Mind and body: Scientists identify immune system link to mental illness

Children with high everyday levels of a protein released into the blood in response to infection are at greater risk of developing depression and psychosis in adulthood, according to new research which suggests a role for the immune system in mental illness.

The study, published today in JAMA Psychiatry, indicates that mental illness and chronic physical illness such as coronary heart disease and type 2 diabetes may share common biological mechanisms.

When we are exposed to an infection, for example influenza or a stomach bug, our immune system fights back to control and remove the infection. During this process, immune cells flood the blood stream with proteins such as interleukin-6 (IL-6), a tell-tale marker of infection. However, even when we are healthy, our bodies carry trace levels of these proteins – known as ‘inflammatory markers’ – which rise exponentially in response to infection.

Now, researchers have carried out the first ever longitudinal study – a study that follows the same cohort of people over a long period of time – to examine the link between these markers in childhood and subsequent mental illness.

A team of scientists led by the University of Cambridge studied a sample of 4,500 individuals from the Avon Longitudinal Study of Parents and Children – also known as Children of the 90s – taking blood samples at age 9 and following up at age 18 to see if they had experienced episodes of depression or psychosis. The team divided the individuals into three groups, depending on whether their everyday levels of IL-6 were low, medium or high. They found that those children in the ‘high’ group were nearly two times more likely to have experienced depression or psychosis than those in the ‘low’ group.

Dr Golam Khandaker from the Department of Psychiatry at the University of Cambridge, who led the study, says: “Our immune system acts like a thermostat, turned down low most of the time, but cranked up when we have an infection. In some people, the thermostat is always set slightly higher, behaving as if they have a persistent low level infection – these people appear to be at a higher risk of developing depression and psychosis. It’s too early to say whether this association is causal, and we are carrying out additional studies to examine this association further.”

The research indicates that chronic physical illness such as coronary heart disease and type 2 diabetes may share a common mechanism with mental illness. People with depression and schizophrenia are known to have a much higher risk of developing heart disease and diabetes, and elevated levels of IL-6 have previously been shown to increase the risk of heart disease and type 2 diabetes.

Professor Peter Jones, Head of the Department of Psychiatry and senior author of the study, says: “Inflammation may be a common mechanism that influences both our physical and mental health. It is possible that early life adversity and stress lead to persistent increase in levels of IL-6 and other inflammatory markers in our body, which, in turn, increase the risk of a number of chronic physical and mental illness.”

Indeed, low birth weight, a marker of impaired foetal development, is associated with increased everyday levels of inflammatory markers as well as greater risks of heart disease, diabetes, depression and schizophrenia in adults.

This potential common mechanism could help explain why physical exercise and diet, classic ways of reducing risk of heart disease, for example, are also thought to improve mood and help depression. The group is now planning additional studies to confirm whether inflammation is a common link between chronic physical and mental illness.

The research also hints at interesting ways of potentially treating illnesses such as depression: anti-inflammatory drugs. Treatment with anti-inflammatory agents leads to levels of inflammatory markers falling to normal. Previous research has suggested that anti-inflammatory drugs such as aspirin used in conjunction with antipsychotic treatments may be more effective than just the antipsychotics themselves. A multicentre trial is currently underway, into whether the antibiotic minocycline, used for the treatment of acne, can be used to treat lack of enjoyment, social withdrawal, apathy and other so called negative symptoms in schizophrenia. Minocycline is able to penetrate the ‘blood-brain barrier’, a highly selective permeability barrier which protects the central nervous system from potentially harmful substances circulating in our blood.

The ‘blood-brain barrier’ is also at the centre of a potential puzzle raised by research such as today’s research: how can the immune system have an effect in the brain when many inflammatory markers and antibodies cannot penetrate this barrier? Studies in mice suggest that the answer may lie in the vagus nerve, which connects the brain to the abdomen. When activated by inflammatory markers in the gut, it sends a signal to the brain, where immune cells produce proteins such as IL-6, leading to increased metabolism (and hence decreased levels) of the ‘happiness hormone’ serotonin in the brain. Similarly, the signals trigger an increase in toxic chemicals such as nitric oxide, quinolonic acid, and kynurenic acid, which are bad for the functioning of nerve cells.

