Investigating cocaine addiction using fruit flies

Researchers have developed a way to use fruit flies to explore the genetic underpinnings of cocaine addiction

Society for Neuroscience

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In a new JNeurosci paper, Adrian Rothenfluh and colleagues from the University of Utah developed a fruit fly model of cocaine self-administration that can be used to explore the genetic underpinnings of cocaine addiction.  

To model voluntary cocaine intake in fruit flies, or Drosophila melanogaster, the researchers first assessed cocaine consumption and preferences of this insect. Cocaine was innately aversive to fruit flies because it activated their bitter-sensing receptors. In other words, the fruit flies did not like cocaine’s bitter taste. When the researchers mutated a gene for these receptors to reduce bitter perception, this made cocaine less aversive to the flies, and they began to approach a solution containing cocaine. Eventually, fruit flies with mutated receptors even preferred the cocaine solution over a sucrose solution.  

Says Rothenfluh, “We have previously modeled alcohol self-administration in fruit flies, and this has revealed that humans and fruit flies share many of the same genes that drive alcohol consumption and addiction. So, it is reasonable to think that the genes involved with cocaine addiction in humans may also be involved in this fruit fly model.” 

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About JNeurosci 

JNeurosci was launched in 1981 as a means to communicate the findings of the highest quality neuroscience research to the growing field. Today, the journal remains committed to publishing cutting-edge neuroscience that will have an immediate and lasting scientific impact, while responding to authors' changing publishing needs, representing breadth of the field and diversity in authorship. 

About The Society for Neuroscience 

The Society for Neuroscience is the world's largest organization of scientists and physicians devoted to understanding the brain and nervous system. The nonprofit organization, founded in 1969, now has nearly 35,000 members in more than 95 countries. 

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Journal

JNeurosci

DOI

10.1523/JNEUROSCI.1040-24.2025 

Article Title

Bitter Sensing Protects Drosophila from Developing Experience-Dependent Cocaine Consumption Preference

Article Publication Date

2-Jun-2025

Fruit flies on cocaine could reveal better therapies for addiction

University of Utah Health

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Adrian Rothenfluh, PhD (left) and Pearl Cummins-Beebee (right, also an author on the paper) inspect a bottle of fruit flies in the lab.

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Credit: Caitlyn Harris / University of Utah Health

For the first time, researchers have created genetically modified fruit flies that can become addicted to cocaine. The flies will self-administer cocaine if given the option. The new model could prove immensely valuable for the development of new therapies to prevent and treat cocaine use disorder, a growing and deadly concern that affects about 1.5 million people nationwide.

Heredity strongly impacts the risk of developing cocaine use disorder, but the large number of genes implicated in addiction risk has made it difficult to determine which might be the best targets for therapeutics.

With their new fruit fly model of cocaine use disorder, the researchers hope to reveal the biology of addiction and find better therapies much faster than was previously possible.

The new results are published in Journal of Neuroscience.

High-flying aspirations

Flies and humans react to cocaine in remarkably similar ways, says Adrian Rothenfluh, PhD, associate professor of psychiatry at the University of Utah and the senior author on the study. “At low doses, they start running around, just like people,” Rothenfluh says. “At very high doses, they get incapacitated, which is also true in people.”

Flies and humans have a lot in common when it comes to addiction. Flies have about 75% of the human genes that are known to be involved in disease, and the insects have been instrumental in discovering the underlying biology behind other substance dependencies.

Because fruit flies grow quickly and are easy to conduct genetic experiments with, a fruit fly model of cocaine use disorder would be a valuable early step toward developing therapies.

There is just one problem—one very significant difference between flies and humans—Rothenfluh says: “Flies do not like cocaine one bit.”

His research team found that when given a choice between sugar water and sugar water laced with cocaine, fruit flies consistently chose the drug-free option, even when they’d been exposed to cocaine previously. To better understand addiction in humans, the scientists needed to figure out why flies wouldn’t take cocaine—and if there was a way to bypass that barrier.

The bitter truth

Travis Philyaw, PhD, first author on the paper, suspected that the answer might lie in the flies’ sense of taste. “Insects are evolutionarily primed to avoid plant toxins, and cocaine is a plant toxin,” says Philyaw, now a research scientist at University of Washington, who did the research as a graduate student in Rothenfluh’s lab. “They have taste receptors on their ‘arms’—their tarsal segments—so they can put their hand in something before it goes in their mouth, and decide, ‘I’m not going to touch that.’”

