Researchers Find Promise in New Treatments for GBM

Glioblastoma multiforme (GBM) is one of the most lethal primary brain tumors, with median survival for these patients only slightly over one year. Researchers at Boston University School of Medicine (BUSM), in collaboration with researchers from the City of Hope, are looking toward novel therapeutic strategies for the treatment of GBM in the form of targeted therapies against a unique receptor, the interleukin-13 receptor α chain variant 2 (IL13Rα2).

In a review paper published in the October issue of Neuro-Oncology, the researchers discuss various targeted therapies against IL13Rα2 and early successes of clinical trials with these therapies in the treatment of GBM. The paper also highlights the need for future trials to improve efficacy and toxicity profiles of targeted therapies in this field.

Targeted therapies, which are drugs that interfere with specific molecules involved in cancer growth, have been successfully used in the treatment of many cancers, including breast and blood cancers. Successful targets for therapies are specific to tumor cells and not found on normal cells. Selectively expressed on GBM and absent on surrounding brain tissue, the interleukin-13 receptor α chain variant 2 (IL13Rα2) was identified as a potential target for therapy for GBM two decades ago. IL13Rα2 also plays an important role in the growth of tumors. In normal physiologic conditions, IL-13 binds to the receptor IL13Rα1 and helps regulate immune responses. In cancer cells, IL-13 binds to the receptor IL13Rα2 and, through a series of steps, prevents cancer cells from undergoing normal cell death. Increased expression of IL13Rα2 promotes the progression of GBM.

Since its discovery, IL13Rα2 has provided a target for therapies in GBM. These therapies have ranged from fusion proteins of IL-13 and bacterial toxins, oncolytic viruses, and immunotherapies. A phase I clinical trial and a phase III clinical trial have been completed for a T-cell based immunotherapy and IL-13/ bacterial toxin fusion protein respectively, both with promising outcomes.

“The field of targeted therapies in gliomas holds a lot of promise, and IL13Rα2 is in an optimal position to materialize these promises,” explained corresponding author Sadhak Sengupta, PhD, assistant professor of neurosurgery at BUSM and principal investigator of the Brain Tumor Lab at Roger Williams. “While early trials are encouraging, we need further research to achieve better targeting of the receptor and improved safety profiles of the treatments.”

(Image caption: In mice whose brain tumor cells (in green) couldn’t make galectin-1, the body’s immune system was able to recognize and attack the cells, causing them to die. In this microscope image, the orange areas show where tumor cells had died in just the first three days after the tumor was implanted in the brain. Six days later, the tumor had been eradicated. Credit: University of Michigan Medical School)

Brain tumors fly under the body’s radar like stealth jets

Brain tumors fly under the radar of the body’s defense forces by coating their cells with extra amounts of a specific protein, new research shows.

Like a stealth fighter jet, the coating means the cells evade detection by the early-warning immune system that should detect and kill them. The stealth approach lets the tumors hide until it’s too late for the body to defeat them.

The findings, made in mice and rats, show the key role of a protein called galectin-1 in some of the most dangerous brain tumors, called high grade malignant gliomas. A research team from the University of Michigan Medical School made the discovery and has published it online in the journal Cancer Research.

In a stunning example of scientific serendipity, the team uncovered galectin-1’s role by pursuing a chance finding. They had actually been trying to study how the extra production of galectin-1 by tumor cells affects cancer’s ability to grow and spread in the brain.

Instead, they found that when they blocked cancer cells from making galectin-1, the tumors were eradicated; they did not grow at all. That’s because the “first responders” of the body’s immune system – called natural killer or NK cells – spotted the tumor cells almost immediately and killed them.

But when the tumor cells made their usual amounts of galectin-1, the immune cells couldn’t recognize the cancerous cells as dangerous. That meant that the immune system couldn’t trigger the body’s “second line of defense”, called T cells – until the tumors had grown too large for the body to beat.

Team leader Pedro Lowenstein, M.D., Ph.D, of the U-M Department of Neurosurgery, says the findings open the door to research on the effect of blocking galectin-1 in patients with gliomas.

"This is an incredibly novel and exciting development, and shows that in science we must always be open-minded and go where the science takes us; no matter where we thought we wanted to go," says Lowenstein, whose graduate student Gregory J. Baker is the first author of the paper.

