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Prokaryotic Genetics III - Gene regulation

Prokaryotic Genetics III - Gene regulation. 1. Lac System Jacob and Monod, 1950's, biochemists. Not cleaved. Non-metabolic inducer. Non-inducer substrates. X-gal. ONPG. Ampicillin enrichment of lac - cells. Lac - mutants - genes mapped close together.

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Prokaryotic Genetics III - Gene regulation

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  1. Prokaryotic Genetics III - Gene regulation 1. Lac System Jacob and Monod, 1950's, biochemists

  2. Not cleaved Non-metabolic inducer Non-inducer substrates X-gal ONPG

  3. Ampicillin enrichment of lac- cells

  4. Lac- mutants - genes mapped close together • Lac- mutants were isolated in Z and Y, prevent utilization • lacZ - -galactosidase breaks lactose into galactose and glucose • lacY - permease is required to transport lactose into the cell One mutant allowed expression in the absence of inducer constitutive mutant, lacI First example of a mutant that affects production not activity

  5. PaJaMo Experiment - Pardee, Jacob & Monond Hfr I+ Z+ T6sSsx F- I-Z-T6rSr

  6. Analysis of lacI mutants LacI is trans acting - a diffusable factor

  7. Analysis of lacOc mutants lacO is cis acting - a non-diffusable element

  8. Analysis of lacP mutants lacP is cis acting - a non-diffusable element

  9. Regulatory models for the lac operon

  10. LacI binds DNA as a tetramer to repress transcription Why did Jacob & Monod not find O2 and O3?

  11. Genetic analysis of the LacI binding sites X-gal White White White Blue Blue

  12. Distinction between factors (proteins) and elements (DNA sites) i) Regulatory factors act in trans ii) Regulatory elements act in cis

  13. Mutational analysis of Repression and Activation

  14. Effect of inducers on regulation

  15. Cross feeding analysis of Trp mutants allows to analyze the biochemistry of Trp biosynthesis pathway TrpE TrpD TrpB precursor Trp

  16. TrpE TrpD TrpC1 TrpC2 TrpA TrpB

  17. Attenuation of trp operator expression attenuator Deletions in the attenuator increase basal synthesis of Trp enzymes

  18. Sequences Coding for Short Peptides are Often Found in Leaders of Transcripts from Biosynthesis Operons

  19. trp Operon expression in response to Trp levels

  20. RNA Pol Terminator Sequences in the trp operon leader region can form different stem-loop structures

  21. What would the phenotype be of a deletion from 118-132? What would the phenotype be of the Trp codon mutations? Stalled ribosomes block the formation of the transcription terminating stem-loop structure +Trp -Trp Can this form of regulation happen in eukaryotes?

  22. Resistant to further infection Not resistant to infection by other phage Life cycle of a Temperate Bacteriophage

  23. Mating by lysogen induces lytic growth in recipient cell Similar to the PaJaMa Experiment Hfr F- No repressor of the prophage in the recipient cell causes lytic growth

  24. Screen for clear plaques How did they define the complementation groups?

  25. WT cI, cII, cIII OL OR Turbid plaques Uninfected Cell Clear Clear Lysogen No plaques No plaques Clear Different complementation groups and phenotypes of the "clear" mutants Recessive trans Dominant - cis

  26. Infection of WT phage into a lysogen Infecting Phage or WT cI, cII, cIII OL OR Turbid plaques Uninfected Cell Clear Clear Lysogen No plaques No plaques Clear Uninfected Lysogen

  27. Infection of cI phage into a lysogen Infecting Phage WT cI, cII, cIII OL OR Turbid plaques Uninfected Cell Clear Clear Lysogen No plaques No plaques Clear Uninfected Lysogen Recessive trans

  28. Infection of cI phage into a lysogen Infecting Phage WT cI, cII, cIII OL OR Turbid plaques Uninfected Cell Clear Clear Lysogen No plaques No plaques Clear Uninfected Lysogen Recessive trans Dominant - cis

  29.  is linear in the virion but circularizes after infection

  30. 15 Kb Not essential Cloning site for DNA libraries  phage genome DNA replication (2) Recombination (10) Head (10), tail (12) lysis (3)

  31. Differential gene expression in the  life cycle cI Int Integrate into genome cI

  32. Regulation of early gene expression N () and Nus (bacteria) function as anti-terminators

  33. Regulation of late lytic gene expression 26 Kb, takes 10' Shuts off genes required for lysogeny

  34. Regulation of late lysogenic and prophage gene expression cI shuts of all other phage genes in Prophage

  35. Poor Media Rich Media Lytic vs lysogen decision To establish lysogen

  36. Induction of prophage through SOS response cI Does not bind DNA

  37. Integration and excision of  phage Int/Xis ratio determines direction

  38. To establish lysogeny: Int > Xis

  39. To establish lytic growth: Xis > Int

  40. Lytic induction from a lysogen: Xis = Int

  41. Construction of a  phage library

  42. Construction of a Cosmid library

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