By watching how flies’ sensory nerves responded to cocaine, the researchers found that the compound strongly activates bitter-sensing taste receptors in the flies’ tarsal segments. When the researchers muted the activity of those bitter-sensing nerves so that the flies couldn’t taste bitter flavors, they did start developing a preference for cocaine-laced sugar water over plain sugar water. The dosage was important—flies would only voluntarily consume cocaine at low concentrations—but they developed a preference remarkably quickly, within 16 hours of first exposure.

From insects to impacts

The researchers say this will help them understand addiction in humans. Now that scientists can study the process in fruit flies, the pipeline to new discoveries can be greatly accelerated, studying hundreds of potentially relevant genes in a much shorter time span.

“We can scale research so quickly in flies,” Philyaw says. “We can identify risk genes that might be difficult to uncover in more complex organisms, and then we pass that information to researchers who work with mammalian models. Then, they’re able to uncover treatment targets that facilitate the jump from studying animal behavior to developing human therapeutics.”

Rothenfluh agrees: “We can really start to understand the mechanisms of cocaine choice, and the more you understand about the mechanism, the more you have a chance to find a therapeutic that might act on that mechanism.”

In addition to specific searches for therapeutics, Rothenfluh says basic research into the mechanisms of how the human mind—and the fruit fly mind—work can have unexpected impacts. “Just trying to understand the simple little fly brain can give us insights that you cannot anticipate,” he emphasizes. “Basic science is important, and you never know what exciting things you might find that turn out to be impactful for understanding the human condition.”

 

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This research is published in Journal of Neuroscience as “Bitter sensing protects Drosophila from developing experience-dependent cocaine consumption preference.”

 

The work was funded by the Huntsman Mental Health Institute, the University of Utah Molecular Medicine Program, and the National Institutes of Health, including the National Institute of Diabetes and Digestive and Kidney Diseases (grant number R01DK110358), the National Institute on Drug Abuse (grants K01DA058919, R21DA049635, and R21DA040439), and the National Institute on Alcohol Abuse and Alcoholism (grants R01AA026818, R01AA019536-S1, and R01AA030881). Content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

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Journal

JNeurosci

Method of Research

Experimental study

Subject of Research

Animals

Article Title

Bitter sensing protects Drosophila from developing experience-dependent cocaine consumption preference

Article Publication Date

2-Jun-2025

 

MSU study: Virtual reality beneficial for remote instruction — but there’s a time limit

Michigan State University

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EAST LANSING, Mich. – Slowly but surely virtual reality, or VR, headsets are becoming a part of classrooms in colleges, high schools and even middle schools. Meanwhile, large companies such as Apple and Meta continue to spend billions on VR headsets, betting on eventual mainstream VR adoption. But there is very little data examining the costs and benefits of this new technology over time.

New research from Michigan State University with colleagues at Stanford shows that the sense of social connection in VR during classroom instruction (called social presence) enhances student outcomes compared to videoconferencing — until virtual meeting fatigue sets in.

The study, published in Computers and Education and partially funded by the National Science Foundation, notes that both the benefits of use and virtual meeting fatigue increase with time spent in VR. Notably, certain benefits — like students’ social presence with peers and perceived competence in the class — start to decline after about 45 minutes of VR use on average. However, this optimal level of VR duration differs widely between students, ranging from about 20 minutes to 280 minutes.

“Class time spent in VR likely leads to a net benefit despite meeting fatigue,” said Rabindra “Robby” Ratan, associate professor of media and information and AT&T Endowed Chair in the MSU College of Communication Arts and Sciences. “Virtual reality amplifies the benefits of online learning because of its ability to provide immersive, interactive and personalized experiences that enhance learner engagement with course content and peers.”

Ratan and his colleagues conducted the study as part of a 15-week online undergraduate class in which students used VR headsets regularly. The class met twice weekly for 80 minutes and used a combination of videoconferencing and virtual reality. Of the 30 students who participated in the study, the majority had not used VR prior to the class.

The study builds on Ratan’s previous research on social presence and online education, which examined a student’s perceived course gains through three constructs:

• Perceived learning, which is generally, though not perfectly, correlated with grades.
• Perceived competence, which refers to students’ self-assessed abilities in class performance.
• Class enjoyment, which reflects students’ perceptions of the class as fun and engaging.

“Class meetings in VR improve social connectivity and enjoyment — at least until the detrimental effects of virtual meeting fatigue build up and become harder to manage,” said Ratan.

Social presence — the sense of being together with others in a mediated environment, shaped by reactions to social cues — may buffer against virtual meeting fatigue, according to the study. Peer social presence was more positively related to VR duration than it was to virtual meeting fatigue, though it peaked around an average of 45 minutes, again with large differences between students.

