This gene-editing success from TAU could change cancer treatment forever.
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Research
Mar 11th, 2025
Half the Tumors Gone: TAU Scientists Remove a Cancer Gene with CRISPR
- Medicine
Researchers from Tel Aviv University utilized CRISPR to cut a single gene from cancer cells of head and neck tumors – and successfully eliminated 50% of the tumors in model animals. This groundbreaking study was led by Dr. Razan Masarwy, MD, Ph.D. from the lab of Prof. Dan Peer - a global pioneer in mRNA-based drugs, Director of the Laboratory of Precision Nanomedicine, VP for Research and Development and member of the Shmunis School of Biomedicine and Cancer Research – all at TAU. The findings were published in the prestigious journal Advanced Science.
A New Approach to Treating Head and Neck Cancers
“Head and neck cancers are prevalent, ranking fifth in cancer mortality”, says Prof. Peer. “These are localized cancers, typically starting in the tongue, throat, or neck, which can later metastasize. If detected early, localized treatment can effectively target the tumor. We aimed to use genetic editing of a single gene expressed in this type of cancer to collapse the entire pyramid of the cancerous cell. This gene is the cancer-specific SOX2, also expressed in other types of cancer and overexpressed in these particular tumors”.
Prof. Dan Peer.
Prof. Peer and his colleagues are global pioneers in developing mRNA-based drugs encased in synthetic lipid particles that mimic biological membranes. In this study, the researchers synthesized special lipids that encapsulate the delivered CRISPR system in an RNA format. An antibody targeting a receptor against a protein named EGF was attached to the surface of these particles.
“These tumors are highly targeted”, explains Prof. Peer. “We targeted EGF because the cancer cells express the EGF receptor. Using our nano-lipid delivery system, we injected the drug directly into the tumor in a tumor model and successfully took out the gene - cutting it out from the cancer cell's DNA with the CRISPR 'scissors'. We were happy to observe the domino effect we had predicted. Following three injections spaced one week apart, 50% of the cancerous tumors simply disappeared after 84 days - which did not happen in the control group”.
Prof. Dan Peer & research team.
TAU Pioneers CRISPR for Cancer Treatment
In 2020, Prof. Peer and his team were the first in the world to use CRISPR to cut genes from cancer cells in mice and a cell-specific manner, and this is the first time they have applied it to head and neck cancers.
“Generally, CRISPR isn't used for cancer because the assumption is that knocking out one gene wouldn’t collapse the whole pyramid. In this study we demonstrated that there are some genes without which a cancer cell cannot survive, making them excellent targets for CRISPR therapy. Since cancer cells sometimes compensate with other genes, it's possible that additional genes need to be cut out, or perhaps not. Theoretically, this approach could be effective against many types of cancer cells, and we are already working on additional cancer types, including myeloma, lymphoma, and liver cancer”.
This study was supported in part by the EXPERT project (European Union’s Horizon 2020 research and innovation programme (under grant agreement # 825828), and the Shmunis Fund for gene editing.
Research
Feb 26th, 2025
The Future of Memory: Superlubricity Sparks Breakthroughs
A two-atom-thick, frictionless layer could boost speed, efficiency, and durability.
- Exact Sciences
A groundbreaking technological advancement from Tel Aviv University has, for the first time, enabled the application of the scientific phenomenon of superlubricity in electronic components. As a result, the research team successfully harnessed frictionless sliding to significantly enhance the performance of memory components in computers and other electronic devices.
The study was led by Dr. Youngki Yeo, Mr. Yoav Sharaby, Dr. Nirmal Roy, and Mr. Noam Raab, all members of the Quantum Layered Matter Group headed by Professor Moshe Ben Shalom's at the School of School of Physics & Astronomy , Tel Aviv University. The research was recently published in the prestigious journal Nature.
The research team explains that friction is a force that prevents free sliding between surfaces. On one hand, it is essential—for example, it keeps us from slipping in the shower—but on the other, it causes wear and energy loss. In the human body, evolution has developed advanced lubricants for joints, but even they degrade over time (as our knees occasionally remind us).
This issue is particularly critical in the world of computing. Tiny memory components operate at extremely high speeds—millions of cycles per second—and run continuously in computers, artificial intelligence, and advanced medical systems. Any improvement in efficiency, durability, and energy consumption directly translates into major technological advancements.
