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The study was led by Dr. Roee Levy of the Berglas School of Economics at Tel Aviv University, Prof. Alexey Makarin of MIT Sloan School of Management, and Prof. Luca Braghieri of Bocconi University. The paper is forthcoming in the scientific journal American Economic Review, and was awarded a prize at the 2022 Economic Society European Meeting (ESEM).

"Over the last fifteen years, the mental health trends of adolescents and young adults in the United States have worsened considerably,” says Prof. Braghieri. “Since such worsening in trends coincided with the rise of social media, it seemed plausible to speculate that the two phenomena might be related.” 

The study was based on data that dates back to the 2004 advent of Facebook at Harvard University, before it took the internet by storm. Facebook was initially accessible only to Harvard students who had a Harvard email address. Quickly spreading to other colleges in and outside the US, the network was made available to the general public in the US and beyond in September 2006. The researchers were able to analyze the impact of social media use by comparing colleges that had access to the platform to colleges that did not. The findings show a rise in the number of students reporting severe depression and anxiety (7% and 20% respectively). 

"We hypothesized that unfavorable social comparisons could explain the effects we found, and that students more susceptible to such comparisons were more likely to suffer negative effects."

Here Comes Trouble

The study combined information from two different datasets: the specific dates on which Facebook was introduced at 775 American colleges, and the National College Health Assessment (NCHA), a survey conducted periodically at American colleges.

The researchers built an index based on 15 relevant questions in the NCHA, in which students were asked about their mental health in the past year. They found a statistically significant worsening in mental health symptoms, especially depression and anxiety, after the arrival of Facebook: 

• 7% increase in number of students who reported having suffering, at least once during the preceding year, depression so severe that it was difficult for them to function 
• 20% increase in number of students who reported anxiety disorders 
• 2% increase in number of students expected to experience moderate to severe depression 
• 3% increase in number of students experienced impairment to their academic performance due to depression or anxiety 
   

Dr. Roee Levy (Photo: Oren Sarig)

Social Media vs. Social Circumstances

TAU’s Dr. Levy notes, "When studying the potential mechanisms, we hypothesized that unfavorable social comparisons could explain the effects we found, and that students more susceptible to such comparisons were more likely to suffer negative effects.”

“More students believed that others consumed more alcohol, even though alcohol consumption had not changed significantly."  

In other words, the methodology also considered any differences in mental health over time or across colleges that were not related to Facebook. This approach enabled conditions similar to those of a 'natural experiment,' which would be impossible today now that billions of people around the world use many different social networks.

To test this interpretation, the team investigated more data from the NCHA. They found, for example, a greater negative impact on the mental health of students who lived off-campus and were consequently less involved in social activities, and a greater negative impact on students with credit card debts who saw their supposedly wealthier peers on the network. 

“We also found evidence that Facebook had changed students’ beliefs about their peers,” adds Levy. “More students believed that others consumed more alcohol, even though alcohol consumption had not changed significantly."  

The three genes were isolated from plants preserved in the Liberman Okinow Gene Bank of Wild Cereals at the Institute for Cereal Crops Research (ICCR) at the George S. Wise Faculty of Life Sciences at Tel Aviv University. Two of the genes, providing immunity against stem rust disease, were isolated by an international team led by researchers from the UK. The third gene, isolated by researchers at TAU, provides resistance against two different diseases – leaf rust and stripe rust, currently exacerbated due to rising temperatures around the world.

Prof. Amir Sharon, Head of ICCR, says that isolating the genes was enabled by several technological breakthroughs, and that these novel technologies can also be used to isolate genes for other beneficial properties. Transferred into the genome of cultivated wheat, such genes will serve to generate better wheat varieties – featuring higher yields, and resistant to diseases, pests, and harsh environmental conditions. "Just as each of us carries only a small part of his/her grandparents' genes, cultivated wheat contains only a remnant of its ancient ancestors' genetic heritage. Since wheat first originated in our part of the world, wild cereals growing in our region are the progenitors of cultivated wheat, still carrying a rich variety of genetic traits that can be used to develop improved wheat varieties," explains Prof. Sharon.

