DNA Recognition in Procaryotes by Helix-Turn-Helix Motifs.

DNA Recognition in Procaryotes DNA Recognition in Procaryotes by Helix-Turn-Helix Motifsby Helix-Turn-Helix Motifs

Lysogeny vs. Lysis

Lysogenic

Lytic

Cro from phage-monomer

Cro from phage-dimer

Cro from phage-dimer

Repressor from phage-monomer

Repressor from phage-dimer

helix-turn-helix

Cro - DNA

recognition helices vs. 34 Å

Genetics + Structural Biology

Repressor from 434 phage-dimer

10.2 Most bacterial repressors are dimers 10.2 Most bacterial repressors are dimers containing containing helices that insert into adjacent helices that insert into adjacent

major grooves of operator DNA major grooves of operator DNA

Figure 10-13

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434 repressor-DNA binding

Before After

434 cro/repressor-DNA binding

434 repressor-DNA binding

434 repressor-DNA binding-specific interaction

434 repressor-DNA binding-Non-specific interaction

Protein-DNA interaction inHelix-turn-helix

By itself, an operon is on and RNA polymerase can bind to the promoter and transcribe the genes.

Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

Fig. 18.20a

However, if a repressor protein, a product of a regulatory However, if a repressor protein, a product of a regulatory gene, binds to the operator, it can prevent transcription of gene, binds to the operator, it can prevent transcription of the operon’s genes.the operon’s genes.– Each repressor protein recognizes and binds only to the Each repressor protein recognizes and binds only to the

operator of a certain operon.operator of a certain operon.– Regulatory genes are transcribed at low rates Regulatory genes are transcribed at low rates

continuously. continuously.

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Fig. 18.20b

trp repressor-monomer

trp repressor-dimer

trp repressor-DNA

10.2 Ligand-induced conformational ch10.2 Ligand-induced conformational changes alter affinity of many repressors fanges alter affinity of many repressors f

or DNAor DNA

Figure 10-14

Tryptophan binding induces a conformational change in the trp aporepressor

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10.2 DNase I footprinting assays ident10.2 DNase I footprinting assays identify protein-DNA interactionsify protein-DNA interactions

Figure 10-6

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10.2 Gel-shift assays identify protein-10.2 Gel-shift assays identify protein-DNA interactionsDNA interactions

Figure 10-7

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10.2 The footprint of RNA polymerase 10.2 The footprint of RNA polymerase and and laclac repressor on the repressor on the laclac control re control re

giongion

Figure 10-8

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10.2 The lac control region contains t10.2 The lac control region contains three critical cis-acting siteshree critical cis-acting sites

Figure 10-9

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10.2 Positive control of the 10.2 Positive control of the laclac operon operon is exerted by cAMP-CAPis exerted by cAMP-CAP

Figure 10-16

CAP = catabolite activator protein

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lac repressor-monomer

lac repressor(tetramer)-DNA

lac repressor(tetramer)-DNA

CAP-DNA

10.2 A space-filling model of cAMP-CA10.2 A space-filling model of cAMP-CAP bound to P bound to laclac promoter DNA promoter DNA

Figure 10-18

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10.2 Cooperative binding of cAMP-CAP and 10.2 Cooperative binding of cAMP-CAP and RNA polymerase to the RNA polymerase to the laclac contol region ac contol region ac

tivates transcriptiontivates transcription

Figure 10-17

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