(Image caption: A peptide responsible for cell communication in the brain, Vip (green) is reduced in the brains of mice that have little or no Lhx1 (right). Credit: Salk Institute for Biological Studies)

Single gene controls jet lag

Scientists at the Salk Institute for Biological Studies have identified a gene that regulates sleep and wake rhythms.

The discovery of the role of this gene, called Lhx1, provides scientists with a potential therapeutic target to help night-shift workers or jet lagged travelers adjust to time differences more quickly. The results, published in eLife, can point to treatment strategies for sleep problems caused by a variety of disorders.

“It’s possible that the severity of many dementias comes from sleep disturbances,” says Satchidananda Panda, a Salk associate professor who led the research team. “If we can restore normal sleep, we can address half of the problem.”

Every cell in the body has a “clock” – an abundance of proteins that dip or rise rhythmically over approximately 24 hours. The master clock responsible for establishing these cyclic circadian rhythms and keeping all the body’s cells in sync is the suprachiasmatic nucleus (SCN), a small, densely packed region of about 20,000 neurons housed in the brain’s hypothalamus.

More so than in other areas of the brain, the SCN’s neurons are in close and constant communication with one another. This close interaction, combined with exposure to light and darkness through vision circuits, keeps this master clock in sync and allows people to stay on essentially the same schedule every day. The tight coupling of these cells also helps make them collectively resistant to change. Exposure to light resets less than half of the SCN cells, resulting in long periods of jet lag.

In the new study, researchers disrupted the light-dark cycles in mice and compared changes in the expression of thousands of genes in the SCN with other mouse tissues. They identified 213 gene expression changes that were unique to the SCN and narrowed in on 13 of these that coded for molecules that turn on and off other genes. Of those, only one was suppressed in response to light: Lhx1.

“No one had ever imagined that Lhx1 might be so intricately involved in SCN function,” says Shubhroz Gill, a postdoctoral researcher and co-first author of the paper. Lhx1 is known for its role in neural development: it’s so important, that mice without the gene do not survive. But this is the first time it has been identified as a master regulator of light-dark cycle genes.

By recording electrical activity in the SCN of animals with reduced amounts of the Lhx1 protein, the researchers saw that the SCN neurons weren’t in sync with one another, despite appearing rhythmic individually.

“It was all about communication–the neurons were not talking to each other without this molecule,” says Ludovic Mure, a postdoctoral researcher and an author on the paper. A next step in the work will be to understand exactly how Lhx1 affects the expression of genes that creates this synchronicity.

Studying a mouse version of jet lag–an 8-hour shift in their day-night cycle–the scientists found that those with little or no Lhx1 readjusted much faster to the shift than normal mice. This suggests that because these neurons are less in sync with one another, they are more easily able to shift to a new schedule, though it is difficult for them to maintain that schedule, Panda says.

These mice also exhibited reduced activity of certain genes, including one that creates vasoactive intestinal peptide or Vip, a molecule that has important roles in development and as a hormone in the intestine and blood. In the brain, Vip affects cell communication, but nobody had known that Lhx1 regulated it until now, Panda says. Interestingly, the team also found that adding Vip restored cell synchrony in the SCN.

“This approach helped us to close that knowledge gap and show that Vip is a very important protein, at least for SCN,” Panda says. “It can compensate for the loss of Lhx1.”

On the other hand, cutting back on Vip could be another way to treat jet lag. Vip could be an even easier drug target compared with Lhx1 because Vip is secreted from cells rather than inside cells, Panda says. “If we find a drug that will block the Vip receptor or somehow break down Vip, then maybe that will help us reset the clock much faster,” he adds.

The new results take the group a step closer to their goal of creating cell regenerative therapies that restore the SCN and ameliorate sleep problems. The scientists have made their gene expression data available through a searchable web interface at http://scn.salk.edu, giving other researchers a handy way to explore the effect of light and dark in genes in the SCN and other tissues.

