Orchestral manoeuvres: multiple sclerosis faces the music

The conductor walks to the stand and takes his place in front of the orchestra. He raises his baton and, with a dramatic flourish, one hundred individuals come to life. From nowhere, the stillness becomes a beautiful harmony as each member takes their part in a complex symphony.

Consider the workings and structure of the human brain – our most complicated organ – in terms of this orchestra. When it works, it is capable of something more remarkable than the greatest musical compositions in human history, but when it is affected by a condition such as multiple sclerosis (MS), “the brain’s tightly orchestrated biological functions become discordant – the conductor begins to fail at their job and several instruments go out of tune,” said Professor Robin Franklin, Head of Translational Science at the Wellcome Trust-Medical Research Council (MRC) Cambridge Stem Cell Institute and Director of the MS Society Cambridge Centre for Myelin Repair.

His research team and those led by other Stem Cell Institute researchers Drs Thóra Káradóttir, Mark Kotter and Stefano Pluchino are each looking at a different aspect of this errant orchestra. They hope that their collective knowledge will one day help ‘re-tune’ the brains of MS patients to self-repair.

In its simplest terms, MS is a disease in which the immune system turns on itself, destroying the oligodendrocytes that make a protective sheath called myelin, which encases nerve fibres. This halts the transmission of neural messages, and eventually leads to nerve fibre damage, resulting in a progressive loss of movement, speech and vision for the 100,000 people in the UK who have MS.

However, the complexities of treating the disease go beyond simply stopping the destruction of myelin, said Franklin: “The myelin damage causes a build-up of debris, which needs removing, and the environment surrounding the cells needs to be conducive to regenerating the sheath. When we think about repairing the damage, we need to be considering several different biological phenomena at the same time.”

Although there are drugs available for modifying the early stages of MS – including alemtuzumab (Lemtrada), developed in Cambridge – there are no treatments that regenerate the damaged tissue. Moreover, although the disease evolves over decades, with periods of remission followed by relapses, there is no treatment once patients have reached the progressive stage (estimated to be about 50% of current patients).

Oligodendrocytes – the master manufacturers of myelin – are formed by a type of stem cell in the brain called oligodendrocyte progenitor cells (OPCs), and are responsible for re-wrapping, or remyelinating, the bare axons with myelin in response to injuries or diseases. But this regenerative ability decreases with age and MS. “As the disease progresses, the need for intervention that galvanises the natural healing process becomes ever more important,” explained Franklin. “Working with colleagues at the Harvard Stem Cell Institute, we’ve shown that the effects of age on remyelination are reversible, which gives us some confidence that we can use the brain’s own OPCs for myelin regeneration.”

However, to understand how to stimulate the brain’s own repair mechanisms first requires an understanding of how the brain detects injury and initiates repair.

Thóra Káradóttir believes that one way the brain ‘senses’ problems are afoot is through the drop in how fast neural messages are passed across the brain. “The difference in speed between an intact neuron and a damaged one can be like comparing the speed of a cheetah to a tortoise,” she said. “I’m eavesdropping on the information superhighway by attaching electrodes to neurons and OPCs.”

Her findings show that damaged fibres release a molecule called glutamate. “It’s their ‘cry for help’ to OPCs. If it doesn’t happen, or if the OPCs don’t ‘hear’, then repair is reduced.” She is working with Numedicus, a company that specialises in developing secondary uses for existing drugs, to test drugs that she hopes will be able to amplify this signal and increase the repair process.

Meanwhile, Robin Franklin’s team has shown that it’s possible to kick-start OPCs, driving the formation of oligodendrocytes and sheath formation, using a drug that targets retinoid X receptor-gamma, a molecule found within OPCs. The results are positive and clinical trials will shortly commence in collaboration with Dr Alasdair Coles from the Department of Clinical Neurosciences and the MRC Centre for Regenerative Medicine at the University of Edinburgh.

