Deck 10: Transcription in Bacteria

Transcription proceeds in the

Alternative sigma factors

Are transcription and translation "coupled" or "uncoupled" in bacteria? Explain your answer.

Diagram a typical bacterial promoter. Exact sequences are not necessary.

Draw a rough sketch of the structure of the bacterial RNA polymerase holoenzyme based on X-ray crystallography. Point out the position of the active site.

Design an experiment to demonstrate that the RNA polymerase holoenzyme binds DNA more tightly compared with the core polymerase. Show sample positive results.

Which DNA strand is part of the DNA-RNA hybrid in the RNA polymerase "open complex," the template or nontemplate strand? Explain your answer.

Diagram the three-step transcription initiation process in E. coli.

Diagram the key features of the bacterial elongation complex. Include a rough sketch showing the direction of RNA synthesis and where a new phosphodiester bond forms.

Compare and contrast Rho-dependent and Rho-independent termination.

What different catalytic activity does RNA polymerase have while "elongating" versus "backtracking?"

Describe an experiment that showed that RNA polymerase can rotate DNA. Did the results of this experiment determine whether RNA polymerase rotates around DNA or vice versa in vivo?

Transcription has a significant local effect on DNA structure (i.e., whether underwound or overwound). Discuss these structural changes and the enzymes that are required to resolve the situation.

Diagram Jacob and Monod's operon model. Discuss some of the testable hypotheses put forth by this model.

Draw diagrams of the lac operon that illustrate repressed transcription, basal transcription, and activated transcription.

"When glucose is abundant, bacteria use it exclusively as their food source, even when other sugars are present." Discuss this statement in the context of how the presence of glucose effects induction of the lac operon.

Draw a rough sketch of a helix-turn-helix motif and show the site of interaction with the DNA double helix.

For bacterial operon induction, describe a specific example of the following: "The repressor and activators are DNA binding proteins that undergo allosteric modification."

For bacterial operon induction, describe a specific example of the following: "DNA looping is a mechanism used in gene regulation."

Present a model to explain attenuation in the trp operon in E. coli. Is attenuation the main regulatory mechanism? Explain your answer.

Define the term "riboswitch." Regulation of gene expression by riboswitches is common in bacteria but not in eukaryotes. Offer reasons why this is the case.

You have discovered a novel riboswitch that you think acts as a metabolite-responsive ribozyme. Design an experiment to demonstrate self-cleaving activity and metabolite specificity. Show sample positive results.

A particular sequence containing six base pairs is located in ten different organisms. The observed sequences are: 5′-ACGCAC-3′, ATACAC, GTGCAC, ACGCAC, ATACAC, ATGTAT, ATGCGC, ACGCAT, GTGCAT, and ATGCGC. What is the consensus sequence?

Draw a diagram of a prokaryotic gene being transcribed and translated. Show the nascent mRNA with ribosomes attached. With an arrow, indicate the direction of transcription.

Show how you could use DNase I footprinting to demonstrate that a sigma ( $\sigma$ ) factor is required for specific binding of RNA polymerase to a bacterial gene promoter.

Consider E. coli cells, each having one of the following mutations:(a) A mutant lac operator sequence that cannot bind lac repressor(b) A mutant lac repressor that cannot bind to the lac operator(c) A mutant lac repressor that cannot bind to allolactose(d) A mutant lac promoter that cannot bind CAP plus cAMPWhat effect would each mutation have on the function of the lac operon (assuming no glucose is present)?

You are studying a new operon in bacteria involved in tyrosine biosynthesis.
(a) You sequence the operon and discover that it contains a short open reading frame at the 5′ end of the operon that contains two codons for tyrosine. What prediction would you make about this leader sequence, the RNA transcript, and the peptide that it encodes?
(b) How would you predict this operon is regulated; i.e., is it inducible or repressible by tyrosine? Why?
(c) Would this kind of regulation work in a eukaryotic cell? Why or why not?

You are studying a repressor protein that you suspect forms a DNA loop between two operator sites, one located very near the promoter and the other located at a distance site upstream. Describe an experiment to test your hypothesis.