Interlocking foam structures demonstrating vanishing large friction for desynchronized atomic planes (Photo credit: Adi Hod).
Nature's Secret: Superlubricity and Frictionless Surfaces
The researchers highlight that nature has found a way to create nearly frictionless surfaces, a phenomenon known as superlubricity. To understand this concept, imagine placing two egg cartons on top of each other: when perfectly aligned, they interlock and resist movement, but when slightly rotated, they slide freely. Similarly, when atomic layers of certain materials are somewhat misaligned, their atoms fail to synchronize, and friction between them nearly disappears.
About 20 years ago, scientists discovered that two rotated layers of graphite exhibit almost immeasurable friction— a breakthrough that paved the way for our development of next-generation memory technologies based on superlubricity.
"In our lab", explains Professor Moshe Ben Shalom, "we construct layered materials where even the tiniest atomic displacement causes electrons to move between layers. The result: a memory device just two atoms thick—the thinnest possible".
In the current study, the team developed a novel method for exploiting frictionless sliding to significantly improve memory performance.
Dr. Yeo's experiment involved combining ultrathin atomic layers of boron and nitrogen, separated by a perforated graphene layer. Within the nano-sized holes (just 100 atoms wide), the boron and nitrogen layers self-align, but between these islands, thanks to the unsynchronized graphene layer, friction disappears!
This phenomenon allows atoms within the aligned islands to slide quickly and efficiently, enabling unprecedentedly efficient data read/write operations while consuming significantly less energy.
Illustration - Superlubricity Applied in Electronic Devices Only Two Atoms Thick (Photo credit: Sayostudio).
Self-Organizing Memory for AI and Beyond
Professor Ben Shalom emphasizes: "Our measurements show that the efficiency of this new memory technology is significantly higher than existing technologies, with zero wear and tear. Beyond this, the new memory arrays reveal an intriguing effect: when the tiny islands are close to one another, atomic motion in one island influences neighboring islands. In other words, the system can self-organize into coupled memory states, a phenomenon that could lead to groundbreaking advancements in computing, including artificial intelligence and neuromorphic architectures (computing that mimics brain function)".
The research team concludes: "We are developing this technology through SlideTro LTD, a company founded on these discoveries, and in collaboration with Ramot, Tel Aviv University's technology transfer company. We believe that in the near future, this innovation will enable the development of ultrafast, reliable, and highly durable memory arrays".
Their future research aims to explore new computational possibilities through mechanical coupling between memory bits, an interaction that was previously impossible. Perhaps superlubricity will drive the next revolution in computing.
This research is funded by the European Research Council (ERC) and the Israel Science Foundation (ISF).
Research
Feb 25th, 2025
Why Do City Bats Give Birth Earlier?
Research reveals the city’s surprising effect on birth timing.
- Life Sciences
A groundbreaking study from Tel Aviv University, the first of its kind on mammals, has found that bats living in urban environments give birth, on average, about 2.5 weeks earlier than bats living in rural areas. The researchers attribute this difference in birthing times between the city and the countryside to more favorable temperatures and greater food abundance in urban areas. Bats are mammals, making this the first study to link the urban living environment to the timing of birth in mammals.
The research was led by the lab team of Prof. Yossi Yovel from the School of Zoology in the Wise Faculty of Life Sciences and the Steinhardt Museum of Natural History at Tel Aviv University. The study included contributions from Dr. Maya Weinberg, Dean Zigdon, and Mor Taub, and was published in the scientific journal BMC Biology.
Prof. Yossi Yovel.
Over three years, the researchers monitored ten bat colonies in urban and rural areas, sampling hundreds of female bats and approximately 120 pups from these colonies. The findings revealed that pups born in urban colonies were, on average, 2.5 weeks older, as evidenced by their longer forearms and higher body weights compared to pups from rural colonies.
Prof. Yovel explains: “Fruit bats living in cities benefit from favorable environmental conditions, including higher temperatures due to the ‘urban heat island’ effect and greater food availability, primarily from ornamental fruit trees irrigated year-round. These conditions allow urban bats to cope better with harsh winters and start their reproductive cycles earlier. This enables females to give birth earlier in the season, increasing their chances of becoming pregnant again within the same year.”