What’s interesting about the rejuvenation of remyelination is that the treatment primarily affected inflammation in demyelinating lesions, and specifically the recruitment of cells called macrophages. These are the body’s ‘big eaters’ – their role is to search out and gobble up rubbish. “We have identified myelin debris as a potent inhibitor of stem cells. Learning how it is being sensed by stem cells enabled us to overcome this inhibition by using drugs such as ibudilast.  A clinical trial to test these effects is currently undergoing preparation,” explained Mark Kotter.

Franklin and Kotter’s work is representative of an interesting turn in MS research within the field. Increasingly, investigators are looking at how the environment around the damage can be improved to help natural remyelination. “It’s a curious paradox,” said Franklin. “MS is caused by the immune system but components of the immune system are also key to its recovery.”

Stefano Pluchino’s team, for instance, has shown that injecting brain stem cells into mice with MS works in a surprising way. Instead of making new oligodendrocytes (or other brain cells), the cells seem to work by re-setting the damaging immune response, creating better conditions for the brain’s own stem cells to replace or restore what has been damaged. He is now developing more-efficient stem cells and new drugs, including nanomedicines, to foster the healing of the damaged brain.

Given the complex landscape of abnormal activities happening in the MS brain, will combination therapies be the way forward? “Certainly,” said Franklin. “Over the next ten years we will see an increased understanding of the fundamental biology in MS, we will identify more targets which may yield effective drugs and we’ll have more-refined strategies for running clinical trials. What makes Cambridge rare is the spectrum of skills here – from understanding the fundamental biology of myelin repair through to clinical trials.”

A discovery could prevent the development of brain tumours in children

Scientists at the IRCM discovered a mechanism that promotes the progression of medulloblastoma, the most common brain tumour found in children. The team, led by Frédéric Charron, PhD, found that a protein known as Sonic Hedgehog induces DNA damage, which causes the cancer to develop. This important breakthrough will be published in the October 13 issue of the prestigious scientific journal Developmental Cell. The editors also selected the article to be featured on the journal’s cover.

Sonic Hedgehog belongs to a family of proteins that gives cells the information needed for the embryo to develop properly. It also plays a significant role in tumorigenesis, the process that transforms normal cells into cancer cells.

“Our team studied a protein called Boc, which is a receptor located on the cell surface that detects Sonic Hedgehog,” explains Lukas Tamayo-Orrego, PhD student in Dr. Charron’s laboratory and co-first author of the study. “We had previously shown that Boc is important for the development of the cerebellum, the part of the brain where medulloblastoma arises, so we decided to further investigate its role.”

“With this study, we found that the presence of Boc is required for Sonic Hedgehog to induce DNA damage,” adds Dr. Charron, Director of the Molecular Biology of Neural Development research unit at the IRCM. “In fact, Boc causes DNA mutations in tumour cells, which promotes the progression of precancerous lesions into advanced medulloblastoma.”

“Our study shows that when Boc is inactivated, the number of tumours is reduced by 66 per cent,” says Frederic Mille, PhD, co-first author of the article and former postdoctoral fellow in Dr. Charron’s research unit. “The inactivation of Boc therefore reduces the development of early medulloblastoma into advanced tumours.”

Medulloblastoma ranks among the leading causes of cancer-related mortality in children. Current treatments include surgery, as well as radiation therapy and chemotherapy. Although the majority of children survive the treatment, radiation therapy damages normal brain cells in infants and toddlers and causes long-term harm.

“As a result, many children who undergo these treatments suffer serious side effects including cognitive impairment and disorders,” states Dr. Charron. “Our results indicate that Boc could potentially be targeted to develop a new therapeutic approach that would stop the growth and progression of medulloblastoma and could reduce the adverse side effects of current treatments.”

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New study finds link between depression and abnormal brain response to visceral pain in patients with IBS

At the 22^nd United European Gastroenterology Week (UEG Week 2014) in Vienna, Austria, Professor Sigrid Elsenbruch from the University of Duisburg-Essen in Germany, will be presenting a new study which suggests that depression, but not anxiety, contributes to the abnormal pain processing observed in IBS in a model that addresses central pain inhibition during placebo analgesia. “Our study has shown that patients with IBS are less able to suppress pain signals in the brain coming from the bowel and that depression plays a role herein,” she says. “This study confirms the complex relationship between the gut and the brain and shows that affective disorders may contribute to the development or maintenance of disturbed pain processing in IBS.”

