Title: Controlling Gene Expression
1Controlling Gene Expression
- Timothy G. Standish, Ph. D.
2All Genes Cant be Expressed At The Same Time
- Some genes are needed for the function of all
cells all the time. These genes are called
constitutive genes and are expressed by all
cells. - Other genes are only needed by certain cells or
at specific times. The expression of these
inducible genes is tightly controlled in most
cells. - For example, beta cells in the pancreas make the
protein insulin by expressing the insulin gene.
If neurons expressed insulin, problems would
result.
3Operons Are Groups Of Genes Expressed By
Prokaryotes
- The genes grouped in an operon are all needed to
complete a given task - Each operon is controlled by a single control
sequence in the DNA - Because the genes are grouped together, they can
be transcribed together then translated together
4The Lac Operon
- Genes in the lac operon allow E. coli bacteria
to metabolize lactose - Lactose is a sugar that E. coli is unlikely to
encounter, so it would be wasteful to produce the
proteins needed to metabolize it unless necessary - Metabolizing lactose for energy only makes sense
when two criteria are met - Other more readily metabolized sugar (glucose) is
unavailable - Lactose is available
5The Lac Operon - Parts
- The lac operon is made up of a control region and
four genes - The four genes are
- LacZ - b-galactosidase - An enzyme that
hydrolizes the bond between galactose and glucose - LacY - Codes for a permease that lets lactose
across the cell membrane - LacA - Transacetylase - An enzyme whose function
in lactose metabolism is uncertain - Repressor - A protien that works with the control
region to control expression of the operon
6The Lac Operon - Control
- The control region is made up of two parts
- Promoter
- These are specific DNA sequences to which RNA
Polymerase binds so that transcription can occur - The lac operon promoter also has a binding site
for another protein called CAP - Operator
- The binding site of the repressor protein
- The operator is located down stream (in the 3
direction) from the promoter so that if repressor
is bound RNA Polymerase cant transcribe
7The Lac OperonWhen Glucose Is Present But Not
Lactose
Come on, let me through
RNA Pol.
No way Jose!
8The Lac OperonWhen Glucose And Lactose Are
Present
Great, I can transcribe!
RNA Pol.
Lac
This lactose has bent me out of shape
Some transcription occurs, but at a slow rate
9The Lac OperonWhen Lactose Is Present But Not
Glucose
Bind to me Polymerase
Yipee!
RNA Pol.
Lac
This lactose has bent me out of shape
10The Lac OperonWhen Neither Lactose Nor Glucose
Is Present
Bind to me Polymerase
Come on, let me through!
RNA Pol.
STOP Right there Polymerase
11The Trp Operon
- Genes in the trp operon allow E. coli bacteria
to make the amino acid tryptophan - Enzymes encoded by genes in the trp operon are
all involved in the biochemical pathway that
converts the precursor chorismate to tryptophan. - The trp operon is controlled in two ways
- Using a repressor that works in exactly the
opposite way from the lac operon repressor - Using a special attenuator sequence
12The TryptophanBiochemical Pathway
13The Trp OperonWhen Tryptophan Is Present
Foiled Again!
RNA Pol.
STOP Right there Polymerase
14Attenuation
- The trp operon is controlled both by a repressor
and attenuation - Attenuation is a mechanism that works only
because of the way transcription and translation
are coupled in prokaryotes - Therefore, to understand attenuation, it is first
necessary to understand transcription and
translation in prokaryotes
15Transcription And Translation In Prokaryotes
16The Trp Leader and Attenuator
Met-Lys-Ala-Ile-Phe-Val
- AAGUUCACGUAAAAAGGGUAUCGACA-AUG-AAA-GCA-AUU-UUC-G
UA- Leu-Lys-Gly-Trp-Trp-Arg-Thr-Ser-STOP CUG-AAA-
GGU-UGG-UGG-CGC-ACU-UCC-UGA-AACGGGCAGUGUAUU CACC
AUGCGUAAAGCAAUCAGAUACCCAGCCCGCCUAAUGAGCGGGCUUUU
Met-Gln-Thr-Gln-Lys-Pro
UUUU-GAACAAAAUUAGAGAAUAACA-AUG-CAA-ACA-CAA-AAA-CCG
trpE . . . Terminator
17The mRNA Sequence Can Fold In Two Ways
Terminator haripin
18The Attenuator When Starved For Tryptophan
RNA Pol.
Help, I need Tryptophan
19The Attenuator When Tryptophan Is Present
RNA Pol.
RNA Pol.
20Control Of Expression In Eukaryotes
- Some of the general methods used to control
expression in prokaryotes are used in eukaryotes,
but nothing resembling operons is known - Eukaryotic genes are controlled individually and
each gene has specific control sequences
preceding the transcription start site - In addition to controling transcription, there
are additional ways in which expression can be
controlled in eukaryotes
21Eukaryotes Have Large Complex Geneomes
- The human genome is about 3 x 109 base pairs or
1 m of DNA - Because humans are diploid, each nucleus contains
6 3 x 109 base pairs or 2 m of DNA - That is a lot to pack into a little nucleus!
22Eukaryotic DNA Must be Packaged
- Eukaryotic DNA exhibits many levels of packaging
- The fundamental unit is the nucleosome, DNA wound
around histone proteins - Nucleosomes arrange themselves together to form
higher and higher levels of packaging.
23Highly Packaged DNA Cannot be Expressed
- The most highly packaged form of DNA is
heterochromatin - Heterochromatin cannot be transcribed, therefore
expression of genes is prevented - Chromosome puffs on some insect chomosomes
illustrate where active gene expression is going
on
24Only a Subset of Genes is Expressed at any Given
Time
- It takes lots of energy to express genes
- Thus it would be wasteful to express all genes
all the time - By differential expression of genes, cells can
respond to changes in the environment - Differential expression, allows cells to
specialize in multicelled organisms. - Differential expression also allows organisms to
develop over time.
25Control of Gene Expression
Packaging
Transportation
26Logical Expression Control Points
- DNA packaging
- Transcription
- RNA processing
- mRNA Export
- mRNA masking/unmasking and/or modification
- mRNA degradation
- Translation
- Protein modification
- Protein transport
- Protein degradation
The logical place to control expression is before
the gene is transcribed
27A Simple Eukaryotic Gene
Transcription Start Site
3 Untranslated Region
5 Untranslated Region
Introns
3
5
Int. 2
Int. 1
Exon 2
Exon 3
Exon 1
Terminator Sequence
Promoter/ Control Region
Exons
RNA Transcript
28Enhancers
Many bases
TF
TF
TF
29Eukaryotic mRNA
3 Untranslated Region
5 Untranslated Region
3
5
G
AAAAA
Exon 2
Exon 3
Exon 1
Protein Coding Region
3 Poly A Tail
5 Cap
- RNA processing achieves three things
- Removal of introns
- Addition of a 5 cap
- Addition of a 3 tail
- This signals the mRNA is ready to move out of the
nucleus and may control its life span in the
cytoplasm
30(No Transcript)