Small molecules are powerful reagents for biological investigation. They provide an alternative to genetic perturbation and may offer more control over a target’s activity. C. elegans has recently gained prominence as a platform to discover new chemical tools. Through large-scale screens for compounds that induce phenotypes consistent with the disruption of conserved pathways, we identified two previously uncharacterized molecules of interest that we named nemadipine and migrazole. Here, I describe my efforts to understand their mechanism of action.
Nemadipine is structurally analogous to 1,4-dihydropyridines (DHPs), which target the Cav1 calcium channel and are used clinically to lower blood pressure. Phenotypic and genetic evidence suggest that nemadipine targets the worm Cav1 channel, EGL-19. To identify the target of nemadipine in an unbiased manner, I performed a forward genetic screen for mutants resistant to its effects. The majority of the mutants from my screen had polymorphisms in EGL-19, providing additional evidence that it is the target of nemadipine. I also found that nemadipine is the only DHP that robustly elicits phenotypes in the worm. Therefore, I used this unique chemical to investigate the in vivo interactions between DHPs and the Cav1 channel. I identified residues in EGL-19 important for DHP-sensitivity in worms and showed that some of these residues are also important for mammalian DHP-interaction. Other labs have since exploited nemadipine’s in vivo properties to demonstrate new biological insights for EGL-19.
Chemical genetic analyses indicated that migrazole disrupts multiple signal transduction pathways. This, together with experiments that I performed in yeast, suggests that migrazole may affect multiple pathways by perturbation of protein transport. To identify migrazole’s target, I performed a forward genetic screen for mutants resistant to migrazole’s effects. However, I was unable to identify the target of migrazole through analysis of the mutants I isolated. This result illustrates that while forward genetic screens can be very successful for target identification, their effectiveness is likely dependent on the nature of the compound-target interaction.
My work shows that all aspects of developing a small molecule into a tool for biological analysis, from its discovery to its characterization, can be accomplished using C. elegans.
Identifer | oai:union.ndltd.org:LACETR/oai:collectionscanada.gc.ca:OTU.1807/42519 |
Date | 19 November 2013 |
Creators | Kwok, Trevor |
Contributors | Roy, Peter John |
Source Sets | Library and Archives Canada ETDs Repository / Centre d'archives des thèses électroniques de Bibliothèque et Archives Canada |
Language | en_ca |
Detected Language | English |
Type | Thesis |
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