IBS, anxiety and depression

IBS is the most common functional gastrointestinal disorder with prevalence rates of up to 23% reported. The condition is characterised by recurrent abdominal pain or discomfort, in combination with bloating and altered bowel habits (e.g. diarrhoea and/or constipation). Depression and anxiety frequently co-exist with IBS, with a recent study reporting that 38% of IBS patients had clinically-confirmed depression (compared with 6% of healthy controls) and 32% had anxiety (compared with 13% of healthy controls).

“The fact that so many people with IBS have anxiety and depression has led many to speculate that IBS is primarily a psychological, not a physical, disorder,” says Prof. Elsenbruch. “However, the condition is complex and most likely results from an interplay between psychological and biological factors. In fact, we don’t really know whether anxiety and depression result from having IBS or whether they contribute to the development or maintenance of symptoms. In many patients, both possibilities may be true at the same time.”

The “brain–gut” axis in IBS

There has been significant scientific interest in the role of central nervous system mechanisms along the “brain–gut” axis in IBS. Neuroimaging studies have demonstrated that neural processing of visceral stimuli (i.e. stimuli generated from internal organs such as the intestine) is altered in IBS, with many IBS patients showing lowered pain thresholds. In Prof. Elsenbruch’s latest study, painful rectal distensions were performed using a pressure-controlled barostat system in 17 patients with IBS and 17 sex- and age-matched healthy controls. Neural activation in pain-related brain areas was assessed using functional MRI (fMRI) while subjects received sequential intravenous administrations of saline and what they thought was an anti-spasmolytic drug (but was actually a saline placebo), in order to observe activation patterns during a typical placebo pain response.

The fMRI results in the healthy volunteers demonstrated reduced neural activation in pain-related brain areas during both the saline and sham treatment (placebo), indicating significant central pain inhibition. However, there was no such inhibition in the group of IBS patients, suggesting a deficiency in central pain inhibitory mechanisms in IBS. Interestingly, higher depression (but not anxiety) scores on the Hospital Anxiety and Depression Scale (HADS) were associated with reduced central pain inhibition in this study.

“Our findings suggest that patients with IBS do not process visceral pain signals in the same way as healthy people and are unable to suppress pain signals in the brain and, as a result, experience more pain from the same stimuli,” says Prof. Elsenbruch. “The fact that the presence of depression was associated with altered brain responses suggests that depression may contribute to these abnormal pain processes in IBS patients.”

How curiosity changes the brain to enhance learning

The more curious we are about a topic, the easier it is to learn information about that topic. New research publishing online October 2 in the Cell Press journal Neuron provides insights into what happens in our brains when curiosity is piqued. The findings could help scientists find ways to enhance overall learning and memory in both healthy individuals and those with neurological conditions.

"Our findings potentially have far-reaching implications for the public because they reveal insights into how a form of intrinsic motivation—curiosity—affects memory. These findings suggest ways to enhance learning in the classroom and other settings," says lead author Dr. Matthias Gruber, of University of California at Davis.

For the study, participants rated their curiosity to learn the answers to a series of trivia questions. When they were later presented with a selected trivia question, there was a 14 second delay before the answer was provided, during which time the participants were shown a picture of a neutral, unrelated face. Afterwards, participants performed a surprise recognition memory test for the faces that were presented, followed by a memory test for the answers to the trivia questions. During certain parts of the study, participants had their brains scanned via functional magnetic resonance imaging.

The study revealed three major findings. First, as expected, when people were highly curious to find out the answer to a question, they were better at learning that information. More surprising, however, was that once their curiosity was aroused, they showed better learning of entirely unrelated information (face recognition) that they encountered but were not necessarily curious about. People were also better able to retain the information learned during a curious state across a 24-hour delay. “Curiosity may put the brain in a state that allows it to learn and retain any kind of information, like a vortex that sucks in what you are motivated to learn, and also everything around it,” explains Dr. Gruber.