"Certain traits of wild plants have already been incorporated into cultivated wheat over the years, however this great genetic potential remained mostly untapped, since, until recently, it took more than a decade to isolate a single gene. Today, thanks to several technological breakthroughs, especially genome sequencing and bioinformatics, we can isolate new genes in less than a year. Thus, in the past year alone, three genes providing resistance to various rust diseases were isolated from seeds of wild plants preserved in our gene bank. These genes, implanted in cultivated wheat, can significantly reduce damage from the relevant diseases with no need for pesticides - preventing yield losses while also protecting the environment."

In addition to disease resistance, Prof. Sharon's team is collaborating with researchers worldwide to isolate genes for other beneficial traits. Thus, for example, they work with researchers from Ben-Gurion University who recently isolated pest-resistance genes from wild wheat, and in our own Institute they've identified a new gene in wheat progenitors, that may provide endurance in an arid climate.

Prof. Amir Sharon & Dr. Arava Shatil Cohen in the lab

'Safe Box' to Tackle Climate Change

In addition to new methods for isolating genes, great advances have been made in biotechnology, specifically in technologies for gene transfer and genome editing. These technologies enable the transfer of new genes to crop plants, as well as introduction of changes into existing wheat genes.

"Essentially, the collection serves as a safe box for genes needed to create new, improved varieties of wheat that will give humanity larger crops and meet the challenges of climate change."

ICCR implements these new technologies, offering services of wheat gene transformation and genome editing to researchers in other institutes, as well as commercial companies. "With the support of the Chief Scientist of Israel's Ministry of Agriculture, and the Israeli Center for Genome Editing in Agriculture, we have established a center for wheat transformation and genome editing at ICCR," shares Prof. Sharon. "This is an important milestone, enabling us, for the first time, to perform effective wheat transformation here in Israel,” says Prof. Sharon.

Dr. Arava Shatil Cohen, Head of the wheat transformation unit, adds: “With these technologies we can implant new genes and use genome editing methods to give wheat new properties. We utilize our systems to promote research at ICCR and help companies and researchers from other institutions who wish to use this technology".

Today, ICCR's gene bank includes over 17,000 seeds of 20 different species of wild cereals, collected in Israel over the past 50 years. The collection is unique, both because of its large number of species related to cultivated wheat, and because a large portion of the plants preserved in the gene bank were collected in natural habitats that no longer exist due to rapid urban development in Israel. "Essentially, the collection serves as a safe box for genes needed to create new, improved varieties of wheat that will give humanity larger crops and meet the challenges of climate change," says Prof. Sharon. "The new technologies are the key to the safe box: they enable us to identify and extract the needed genes quickly and incorporate them into cultivated wheat."

The research was led by Dr. Natalia Freund and doctoral students Michael Mor and Ruofan Lee of the Department of Clinical Microbiology and Immunology at the Sackler Faculty of Medicine and of the TAU Center for Combating Pandemics. The study was conducted in collaboration with Dr. Ben Croker of the University of California San Diego. Prof. Ye Xiang of Tsinghua University in Beijing. Prof. Meital Gal-Tanamy and Dr. Moshe Dessau of Bar-Ilan University also took part in the study. The study was published in the Nature journal Communications Biology.

Highly Effective Against Delta and Omicron

The present study is a continuation of a preliminary study conducted in October 2020, at the height of the COVID-19 crisis. At that time, Dr. Freund and her colleagues sequenced all the B immune system cells from the blood of people who had recovered from the original COVID strain in Israel, and isolated nine antibodies that the patients produced. The researchers now found that some of these antibodies are very effective in neutralizing the new coronavirus variants, Delta and Omicron.

“In the previous study, we showed that the various antibodies that are formed in response to infection with the original virus are directed against different sites of the virus," says Dr. Freund. "The most effective antibodies were those that bound to the virus’s ‘spike’ protein, in the same place where the spike binds the cellular receptor ACE2. Of course, we were not the only ones to isolate these antibodies, and the global health system made extensive use of them until the arrival of the different variants of the coronavirus, which in fact rendered most of those antibodies useless."

“In the current study, we proved that two other antibodies, TAU-1109 and TAU-2310, which bind the viral spike protein in a different area from the region where most of the antibodies were concentrated until now (and were therefore less effective in neutralizing the original strain) are actually very effective in neutralizing the Delta and Omicron variants. According to our findings, the effectiveness of the first antibody, TAU-1109, in neutralizing the Omicron strain is 92%, and in neutralizing the Delta strain, 90%. The second antibody, TAU-2310, neutralizes the Omicron variant with an efficacy of 84%, and the Delta variant with an efficacy of 97%.”