However, the researchers emphasize that it remains unclear whether the bats are shortening their pregnancies (a capability known in some bat species) or becoming pregnant earlier. They add that the study opens the door to further research on how urbanization affects mammalian reproductive patterns in general and bats in particular, and how these findings can be used to protect other species in changing ecosystems. “This study highlights the importance of understanding the connection between animals and their environments, especially in an era when urbanization is reshaping the planet,” concludes Prof. Yovel.
A mother bat in flight, carrying her pup beneath her in the city and countryside (Photo credit: Yuval Barkai).
Research
Feb 11th, 2025
Is the Spread of Deadly Pathogens Threatening Coral Reefs Worldwide?
From Eilat to the Indian Ocean, a relentless pathogen is ravaging marine ecosystems
- Life Sciences
An international team of researchers, led by scientists from Tel Aviv University, has discovered that the pathogen responsible for the mass deaths of sea urchins along the Red Sea coast is the same one responsible for mass mortality events among sea urchins off the coast of Réunion Island in the Indian Ocean. This finding raises fears that the pathogen – a waterborne ciliate - could spread further, to the Pacific Ocean. The researchers warn that this is a highly aggressive global pandemic, and are now spearheading an international effort to track the disease and preserve sea urchins, which play a crucial role in the health of coral reefs.
The study, led by Dr. Omri Bronstein from the School of Zoology at Tel Aviv University’s Wise Faculty of Life Sciences and the Steinhardt Museum of Natural History, was published in the prestigious journal Ecology.
The Research Team. Photo credit: Tel Aviv University.
“This is a first-rate ecological disaster”, explains Dr. Bronstein.
She continues: “Sea urchins are vital to the health of coral reefs. They act as the ‘gardeners’ of the reef by feeding on algae, preventing it from overgrowing and suffocating the coral, which competes with algae for sunlight. In 1983, a mysterious disease wiped out most of the Diadema sea urchins in the Caribbean. Unchecked, the algae there proliferated, blocking sunlight from the coral, and the region shifted from a coral reef ecosystem to an algae-dominated one. Even 40 years later, the sea urchin population — and consequently the reef — has not recovered”.
In 2022, the disease reemerged in the Caribbean, targeting the surviving sea urchin populations and individuals. This time, armed with advanced scientific and technological tools to collect and interpret the forensic evidence, researchers at Cornell University successfully identified the pathogen as a ciliate Scuticociliate parasite. A year later, in early 2023, Dr. Bronstein was the first to identify mass mortality events among long-spined sea urchins, a close relative of the Caribbean Sea urchins, in the Red Sea.
Sea urchin mortalities on Reunion Island. Photo credit: Jean-Pascal Quod.
“Until recently, this was one of the most common sea urchins in Eilat’s coral reefs — the familiar black urchins with long spines,” says Dr. Bronstein. “Today, this species no longer exists in significant numbers in the Red Sea. The event was extremely violent: within less than 48 hours, a healthy population of sea urchins turned into crumbling skeletons. In some locations in Eilat and the Sinai, mortality rates reached 100 percent. In follow-up research, we demonstrated that the Caribbean pathogen was the same one affecting populations in the Red Sea”.
Genetic Proof Links Global Sea Urchin Deaths to One Pathogen
Now, using genetic tools, Dr. Bronstein and his international colleagues have shown that the same ciliate parasite is responsible for similar mortality events off the coast of Réunion Island in the Indian Ocean. “This is the first genetic confirmation that the same pathogen is present in all these locations,” he says. “Now it’s a global event, a pandemic. The Caribbean, Red Sea, and the Indian Ocean are critical regions for the world’s coral reefs, and mortality rates for sea urchins in these areas are very high — over 90 percent. As of now, we have no evidence of this pathogen in Pacific Ocean sea urchins, but this is something we are actively investigating. Although we’ve developed genetic tools for the specific identification of the pathogen, it’s difficult to monitor such rapid extinction events in the vast underwater environment. We are terrestrial creatures, and some reefs are located in deep or remote areas. If we miss the mortality event by even a couple of days, we might find no trace of the extinct population”.