“Social presence plays a vital role in online learning, influencing outcomes such as engagement, class performance and learner satisfaction,” said Ratan. “VR can facilitate more natural communication in online classrooms by providing interactive avatars and nonverbal cues.”

Ratan recommends keeping VR duration low for new users but notes that VR duration may increase as students become more comfortable with the medium. He also suggests employing it for activities that emphasize active engagement, such as small group discussions, not lectures, as VR is more effective for participative activities than for passive learning.

“Instructors should find a balance to harness the benefits of social presence in VR, be mindful of new users as they acclimate to the technology and offer alternative modes of access to classes in virtual worlds,” he said. “Instructors should use virtual reality platforms that offer desktop computer and mobile applications, allowing students to participate without a VR headset and avoid fatigue and simulator sickness when they need to.”

Simulator sickness is a type of motion sickness that can occur from prolonged exposure to VR.

“At any class duration, providing alternative access options can enhance accessibility, inclusivity and sustained engagement across students,” Ratan said.

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Michigan State University has been advancing the common good with uncommon will for 170 years. One of the world’s leading public research universities, MSU pushes the boundaries of discovery to make a better, safer, healthier world for all while providing life-changing opportunities to a diverse and inclusive academic community through more than 400 programs of study in 17 degree-granting colleges.

For generations, Spartans have been changing the world through research. Federal funding helps power many of the discoveries that improve lives and keep America at the forefront of innovation and competitiveness. From lifesaving cancer treatments to solutions that advance technology, agriculture, energy and more, MSU researchers work every day to shape a better future for the people of Michigan and beyond. Learn more about MSU’s research impact powered by partnership with the federal government. 

For MSU news on the web, go to MSUToday or x.com/MSUnews.

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Journal

Computers & Education

DOI

10.1016/j.compedu.2025.105328 

Article Title

Time matters in VR: Students benefit from longer VR class duration, but certain outcomes decline after 45 minutes, with large individual variance

Article Publication Date

1-Oct-2025

 

Set it and forget it: Autonomous structures can be programmed to jump days in advance

North Carolina State University

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Researchers have created dynamic structures that leap into the air on a predetermined schedule without intervention from computers or external stimuli. Precisely when these “metashells” jump, and how high they jump, is engineered into the physical structure of the materials. This image combines time-lapsed photos to show one of these "metashells" leaping into the air from a snowy surface.

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Credit: Haitao Qing, NC State University

Researchers have created dynamic structures that leap into the air on a predetermined schedule without intervention from computers or external stimuli. Precisely when these “metashells” jump, and how high they jump, is engineered into the physical structure of the materials.

“There are structures that ‘jump’ immediately when loading is removed – such as when a coiled spring is released,” says Jie Yin, corresponding author of a paper on the work and an associate professor of mechanical engineering at North Carolina State University. “We wanted to create a structure that does not rely on external stimuli and allows us to dictate the timing of the jump in advance. We have developed a technique that allows us to precisely schedule when the structure leaps into action, whether that is in seconds or hours.”

For this work, the researchers created spherical structures made of strands of a material called polyethylene terephthalate (PET) which are connected into a complex lattice pattern. The design of the structure maximizes the material’s ability to store energy. When a load is applied to the structure, it is deformed out of shape, but when that load is removed it returns to its original shape. However, PET has viscoelastic material properties, which means it doesn’t snap back into its original shape right away.

Instead, once the load is removed, the viscoelastic metashell slowly starts “creeping” back to its original shape before reaching a critical point – at which point it snaps the rest of the way back to its original shape all at once. And the longer the load is applied to the structure, the longer it takes for the structure to reach that critical point once the load is removed.

“The end result is that if you apply a load to our spherical metashell, it is compressed into a shape like a flower bud,” says Haitao Qing, first author of the paper and a Ph.D. student at NC State. “When the flower bud snaps back into the spherical shape, the release of energy hurls the structure into the air. And you can dictate exactly when that jump will happen by controlling how long the load is applied to the structure. This also controls how high the metashell jumps, because the longer the load is applied, the less high the metashell will jump.”

“Material properties play a critical role, and the design of the structure we created amplifies those properties,” says Yin. “The material is viscoelastic and the structure design is responsible for storing elastic energy, and both features are critical to the performance of this technology.”

In testing, the researchers demonstrated that jumps could be scheduled from three seconds to 58 hours in advance. The metashells could jump up to nine times their height into the air, or as little as 0.5 times their height, depending on how far ahead the jumps were scheduled. The researchers also demonstrated that the metashells could jump effectively on a variety of surfaces – from solid surfaces to sand, snow or water – and at temperatures as low as minus 15 degrees Celsius.