Can Serve as Effective Substitute for Boosters

According to Dr. Freund, the surprising effectiveness of these antibodies might be related to the evolution of the virus: “The infectivity of the virus increased with each variant because each time, it changed the amino acid sequence of the part of the spike protein that binds to the ACE2 receptor, thereby increasing its infectivity and at the same time evading the natural antibodies that were created following vaccinations."

"In contrast, the antibodies TAU-1109 and TAU-2310 don’t bind to the ACE2 receptor binding site, but to another region of the spike protein – an area of ​​the viral spike that for some reason does not undergo many mutations – and they are therefore effective in neutralizing more viral variants. These findings emerged as we tested all the known COVID strains to date.”

"In our view, targeted treatment with antibodies and their delivery to the body in high concentrations can serve as an effective substitute for repeated boosters, especially for at-risk populations and those with weakened immune systems." 

The two antibodies, cloned in Dr. Freund’s laboratory at Tel Aviv University, were sent for tests to check their effectiveness against live viruses in laboratory cultures at the University of California San Diego, and against pseudo viruses in the laboratories of the Faculty of Medicine of Bar-Ilan University in the Galilee; the results were identical and equally encouraging in both tests.

Dr. Freund believes that the antibodies can bring about a real revolution in the fight against COVID-19: “We need to look at the COVID-19 pandemic in the context of previous disease outbreaks that humankind has witnessed. People who were vaccinated against smallpox at birth and who today are 50 years old still have antibodies, so they are probably protected, at least partially, from the monkeypox virus that we have recently been hearing about. Unfortunately, this is not the case with the coronavirus. For reasons we still don’t yet fully understand, the level of antibodies against COVID-19 declines significantly after three months, which is why we see people getting infected again and again, even after being vaccinated three times."

"In our view, targeted treatment with antibodies and their delivery to the body in high concentrations can serve as an effective substitute for repeated boosters, especially for at-risk populations and those with weakened immune systems. COVID-19 infection can cause serious illness, and we know that providing antibodies in the first days following infection can stop the spread of the virus. It is therefore possible that by using effective antibody treatment, we will not have to provide booster doses to the entire population every time there is a new variant.”

The study was led by Ph.D. student Rita Perelroizen, under the supervision of Dr. Lior Mayo of the Shmunis School of Biomedicine and Cancer Research and the Sagol School of Neuroscience, in collaboration with Prof. Eytan Ruppin of the National Institutes of Health (NIH) in the USA. The paper was published in the scientific journal Brain and was highlighted with special commentary.

Focusing on Tumor Environment

The researchers explain: "Glioblastoma is an extremely aggressive and invasive brain cancer, for which there exists no known effective treatment. The tumor cells are highly resistant to all known therapies, and, sadly, patient life expectancy has not increased significantly in the last 50 years. Our findings provide a promising basis for the development of effective medications for treating glioblastoma and other types of brain tumors."

"We tackled the challenge of glioblastoma from a new angle," explains Dr. Mayo. "Instead of focusing on the tumor, we focused on its supportive microenvironment, that is, the tissue that surrounds the tumor cells."

"In the absence of astrocytes, the tumor quickly disappeared, and in most cases, there was no relapse - indicating that the astrocytes are essential to tumor progression and survival."

"Specifically, we studied astrocytes – a major class of brain cells that support normal brain function, discovered about 200 years ago and named for their starlike shape. Over the past decade, research from us and others revealed additional astrocyte functions that either alleviate or aggravate various brain diseases. Under the microscope we found that activated astrocytes surrounded glioblastoma tumors. Based on this observation, we set out to investigate the role of astrocytes in glioblastoma tumor growth."

Using a lab model, in which they could eliminate active astrocytes around the tumor, the researchers found that in the presence of astrocytes, the cancer killed all lab models with glioblastoma tumors within 4-5 weeks. Applying a unique method to specifically eradicate the astrocytes near the tumor, they observed a dramatic outcome: the cancer disappeared within days, and all treated lab models survived. Moreover, even after discontinuing treatment, most of the lab models survived.