Four healthy sea urchin species on Reunion Island. Photo credit: Jean-Pascal Quod.
To track the progression of the pandemic, Dr. Bronstein has established an international network of collaborators. He provides them with alerts about the likelihood of mortality events in their regions and sends them the necessary equipment to sample and preserve affected sea urchins for comparison with samples from other locations. These kits are then sent back to the laboratory at Tel Aviv University.
“For populations that are already infected, we really have no tools to help them,” says Dr. Bronstein with regret. “There is no Pfizer or Moderna for sea urchins — not because we don’t want one, but because we simply can’t treat them underwater. Our focus must be on two entirely different tracks. The first is prevention. To prevent further spread of the pandemic, we need to understand why it erupted here and now. We’ve developed two hypotheses for this. The first is the transportation hypothesis — that the pathogen from the Caribbean was transported by humans to new and distant regions after being carried in the ballast water of ships, infecting sea urchins in the Red Sea before spreading to the Western Indian Ocean.
The sea urchin Diadema setosum before (left) and after (right) mortality. The white skeleton is exposed following tissue disintegration and loss of spines. Photo credit: Tel Aviv University.
How climate change might be spreading marine diseases worldwide
Incidentally, if this hypothesis is correct, we would expect to see mortality events in West Africa as well — as many cargo ships from the Caribbean stop there on their way to the Mediterranean and then through the Suez Canal to the Red Sea. Indeed, just in the past few weeks, we’ve discovered widespread mortality events in West Africa, as we predicted, and we’ve managed to obtain a limited number of samples collected during these events, which we are currently analyzing in the lab. If ships are indeed the source of the spread, then we could think of mitigation strategies. It’s not simple, and ships will never be completely sterile, but there are measures we can take. The second possibility is even more concerning: that the pathogen has always been present, and climatic changes have triggered its virulence and outbreak. That’s a challenge of an entirely different magnitude, one that we, as marine biologists, have very limited means to address”.
In parallel with global efforts, Dr. Bronstein has recently established a breeding nucleus for the affected sea urchins at the Israel Aquarium in Jerusalem, in collaboration with the Biblical Zoo and the Israel Nature and Parks Authority. This breeding population will serve as a reserve to restore affected populations and advance research into infection mechanisms and possible treatments.
“The pathogen is transmitted through water, so even sea urchins raised for research purposes in aquariums at the Interuniversity Institute for Marine Sciences and the Underwater Observatory in Eilat became infected and died. That is why we established a breeding nucleus with the Israel Aquarium, whose aquariums are completely disconnected from seawater. We genetically test the urchins transferred to the nucleus to ensure they are not carriers of the disease and that they genetically belong to the Red Sea population, enabling us to rehabilitate the population in the future. At the same time, we are using them to develop sensitive genetic tools for early disease detection from seawater samples — essentially creating ‘underwater COVID tests’ for sea urchins”.
Research
Feb 9th, 2025
When Marine Animals Become 'Plastic Distributors'
Marine animals eat and release microplastics, harming the environment.
- Environment
A new Tel Aviv University study has uncovered alarming findings about the spread of microplastic particles in the marine food web. In recent years, numerous studies have examined the dangers of aquatic animals and more specifically, filter-feeding organisms, ingesting non-degradable microplastic particles. In the current study, the research team sought to understand how the biological filtration by filter-feeding organisms affects the microplastics in their environment. The findings indicate that the particles are excreted in the feces of marine animals, causing them to be unidentifiable as plastic to the aquatic environment, but potentially as other organic matter suitable for consumption.
Additionally, the presence of microplastic within feces affects the feces dispersal which causes accumulation of feces and plastic particles. This may increase carbon and nitrogen levels on the seafloor and lead to algal blooms, which have a critical impact on the balance of the marine food web.
The research was conducted by PhD student Eden Harel of the School of Zoology in the Wise Faculty of Life Sciences, Prof. Noa Shenkar of the School of Zoologyand the Steinhardt Museum of Natural History, and Prof. Ines Zucker of the School of Mechanical Engineering and the Porter School of Environment and Earth Sciences, all at Tel Aviv University. The study was published in the journal Chemosphere.
Prof. Shenkar during a research dive (Photo credit: Dr. Tom Shlesinger).
