P-Elements Explained
Summary
TLDRThis video delves into P elements, mobile genetic elements in Drosophila's genome that transpose via a cut-and-paste mechanism. It explains the process of P element movement involving excision, drift, and integration, facilitated by the transposase enzyme. Autonomous P elements can encode transposase, while non-autonomous ones require it from elsewhere. Hybrid dysgenesis in Drosophila strains highlights the conditions under which P elements can transpose, primarily in germline cells. The video also touches on P elements' utility in enhancer trapping for gene activity studies.
Takeaways
- 🐛 P elements are transposable elements found in the genome of Drosophila, commonly known as the fruit fly.
- 🔄 They move using a cut-and-paste mechanism, involving DNA intermediates without RNA involvement.
- 🔬 P elements have 31 base pair terminal inverted repeats and a single open reading frame across four exons.
- ✂️ The transposition process includes excision, drift, and integration steps facilitated by the transposase enzyme.
- 🧬 Autonomous P elements have intact terminal inverted repeats and can encode transposase, enabling self-transposition.
- 🚫 Non-autonomous P elements lack functional transposase and require it from other elements to transpose.
- 🔄 Transposition in Drosophila occurs only in germline cells, not in somatic cells due to the absence of necessary splicing.
- 🌟 Hybrid dysgenesis is the phenomenon where P elements can move in the germline cells of offspring from a cross between P and M strains.
- 🚸 P element movement is restricted in offspring that inherit the P chromosome from the mother, due to the presence of repressor molecules.
- 🔬 P elements are used in scientific research, such as enhancer trapping, to study gene activity and regulation.
Q & A
What is a P element?
-A P element is a class of transposable DNA-based mobile genetic elements found in the genome of Drosophila, commonly known as the fruit fly. It moves with a cut-and-paste mechanism using only DNA intermediates.
How does a P element differ from other transposons?
-A P element is characterized by having 31 base pair terminal inverted repeats at both ends and a single open reading frame across four exons that encode the enzyme transposase.
What are the steps involved in the movement of a P element?
-The movement of a P element involves discrete steps called excision, drift, and integration. This includes transcription into RNA, splicing of exons, translation into the transposase polypeptide, and the subsequent binding and excision of the transposon from the DNA.
What is the role of transposase in the movement of P elements?
-Transposase recognizes and binds to the terminal inverted repeats of the P element, facilitating the excision of the entire transposon from the DNA and its subsequent movement to a recipient site.
Why are the integrated P elements always flanked by eight base pair direct repeats?
-The integrated P elements are flanked by eight base pair direct repeats because of the way transposase cuts the recipient site, resulting in sticky ends on either end of the transposon insertion.
What is the difference between autonomous and non-autonomous P elements?
-Autonomous P elements have intact terminal inverted repeats and a full coding gene for transposase, allowing them to encode transposase and move independently. Non-autonomous P elements have deletions or mutations preventing the expression of functional transposase protein and require transposase from other autonomous P elements to transpose.
In which Drosophila strains can P elements be found?
-P elements can be found in the P strain of Drosophila, while the M strain does not contain P elements.
Why can't P elements transpose in somatic cells of Drosophila?
-P elements cannot transpose in somatic cells because the necessary splicing event to create active transposase does not occur in these cells.
What is hybrid dysgenesis and when does it occur?
-Hybrid dysgenesis is the movement of P elements in germline cells, which can only occur when offspring receive the P strain chromosome from their father and the M strain chromosome from their mother.
How do P elements contribute to mutagenesis?
-P elements can become mutagenic if they land in a gene during their movement within the genome, potentially disrupting the gene's function.
What is enhancer trapping and how can P elements be used for this purpose?
-Enhancer trapping is a technique where a modified P element inserts near an enhancer in a fly's genome. This can be used to identify and study the activity of the enhancer and the genes associated with it.
Outlines
This section is available to paid users only. Please upgrade to access this part.
Upgrade NowMindmap
This section is available to paid users only. Please upgrade to access this part.
Upgrade NowKeywords
This section is available to paid users only. Please upgrade to access this part.
Upgrade NowHighlights
This section is available to paid users only. Please upgrade to access this part.
Upgrade NowTranscripts
This section is available to paid users only. Please upgrade to access this part.
Upgrade NowBrowse More Related Video
Retrotransposons | Retroviral retro transposon | Non LTR retrotransposon | LINEs and SINEs | molbio
What is the difference between Tags and Elements in HTML? | Frontend Bootcamp Hindi | Ep.05
Subsets, Proper Subsets and Supersets | Don't Memorise
5.2 Electron Configuration and the Periodic Table
The Classroom of Engagement - EPI's Launch Your Classroom!
Hoạt động của tiếp xúc P-N | Chất bán dẫn là gì?
5.0 / 5 (0 votes)