Finding the Genes that Enable Worm Cell Migration
Vida Praitis, professor of biology, Sam Naik 鈥21, Sarina Kopf 鈥22, Stephany Dos Santos 鈥21, and Sarah Weltz 鈥21 planned to research in the lab together during the summer of 2021. Then the pandemic began and access to the Noyce Science Center and the labs within was restricted.
So, Praitis, Naik, Kopf, Dos Santos, and Weltz did a 鈥渄ynamic pivot.鈥 Joined by Jasper Yang 鈥21, whose internship plans were canceled because of the pandemic, they turned to their laptops. Through those laptops, they carried out bioinformatics research to find genes that likely play a role in cell migration during worm development.
From Worm Cell Migration to Human Cancer and More
鈥淎 huge part of how we become a complex organism 鈥 has to do with the fact that cells come together in particular ways,鈥 says Praitis. She studies how cells come together, how cells 鈥渕igrate.鈥
Cell migration plays an important role in development and the immune system. Additionally, parts of the cancer process seem to be the reverse of parts of the cell migration process. As a result, 鈥渦nderstanding the pathway in one direction, we hope will actually give us information about how that pathway works in the opposite direction during cancer,鈥 says Praitis.
Praitis researches cell migration in Caenorhabditis elegans, a worm often used as a model organism in biological research. 鈥淲e can do research in a really simple system to ask questions about cell behavior that occurs in more complicated systems where it鈥檚 more difficult to really understand what鈥檚 going on,鈥 she explains. So, by advancing our understanding of worm cell migration, her research also advances our understanding of human cell migration.
Asking Difficult Questions
Praitis is not alone in studying C. elegans development. In 2019, Packer et al. published an that included a database of which genes are expressed, or 鈥渢urned up or down,鈥 in which cells at different developmental stages. That database was the starting point for Praitis鈥 teams鈥 research.
Praitis鈥 team wanted to use the database to find which genes are expressed during cell migration but not expressed during other stages, i.e., which genes specifically enable cell migration. Praitis thought, 鈥淚 know that I can ask some really interesting questions using this dataset. Can we actually answer them?鈥
Lighting Their Own Path
In the end, they did answer some of those questions, but the path to the answers was not an easy one. 鈥淭he students came in with really good skill sets,鈥 says Praitis. Despite that, they had much to learn before they could answer their questions.
The sheer amount of data they had to sort through made their work even more difficult. 鈥淭he database has tens of thousands of data points in it, so even downloading it so we could work with it was non-trivial,鈥 says Praitis.
After downloading the data, they created a list of migrating cells to focus on, which Praitis says 鈥渢ook a lot of patience and perseverance to build.鈥 For each migrating cell, they also chose a nonmigrating cell to use as a control.
Then Praitis鈥 team 鈥渕agically鈥 turned the database into a list of genes that likely enable cell migration 鈥 magically meaning they spent hours, days, and weeks reading relevant literature, programming, troubleshooting, and doing statistics. Kopf describes this experience: 鈥淚 felt like I was wandering around in the dark for all 10 weeks of the summer, but I feel like that was a good thing to realize about research itself.鈥
While wandering around in the dark, they were lighting the path for themselves and for those who will come after them. The methods they used were new and, as a result, their work helped develop and improve those methods, which may even be used in research beyond cell migration.
This work would not have been possible in the lab alone. They were able to study many more genes in much less time than they would have otherwise been able to. Kopf explains this powerful approach: 鈥淵ou can cut [the scientific] process short by doing a bunch of computational work and then hybridizing that with lab work. I think that鈥檚 really a cool concept and also where the future is going.鈥
To Be Continued
鈥淪cience takes time, and it takes effort. Just seeing a story come together is pretty cool,鈥 says Praitis. Finding genes that likely enable cell migration was the first part of the research story. Many of those genes are known to be involved in cell migration, which is a promising sign that their methods were accurate. However, they are interested in the genes that are not known to be involved in cell migration. For those genes, they need to do further research.
That research will be the second part of the story and will take place in the lab. There, Kopf will validate that the genes they found are involved in cell migration by observing how mutating those genes affects cell migration.
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This pivot was a pandemic silver lining; not having access to the lab made Praitis鈥 team get creative. In doing so, her team advanced our understanding of cell migration and, therefore, our understanding of development, the immune system, and cancer. As Praitis says, 鈥渟ometimes it takes difficult circumstances to encourage you to take a leap.鈥
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Vishva Nalamalapu 鈥20 is the content specialist fellow in the Office of Communications and Marketing at 99精品视频 College. She loves writing about scientific research in a way that is accessible and interesting to readers with or without science backgrounds. Her series on scientific research projects focuses on doing just that. If you are a 99精品视频 College professor or student interested in having your scientific research project featured or think someone else鈥檚 project would be a good fit, please听contact her.