Vajrayana Meditation Techniques Associated with Tibetan Buddhism Can Enhance Brain Performance

Contrary to popular belief, not all meditation techniques produce similar effects of body and mind. Indeed, a recent study by researchers from the National University of Singapore (NUS) has demonstrated for the first time that different types of Buddhist meditation – namely the Vajrayana and Theravada styles of meditation - elicit qualitatively different influences on human physiology and behaviour, producing arousal and relaxation responses respectively.

In particular, the NUS research team found that Vajrayana meditation, which is associated with Tibetan Buddhism, can lead to enhancements in cognitive performance.

The study by Associate Professor Maria Kozhevnikov and Dr Ido Amihai from the Department of Psychology at the NUS Faculty of Arts and Social Sciences was first published in the journal PLOS ONE in July 2014.

Vajrayana and Theravada meditation produce different physiological responses

Previous studies had defined meditation as a relaxation response and had attempted to categorise meditation as either involving focused or distributed attentional systems. Neither of these hypotheses received strong empirical support, and most of the studies focused on Theravada meditative practices.

Assoc Prof Kozhevnikov and Dr Amihai examined four different types of meditative practices: two types of Vajrayana meditations (Tibetan Buddhism) practices (Visualisation of self-generation-as-Deity and Rig-pa) and two types of Theravada practices (Shamatha and Vipassana). They collected electrocardiographic (EKG) and electroencephalographic (EEG) responses and also measured behavioural performance on cognitive tasks using a pool of experienced Theravada practitioners from Thailand and Nepal, as well as Vajrayana practitioners from Nepal.

They observed that physiological responses during the Theravada meditation differ significantly from those during the Vajrayana meditation. Theravada meditation produced enhanced parasympathetic activation (relaxation). In contrast, Vajrayana meditation did not show any evidence of parasympathetic activity but showed an activation of the sympathetic system (arousal).

The researchers had also observed an immediate dramatic increase in performance on cognitive tasks following only Vajrayana styles of meditation. They noted that such dramatic boost in attentional capacity is impossible during a state of relaxation. Their results show that Vajrayana and Theravada styles of meditation are based on different neurophysiological mechanisms, which give rise to either an arousal or relaxation response.

Applications of the research findings

The findings from the study showed that Vajrayana meditation can lead to dramatic enhancement in cognitive performance, suggesting that Vajrayana meditation could be especially useful in situations where it is important to perform at one’s best, such as during competition or states of urgency. On the other hand, Theravada styles of meditation are an excellent way to decrease stress, release tension, and promote deep relaxation.

Further research

After seeing that even a single session of Vajrayana meditation can lead to radical enhancements in brain performance, Assoc Prof Kozhevnikov and Dr Amihai will be investigating whether permanent changes could occur after long-term practice. The researchers are also looking at how non-practitioners can benefit from such meditative practices.

Assoc Prof Kozhevnikov said, “Vajrayana meditation typically requires years of practice, so we are also looking into whether it is also possible to acquire the beneficial effects of brain performance by practicing certain essential elements of the meditation. This would provide an effective and practical method for non-practitioners to quickly increase brain performance in times of need.”

(Image caption: Engineers have developed a new microscopy method that uses a fine needle or cannula and an LED light to make 3-D images. They hope this new microscope technology, shown here, can be implanted into the brains of mice to show images of cells. Credit: Ganghun Kim, University of Utah)

3-D Microscope Method to Look Inside Brains

A University of Utah team discovered a method for turning a small, $40 needle into a 3-D microscope capable of taking images up to 70 times smaller than the width of a human hair. This new method not only produces high-quality images comparable to expensive microscopes, but may be implanted into the brains of living mice for imaging at the cellular level.

The study appears in the Aug. 18 issue of the journal Applied Physics Letters.

Designed by Rajesh Menon, an associate professor of electrical and computer engineering, and graduate student Ganghun Kim, the microscope technique works when an LED light is illuminated and guided through a fiberoptic needle or cannula. Returned pictures are reconstructed into 3-D images using algorithms developed by Menon and Kim.

“Unlike miniature microscopes, our approach does not use optics,” Menon says. “It’s primarily computational.”

He says this approach will allow researchers not only to take images far smaller than those taken by current miniature microscopes, but do it for a fraction of the cost.