The researchers also demonstrated that the metashells could be loaded with cargo, such as seeds, and would disperse those contents when it jumped. Video of the metashells in action can be found at https://www.youtube.com/watch?v=6LWB3MujBTc.

“For this test, we were inspired by explosive seed dispersal, which we see in nature, such as Impatiens balsamina,” Qing says. “We showed that a 100-millimeter metashell was capable of dispersing seeds across an area of 1.5 meters.”

“Moving forward, we are interested in exploring biodegradable materials that would work with this design and investigating various potential applications,” Yin says. “We are also open to collaborating with other researchers or the private sector on ways to make use of this technology.”

The paper, “Programmable seconds-to-days long delayed snapping in jumping metashell,” will be published the week of June 2 in the Proceedings of the National Academy of Sciences. The paper was co-authored by Caizhi Zhou and Fangjie Qi, Ph.D. students at NC State.

This work was done with support from the National Science Foundation under grants 2126072 and 2329674. Qing and Yin are co-inventors on a pending patent invention disclosure filed by North Carolina State University related to this work.

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Journal

Proceedings of the National Academy of Sciences

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Programmable seconds-to-days long delayed snapping in jumping metashell

Article Publication Date

2-Jun-2025

COI Statement

Qing and Yin are co-inventors on a pending patent invention disclosure filed by North Carolina State University related to this work.

 

Iron from coal, steel industries alters North Pacific ecosystem

University of Hawaii at Manoa

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Rosette water sampler prepped for deployment during Gradients Cruise onboard the Univeristy of Hawai'i Research Vessel Kilo Moana.

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Credit: Ryan Tabata

Along with nutrients like nitrogen and phosphorus, iron is essential for the growth of microscopic phytoplankton in the ocean. However, a new study led by oceanographers at the University of Hawai‘i (UH) at Mānoa revealed that iron released from industrial processes, such as coal combustion and steel making, is altering the ecosystem in the North Pacific Transition Zone, a region just north of Hawai‘i that is important for fisheries in the Pacific. The study was published today in the Proceedings of the National Academy of Sciences USA.

“This is an example of the large-scale impact that human pollution can have on marine ecosystems that are thousands of miles away from the source,” said Nick Hawco, lead author of the study and assistant professor in the Department of Oceanography at the UH Mānoa School of Ocean and Earth Science and Technology. 

Iron from human activities billows into the atmosphere and can be carried to distant lands or oceans before being scrubbed from the skies by rain. Industrial iron has previously been detected in the North Pacific Transition Zone, however, it was unclear what effect iron was having on the ecosystem.

To piece together the season cycle of iron input, phytoplankton growth, and ocean mixing, Hawco and collaborators from several universities analyzed water and phytoplankton samples and studied ocean dynamics during four different expeditions to this region of the Pacific Ocean. They also assessed the iron in these waters to determine whether it had the unique isotope signature of iron that is released from industrial processes. 

The team found that phytoplankton in the region are iron-deficient during the spring, so an increase in the supply of iron boosts the spring phytoplankton bloom that is typical in the area. However, as a result of a booming bloom, they deplete other nutrients more quickly, leading to a crash in phytoplankton later in the season. Importantly, the iron isotope signature did, in fact, indicate the presence of industrial iron out in the Pacific, thousands of miles away from its source.

“The ocean has boundaries that are invisible to us but known to all sorts of microbes and animals that live there,” said Hawco. “The North Pacific Transition Zone is one of these boundaries. It divides the low nutrient ocean gyres from the high nutrient temperate ecosystems to the North. With more iron coming into the system, that boundary is migrating north, but we are also expecting to see these boundaries shift northward as the ocean warms.”

That’s not necessarily all bad, Hawco shared. But unfortunately, the regions of the Transition Zone that are closer to Hawai‘i are among those that are losing out. 

“It's a one-two punch: industrial iron is impacting the base of the food web and the warming of the ocean is pushing these phytoplankton-rich waters further and further away from Hawai‘i,” Hawco said.

The research team is developing new techniques to monitor the iron nutrition of ocean plankton. This will shed light on how changes in iron supply, from both natural or industrial sources, could impact ocean life.

Horizon on Gradients Cruise onboard the R/V Kilo Moana.

Credit

Ryan Tabata

Coal power plant.

Credit

Arnold Paul

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Journal

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2418201122 

Method of Research

Experimental study

Article Title

Anthropogenic iron alters the spring phytoplankton bloom in the 4 North Pacific Transition Zone

Article Publication Date

2-Jun-2025