Researchers uncover on/off switch for breast cancer metastasis

Songnan Wang (left) and Lingyin Li (right) found that a protein called ENPP1 acts as an on/off switch for breast cancer metastases. High protein levels lead to a high chance of metastasis (as seen by cells growing in the dish on the left), while low levels lead to no metastasis (as seen by no cells growing in the dish on the right).
Photo Credit: Lingyin Li and Songnan Wang

New research from Stanford and the Arc Institute could lead to a new and more effective immunotherapy and help clinicians better predict patient response to existing medicines.

Despite their promise, immunotherapies fail to treat many cancers, including over 80% of some of the most advanced breast cancers. And many of those patients who do respond still experience metastases eventually. New research from Stanford University and the Arc Institute has revealed a better way to predict and improve patient responses.

A team led by Lingyin Li, associate professor of biochemistry at Stanford and Arc Core Investigator, found that a protein called ENPP1 acts as an on/off switch that controls breast cancer’s ability to both resist immunotherapy and metastasize. The study, published on Dec. 20 in the Proceedings of the National Academy of Sciences, showed that ENPP1 is produced by cancer cells and by healthy cells in and around the tumor, and that high patient ENPP1 levels are linked to immunotherapy resistance and subsequent metastases. The research could lead to new, more effective immunotherapies and help clinicians better predict patient response to existing medicines.

“Our study should offer hope for everyone,” said Li, who is also an institute scholar at Sarafan ChEM-H.

RIT researchers develop new technique to study how cancer cells move

Vinay Abhyankar, right, assistant professor of biomedical engineering, works closely with two doctoral students, Mehran Mansouri, left, and Indranil Joshi, on research to assess cancer cell migration processes.
Photo Credit: A. Sue Weisler/RIT

In tumors, cells follow microscopic fibers, comparable to following roads through a city. Researchers at the Rochester Institute of Technology developed a new technique to study different features of these “fiber highways” to provide new insights into how cells move efficiently through the tumor environment.

The study, published in the journal Advanced Functional Materials, focused on contact guidance, a process where migrating cells follow aligned collagen fibers. Understanding this process is crucial, as it plays a key role in cancer metastasis, the spread of cancer to other parts of the body.

“Previous research on contact guidance, a process where cancer cells migrate along aligned collagen fibers, has been largely studied in collagen gels with uniform fiber alignment,” said Vinay Abhyankar, associate professor of biomedical engineering in RIT’s Kate Gleason College of Engineering, and study co-author. “However, the tumor microenvironment also features subtle variations or gradients in fiber alignment, and their role in cell migration has been largely unexplored. We suspected that alignment gradients could efficiently direct cell movement but lacked the technology to test the hypothesis.”

A Trillion Scents. One Nose.

The genome inside an olfactory cell’s nucleus is shown as a tangle of color-marked chromosomes with genomic locations of olfactory receptor genes revealed on the right
Illustration Credit: Lomvardas lab, Columbia's Zuckerman Institute

The mammalian nose is a work of evolutionary art. Its millions of nerve cells, each tailored with just one of thousands of specific odor-chemical receptors encoded in the genome, can collectively distinguish a trillion distinct scents. Those sensations, in turn, inform many behaviors, from assessing food options to discerning friends from foes to sparking memories. 

Today, in the journal Nature, a research team led by scientists at Columbia’s Zuckerman Institute describes a previously undetected mechanism in mice—starring the genetic molecule RNA—that could explain how each sensory cell, or neuron, in mammalian noses becomes tailored to detect a specific odor chemical. 

For example, there are sensory neurons in our noses that bear receptors uniquely tuned to detect ethyl vanillin, the main odorant in vanilla, and other cells with receptors for limonene, lemon’s signature odorant.

