slightly different between bacteria and eukaryotes, but the
end result is the same:
READY FOR TRANSLATION !
 Building a Polypeptide: Step 2 - Elongation

 tRNAs pass sequentially through the ribosome’s 3
binding sites

 In the A site (aminoacyl-tRNA site - Attachment site), the
anticodon on
the incoming tRNA binds to the codonon mRNA in the
vacant A site
 While in the A site, rRNA in the large subunit catalyzes the
formation of a peptide bond between the new amino acid in
the A site and the growing polypeptide chain sitting in the P
site

◼ The P site (peptidyl-tRNA site - Polypeptide building site),

The growing
polypeptide is
transferred to the
tRNA in the A site
 Everything shifts along one place

 The tRNAs in the P and A sites,
plus the mRNA they are attached
to are all shifted along one place in
the ribosome

 TRANSLOCATION

 The empty tRNA is now in the E
site – EXIT site

 tRNA leaves the ribosome to pick
up another AMINO ACID
Figure 17.20 – The Elongation Cycle of Translation

A new tRNAarrives
1 in the Asite

This goes on until
the polypeptide
2 is complete
4

3
Step 3 - Termination

 Eventually, a STOP codon (UAA,
UAG, UGA) on mRNA arrives in the
A site

 A release factor protein (not another
tRNA) binds to the STOP codon, and

 Cuts the polypeptide free of the last
tRNA

 The completed polypeptide is released
◼ and departs through the exit tunnel of
the ribosome’s large sub-unit
End Result - Production of Polypeptides (Proteins)

 The job is done; the ribosome subunits come apart

Fig. 17.21 - The termination of translation
 Figure 17.25 - A summary of transcription and translation in a
eukaryotic cell
Self Study
 Completing and Targeting the Functional Protein
(pages 376-377)

 Making multiple Polypeptides in Bacteria and
Eukaryotes (pages 377-378)
Check out the animation “Protein Synthesis” in the
Animations folder on our Brightspace

 Plus this good you tube video of transcription and translation

 DNA transcription and translation [HD animation]

 https://www.youtube.com/watch?v=8_f-8ISZ164