1. Bacterial Transcription
Chapter 11
Bacterial Transcription

2. Figure 11.1: One strand of DNA is transcribed into RNA.
11.1 Introduction
Transcription is the synthesis of RNA in the 5' to 3' direction from a template strand that is 3' to 5'.
Figure 11.1: One strand of DNA is transcribed into RNA.

4. 11.2 Transcription Occurs by Base Pairing in a “Bubble” of Unpaired DNA
RNA polymerase separates the two strands of DNA in a transient “bubble”
It uses one strand that runs 3 to 5 as a template to direct synthesis of a complementary sequence of RNA running 5 to 3.
The length of the bubble is ~12 to 14 bp, and the length of RNA-DNA hybrid within it is ~8 to 9 bp.

5. Figure 11.03: RNA synthesis occurs in the transcription bubble.
11.2 Transcription Occurs by Base Pairing in a “Bubble” of Unpaired DNA
Figure 11.03: RNA synthesis occurs in the transcription bubble.

6. Figure 11.04: The transcription bubble moves along DNA.

7. Figure 11.5: During transcription, the bubble is maintained within RNA polymerase, which unwinds and rewinds DNA and synthesize RNA.

8. 11.3 The Transcription Reaction Has Three Stages
RNA polymerase binds to the promoter on the DNA to form a closed complex.
RNA polymerase initiates transcription after opening the DNA duplex to form a transcription bubble.
During elongation the transcription bubble moves along DNA and the RNA chain is extended in the 5 to 3 direction by adding nucleotides to the 3 end of the growing chain.
When transcription stops, the DNA duplex reforms and RNA polymerase dissociates at a terminator site.

9. 11.3 The Transcription Reaction Has Three Stages
Figure 11.06: RNA polymerase catalyzes transcription.

10. 11.4 A Model for Enzyme Movement Is Suggested by the Crystal Structure
RNA polymerase contains a groove on the surface for the path of the DNA.
Figure 11.7: The b and b’ subunit of RNA polymerase have a channel for the DNA template. The DNA template (red) and coding (yellow) strands are separated in a transcription bubble.
Photo courtesy of Seth Darst, Rockefeller University.

11. Figure 11.8: Movement of RNA polymerase requires breaking and making bonds to the nucleotides at fixed positions relative to the enzyme.

12. Figure 11.09: The bridge controls nucleotide entry.
A protein bridge changes conformation to control the entry of nucleotides to the active site.
Figure 11.09: The bridge controls nucleotide entry.

13. 11.5 Bacterial RNA Polymerase Consists of the Core Enzyme and Sigma Factor
Bacterial RNA polymerase holoenzyme can be divided into:
an α2ββ’ core enzyme that catalyzes transcription
a sigma () subunit that is required only for initiation.
Sigma factor changes the DNA-binding properties of RNA polymerase so that its affinity for general DNA is reduced and its affinity for promoters is increased.
Binding constants of RNA polymerase for different promoters vary greatly, and correlate with the frequency with which transcription is initiated at each promoter.

14. 11.5 Bacterial RNA Polymerase Consists of the Core Enzyme and Sigma Factor
Figure 11.10: Sigma factor controls specificity. Core enzyme binds indiscriminately to any DNA. Sigma factor reduces the affinity for sequence-independent binding and confers specificity for promoters.

15. 11.6 How Does RNA Polymerase Find Promoter Sequences?
The rate at which RNA polymerase binds to promoters is too fast to be accounted for by random diffusion.
RNA polymerase probably binds to random sites on DNA and exchanges them with other sequences very rapidly until a promoter is found.

16. Figure 11.11: Core enzyme and holoenzyme are distributed on DNA, very little RNA polymerase is free.

17. Figure 11.12: RNA polymerase binds very rapidly to random DNA sequences and could find a promoter by direct displacement of the bound DNA sequence.

18. 11.7 Sigma Factor Controls Binding to Promoters
RNA polymerase binds to the promoter as a closed complex in which the DNA remains double-stranded.
RNA polymerase then separates the DNA strands to form an open complex and a transcription bubble that incorporates up to nine nucleotides into RNA.

19. 11.7 Sigma Factor Controls Binding to Promoters
Figure 11.13: There are several stages in initiation.

20. 11.7 Sigma Factor Controls Binding to Promoters
There may be a cycle of abortive initiations before the enzyme moves to the next phase.
Sigma factor may be released from RNA polymerase when the nascent RNA chain reaches eight to nine bases in length.
A change in association between sigma factor and holoenzyme changes binding affinity for DNA so that core enzyme can move along DNA.