Second, the investigators found that when curiosity is stimulated, there is increased activity in the brain circuit related to reward. “We showed that intrinsic motivation actually recruits the very same brain areas that are heavily involved in tangible, extrinsic motivation,” says Dr. Gruber. This reward circuit relies on dopamine, a chemical messenger that relays messages between neurons.

Third, the team discovered that when curiosity motivated learning, there was increased activity in the hippocampus, a brain region that is important for forming new memories, as well as increased interactions between the hippocampus and the reward circuit. “So curiosity recruits the reward system, and interactions between the reward system and the hippocampus seem to put the brain in a state in which you are more likely to learn and retain information, even if that information is not of particular interest or importance,” explains principal investigator Dr. Charan Ranganath, also of UC Davis.

The findings could have implications for medicine and beyond. For example, the brain circuits that rely on dopamine tend to decline in function as people get older, or sooner in people with neurological conditions. Understanding the relationship between motivation and memory could therefore stimulate new efforts to improve memory in the healthy elderly and to develop new approaches for treating patients with disorders that affect memory. And in the classroom or workplace, learning what might be considered boring material could be enhanced if teachers or managers are able to harness the power of students’ and workers’ curiosity about something they are naturally motivated to learn.

Altered Activity in the Central Medial Thalamus Precedes Changes in the Neocortex during Transitions into Both Sleep and Propofol Anesthesia

How general anesthetics cause loss of consciousness is unknown. Some evidence points toward effects on the neocortex causing “top-down” inhibition, whereas other findings suggest that these drugs act via subcortical mechanisms, possibly selectively stimulating networks promoting natural sleep. To determine whether some neuronal circuits are affected before others, we used Morlet wavelet analysis to obtain high temporal resolution in the time-varying power spectra of local field potentials recorded simultaneously in discrete brain regions at natural sleep onset and during anesthetic-induced loss of righting reflex in rats. Although we observed changes in the local field potentials that were anesthetic-specific, there were some common changes in high-frequency (20–40 Hz) oscillations (reductions in frequency and increases in power) that could be detected at, or before, sleep onset and anesthetic-induced loss of righting reflex. For propofol and natural sleep, these changes occur first in the thalamus before changes could be detected in the neocortex. With dexmedetomidine, the changes occurred simultaneously in the thalamus and neocortex. In addition, the phase relationships between the low-frequency (1–4 Hz) oscillations in thalamic nuclei and neocortical areas are essentially the same for natural sleep and following dexmedetomidine administration, but a sudden change in phase, attributable to an effect in the central medial thalamus, occurs at the point of dexmedetomidine loss of righting reflex. Our data are consistent with the central medial thalamus acting as a key hub through which general anesthesia and natural sleep are initiated.

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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.”

Lift weights, improve your memory

The Georgia Tech research isn’t the first to find that exercise can improve memory. But the study, which was just published in the journal Acta Psychologica, took a few new approaches. While many existing studies have demonstrated that months of aerobic exercises such as running can improve memory, the current study had participants lift weights just once two days before testing them. The Georgia Tech researchers also had participants study events just before the exercise rather than after workout. They did this because of extensive animal research suggesting that the period after learning (or consolidation) is when the arousal or stress caused by exercise is most likely to benefit memory.

The study began with everyone looking at a series of 90 photos on a computer screen. The images were evenly split between positive (i.e. kids on a waterslide), negative (mutilated bodies) and neutral (clocks) pictures. Participants weren’t asked to try and remember the photos. Everyone then sat at a leg extension resistance exercise machine. Half of them extended and contracted each leg at their personal maximum effort 50 times. The control group simply sat in the chair and allowed the machine and the experimenter to move their legs. Throughout the process, each participant’s blood pressure and heart rate were monitored. Every person also contributed saliva samples so the team could detect levels of neurotransmitter markers linked to stress.