"In this case, we found that over-expression of galectin-1 inhibits the innate immune system, and this allows the tumor to grow enough to evade any possible effective T cell response," he explains. "By the time it’s detected, the battle is already lost."

The NK-evading “stealth” function of the extra-thick coating of galectin-1 came as a surprise, because glioma researchers everywhere had assumed the extra protein had more to do with the insidious ability of gliomas to invade the brain, and to evade the attacks of T cells.

Gliomas, which make up about 80 percent of all malignant brain tumors, include anaplastic oligodendrogliomas, anaplastic astrocytomas, and glioblastoma multiforme. More than 24,000 people in the U.S. are diagnosed with a primary malignant brain tumor each year.

The tiny tendrils of tumor that extend into brain tissue from a glioma are what make them so dangerous. Even when a neurosurgeon removes the bulk of the tumor, small invasive areas escape detection and keep growing, unchecked by the body.

Helping the innate immune system to recognize early stages of cancer growth, and sound the alarm for the body’s defense system to act while the remaining cancer is still small enough for them to kill, could potentially help patients.

While the new discovery opens the door to that kind of approach, much work needs to be done before the mouse-based research could help human patients, says Lowenstein, who is the Richard Schneider Collegiate Professor in Neurosurgery and also holds an appointment in the U-M Department of Cell and Developmental Biology. Galectin-1 may help other types of tumor evade the innate NK cells, too

The new research suggests that in the brain’s unique environment, galectin-1 creates an immunosuppressive effect immediately around tumor cells. The brain cancer cells seem to have evolved the ability to express their galectin-1 genes far more than normal, to allow the tumor to keep growing.

Lowenstein and co-team leader Maria Castro, Ph.D., have long studied the immune system’s interactions with brain cancer, using funding from the National Institutes of Health, and are co-leading a new clinical trial for malignant glioma (NCT01811992), that aims to translate prior research achievements into new trials for patients with brain tumors.

Most brain tumor immune research has focused on triggering the action of the adaptive immune system – whose cells control the process that allows the body to kill invaders from outside or within.

But that system take days or even weeks to reach full force – enough time for incipient tumors to grow too large for immune cells to eliminate solid tumor growth. The new research suggests the importance of enhancing the ability of the innate immune system’s “early warning” sentinels to spot glioma cells as early as possible.

Molecular imbalance linked to brain tumour seizures

Researchers in France may have discovered why some patients with a type of brain tumour have epileptic seizures.

“This small study is interesting and shows that glioma-linked epilepsy may be connected to certain channels found in the membranes of nerve cells” - Dr Robin Grant, Edinburgh Cancer Research UK Centre

Their study, published in Science Translational Medicine, suggests that seizures in patients with glioma may be linked to an imbalance of chloride – which is involved in nerve activity – in certain brain cells.

Whether a patient has seizures is linked to how aggressive their tumour is – with less aggressive cases being more prone to epilepsy as tumour cells slowly progress and alter brain tissue.

It is hoped that further research could explore treatments for glioma-linked epilepsy by controlling chloride levels in the brain.

Glioma develops from specialised brain cells known as ‘glial cells’ that usually help to keep brain nerve cells in place, providing support and protection to ensure correct brain function.

In the latest study, scientists from Sorbonne University studied brain tissue samples from 47 glioma patients and found that nerve tissue infiltrated by glioma cells behaves in similar ways to other forms of epilepsy.

Looking at the patient samples, the team found that a particular type of nerve cell – called a pyramidal cell – released excessive amounts of chloride from inside the cells when exposed to a molecule called GABA, which is also involved in transmitting nerve signals.

GABA was released by other neighbouring nerve cells called ‘interneurons’. And the researchers believe that the release of chloride through specialised molecular channels in the membrane of nerve cells, may be responsible for the seizures experienced in some glioma patients.

Dr Robin Grant, an expert in epilepsy and glioma from the Edinburgh Cancer Research UK Centre, who was not involved in the research, said that the channels may make good drug targets for further investigation, but a finer understanding of the involvement of other processes is still needed.

“This small study is interesting and shows that glioma-linked epilepsy, as with other types of epilepsy, may be connected to certain channels found in the membranes of nerve cells.