Moderate low-carbohydrate diet is beneficial for adults with type 1 diabetes

Sofia Sterner Isaksson and Marcus Lind, Institute of Medicine, Sahlgrenska Academy at the University of Gothenburg.
Photo Credit: Malin Arnesson, Johan Wingborg

A moderate low-carbohydrate diet for adults with type 1 diabetes has advantages over traditional diet. The average blood sugar level is reduced and the time with good values during a 24-hour period is increased, without any negative health impact. This has been shown in a study carried out at the University of Gothenburg.

The study published in The Lancet Regional Health - Europe is the largest of its kind to date. Participants were for different periods randomly assigned in a crossover manner to eat a traditional diet with 50% of the energy from carbohydrates, or a moderate low-carbohydrate diet with 30% of the energy from carbohydrates.

This is a moderate reduction in carbohydrates, with 24-hour monitoring of all participants via continuous glucose monitoring (CGM). Blood glucose levels were recorded at least every 15 minutes during the 16 weeks of the study, and were followed up by a dietitian and diabetes nurse.

The researchers emphasize that for safety reasons, major changes in carbohydrate intake in type 1 diabetes should always be made in consultation with the healthcare provider. Individuals should not make these dietary changes on their own, especially not for children with type 1 diabetes. The current study concerns only adults.

Inhaled statins show promise as effective asthma treatment

This diagram shows how the inhaled medication pitavastatin may play a beneficial role in reducing obstructive airway diseases such as asthma.
Illustration Credit: Courtesy of University of California at Davis

Statins are a class of drugs commonly used to lower bad cholesterol, but can they also treat obstructive airway diseases, such as asthma?

UC Davis Health pulmonologists taking part in an NIH-funded study are exploring an innovative approach to determine whether statins may help treat obstructive airway diseases by delivering the medication via inhalation.

“Delivering statins by inhalation is a creative way to deploy a drug that has potent biological effects in pre-clinical cell-based and animal model studies,” said Amir A. Zeki, the principal investigator of the study and professor of internal medicine who specializes in pulmonary, critical care and sleep medicine. “Because oral statins do not penetrate the airway compartment at high enough levels to be effective, delivering statins directly to the lung via inhalation might achieve better local tissue drug levels, and therefore, better clinical results. This allows the use of lower drug doses to achieve efficacy while also minimizing systemic side effects.”

Scientists uncover link between the ocean’s weather and global climate

Oceanic weather systems (mesoscale eddies) from data overlaid with atmospherically driven climate-scale currents (black lines), which can be extracted with a coarse graining technique developed in the lab of Hussein Aluie. The image reveals how these ocean weather systems are energized (red) or weakened (blue) when interacting with climate-scales, which follows a pattern mirroring the global atmospheric circulation.
Illustration Credit: Benjamin Storer

Using mechanical rather than statistical analysis, the team offers a new framework for understanding the climate system.

An international team of scientists has found the first direct evidence linking seemingly random weather systems in the ocean with climate on a global scale. Led by Hussein Aluie, an associate professor in the University of Rochester’s Department of Mechanical Engineering and staff scientist at the University’s Laboratory for Laser Energetics, the team reported their findings in Science Advances.

The ocean has weather patterns like what we experience on land, but on different time and length scales, says lead author Benjamin Storer, a research associate in Aluie’s Turbulence and Complex Flow Group. A weather pattern on land might last a few days and be about 500 kilometers wide, while oceanic weather patterns such as swirling eddies last three to four weeks but are about one-fifth the size.

Cosmic lights in the forest

TACC’s Frontera, the fastest academic supercomputer in the US, is a strategic national capability computing system funded by the National Science Foundation.
Photo Credit: TACC.

Like a celestial beacon, distant quasars make the brightest light in the universe. They emit more light than our entire Milky Way galaxy. The light comes from matter ripped apart as it is swallowed by a supermassive black hole. Quasar light reveals clues about the large-scale structure of the universe as it shines through enormous clouds of neutral hydrogen gas formed shortly after the Big Bang on the scale of 20 million light years across or more. 

Using quasar light data, the National Science Foundation (NSF)-funded Frontera supercomputer at the Texas Advanced Computing Center (TACC) helped astronomers develop PRIYA, the largest suite of hydrodynamic simulations yet made for simulating large-scale structure in the universe.

