Geraldine Seydoux (Johns Hopkins / HHMI) 2: How to Polarize the Cytoplasm

Science Communication Lab

28 Nov 201725:16

Summary

TLDRIn this engaging presentation, Professor Geraldine Seydoux explores the intricate process of how the zygote becomes polarized, focusing on the role of the MEX-5 protein in establishing anterior-posterior gradients. Through various experiments, she demonstrates that MEX-5 redistribution, governed by PAR-1 kinase, is crucial for this polarization. The findings reveal that MEX-5 exists in two species—slow and fast—whose proportions differ between the anterior and posterior sides, leading to a concentration gradient. The research highlights the importance of reversible phosphorylation in controlling diffusion rates, paving the way for a deeper understanding of embryonic development.

Takeaways

🎓 Geraldine Seydoux discusses the polarization of the zygote's cytoplasm and how it contributes to body axis formation.
🔬 The PAR proteins play a crucial role in establishing polarity within the one-cell embryo.
📈 MEX-5, an RNA-binding protein, forms an anterior-posterior gradient during the polarization process.
⚗️ Erik Griffin's experiments aim to determine how the MEX-5 gradient is established, considering various hypotheses.
💡 One hypothesis suggests that MEX-5 levels could either increase in the anterior or decrease in the posterior, while another proposes redistribution of existing protein.
🧪 Erik created a photoactivatable version of MEX-5 fused with a fluorescent protein, allowing for tracking of its distribution during polarization.
📊 Experiments showed that total MEX-5 levels remain constant, indicating that redistribution is key to the gradient formation.
🌊 The diffusion of MEX-5 was found to vary in speed across different regions of the cytoplasm during polarization.
🔄 PAR-1 kinase phosphorylates MEX-5, which increases its diffusion rate, while a phosphatase can reverse this effect.
💻 Computational modeling by David Odde successfully recreated the MEX-5 gradient based on experimental data, showing that local reversible phosphorylation can explain gradient formation without directed movement.

Q & A

What is the primary focus of Geraldine Seydoux's presentation?
-The presentation focuses on how the cytoplasm of the zygote in Caenorhabditis elegans becomes polarized and how this process is controlled by PAR proteins and the distribution of MEX-5 protein.
How do the PAR proteins influence the one-cell embryo?
-The PAR proteins control various aspects of the polarity of the one-cell embryo by directing the distribution of proteins and organelles in the cytoplasm along the anterior-posterior axis.
What role does MEX-5 play in the polarization process?
-MEX-5 is an RNA-binding protein that forms an anterior-posterior gradient in the cytoplasm during the polarization process, which is crucial for determining the fate of the resulting cells.
What experimental approach did Erik Griffin use to study MEX-5 distribution?
-Erik Griffin created a fusion protein of MEX-5 and a photoactivatable fluorescent protein, allowing him to label existing MEX-5 in red and newly synthesized MEX-5 in green to study the protein's redistribution.
What did Erik's experiments reveal about the necessity of new MEX-5 synthesis during polarization?
-Erik's experiments indicated that new MEX-5 synthesis is not necessary for gradient formation; instead, existing MEX-5 protein can redistribute to create the gradient.
How did the diffusion rates of MEX-5 differ between the anterior and posterior cytoplasm?
-Before polarization, MEX-5 diffused slowly in both anterior and posterior regions, but during polarization, it became faster in the posterior cytoplasm while remaining slow in the anterior.
What impact does PAR-1 have on MEX-5 diffusion?
-PAR-1 phosphorylates MEX-5, which is essential for increasing the diffusion rate of MEX-5 in the posterior cytoplasm while keeping it sluggish in the anterior cytoplasm.
What conclusion did Erik draw from the fluorescence correlation spectroscopy experiments?
-Erik concluded that MEX-5 exists in two species: a slow, sluggish form and a faster form, with the proportion of these species differing between the anterior and posterior cytoplasm.
What is the significance of reversible phosphorylation in the MEX-5 gradient formation?
-Reversible phosphorylation allows for a dynamic change in MEX-5's diffusion rate, contributing to the establishment of the concentration gradient without requiring directed movement.
How did David Odde contribute to understanding the MEX-5 gradient?
-David Odde utilized computational modeling to recreate the MEX-5 gradient using experimentally determined values, confirming the relationship between PAR-1 kinase activity and MEX-5 diffusion rates.