“More research will be needed to understand the finer details of this process in glioma and whether these channels, along with other similar channels found in nerve cells, could be good targets for drugs to help control the condition.”

Study shows how brain tumor cells move and damage tissue, points to possible therapy

Researchers at the University of Alabama at Birmingham have shed new light on how cells called gliomas migrate in the brain and cause devastating tumors. The findings, published June 19, 2014 in Nature Communications, show that gliomas — malignant glial cells — disrupt normal neural connections and hijack control of blood vessels.

The study provides insight into the mechanisms of how glioma cells spread throughout the brain as a devastating form of brain cancer, and potentially offers a tantalizing opportunity for therapy.

A hallmark of gliomas is that the cells can migrate away from a central tumor, invading healthy brain tissue. Even if a tumor mass is surgically removed, malignant cells that have migrated are left behind, and can grow into a new tumor.

To grow, glioma cells need access to nutrients in the blood supply, and it is known that gliomas travel along blood vessels within the brain. Now, researchers in the lab of neuroscientist Harald Sontheimer, Ph.D., professor in the UAB Department of Neurobiology, have discovered that, as they move, gliomas dislodge astrocytic endfeet, which play a critical role in regulating blood flow in the brain.

Astrocytes are star-shaped cells in the brain that surround blood vessels and connect to them through projections called endfeet, which extend from the astrocyte and latch onto the vessel wall. The surface of nearly every blood vessel in the brain is covered by endfeet, which regulate the smooth muscle cells on the walls of blood vessels. Through that connection, instructions can be given to the muscle cells to constrict the blood vessel and limit blood flow, or dilate the vessel and increase blood flow.

Sontheimer, director of the UAB Center for Glial Biology in Medicine, says that, as a person performs different neurological functions, blood flow needs to be increased to the areas responsible for that function and correspondingly decreased in other areas to maintain balance.

The arrival of a glioma cell changes all that.

“Glioma cells traveling along blood vessels literally cut the connection of astrocytic endfeet with the vessels and push them out of the way,” said Sontheimer. “By disrupting this important neural connection, adverse cognitive effects could be expected. Additionally, our study showed that gliomas then take control of the blood vessels for their own ends. And those ends are primarily to obtain nutrients from blood so that they can continue to grow and spread.”

Sontheimer’s team says the glioma cells tend to congregate at blood vessel junctions, almost as if camping alongside a stream where it joins a river. The ready supply of nutrients would allow the cell to grow into a larger tumor mass.

By traveling on the outside of a blood vessel, glioma cells are able to access nutrients from the blood stream. As a side effect to that process, they damage the blood brain barrier. The barrier, a layer of endothelial cells, protects the brain by restricting passage of harmful substances from the blood stream into brain tissue.

“We found that, when gliomas push away the astrocytic endfeet, damage occurs to the integrity of the endothelial cells that make up the blood brain barrier,” said Stefanie Robel, Ph.D., a postdoctoral researcher in Sontheimer’s lab and co-first author of the study. “The barrier becomes weakened, and begins to leak. A leak across the barrier can cause severe damage to brain tissue.”

“That leakage appears to be a consequence of glioma cells’ migrating along the blood vessels in their search for nutrients,” said Stacey Watkins, an M.D./Ph.D. student in Sontheimer’s lab and co-first author. “When glioma cells contact the vessels, they have direct access to nutrients.”

But amid the deleterious effects that Sontheimer’s team observed — shearing away the endfeet from their blood vessels, disrupting normal brain activity, hijacking control of blood vessels and causing leaks in the blood brain barrier — he says there may be a silver lining. The idea that gliomas cause the blood brain barrier to become porous and leak might open up a new avenue to kill the malignant cells as they migrate.

Chemotherapy, usually delivered intravenously, is not considered an effective strategy for killing gliomas. Chemotherapeutic agents are very effective in killing cancer cells elsewhere in the body, but the predominant belief is that such drugs will not pass the blood brain barrier and thus will not reach their target.

“Chemotherapy is typically not tried in cases of glioma until after other therapies such as surgery and radiation have been employed,” Sontheimer said. “Our findings, which suggest that gliomas actually weaken the blood brain barrier and cause leakage, might indicate that high-dose, intravenous chemotherapy used early on following a diagnosis of brain cancer would be beneficial.”

