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Bacteriophage lambda (l) Transcriptional switches can regulate cellular decisions Lysis or Lysogeny • Lysis: Infection by phage produces many progeny and breaks open (lyses) the host bacterium • Lysogeny: After infection, the phage DNA integrates into the host genome and resides there passively – No progeny – No lysis of the host – Can subsequently lyse (lysogeny) • Bacteriophage lambda can do either. UV Induction Lysis Lysogeny Elements of lysogeny • The phage genome integrated into the host bacterial genome is a prophage. • Bacterium carrying the prophage is a lysogen. • Lysogens are immune to further infection by similar phage because the phage functions are repressed in trans. • Induction of the lysogen leads to excision of the prophage, replication of the phage DNA, and lysis of the host bacterium. Genes are clustered by function in the lambda genome Late control Recombination att int Control region Replication gam red xis cIII N Pint tL1 cI cro cII O P Q Virus head Lysis &tail SR A…J PL oL PRM PR tR1 PRE tR2 PR‘ t6S cos tR3 oR origin promoter operator terminator Not to scale! Immediate early transcription Transcription by E. coli RNA polymerase initiates at strong promoters PR , PR’, and PL , and terminates at t’s. att int gam red xis cIII N Pint tL1 cI cro cII O P Q PL oL PRM PR tR1 PRE oR SR tR2 PR‘ t6S tR3 6S RNA N Cro A…J Antitermination by N protein leads to early gene expression N att int gam red xis cIII N Pint tL1 N cI PL cro N cII O P Q PRM PR tR1 PRE SR A…J tR2 PR‘ t6S tR3 6S RNA N protein CIII Recombination proteins Cro CII Q protein Replication proteins Lytic cascade: Cro turns off cI, Q protein action leads to late gene expression Cro att int gam red xis cIII N Pint tL1 Cro cI cro Q cII O P Q PL oL PRM PR tR1 PRE oR SR A…J tR2 PR‘ t6S tR3 Lytic functions Replication proteins Viral head & tail proteins Late stage of lytic cascade High concentrations of Cro turn off PR and PL . Abundant expression from PR’. Cro att int gam red xis cIII N Pint tL1 Cro cI Q cro cII O P Q PL oL PRM PR tR1 PRE oR SR A…J tR2 PR‘ t6S tR3 Lytic functions Viral head & tail proteins Lysogeny: CII and CIII stimulate expression of cI to make repressor + CII att int gam red xis cIII N tint Pint Int + CIII tL1 cI cro CII cII O P Q PL oL PRM PR tR1 PRE oR CI Repressor SR A…J tR2 PR‘ t6S tR3 PRE = promoter for repression establishment Lysogeny: Repressor turns off transcription CI att int gam red xis cIII N Pint tL1 CI cI cro cII O P Q PL oL PRM PR tR1 PRE oR CI Repressor SR A…J tR2 PR‘ t6S tR3 PRM = promoter for repression maintenance Activated by Repressor binding to oR1 & oR2 Regulatory mutants of lambda Clear plaque mutants Need wild type for lysogeny: cI Establishment Yes Maintenance Yes cII Yes No cIII Yes No Act in trans Virulent mutants (vir) Act in cis : are double mutants in oR &/or oL l operators overlap promoters oR : oR3 oR2 oR1 PR -35 TTGACT -10 GATAAT cro N TTAGAT 5’ -10 ATAGAT 5’ -35 PRM Repressor structure l repressor is a dimer; monomer has 236 amino acids. C-terminal domain: protein-protein interaction; dimerization and cooperativity Connector N-terminus: DNA binding; Helix-Turn-Helix motif operator l repressor can bind cooperatively to operator sub-sites. operator oR2 operator oR1 Use hybrid genes to dissect regulatory schemes • Place a convenient reporter gene under control of the regulatory elements being studied • Use a known regulatory region to control the trans-acting regulatory element l-lac hybrid genes Place l cI gene under lac control. lac p, o l cI Use lacZ as a reporter. l pR , OR lacZ 321 Control amount of l repressor by [IPTG]. E. coli with lac repressor, no lacZ. See effect of l repressor by b-galactosidase activity l repressor will turn off expression from PR & PL lac p, o l cI l pR , OR b-galactosidase [IPTG] l repressor acts cooperatively. lacZ l repressor Repressor stimulates transcription from PRM lac p, o l cI l pRM , OR lacZ 123 b-galactosidase l repressor [IPTG] l repressor at oR1 and oR2 stimulates transcription from pRM. Binding of repressor blocks transcription from pR but activates pRM PR -35 -10 oR3 N 2 dimers of Repressor, bound cooperatively cro RNA Pol -10 oR2 oR1 -35 = operator PRM -35 -10 = promoter Bacteriophage l: Events leading to lysis • lysis or lysogeny (cI or Cro?) ? • Both lysis and lysogeny: – PR, PL, PR’ active : synthesize N, Cro – antitermination by N : synthesize cIII, cII, Q • Lysis: – Low [Cro] : binds OR3, shuts off PRM (cI) – High [Cro] : shuts off PR and PL – antitermination by Q + activation of PR’ by Cro Bacteriophage l: Events leading to lysogeny • lysis or lysogeny (cI or Cro?) ? • Lysis and lysogeny : – PR, PL, PR’ active : synthesize N, Cro – antitermination by N : synthesize cIII, cII, Q • Lysogeny: – cII stimulate expression from PRE (cI repressor) and PINT (integrase) – cIII stabilizes cII – cI repressor shuts off PR, PL, PR’ (no lytic functions), stimulates PRM Temperate and lytic phage have a different plaque morphology T emperate phage generate turbid plaques Mutants of phage that have lost the capacity to lysogenize form clear plaques lysogenized cells lysed cells lysed cells uninfected cells Lytic phage: clear plaques Induction and immunity of lysogens l A l lysogen Spontaneously, 1/1000 lysogens will induce, i.e. the l l prophage will excise, replicate and lyse the cell. + UV treatment leads to induction of virtually all lysogens in a culture. Lysogens are immune to further infection with similar (lambdoid) phage l