“We can get approximately 1-micron-resolution images that only $250,000 and higher microscopes are capable of generating,” Menon says. “Miniature microscopes are limited to the few tens of microns.”

Menon hopes to extend the technology in the future so it can see details down to submicron resolutions, compared with the current 1.4 microns. (A micron is a millionth of a meter. A human hair is about 100 microns wide.)

The microscope was originally designed for the lab of Nobel Prize-winning U human genetics professor, Mario R. Capecchi, whose team will use it to observe the brains of living mice to gain insight into how certain proteins in the brain react to various stimuli. Because the microscope can be assembled so inexpensively and easily go into hard-to-reach places, Menon and Kim expect many other uses for the device.

“This microscope will open up new avenues of research,” Menon says. “Its low-cost, small-size, large field-of-view and implantable features will allow researchers to use this in fields ranging from biochemistry to mining.”

Biomarker Could Reveal Why Some Develop Post-Traumatic Stress Disorder

Blood expression levels of genes targeted by the stress hormones called glucocorticoids could be a physical measure, or biomarker, of risk for developing Post-Traumatic Stress Disorder (PTSD), according to a study conducted in rats by researchers at the Icahn School of Medicine at Mount Sinai and published August 11 in Proceedings of the National Academy of Sciences (PNAS). That also makes the steroid hormones’ receptor, the glucocorticoid receptor, a potential target for new drugs.  

Post-Traumatic Stress Disorder (PTSD) is triggered by a terrifying event, either witnessed or experienced. Symptoms may include flashbacks, nightmares and severe anxiety, as well as uncontrollable thoughts about the event. Not everyone who experiences trauma develops PTSD, which is why the study aimed to identify biomarkers that could better measure each person’s vulnerability to the disorder.  

“Our aim was to determine which genes are differentially expressed in relation to PTSD,” said lead investigator Rachel Yehuda, PhD, Professor of Psychiatry and Neuroscience and Director of the Traumatic Stress Studies Division at the Icahn School of Medicine at Mount Sinai. “We found that most of the genes and pathways that are different in PTSD-like animals compared to resilient animals are related to the glucocorticoid receptor, which suggests we might have identified a therapeutic target for treatment of PTSD,” said Dr. Yehuda, who also heads the Mental Health Patient Care Center and PTSD Research Program at the James J. Peters Veterans Affairs Medical Center in the Bronx.

The research team exposed a group of male and female rats to litter soiled by cat urine, a predatory scent that mimics a life-threatening situation. Most PTSD studies until now have used only male rats. Mount Sinai researchers included female rats in this study since women are more vulnerable than men to developing PTSD. The rats were then categorized based on their behavior one week after exposure to the scent. The authors also examined patterns of gene expression in the blood and in stress-responsive brain regions.

After one week of being exposed to soiled cat litter for 10 minutes, vulnerable rats exhibited higher anxiety and hyperarousal, and showed altered glucocorticoid receptor signaling in all tissues compared with resilient rats. Moreover, some rats were treated with a hormone that activates the glucocorticoid receptor called corticosterone one hour after exposure to the cat urine scent. These rats showed lower levels of anxiety and arousal one week later compared with untreated, trauma-exposed rats.

“PTSD is not just a disorder that affects the brain,” said co-investigator Nikolaos Daskalakis, MD, PhD, Associate Research Scientist in the Department of Psychiatry at the Icahn School of Medicine at Mount Sinai. “It involves the entire body, which is why identifying common regulators is key. The glucocorticoid receptor is the one common regulator that consistently stood out.”

(Image: photos.com)

Neurons at work

Film editors play a critical role by helping shape raw footage into a narrative. Part of the challenge is that their work can have a profound impact on the finished product — with just a few cuts in the wrong places, comedy can become tragedy, or vice versa.

A similar process, “alternative splicing,” is at work inside the bodies of billions of creatures — including humans. Just as a film editor can change the story with a few cuts, alternative splicing allows cells to stitch genetic information into different formations, enabling a single gene to produce up to thousands of different proteins.

Harvard scientists say they’ve now been able to observe that process within the nervous system of a living creature.

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