1. OPERONS * Indicated slides borrowed from: Kim Foglia
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2. Slide by Kim Foglia modified
PROKARYOTES
Slide by Kim Foglia modified
Genes with related functions grouped together = Operon
example: all enzymes in a metabolic pathway
promoter = RNA polymerase binding site
single promoter controls transcription of all genes in operon
transcribed as one unit & a single mRNA is made
operator = DNA binding site of repressor protein
regulatory genes = code for regulatory proteins (EX: repressors)

3. Slide by Kim Foglia modified
When gene is turned ON:
Polymerase binds promoter mRNA is made (transcription) mRNA is turned into proteins by ribosomes
RNA
polymerase
DNA
TATA
operator 1 2 3 4
promoter
mRNA
enzyme1
enzyme2
enzyme3
enzyme4
gene1
gene2
gene3
gene4
RNA
polymerase
gene1
gene2
gene3
gene4
repressor
TATA
gene1
gene2
gene3
gene4
DNA
operator
promoter
When gene is turned OFF
Repressor binds operator RNA polymerase can’t transcribe gene
Slide by Kim Foglia modified

4. INDUCIBLE OPERONS Usually OFF/repressor INACTIVE
REPRESSABLE OPERONS Usually ON/repressor usually ACTIVE Can be turned off (repressed) Genes for enzymes that make product always needed
EX: trp operon
makes enzymes used in essential amino acid synthesis
INDUCIBLE OPERONS Usually OFF/repressor INACTIVE
Can be turned on (induced) Genes for enzymes that are only needed sometimes
EX: lac operon makes enzymes used in lactose digestion

5. DIFFERENCE BETWEEN THE TWO IS WHAT MAKES REPRESSOR ACTIVE OR INACTIVE!
REPRESSOR is usually INACTIVE Cells need to make tryptophan
If tryptophan is available, don’t need to make it
Tryptophan ACTIVATES repressor TURNS GENE OFF
REPRESSOR is usually ACTIVE Cells don’t need to make lactose digesting enzymes if no lactose present
If lactose is available, need to digest it
Lactose INACTIVATES repressor TURNS GENE ON

6. Repressible trp operon: Codes for enzymes that synthesize tryptophan
Synthesis pathway model
When excess tryptophan is present, it binds to trp repressor protein & triggers repressor to bind to DNA
blocks (represses) transcription
RNA
polymerase
repressor
trp
TATA
gene1
gene2
gene3
gene4
DNA
promoter
operator
trp
trp
repressor
repressor protein = INACTIVE
trp
trp
trp
trp
trp
trp
conformational change in repressor protein makes it ACTIVE!
trp
tryptophan
trp
repressor
tryptophan – repressor protein
Complex = ACTIVE
trp
SLIDE FROM: Kim Foglia

7. Inducible lac operon codes for enzymes for lactose digestion
SLIDE FROM: Kim Foglia
Inducible lac operon codes for enzymes for lactose digestion
lac
Digestive pathway model
When lactose is present, binds to lac repressor protein & triggers repressor to release DNA
induces transcription
RNA
polymerase
repressor
TATA
lac
gene1
gene2
gene3
gene4
DNA
promoter
operator 1 2 3 4
mRNA
enzyme1
enzyme2
enzyme3
enzyme4
repressor
repressor protein =ACTIVE
lactose
lac
conformational change in repressor protein makes it
INACTIVE!
repressor
lactose – repressor protein
Complex = INACTIVE
lac

8. Using REPRESSORS to TURN OFF genes =
NEGATIVE CONTROL
REPRESSIBLE and INDUCIBLE operons ARE BOTH TYPES OF NEGATIVE CONTROL ! ! ! !

9. Using ENHANCER REGIONS and ACTIVATORS to TURN ON genes =
POSITIVE CONTROL

10. POSTIVE CONTROL of Lactose operon
What happens when concentration of glucose is LOW?
LOW GLUCOSE → HIGH cAMP
cAMP makes CAP active; starts transcription
GLUCOSE IS FOOD OF CHOICE
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11. POSTIVE CONTROL of Lactose operon
What happens if BOTH GLUCOSE AND LACTOSE are present?
GLUCOSE IS FOOD OF CHOICE
Repressor is inactive but CAP activator is not activated Gene is unable to turn on at significant rate
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12. WHAT ABOUT EUKARYOTES
Genes for proteins that work together in a pathway are spread out on different chromosomes (NO OPERONS)
Separate control sequences for each gene
BOTH POSTIVE (enhancers) and NEGATIVE (repressors) control

13. ACTIVATORS BIND TO ENHANCER region
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14. WHERE DO ACTIVATOR proteins come from?
MAKE A CONNECTION
WHERE DO ACTIVATOR proteins come from?
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15. ACTIVATED ENHANCERS attach to TRANSCRIPTION FACTORS and FOLD DNA back onto itself
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16. RNA POLYMERASE attaches to TRANSCRIPTION INTIATION COMPLEX to start transcription (GENE is turned ON!)
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17. Different genes have different enhancer regions and are controlled by different activators
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18. DIFFERENT ENHANCER sequences can TURN ON a gene in DIFFERENT KINDS of cells at DIFFERENT TIMES.
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