The study, funded by the National Institutes of Health and the American Brain Tumor Association, was conducted on a clinically relevant mouse model of human malignant glioma.

Sontheimer says logical next steps would be to further examine the cognitive impact of severing the astrocytic endfeet connection to blood vessels.

Longer Telomeres Linked to Risk of Brain Cancer

New genomic research led by UC San Francisco scientists reveals that two common gene variants that lead to longer telomeres, the caps on chromosome ends thought by many scientists to confer health by protecting cells from aging, also significantly increase the risk of developing the deadly brain cancers known as gliomas.

The genetic variants, in two telomere-related genes known as TERT and TERC, are respectively carried by 51 percent and 72 percent of the general population. Because it is somewhat unusual for such risk-conferring variants to be carried by a majority of people, the researchers propose that in these carriers the overall cellular robustness afforded by longer telomeres trumps the increased risk of high-grade gliomas, which are invariably fatal but relatively rare cancers.

The research was published online in Nature Genetics on June 8, 2014.

“There are clearly high barriers to developing gliomas, perhaps because the brain has special protection,” said Margaret Wrensch, MPH, PhD, the Stanley D. Lewis and Virginia S. Lewis Endowed Chair in Brain Tumor Research at UCSF and senior author of the new study. “It’s not uncommon for people diagnosed with glioma to comment, ‘I’ve never been sick in my life.’”

In a possible example of this genetic balancing act between risks and benefits of telomere length, in one dataset employed in the current study—a massive genomic analysis of telomere length in nearly 40,000 individuals conducted at the University of Leicester in the United Kingdom—shorter telomeres were associated with a significantly increased risk of cardiovascular disease.

“Though longer telomeres might be good for you as a whole person, reducing many health risks and slowing aging, they might also cause some cells to live longer than they’re supposed to, which is one of the hallmarks of cancer,” said lead author Kyle M. Walsh, PhD, assistant professor of neurological surgery and a member of the Program in Cancer Genetics at UCSF’s Helen Diller Family Comprehensive Cancer Center.

In the first phase of the new study, researchers at UCSF and The Mayo Clinic College of Medicine analyzed genome-wide data from 1,644 glioma patients and 7,736 healthy control individuals, including some who took part in The Cancer Genome Atlas project sponsored by the National Cancer Institute and National Human Genome Research Institute. This work confirmed a link between TERT and gliomas that had been made in previous UCSF research, and also identified TERC as a glioma risk factor for the first time.

Since both genes have known roles in regulating the action of telomerase, the enzyme that maintains telomere length, the research team combed the University of Leicester data, and they found that the same TERT and TERC variants associated with glioma risk were also associated with greater telomere length.

UCSF’s Elizabeth Blackburn, PhD, shared the 2009 Nobel Prize in Physiology or Medicine for her pioneering work on telomeres and telomerase, an area of research she began in the mid-1970s. In the ensuing decades, untangling the relationships between telomere length and disease has proved to be complex.

In much research, longer telomeres have been considered a sign of health—for example, Blackburn and others have shown that individuals exposed to chronic stressful experiences have shortened telomeres. But because cancer cells promote their own longevity by maintaining telomere length, drug companies have searched for drugs to specifically target and block telomerase in tumors in the hopes that cancer cells will accumulate genetic damage and die.

Walsh said the relevance of the new research should extend beyond gliomas, since TERT variants have also been implicated in lung, prostate, testicular and breast cancers, and TERC variants in leukemia, colon cancer and multiple myeloma. Variants in both TERT and TERC have been found to increase risk of idiopathic pulmonary fibrosis, a progressive disease of the lungs.

In some of these cases, the disease-associated variants promote longer telomeres, and in others shorter telomeres, suggesting that “both longer and shorter telomere length may be pathogenic, depending on the disease under consideration,” the authors write.

Malignant brain tumours can be transformed into benign forms

Cells of malignant brain tumours deceive our immune system so effectively that it starts working for them. But who lives by the sword, dies by the sword. Researchers from the Nencki Institute in Warsaw show how to deceive brain tumours and change malignant gliomas into benign forms.

The research team of Prof. Bożena Kamińska from the Nencki Institute of Experimental Biology of the Polish Academy of Sciences in Warsaw developed – so far only in animal model – a method of converting malignant gliomas (brain tumours) into benign forms. Since the cells of benign gliomas are subdued and sometimes even eliminated by the host’s immune system, the prospects for survival of sick animals significantly increase. This novel research was funded by the Polish National Science Centre.