“We’ve created a new simulation model to compare data that exists at the real universe,” said Simeon Bird, an assistant professor in astronomy at the University of California, Riverside. 

Bird and colleagues developed PRIYA, which takes optical light data from the Extended Baryon Oscillation Spectroscopic Survey (eBOSS) of the Sloan Digital Sky Survey (SDSS). He and colleagues published their work announcing PRIYA in the Journal of Cosmology and Astroparticle Physics (JCAP). 

Research offers a reason why diversity in plant species causes higher farming yield, solving 'a bit of a mystery'

Co-author Peggy Schultz collects data on plots with undergraduate workers.
Photo Credit: KU Marketing

A study appearing in Nature Communications based on field and greenhouse experiments at the University of Kansas shows how a boost in agricultural yield comes from planting diverse crops rather than just one plant species: Soil pathogens harmful to plants have a harder time thriving.

“It’s commonly observed that diverse plant communities can be more productive and stable over time,” said corresponding author James Bever, senior scientist with the Kansas Biological Survey & Center for Ecological Research and Foundation Distinguished Professor of Ecology & Evolutionary Biology at KU. “Range lands with numerous species can show increased productivity. But the reason for this has been a bit of a mystery.”

While crop rotation and other farming and gardening practices long have reflected benefits of a mix of plants, the new research puts hard data to one important mechanism underpinning the observation: the numbers of microorganisms in the soil that eat plants.

“Diverse agricultural communities have the potential to keep pathogens at bay, resulting in greater yields,” Bever said. “What we show is that a major driver is the specialization of pathogens, particularly those specific to different plant species. These pathogens suppress yields in low-diversity communities. A significant advantage of rangeland diversity is that less biomass is consumed by pathogens, allowing more biomass for other uses, such as cattle. The same process is crucial for agricultural production.”

Aerogel can become the key to future terahertz technologies

Aerogel can obtain high hydrophobicity by simple chemical modifications.
Photo Credit: Thor Balkhed

High-frequency terahertz waves have great potential for a number of applications including next-generation medical imaging and communication. Researchers at Linköping University, Sweden, have shown, in a study published in the journal Advanced Science, that the transmission of terahertz light through an aerogel made of cellulose and a conducting polymer can be tuned. This is an important step to unlock more applications for terahertz waves.

The terahertz range covers wavelengths that lie between microwaves and infrared light on the electromagnetic spectrum. It has a very high frequency. Thanks to this, many researchers believe that the terahertz range has great potential for use in space exploration, security technology and communication systems, among other things. In medical imaging, it can also be an interesting substitute for X-ray examinations as the waves can pass through most non-conductive materials without damaging any tissue.

However, there are several technological barriers to overcome before terahertz signals can be widely used. For example, it is difficult to create terahertz radiation in an efficient way and materials that can receive and adjust the transmission of terahertz waves are needed.

Uncovering the role of beta diversity in ecosystems

Karen Castillioni observes beta diversity in a prairie habitat.
Photo Credit: College of Biological Sciences

As climate change progresses, scientists want to better understand how species interact across habitats to preserve diversity. Key to these efforts is the concept of beta diversity, which explores species that thrive exclusively in specific habitats. The University of Minnesota's Cedar Creek Ecosystem Science Reserve in East Bethel is an ideal place to study beta diversity because it gives researchers access to many distinct habitats in one place. 

Karen Castillioni, a postdoctoral research associate in the College of Biological Sciences, along with Associate Professor Forest Isbell, wanted to know how beta diversity affects plant biomass, the total mass of living plants in a given area. Plant biomass is crucial for various ecological and environmental functions, including carbon sequestration and supporting food webs.

During the first phase of an experiment at Cedar Creek called BetaDIV, the researchers looked at five habitats: oak savanna, where bur oak tree dominates; coniferous forest, where white pine dominates; deciduous forest, where red maple dominates; bog, where tamarack dominates; and an old grassland where big bluestem dominates.