Biology

The 2024 Nobel Prize in Physiology or Medicine has been awarded to Victor Ambros '75, PhD '79 and Gary Ruvkun for the discovery of microRNA, “a tiny class of RNA molecules that play a crucial role in determining how organisms mature and function – and how they sometimes malfunction,” reports Teddy Rosenbluth and Derrick Bryson Taylor for The New York Times. Ambros and Ruvkun “had been postdoctoral fellows at the same time at Massachusetts Institute of Technology,” they explain . “As they studied C. elegans, they at first felt a smidgen of friendly competition as they each started their own labs in the Boston area, Dr. Ambros said.”

Victor Ambros '75, PhD '79 and Gary Ruvkun have won the 2024 Nobel Prize in Physiology or Medicine for the discovery of microRNAs, report Mark Johnson and Lizette Ortega for The Washington Post. “Ambros and Ruvkunhad worked together as postdoctoral researchers in the lab of Nobel laureate and MIT Professor Robert Horvitz. “What the microRNAs really end up revealing for us is a way that parts of our genome can communicate with other parts of the genome,” says Ambros. “The significance of this discovery of microRNAs is that it allowed us to be aware of a very complex and nuanced layer of regulation whereby genes in our cells talk to each other.”

Victor Ambros ‘75, PhD ‘79 and Gary Ruvkun have won the 2024 Nobel Prize in Physiology or Medicine for “their groundbreaking work on how genes behave,” reports Patrick Smith for NBC News. Ambros and Ruvkun, who worked as postdocs in the lab of Professor H. Robert Horvitz in the late 1980s, discovered how microRNA molecules play a key role in gene regulation. "The pair sought to explore how nerve cells and muscle cells, for example, have very different characteristics despite having the same genetic information," writes Smith.

A new study led by researchers at MIT suggests that fasting and then refeeding stimulates cell regeneration in the intestines, reports Katharine Lang for Medical News Today. However, notes Lang, researchers also found that fasting “carries the risk of stimulating the formation of intestinal tumors.” 

Prof. Ömer Yilmaz and his colleagues have discovered the potential health benefits and consequences of fasting, reports Max Kozlov for Nature. “There is so much emphasis on fasting and how long to be fasting that we’ve kind of overlooked this whole other side of the equation: what is going on in the refed state,” says Yilmaz.

MIT researchers have discovered how fasting impacts the regenerative abilities of intestinal stem cells, reports Ed Cara for Gizmodo. “The major finding of our current study is that refeeding after fasting is a distinct state from fasting itself,” explain Prof. Ömer Yilmaz and postdocs Shinya Imada and Saleh Khawaled. “Post-fasting refeeding augments the ability of intestinal stem cells to, for example, repair the intestine after injury.” 

Prof. Emerita Mary-Lou Pardue, a cellular and molecular biologist whose work “formed the foundation for key advancements and discoveries in understanding the structure of chromosomes,” has died at age 90, reports Bryan Marquard for The Boston Globe. Pardue “was a role model of what women in science can be at a time when there weren’t a lot of those, and a trailblazer as a woman,” emphasizes Ky Lowenhaupt, manager of the Biophysical Instrumentation Facility at MIT, “but also a trailblazer as a scientist who didn’t do things along the path that other people took.”

MIT scientists have created a high-resolution brain map of the neurons that encode the meanings of various words, reports Sara Reardon for Nature. “The results hint that, across individuals, the brain uses the same standard categories to classify words,” Reardon explains, “helping us to turn sound into sense.” 

Sonia Vallabh and Eric Minikel, senior group leaders from the Broad Institute have created a gene-editing tool to combat prion diseases, reports Karen Weintraub for USA Today. The approach “should also work against diseases such as Huntington's, Parkinson's, ALS and even Alzheimer's, which result from the accumulation of toxic proteins,” Weintraub writes.

STAT lists “The Exceptions: Sixteen Women, MIT, and the Fight for Equality in Science,” by Kate Zernicke as a “best book on health and science to check out this summer.”  The book focuses on Prof. Nancy Hopkins’ “career, which culminates in not only numerous scientific successes but also a collaborative effort with 15 other women faculty demonstrating evidence of gender discrimination at MIT,” explains STAT. “This work led to studies to address gender equity at nine other universities.” 

MIT researchers have discovered a protein found in human sweat that holds antimicrobial properties and can “inhibit the growth of the bacteria that causes Lyme disease,” reports Matt Fortin for NENC. The team believes this “type of protein could be put into a topical cream to make something called ‘Lyme Block’ – like sunblock, but for preventing Lyme.”  "Ideally what we would love to do is give people more control over their own risk," says Principal Research Scientist Michal Tal. "And really try to develop this into a possible preventative that you could put on repellant or sunblock to protect against other elements of the outdoors that you could also protect yourself against Lyme."

Ms. Magazine reporter Kalindi Vora spotlights Prof. Emerita Evelyn Fox Keller and the legacy of her work in the field of science. “Through her work, [Keller] showed that objectivity, the key value of the sciences, is in fact always partially subjective,” writes Vora. “Her legacy demonstrates that diversifying the sciences will improve research and discovery.”

Researchers from MIT and elsewhere have isolated a “protein in human sweat that protects against Lyme disease,” reports Matthew Rozsa for Salon. The researchers believe that if “properly harnessed the protein could form the basis of skin creams that either prevent the disease or treat especially persistent infections,” writes Rosza.

Bingxu Liu PhD '23 speaks with Science reporter Christie Wilcox about his work  studying STING, an immune protein that plays a key role in defending the human body against viruses, bacteria, and tumors. “STING is actually one of the most promising cancer immunotherapy targets,” explains Wilcox. “If you activate the STING pathway, it triggers a very strong immune response. But when it’s too strong, it can actually kill your T cells. Initial evidence suggest that T cells die because of some ion impact. Which begs the question: Can we just use STING to activate some parts of the immune response, like interferon, but also block the ion flow [that’s harming T cells]?” 

Prof. Jonathan Weissman and his colleagues have developed a new tool for monitoring changes in human blood cells, which could one day help researchers predict disease risk, reports Megan Molteni for STAT. “The technology paves the way for a day in the not too distant future where it is conceivable that from a simple blood draw, a doctor could get a sense of what’s going on in that patient’s bone marrow,” writes Molteni, “picking up perturbations there that could help predict a diverse range of diseases.”