The nervous system, including the brain, is inhabited, besides neurons and glial cells, by microglial cells. They support the nervous cells but also have important protective functions, patrolling the surroundings with their extenses and eliminating damaged or unnecessary cells. As macrophages of our immune system they also fight foreign bacteria, viruses and tumorous cells. Unfortunately, sometimes the glia cells themselves become cancerous. This is how brain tumours called gliomas form. However, they are not uniform entity and could differ significantly with respect to their behaviour and degree of malignancy. In benign variants the survival prospects for patients are quite high, while in the case of malignant gliomas few patients are expected to live longer than a year.

In 2007 the group of Prof. Kamińska showed that malignant gliomas can “re-program” the brain immune cells (microglia) to support tumour development instead of fighting it. Similarly the tumour even changed the protective immune cells recruited to the brain from blood and bone marrow (peripheral macrophages). The research to understand how the tumour deceives the host’s immune system and forces the microglial cells to support and foster its growth has taken several years.

The results of other research groups showed that in the case of breast cancer the factor responsible for changing the behaviour of tumour-infiltrating macrophages is the CSF1 protein, controlling the maturation of macrophages. Researchers from the Nencki Institute asked, whether a similar substance is not produces by the cells of the malignant gliomas.

Studies conducted by Prof. Kamińska’s group has shown that gliomas do not produce larger amounts of the CSF1 protein and this protein does not significantly impact tumour development. They were however lucky to discover the production of a different protein from the same family, the CSF2 protein. In benign tumours this protein was present in small amounts, while in malignant gliomas large amounts of it were discovered. Researchers from the Nencki Institute decided to investigate, whether this protein really influences tumour invasiveness. With the help of self-developed tools they turned off the gene responsible for the production of the CSF2 protein in glioma cells.

“We have observed that after turning off a single gene – the gene producing the CSF2 protein – the tumour cells stopped attracting the microglia and were not capable of converting these cells to support the tumour’s development. As a result the immune system started working as expected and the malignant tumour was transformed into a benign form. It did not disappear, but stopped growing”, says a PhD candidate Małgorzata Sielska from the Nencki Institute.

The protein responsible for “re-programming” the anti-tumour response and for high invasiveness of gliomas is present only in cancerous cells and is practically absent from healthy brain. Therefore researchers from the Nencki Institute suspect that when the gene responsible for its production is turned off in the brain, it would affect only the tumour.

Research on taming malignant brain tumours and converting them into benign forms has been conducted on mouse glioma cells growing in the brains of experimental animals, and published in the Journal of Pathology. Presently the group of Prof. Kamińska is checking the effectiveness of this method in the cells of human malignant gliomas. Preliminary results confirm that silencing one gene in human glioma cells growing in mouse brains also stops the growth of the tumour. Developing tools to turn off this gene’s expression, following the creation of appropriate carriers, will in the future open new possibilities for gene therapy in humans.

The findings has helped Nencki researchers develop small molecules (short peptides) which interfere with binding the CSF2 protein (expressed by tumorous cells) to the appropriate receptors on microglial cells. This way the signal coming from tumorous cells gets blocked and the microglia is prevented from “re-programming” itself. The developed molecules, together with relevant genetic tools, are covered by an international patent. Presently researchers work towards starting preclinical and clinical trials of this method.

The proposed solution holds great potential for therapies using small molecules – short peptides or in the case of gene therapy, short RNA silencing gene expression. Will this method really work? This will be confirmed by further experiments and tests. For Nencki researchers it is important that the patented molecules target only one fragment of the signalling pathway which functions between the cells of the malignant tumour and the microglia, thus guaranteeing that no other functions of the organism are affected. Moreover discovery of such an important signalling pathway encourages scientists to search for ways of blocking it in other places, which could be technically more feasible.

“Our research is investigative in nature and above all aims to explain why and how tumours develop. We conducted our research mostly on experimental models, mouse glioma cells or human glioma cells growing in mice. Therefore the road to develop drugs and therapies limiting the invasiveness of gliomas in human is still very long. Luckily we already discovered the molecule that is worth targeting”, sums up Prof. Kamińska.