So the arabinose operon is responsible for encoding genes that control the breakdown of arabinose, and what is that? It is a sugar. So, when there's a lot of arabinose present, the cell wants to break it down, and therefore, it does that through activating the operon. And if arabinose is not present, it doesn't want to waste the energy from producing those genes and those proteins. And so when arabinose is not there, it wants to repress the transcription of the operon. So how does it do that? Well, there are 2 regulatory regions you need to know about. The araI, which is also called the initiator, and the araO regions. And these are DNA sequences, actually, just upstream of the, arabinose operon. And so how are they activated or repressed? Well, there's a certain protein called ARAC. So when arabinose is present, so when there's an abundance of this sugar, the ARAC binds the araI side or the initiator side, and that initiates transcription, which makes sense. Right? But there's also a second thing that is also required for initiating transcription, and that is the cAMP cap complex. Now you may remember this complex, the glucose regulation of the lac operon. So if you're unfamiliar with how this complex works, or you've never heard of it before, I would go back and review this video because this, the glucose like operon video, really goes into detail how the camp cap complex works to activate operons. So, in this case, there's also a binding site for this complex, and that also helps to initiate transcription. So that's initiation. The ARAC binds the araI and the cAMP cap complex, but both are binding, and they activate transcription. But when arabinose is not present, how is that inactivated? How is that transcription repressed? Well, how it is is it's done through the same protein, ARAC, but instead of just binding the araI or the initiator site, it binds both the araI and the araO, and that represses transcription. Operon. So binding. So let me show you what that looks like. So here we have the operon. So, there would be genes here. Right? So I'm just drawing genes. There are, arabinose genes, part of this operon that would break down arabinose. So when we have the ARAC protein and when arabinose is present, what happens is it only binds the ARAA site. In addition to that, there's this camp cap complex that comes in and binds to an adjacent side as well, and this helps to activate the operon that will break down the sugar. Now, if arabinose is not present, so if I just scribble it out here, say, okay, well, it's not present, then what happens is the ARAC protein also binds the araO site, which is here. And when it does, it actually folds this DNA up to the side of the protein, and it will create a DNA loop. And when the DNA is looped, like this, then that prevents polymerases from binding, and therefore transcription cannot occur if the polymerase can't bind. So the ARAC protein, depending on which side it binds to, whether it's bound to just 1, the initiator, or both, that determines whether or not the arabinose operon is activated or inhibited. So with that, let's now move on.
- 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
- 19. Cancer Genetics29m
- 20. Quantitative Genetics1h 26m
- 21. Population Genetics50m
- 22. Evolutionary Genetics29m
Arabinose Operon: Study with Video Lessons, Practice Problems & Examples
The arabinose operon regulates the breakdown of arabinose, a sugar, through transcriptional activation or repression. When arabinose is abundant, the ARAC protein binds to the araI site, aided by the cAMP-CAP complex, initiating transcription. In contrast, in the absence of arabinose, ARAC binds both araI and araO, creating a DNA loop that prevents polymerase binding, thus repressing transcription. This operon exemplifies catabolite repression, where energy is conserved by regulating gene expression based on substrate availability.
Arabinose Operon
Video transcript
The genes in the arabinose operon are responsible for what?
When arabinose is present, the arabinose operon is what?
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What is the arabinose operon and how does it function?
The arabinose operon is a set of genes responsible for the breakdown of arabinose, a sugar. When arabinose is present, the ARAC protein binds to the araI site, initiating transcription with the help of the cAMP-CAP complex. This leads to the production of enzymes that break down arabinose. In the absence of arabinose, ARAC binds both the araI and araO sites, creating a DNA loop that prevents RNA polymerase from binding, thus repressing transcription. This regulation ensures that the cell conserves energy by only producing the necessary enzymes when arabinose is available.
How does the ARAC protein regulate the arabinose operon?
The ARAC protein plays a crucial role in regulating the arabinose operon. When arabinose is present, ARAC binds to the araI site, and with the aid of the cAMP-CAP complex, it initiates transcription of genes that break down arabinose. In the absence of arabinose, ARAC binds to both the araI and araO sites, causing the DNA to loop. This loop formation prevents RNA polymerase from binding to the DNA, thereby repressing transcription. This dual binding mechanism allows ARAC to either activate or repress the operon based on the presence of arabinose.
What role does the cAMP-CAP complex play in the arabinose operon?
The cAMP-CAP complex is essential for the activation of the arabinose operon. When arabinose is present, the ARAC protein binds to the araI site, but this alone is not sufficient for transcription initiation. The cAMP-CAP complex also binds to an adjacent site, enhancing the binding of RNA polymerase to the promoter region. This cooperative binding ensures efficient transcription of the genes required for arabinose breakdown. The cAMP-CAP complex thus acts as a secondary regulatory mechanism, ensuring that the operon is activated only when both arabinose is present and energy conditions are favorable.
What happens to the arabinose operon when arabinose is not present?
In the absence of arabinose, the ARAC protein binds to both the araI and araO sites on the DNA. This dual binding causes the DNA to loop, which physically obstructs RNA polymerase from binding to the promoter region. As a result, transcription of the genes involved in arabinose breakdown is repressed. This mechanism ensures that the cell does not waste energy producing enzymes that are not needed when arabinose is not available, thereby conserving resources.
How does the arabinose operon exemplify catabolite repression?
The arabinose operon exemplifies catabolite repression by regulating gene expression based on the availability of arabinose. When arabinose is present, the operon is activated to produce enzymes for its breakdown. However, in the absence of arabinose, the operon is repressed to conserve energy. This regulation is further influenced by the cAMP-CAP complex, which ensures that the operon is only activated when energy conditions are favorable. This dual regulation mechanism allows the cell to efficiently manage its resources, producing enzymes only when necessary and conserving energy when the substrate is not available.