Table of contents

1. Introduction to Genetics51m
2. Mendel's Laws of Inheritance3h 37m
3. Extensions to Mendelian Inheritance2h 41m
4. Genetic Mapping and Linkage2h 28m
5. Genetics of Bacteria and Viruses1h 21m
6. Chromosomal Variation1h 48m
7. DNA and Chromosome Structure56m
8. DNA Replication1h 10m
9. Mitosis and Meiosis1h 34m
10. Transcription1h 0m
11. Translation58m
12. Gene Regulation in Prokaryotes1h 19m
13. Gene Regulation in Eukaryotes44m
14. Genetic Control of Development44m
15. Genomes and Genomics1h 50m
16. Transposable Elements47m
17. Mutation, Repair, and Recombination1h 6m
18. Molecular Genetic Tools19m
- Genetic Cloning
  9m
- Methods for Analyzing DNA
  9m
19. Cancer Genetics29m
- Overview of Cancer
  21m
- Cancer Mutations
  7m
20. Quantitative Genetics1h 26m
21. Population Genetics50m
- Hardy Weinberg
  19m
- Allelic Frequency Changes
  31m
22. Evolutionary Genetics29m

12. Gene Regulation in Prokaryotes

Riboswitches

Genetics

12. Gene Regulation in Prokaryotes

Riboswitches

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Problem 23

Textbook Question

What is a riboswitch? Describe the riboswitch mechanism that regulates transcription of the thi operon in B. subtilus. What parallels can you see between this mechanism and the regulation of transcription of the trp operon in E. coli?

Verified step by step guidance

A riboswitch is a regulatory segment of an mRNA molecule that can bind a small molecule ligand directly, causing a conformational change in the mRNA structure. This change influences gene expression by affecting transcription or translation.

To regulate transcription of the thi operon in *Bacillus subtilis*, the riboswitch mechanism involves the binding of thiamine pyrophosphate (TPP), a derivative of vitamin B1, to the riboswitch located in the leader sequence of the mRNA. When TPP levels are high, it binds to the riboswitch, stabilizing a structure that forms a transcription termination signal, halting transcription of the thi operon.

When TPP levels are low, the riboswitch does not bind TPP, allowing the mRNA to adopt a structure that permits transcription of the thi operon, leading to the production of enzymes involved in thiamine biosynthesis.

The regulation of the thi operon in *B. subtilis* parallels the regulation of the trp operon in *E. coli* in that both systems use feedback mechanisms to control transcription based on the availability of a metabolite. In the trp operon, high levels of tryptophan activate a repressor protein that binds to the operator region, preventing transcription. Similarly, high levels of TPP bind to the riboswitch, halting transcription of the thi operon.

Both mechanisms exemplify how cells conserve energy and resources by regulating gene expression in response to metabolite concentrations, ensuring that biosynthetic pathways are active only when their products are needed.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Riboswitches

Riboswitches are regulatory segments of RNA that can bind small molecules, leading to changes in gene expression. They typically exist in the untranslated regions of mRNA and can influence transcription or translation by altering the RNA structure in response to the presence of specific metabolites.

Thi Operon Regulation in B. subtilis

The thi operon in Bacillus subtilis is regulated by a riboswitch that responds to thiamine (vitamin B1) levels. When thiamine is abundant, it binds to the riboswitch, causing a conformational change that promotes the formation of a transcription terminator, halting transcription. Conversely, low thiamine levels lead to the formation of an anti-terminator structure, allowing transcription to proceed.

Trp Operon Regulation in E. coli

The trp operon in Escherichia coli is also regulated by a riboswitch mechanism, but it primarily responds to tryptophan levels. High tryptophan concentrations lead to the formation of a transcription terminator, while low levels allow for the anti-terminator structure to form, enabling transcription. This mechanism highlights a common theme in bacterial gene regulation, where nutrient availability directly influences gene expression.