WATCH: Dr. Lior Mayo explains the dramatic breakthrough in addressing glioblastoma, a deadly brain cancer

Exposing Mechanisms of Double Agents

"In the absence of astrocytes, the tumor quickly disappeared, and in most cases, there was no relapse - indicating that the astrocytes are essential to tumor progression and survival," notes Dr. Mayo. "Therefore, we investigated the underlying mechanisms: How do astrocytes transform from cells that support normal brain activity into cells that support malignant tumor growth?"

To answer these questions, the researchers compared the gene expression of astrocytes isolated from healthy brains and from glioblastoma tumors. They found two main differences – thereby identifying the changes that astrocytes undergo when exposed to glioblastoma:

1. The first change was in the immune response to glioblastoma. Dr. Mayo clarifies, "The tumor mass includes up to 40% immune cells – mostly macrophages recruited from the blood or from the brain itself. Furthermore, astrocytes can send signals that summon immune cells to places in the brain that need protection. In this study, we found that astrocytes continue to fulfill this role in the presence of glioblastoma tumors. However, once the summoned immune cells reach the tumor, the astrocytes 'persuade' them to 'change sides' and support the tumor instead of attacking it. Specifically, we found that the astrocytes change the ability of recruited immune cells to attack the tumor both directly and indirectly – thereby protecting the tumor and facilitating its growth."
2. The second change through which astrocytes support glioblastoma is by modulating their access to energy - via the production and transfer of cholesterol to the tumor cells. The malignant glioblastoma cells divide rapidly, a process that demands a great deal of energy. With access to energy sources in the blood barred by the blood-brain barrier, they must obtain this energy from the cholesterol produced in the brain itself – namely in the astrocytes' 'cholesterol factory', which usually supplies energy to neurons and other brain cells. "We discovered that the astrocytes surrounding the tumor increase the production of cholesterol and supply it to the cancer cells," explains Dr. Mayo. "Therefore, we hypothesized that, because the tumor depends on this cholesterol as its main source of energy, eliminating this supply will starve the tumor."

The Tumor's Vulnerability, a Therapeutic Opportunity

Next, the researchers engineered the astrocytes near the tumor to stop expressing a specific protein that transports cholesterol (ABCA1), thereby preventing them from releasing cholesterol into the tumor. Once again, the results were dramatic: with no access to the cholesterol produced by astrocytes, the tumor essentially 'starved' to death in just a few days. These remarkable results were obtained in both lab models and glioblastoma samples taken from human patients and are consistent with the researchers' starvation hypothesis.

"The challenge now, is to develop drugs that target the specific processes in the astrocytes that promote tumor growth. Alternately, existing drugs may be repurposed to inhibit mechanisms identified in this study."

Dr. Mayo notes: "This work sheds new light on the role of the blood-brain barrier in treating brain diseases. The normal purpose of this barrier is to protect the brain by preventing the passage of substances from the blood to the brain. But in the event of a brain disease, this barrier makes it challenging to deliver medications to the brain and is considered an obstacle to treatment. Our findings suggest that, at least in the specific case of glioblastoma, the blood-brain barrier may be beneficial to future treatments, as it generates a unique vulnerability – the tumor's dependence on brain-produced cholesterol. We think this weakness can translate into a unique therapeutic opportunity."

The project also examined databases from hundreds of human glioblastoma patients and correlated them with the results described above. The researchers explain: "For each patient, we examined the expression levels of genes that either neutralize the immune response or provide the tumor with a cholesterol-based energy supply. We found that patients with low expression of these identified genes lived longer, thus supporting the concept that the genes and processes identified are important to the survival of glioblastoma patients."

"Currently, tools to eliminate the astrocytes surrounding the tumor are available in lab models, but not in humans," notes Dr. Mayo. "The challenge now, is to develop drugs that target the specific processes in the astrocytes that promote tumor growth. Alternately, existing drugs may be repurposed to inhibit mechanisms identified in this study. We think that the conceptual breakthroughs provided by this study will accelerate success in the fight against glioblastoma. We hope that our findings will serve as a basis for the development of effective treatments for this deadly brain cancer and other types of brain tumors," he concludes.