So prokaryotic cells have two types of transposable elements. The very first type is called an insertion sequence. And what is an insertion sequence? It's going to be a short bacterial DNA sequence that jumps around the genome because it's a transposable element, and we know transposable elements jump. So, the important part to know about all transposable elements, prokaryotic ones, eukaryotic ones, doesn't matter, is that there's an enzyme that allows them to jump, and this enzyme is called transposase. This is the protein that's required for the movement of the insertion sequence, but it's also important for the movement of all different kinds of transposable elements. And so, we're going to see that different transposable elements control transposase a little bit differently. We're going to talk about the insertion sequence. An insertion sequence has two main structural features. The first is that they contain inverted repeat sequences at each end. These are actually a very common feature in transposable elements, and these repeats are required for the gene to be able to jump. So super important one. And then the second is the transposase. In insertion elements, how they control that transposase activity is they actually encode it between the inverted repeats. So what this looks like is, here's an inverted repeat, and you can see why it’s called that way because these are inverted repeats. Right? This is the same sequence, but backwards over here. And if this was an insertion sequence, the transposase gene would sit here. And when this is transcribed, the transposase would be transcribed with it. We process, translate, produce into a protein. The second type is called just a transposon, and it's probably what you're more familiar with hearing. These are longer DNA sequences compared to the insertion elements that also jump around the genome. And there are two types of these. So the first type of transposon is called a composite transposon. Composite transposons are flanked by insertion sequences. And as I said before, insertion sequences were flanked by inverted repeats, but composite transposons actually have two insertion sequences on either end. And the insertion sequences, which we talked about before, encode transposase. So the composite transposons don't actually encode for transposase, themselves. They have the insertion sequences on either side that encode for transposase, so they don't need to. This is how a composite transposon handles transposase differently. And then there are different genes that sit in between those insertion sequences. The second type is the simple transposon. These are flanked by inverted repeats, and that's around genes that include transposase. And these look much more similar to insertion sequences, except they tend to be longer. But, this looks very different. So, generally, the important part about transposon, we always talk about drug resistance in bacteria. Right? Oh, that's a big thing in the news right now, these superbugs. Well, generally, drug resistance is actually conferred and transferred between different bacteria based on transposons found on these bacterial r plasmids. And that's just a fun fact. You don't necessarily need to know it, but just fun fact, transposons are really what's responsible for these superbugs that we are developing now. So here we have a composite transposon. These are the insertion sequences. Remember, the insertion sequences encode for transposase. So, they're already present here, so we don't need transposase in the genes. And the simple transposon instead, has inverted repeats. The inverted repeats don't have transposase themselves, so the transposon has to actually encode for transposase. So, you can see that here in red. Now, transposon, so we're still in this second type of transposable element. So transposon, transpose, that's the verb of actually jumping, in two main ways. You can see that we like the two pattern here. So, and within transposon, there are two ways to jump, and the first is called replicative transposition, and that is when the transposon is actually copied, so it's replicated. And then the new copy travels to the new location while the old copy remains in the same location. So you can think of replicative transposition as copy and paste. So, there's now, after this copy and paste has happened, there are now two of the exact same type of transposons just located in different regions of the genome. Then, the second type is conservative transposition, and this is where the transposon is cut out and moved to a new location. So, this is the cut-and-paste method, where after the jump you still have the same number of transposons, it's just moved to a new location. So the two types are the copy and paste and the cut and paste. And those are, you know, make sure you understand that difference. So if we have the copy and paste method, what happens is this gets replicated, and this old one stays in the same spot, and the new one moves somewhere else in the genome. Whereas in conservative transposition, if you start out like this, what happens is it's just cut out and it moves to a new location when you still only have one copy. And this, you end up with two copies. So the copy and paste, and this is the cut and paste method. And, obviously, those have different impacts on the genome where this one keeps replicating itself, getting more and more copies, whereas this one always stays the same number of copies. 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
Transposable Elements in Prokaryotes: Study with Video Lessons, Practice Problems & Examples
Prokaryotic cells contain two types of transposable elements: insertion sequences and transposons. Insertion sequences are short DNA segments that move within the genome, requiring the enzyme transposase for their mobility. Transposons, which are longer, can be composite or simple. Composite transposons are flanked by insertion sequences that encode transposase, while simple transposons have inverted repeats and encode transposase themselves. Transposons can move via replicative transposition (copy and paste) or conservative transposition (cut and paste), impacting genetic diversity and contributing to phenomena like antibiotic resistance in bacteria.
Prokaryotic Transposable Elements
Video transcript
Transposase is a protein that is responsible for what?
Which of the following transposons do not encode for the transposase enzyme?
Which of the following sequences is an example of an inverted repeat sequence that would surround one strand of an insertion sequence element?
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What are the two main types of transposable elements in prokaryotes?
Prokaryotic cells contain two main types of transposable elements: insertion sequences and transposons. Insertion sequences are short DNA segments that move within the genome and require the enzyme transposase for their mobility. They have two main structural features: inverted repeat sequences at each end and the transposase gene located between these repeats. Transposons, which are longer than insertion sequences, can be either composite or simple. Composite transposons are flanked by insertion sequences that encode transposase, while simple transposons have inverted repeats and encode transposase themselves. Both types of transposons can move via replicative transposition (copy and paste) or conservative transposition (cut and paste).
How do insertion sequences differ from transposons in prokaryotes?
Insertion sequences and transposons are both types of transposable elements in prokaryotes, but they differ in several ways. Insertion sequences are short DNA segments that contain inverted repeat sequences at each end and a transposase gene in between. They rely on the transposase enzyme for mobility. Transposons, on the other hand, are longer DNA sequences and can be either composite or simple. Composite transposons are flanked by insertion sequences that encode transposase, while simple transposons have inverted repeats and encode transposase themselves. Additionally, transposons can move via two mechanisms: replicative transposition (copy and paste) and conservative transposition (cut and paste).
What is the role of transposase in transposable elements?
Transposase is an enzyme crucial for the mobility of transposable elements in both prokaryotes and eukaryotes. It facilitates the 'jumping' of these elements within the genome. In insertion sequences, the transposase gene is located between inverted repeat sequences. In composite transposons, transposase is encoded by the flanking insertion sequences, while in simple transposons, it is encoded within the transposon itself. Transposase enables two types of transposition: replicative transposition (copy and paste), where a new copy of the transposon is created, and conservative transposition (cut and paste), where the transposon is excised and moved to a new location.
What are the differences between replicative and conservative transposition?
Replicative and conservative transposition are two mechanisms by which transposons move within the genome. In replicative transposition, the transposon is copied, and the new copy moves to a new location while the original remains in place. This 'copy and paste' method results in two copies of the transposon in different genome locations. In contrast, conservative transposition involves the transposon being cut out from its original location and moved to a new one. This 'cut and paste' method does not increase the number of transposon copies; it simply relocates the existing transposon. Both mechanisms impact genetic diversity and can contribute to phenomena like antibiotic resistance.
How do transposons contribute to antibiotic resistance in bacteria?
Transposons play a significant role in the spread of antibiotic resistance among bacteria. They often carry genes that confer resistance to antibiotics and can move these genes between different locations within the genome or between different bacterial cells. This movement can occur via plasmids, which are small, circular DNA molecules separate from the bacterial chromosome. When a transposon carrying an antibiotic resistance gene inserts itself into a plasmid, it can be transferred to other bacteria through processes like conjugation. This horizontal gene transfer accelerates the spread of antibiotic resistance, contributing to the emergence of 'superbugs' that are difficult to treat with existing antibiotics.