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Regulation of Gene expression

Explore the regulatory mechanisms in bacterial gene expression through biosynthetic and catabolic reactions, focusing on tryptophan biosynthesis and lactose operon. Learn about feedback inhibition, end product repression, and catabolic repression.

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Regulation of Gene expression

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  1. Regulation of Gene expression by E. Börje Lindström This learning object has been funded by the European Commissions FP6 BioMinE project

  2. Introduction • Biosynthetic reactions consume energy:  Sophisticated control mechanisms in bacteria • Available energy is limited in Nature:  Production of as much cell material per energy as possible • The environment is important: • the nutrient in the medium is used first • rapid and drastic changes in the nutrients  • reversible control reactions needed • Two types of model systems: - Biosynthetic - Catabolic

  3. Biosynthetic reactions Tryptophan is chosen as a model system: • Tryptophan is an essential amino acid • Tryptophan is missing in some plant proteins  • of industrial importance • The bacterial cells are controlling the biosynthesis of tryptophan in three ways: • feedback inhibition • end product repression • attenuation

  4. Biosynthetic reactions, cont. • Feedback inhibition: - The biosynthesis of tryptophan occurs in several steps: E1 E2 E3 E4 E5 Chorismate + glutamine  antranilic acid  B  C  D  tryptophan Mechanism: • - enzyme E1 (the first enzyme) is an allosteric protein with • - a binding site for for the substrate • a binding site for the effectors (inhibitor = try) • E1 + try  [E1-try]-complex that is inactive • the complete biosynthesis of try is stopped

  5. Biosynthetic reactions, cont. • End product repression (EPR): • In spite of ’end product inhibition’  • loss of energy due to enzymes E2-E5 are still synthesized • another regulation is needed • end product repression

  6. P O att E1 E2 E3 E4 E5 Biosynthetic reactions, cont. Mechanism: P = promoter; O = operator att = attenuator E1 – E5 = structural genes for the enzymes E1-E5. • RNA polymerase binds to P  Initiation of mRNA synthesis • The repressor is an allosteric protein • - inactive without tryptophan (does not bind to the operator) • tryptophan acts as co-repressor • binds to the repressor • makes the repressor active  Blocks the RNA polymerase movement • The repressor binds to O

  7. Biosynthetic reactions, cont. • Attenuator region: - barrier for the RNA polymerase 1) + try  the polymerase removed from the DNA 2) - try  the polymerase continues into the structural genes • EPR inhibits all enzymes in tryptophan biosynthesis •  save energy • however, a slow total inhibition – does not effect already existing enzymes • high specificity – only the tryptophan operon is effected

  8. Biosynthetic reactions, cont.

  9. Biosynthetic reactions, cont.

  10. Biosynthetic reactions, cont.

  11. Biosynthetic reactions, cont.

  12. R P O lacZ lacY lacA Catabolic reactions • Catabolic systems are inducible • The inducer is the available carbon/energy source • Model system – lactose operon in E. coli • Where: • gene R : repressor protein – active without the inducer •  blocks mRNA polymerase • gene lacZ : b-galactosidase – splits lactose into glycose + galactose • gene lacY: permease – transport lactose into the cell • no attenuator sequence in catabolic systems

  13. Catabolic reactions, cont. • Mechanism: + lactose: • transported into the cell  transformed into allo-lactose (inducer) • allo-lactose + repressor  [allo-lactose-repressor]- complex  inactive • RNA polymerase starts transcription of lactose operon •  b-galactosidase is produced  break down of lactose - lactose: • [allo-lactose-repressor]- complex disintegrate • the repressor binds to O and blocks further transcription of the operon

  14. Catabolic reactions, cont.

  15. Catabolic reactions, cont.

  16. Log OD time Catabolic repression (glucose-effect) • Works in bacteria and other prokaryotes (here in E. Coli K12) • Diauxi: • growth on two energy sourcesglucose + lactose  • two-step growth curve Growth on lactose lactose Growth on glucose glucose

  17. Catabolic repression (glucose-effect) • Mechanism: • cAMP an important substance • required for initiation of transcription of many inducible systems • global regulation • glucose present  [cAMP]  (decreases) - CAP (katabolite activator protein) an allosteric protein - [cAMP-CAP]-complex binds to the promoter  promotes transcription • production of b-galactosidase  • 1) lactose present • 2) [cAMP-CAP]-complex present

  18. Catabolic repression (glucose-effect), cont. • + glucose: • no [cAMP-CAP]-complex  • no transcription of lactose operon • no b-galactosidase production • - glucose: • [cAMP-CAP]-complex present  • transcription of lactose operon • b-galactosidase production • brake down of lactose

  19. Catabolic repression (glucose-effect), cont. • Conclusions: • Katabolite repression – a very useful function in bacteria • forces the bacteria to usethe best energy source first

  20. Other types of Regulations • Constitutive systems: • no regulation • always present • Enzymes that are needed during all types of growth • e.g. those involved in glycolysis • mRNA: • Unstable • half-life ~ 2 min  sub-units •  new mRNA • polycistronic mRNA - one operator for several genes • monocistronic mRNA - one operator per gene (in eukaryotes)

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