21. Figure 11.14: Sigma factor and core enzyme recycle at different points in transcription.

22. 11.8 Promoter Recognition Depends on Consensus Sequences
A promoter is the site where RNA polymerase binds the DNA.
The promoter consensus sequences consist of:
a purine at the startpoint
the hexamer TATAAT centered at –10
another hexamer centered at –35
Individual promoters usually differ from the consensus at one or more positions.

23. Figure 11.15: The promoter has three components, consisting of consensus sequences at -35, -10, and the startpoint.

24. Figure 11.16: The consensus sequences at -35, and -10 provide most of the contact points for RNA polymerase in the promoter.

25. 11.9 Promoter Efficiencies Can Be Increased or Decreased by Mutation
Down mutations that decrease promoter efficiency usually decrease conformance to the consensus sequences.
Up mutations have the opposite effect.
Mutations in the –35 sequence usually affect initial binding of RNA polymerase.
Mutations in the –10 sequence usually affect the melting reaction that converts a closed to an open complex.

26. 11.10 Supercoiling Is an Important Feature of Transcription
Negative supercoiling increases the efficiency of some promoters by assisting the melting reaction.
Transcription generates positive supercoils ahead of the enzyme and negative supercoils behind it.
These must be removed by gyrase and topoisomerase.

27. Figure 11.18: Transcription generates more tightly wound (positively supercoiled) DNA ahead of RNA polymerase, while the DNA behind becomes less tightly wound (negatively supercoiled).

28. 11.11 Substitution of Sigma Factors May Control Initiation
E. coli has several sigma factors, each of which causes RNA polymerase to initiate at a set of promoters defined by specific –35 and –10 sequences.
70 is used for general transcription, and the other sigma factors are activated by special conditions.

29. Figure 11.19: The sigma factor associated with core enzyme determines the set of promoters at which transcription is initiated.

30. Figure 11.20: E. coli has several sigma factors that are induced by particular environmental conditions.

31. 11.11 Substitution of Sigma Factors May Control Initiation
A cascade of sigma factors is created when one sigma factor is required to transcribe the gene coding for the next sigma factor.
Sporulation divides a bacterium into two compartments:
a mother cell that is lysed
a spore that is released
Each compartment advances to the next stage of development by synthesizing a new sigma factor that displaces the previous sigma factor.

32. Figure 11.21: Sporulation involves successive changes in the sigma factors that control the initiation specificity of RNA polymerase. The cascades in the mother cell and the forespore are related by signals passed across the septum.

33. 11.12 Sigma Factors Directly Contact DNA
Figure 11.22: Amino acids in the 2.4 a-helix of s70 contact specific bases in the coding strand of the -10 promoter sequence.

34. 11.12 Sigma Factors Directly Contact DNA
70 changes its structure to expose its DNA-binding regions when it associates with core enzyme.
70 binds both the –35 and –10 sequences.

35. Figure 11.23: Sigma N-terminus controls DNA-binding.

36. 11.13 Bacterial Transcription Termination
Termination may require both:
recognition of the terminator sequence in DNA
formation of a hairpin structure in the RNA product
Figure 11.24: Bacterial termination occurs at a discrete site.

37. 11.14 Intrinsic Termination Requires a Hairpin and a U-Rich Region
Intrinsic terminators consist of a G-C-rich hairpin in the RNA product followed by a U-rich region in which termination occurs.
Figure 11.25: An intrinsic terminator has two features.

38. 11.15 Rho Factor Is a Site-Specific Terminator Protein
Rho factor is a terminator protein that binds to a rut site on a nascent RNA.
It tracks along the RNA to release it from the RNA-DNA hybrid structure at the RNA polymerase.

39. 11.15 Rho Factor Is a Site-Specific Terminator Protein
Figure 11.26: Rho factor binds to RNA at a rut site and translocates along RNA until it reaches the RNA-DNA hybrid in RNA polymerase, where it releases the RNA from the DNA.

40. Figure 11.27: A rut site has a sequence rich in C and poor in G preceding the actual site(s) of termination.

41. 11.16 Antitermination May Be a Regulated Event
Termination is prevented when antitermination proteins act on RNA polymerase to cause it to read through a specific terminator or terminators.

42. Figure 11.29: Antitermination can control transcription by determining whether RNA polymerase terminates or reads through a particular terminator into the following region.

43. 11.16 Antitermination May Be a Regulated Event
Phage lambda has two antitermination proteins, pN and pQ, that act on different transcription units.
The site where an antiterminator protein acts is upstream of the terminator site in the transcription unit.
The location of the antiterminator site varies in different cases and can be in the promoter or within the transcription unit.

44. Figure 11.31: An antitermination protein can act on RNA polymerase to enable it to read through a specific terminator.

45. Figure 11.31: Antiterminators can act at different locations in the transcription unit.

46. Figure 11.32: Ancillary factors bind to RNA polymerase as it passes the nut site. They prevent rho from causing termination when the polymerase reaches the terminator.