Prof. Shenkar explains: “About a decade ago, when awareness of the plastic pollution problem in the marine environment began to grow, many researchers focused on identifying the location and scale of microplastic particles. Recently, the research focus has shifted to the effects and damage caused by microplastics. However, many experiments in this field are conducted using clean, purchased plastic, whereas in the sea, plastic particles are exposed to a wide range of influences and pollutants. We aimed to examine whether and how plastic changes after passing through the digestive system of a marine organism and how this process affects the presence of plastic and its availability to other organisms”.
How Marine Organisms Process Microplastics
The researchers created an experimental system in the lab simulating seawater containing ascidians — marine animals that feed by efficiently and indiscriminately filtering tiny particles from the water. They exposed the ascidians to two types of plastic particles: conventional polystyrene (PS), which is widely used, and polylactic acid (PLA), marketed as a biodegradable, environmentally friendly bioplastic. They then examined the impact of the ascidians’ filtration process on the concentration and distribution of plastic particles in the water at four intervals: at the time of exposure, after two hours (when the ascidians had filtered all available water and ingested the microplastic particles), after 24 hours, and after 48 hours (following digestion and the excretion of feces into the water).
The laboratory at Tel Aviv University where the experiment was conducted (Photo credit: Eden Harel).
The findings showed that approximately 90% of the polystyrene particles were removed from the water after two hours of filtration, but all the particles returned to the water after 48 hours, following passage through the digestive system. In contrast, the concentration of PLA particles in the water significantly decreased and remained low for 48 hours, larger PLA particles likely broke down during digestion and returned to the water as smaller undetectable nano-sized particles.
In the second phase of the study, the researchers examined what had happened to the microplastic particles that were filtered, digested, and excreted back into the water column. To do so, they isolated microplastic particles from the ascidians’ feces and analyzed them using Raman spectroscopy, an advanced device that identifies the chemical composition of materials by scattering a laser beam.
Eden Harel explains: “We found that the sensitive spectroscopy device could not identify the material as plastic at all and instead identified the particle as another type of organic material. Our findings revealed that microplastic particles are excreted from the ascidian’s digestive system coated with a fecal layer, and it is likely that the marine environment also identifies these particles as this organic material. Since many marine animals feed on feces, they may well ingest plastic that has changed its properties, identifying it as food. In this way, they are also exposed to microplastics and spread them further within the marine food web. The fecal coating may serve as a substrate for bacterial colonization and increase the adhesion and accumulation of pollutants such as heavy metals and residual organic substances (like antibiotics) on the plastic particles”.
Prof. Zucker adds: "This phenomenon also affects bioplastics marketed as 'biodegradable': unless conditions are met for their complete breakdown, they remain as particle pollution that changes properties during passage through the digestive system. The many transformations plastic particles undergo in the environment — from weathering to digestive processes, as investigated in this study — turn them into carriers of pollutants and diseases within the food web”.
The researchers analyzing the secretions of marine animals (Photo credit: Eden Harel).
What’s the Impact of Microplastics on Marine Life?
In the third phase of the study, the researchers examined the reverse effect: how microplastic particles affect feces, an organic material that plays a vital role in marine ecology. Eden Harel explains: “We found that plastic changes important physical properties of feces. Normal feces sink very slowly through the water column, serving as food for many organisms along the way. In contrast, feces containing microplastic particles sink rapidly to the seafloor. This removes an important nutrient source from the water column. Additionally, the faster sinking rate decreased the dispersion of the feces causing accumulation of feces and plastic particles near where the animals are settled. This accumulation can increase carbon and nitrogen levels on the seafloor and trigger algal blooms, representing another critical impact of microplastics on the balance of the marine food web”.
The researchers conclude: “In this study, we uncovered significant aspects of the influence of filter-feeding animals on the characteristics of microplastic particles in their environment and within the marine food web. The most alarming conclusion is that the microplastic problem is far more complex than initially thought. Plastic pollution in the marine environment has many unexpected dimensions, and its complexities continue to grow. Sometimes, neither we nor the environment can even recognize it as plastic. As time goes on, plastic continues to harm more and more marine ecosystems. We must develop new technologies to mitigate this dangerous phenomenon”.