The participants returned to the lab 48 hours later and saw a series of 180 pictures – the 90 originals were mixed in with 90 new photos. The control group recalled about 50 percent of the photos from the first session. Those who exercised remembered about 60 percent.

“Our study indicates that people don’t have to dedicate large amounts of time to give their brain a boost,” said Lisa Weinberg, the Georgia Tech graduate student who led the project.

Although the study used weight exercises, Weinberg notes that resistance activities such as squats or knee bends would likely produce the same results. In other words, exercises that don’t require the person to be in good enough to shape to bike, run or participate in prolonged aerobic exercises.

While all participants remembered the positive and negative images better than the neutral images, this pattern was greatest in the exercise participants, who showed the highest physiological responses. The team expected that result, as existing research on memory indicates that people are more likely to remember emotional experiences especially after acute (short-term) stress.

But why does it work? Existing, non-Georgia Tech human research has linked memory enhancements to acute stress responses, usually from psychological stressors such as public speaking. Other studies have also tied specific hormonal and norepinephrine releases in rodent brains to better memory. Interestingly, the current study found that exercise participants had increased saliva measures of alpha amylase, a marker of central norepinephrine.

“Even without doing expensive fMRI scans, our results give us an idea of what areas of the brain might be supporting these exercise-induced memory benefits,” said Audrey Duarte, an associate professor in the School of Psychology. “The findings are encouraging because they are consistent with rodent literature that pinpoints exactly the parts of the brain that play a role in stress-induced memory benefits caused by exercise.”

The collaborative team of psychology and applied physiology faculty and students plans to expand the study in the future, now that the researchers know resistance exercise can enhance episodic memory in healthy young adults.

“We can now try to determine its applicability to other types of memories and the optimal type and amount of resistance exercise in various populations,” said Minoru Shinohara, an associate professor in the School of Applied Physiology. “This includes older adults and individuals with memory impairment.”

Judgment and decision-making: brain activity indicates there is more than meets the eye

Published today in PLOS ONE, the study is the first in the world to show that it is possible to predict abstract judgments from brain waves, even though people were not conscious of making such judgments. The study also increases our understanding of impulsive behaviours and how to regulate it. 



It found that researchers could predict from participants’ brain activity how exciting they found a particular image to be, and whether a particular image made them think more about the future or the present. This is true even though the brain activity was recorded before participants knew they were going to be asked to make these judgments.


Lead authors Dr Stefan Bode from the Melbourne School of Psychological Sciences and Dr Carsten Murawski from the University of Melbourne Department of Finance said these findings illustrated there was more information encoded in brain activity than previously assumed.


“We have found that brain activity when looking at images can encode judgments such as time reference, even when the viewer is not aware of making such judgments. Moreover, our results suggest that certain images can prompt a person to think about the present or the future,” they said.


The authors said the results contributed to our understanding of impulsive behaviours, especially where those behaviours were caused by ‘prompts’ in the world around us. 



“For instance, consider someone trying to quit gambling who sees a gambling advertisement on TV. Our results suggest that even if this person is trying to ignore the ad, their brain may be unconsciously processing it and making it more likely that they will relapse,” he said. 


The researchers used electroencephalography technology (EEG) to measure the electrical activity of people’s brains while they looked at different pictures. The pictures displayed images of food, social scenes or status symbols like cars and money. 



After the EEG, researchers showed participants the same pictures again and asked questions about each image, such as how exciting they thought the image was or how strongly the image made them think of either the present or the future.

A statistical ‘decoding’ technique was then used to predict the judgments participants made about each of the pictures from the EEG brain activity that was recorded.

Co-author Daniel Bennett said just as certain prompts might cause impulsive behaviour, images could be used to prompt people to be more patient by regulating impulse control.


“Our results suggest that prompting people with images related to the future might cause processing outside awareness that could make it easier to think about the future. In theory, this could make people less impulsive and more likely to make healthy long-term decisions. These are hypotheses we will try to test in the future,” he said. 

The research was done in collaboration with the University of Cologne, Germany.