Invert dev - exam questions Flashcards
- What is a stem cell niche? Explain on the germline of Drosophila with cell names and pathways.
- probably need to explain this one better - X
- The stem cell niche is a permissive environment that allows stem cell self-renewal
- Cell Types:
- Terminal filament cells (TF)
- Cap cells (CC)
- Escort Cells (EC)
- Escort Stem cells (ESC)
- Follicle stem cells (FSC)
- Cytoblast (CB)
- You have a lin-3 egf(0) lin-12(gof) mutant: what phenotype does it have and how can you explain it with the function of the two genes in the wild type worm?
- Likely phenotype would be vulvaless (Vul).
- This is because lin-3 is required for inductive signal from anchor cell (AC) for VPCs to differentiate into 1° or 2° cells
- Lin-12 (gof) does not make a difference here, because lin-12 (lof) means cells become 1° and lin-12 (gof) means they become 2° assuming that lin-3 egf is wt. But in this case all cells are 3° due to lin-3 mutation.
- Shows the way in which lin-3 not working properly will suppresses a Muv phenotype.
- What relationship is there between mutation in a gene and a phenotype and how does this relate to the wild type worm? How is a mutant helpful?
- A mutation in a gene can lead to changes in how the gene is expresses. For example it can be always turned on (gof) or always off (lof).
- This mutation can then change the phenotype of the worm by changing which proteins are expressed.
- For example, if the lin-3 gene is knocked out, then the worm does not develop any vulval cells due to the loss of the inductive signal. This may be observed by looking a the worm and seeing lots of eggs inside of it, and eventually lots of baby worms inside it because they can’t leave the worm due to lack of a vulva.
- Mutants are helpful because they allow us to observe which genes affects which cells, and allow us to determine pathways by which these genes function.
- For example, if one knows that gain of function in a gene such as lin-12 leads to all VPCs becoming 2°. One can then do an additional experiment with the mutant worms, where you also knock out lin-3. This would suppress the lin-12 phenotype, showing that lin-3 is upstream of lin-12.
- Mex-5 and mex-6: when and where are they expressed? What biological function do they have? What encodes the gene (gene product)? Where is it localized and what is its function?
- Are expressed in the 1-cell stage embryo
- Are localized to the anterior pole
- Function to establish Soma/germline asymmetry in early C. elegans embryos.
- Do this via inhibiting anterior expression of germline proteins through translational inhibition.
- Oskar: what is the largest protein of Oskar? What is the function of Oskar? Where is it expressed?
- OSKAR is largest protein of oskar
- Oskar mRNA is localized to the anterior pole of the drosophila oocyte
- Induces germ plasm and ectopic PGC formation
- OSKAR protein has central duel role in germ plasm formation:
- RNA binding protein that crosslinks nanos, pgc, and gcl mRNAs
- Localizes nanos mRNA at extreme posterior pole of unfertilized egg
- You have the segmentation mutant drosophila: it is missing two segments (one in the front and one in the back). What kind of mutation is this and explain.
Likely a GAP gene mutation
Probably tailless
Gap gene mutations are missing entire segments, while pair rule would be missing every other segment, and segment polarity are not missing any segments
- You have two mutants: mutant A and mutant B. they both show the same phenotype: how can you find out whether they have a mutation in the same gene?
- Complementation analysis
- Cross the two mutants together
- If offspring have same phenotype as parents, they have failed to complement, meaning that mutation is on same gene
- If heterozygous offspring have restored phenotype, genes have complemented, meaning that the mutations are on different genes
- The gene of mutant C is sequences and mapped and cloned. How can you find out where this gene is expressed?
- Can use fluorescence in situ hybridization (FISH)
- Fluorescent probes bind only to mRNA with high degree of complementarity
- Can use it to see where the mRNA for this gene is localized
- The gene C is expressed in stripes over the body: how is it regulated, suggest and underlying molecular pathway that explains is morphology.
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Can be explained by the reaction-diffusion model (Turing model)
- 2 substances in organism: activator and inhibitor
- Activator stimulates production of both, inhibitor slows production of activator
- Relative abundance of activator vs. inhibitor, as well as starting amounts for each can change the phenotype of stripes seen.
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Another method is via Cis regulatory elements (CRE) modularity
- A morphogen activates expression of target gene
- Patterning output will then depend of morphogen concentration and binding site affinity for target genes
- This allows a gradient concentration of morphogen to control the activation of genes that might control pattern of stripes on a body
- Ced-1 is necessary to engulf dead cells, explain how this helped to find ced-3 and ced-4 who are necessary for killing and how this helped.
- Ced-1 (lf) helpful because can see that if cells die they stay around (due to lack of engulfment)
- Thus, in a ced-3 mutant we know that nothing died due to lack of corpses, rather than them being engulfed
- Two functions of PIE-1
a. Regulates maternal and zygotic gene expression in embryonic germ line
b. Keeps P2 from turning into EMS
c. Represses transcription by binding to RNA Pol II
- Main apoptotic pathway and function of each gene. How engulfment mutants allowed to detect mutations in the killing step (10 pts)
a. In ced-1 (lf) mutants, cells which died in the embryo phase would not be engulfed, and thus would still be visible in the larval stage, compared to wild-type where no cell corpses would be visible in the larval stage.
b. Thus, if killing step did not occur (such as in ced-3 (lf) mutants), no cell corpses would be visible in the larval stage.
c. A double mutant (ced-1 (lf); ced-3 (lf)) has a larval phenotype without cell corpses. A ced-1 (lf) mutant has a larval phenotype with cell corpses. A ced-3 (lf) mutant has a larval phenotype without cell corpses. This indicates that cells did not die in the double mutant and the ced-3 (lf) mutant. Because if they had died, cell corpses would be present in the double mutant larva due to ced-1 (lf) mutation.
- What happens when anchor cell is Mutated and let60 has a gain of function mutation?
a. Meaning that let60 is always on. Would be similar to Lin-3 (gf) mutation in which there is excess vulval induction. So would cause a Muv phenotype in the worm.
- What happens when the anchor cell is depleted in vulva development?
a. Assuming this is the same as experimentally ablating the anchor cell, then the result would be that if done early, no vulval cells would develop because the anchor cell sends out the inductive signal. So all VPCs would adopt the 3° cell fate.
- Two main functions of the niche of the germ line stem cells
a. Occupancy: is promoted by stimulating adherent junctions between niche cells and cells within, but not outside, the niche
b. Fate regulation: by repressing differentiation genes in cells inside, but not outside the niche.