Posts tagged brain

May 11, 2012

Neurons are arranged in periodic patterns that repeat over large distances in two areas of the cerebral cortex, suggesting that the entire cerebral cortex has a stereotyped organization, reports a team of researchers led by Toshihiko Hosoya of the RIKEN Brain Science Institute. The entire cortex has a stereotypical layered structure with the same cell types arranged in the same way, but how neurons are organized in the other orientation—parallel to the brain’s surface—is poorly understood.

Figure 1: In the mouse visual cortex, neurons expressing id2 mRNA (magenta) are found in regularly repeating clusters. Reproduced from Ref. 1 © 2011 Hisato Maruoka et al., RIKEN Brain Science Institute

Hosoya and his colleagues therefore examined layer V (5) of the mouse cortex, which contains two classes of large pyramidal neurons that look identical but differ in the connections they form. One projects axons straight down to regions beneath the cortex; the other projects to the cortex on the opposite side of the brain.

First, the researchers examined expression of the id2 gene in cells of the visual cortex, because these cells form clusters in that part of the brain. They found that id2 is expressed in nearly all cells that project axons downward, but not in those that cross over. Hosoya and colleagues verified this by visualizing the connections of cells using fluorescent cholera toxin, which binds to cell membranes and travels along the axons.

Further examination of gene expression patterns in tissue slices revealed that the cells are arranged in clusters aligned perpendicular to the brain’s surface, and that the clusters are organized in a regular pattern, with the same basic unit repeating every thirty micrometers (Fig. 1). They also observed the same pattern in layer V of the somatosensory cortex, suggesting that this organization is common to all other areas.

By generating a strain of mutant mice expressing green fluorescent protein in the progenitor cells that produce the cells in layer V during brain development, Hosoya and his colleagues investigated the embryonic origin of these cells. This revealed that each cluster contains neurons that are produced by different progenitor cells.

Finally, the researchers showed that the regular pattern persists in the adult visual cortex, and that neurons in each cluster show the same activity patterns in response to visual stimulation. “Our preliminary data suggest that at least several other areas in the cortex have the same structure,” says Hosoya. “It’s likely that the entire cortex has the same organization, and I expect that the human cortex has the same structure.”

Provided by RIKEN

Source: medicalxpress.com

May 11, 2012

Global network activity in the brain modulates local neural circuitry via calcium signaling in non-neuronal cells called astrocytes (Fig. 1), according to research led by Hajime Hirase of the RIKEN Brain Science Institute. The finding clarifies the link between two important processes in the brain.

Figure 1: Astrocytes are star-shaped cells with numerous fine projections that ensheath synapses in the brain. © 2012 Hajime Hirase

Activity in large-scale brain networks is thought to modulate changes in neuronal connectivity, so-called ‘synaptic plasticity’, in the cerebral cortex. The neurotransmitter acetylcholine regulates global brain activity associated with attention and awareness, and is involved in plasticity.

To investigate how these processes are linked, Hirase and his colleagues simultaneously stimulated the whiskers of mice and the nucleus basalis of Meynert (NBM), a basal forebrain structure containing neurons that synthesize acetylcholine and project widely to the cortex. Using electrodes and an imaging technique called two-photon microscopy, performed through a ‘cranial window’, they monitored the responses of cells in the barrel cortex, which receives inputs from the whiskers.

Recordings from the electrodes showed that repeated co-stimulation of the whiskers and NBM induced plasticity in the barrel cortex. This plasticity depended on two types of receptors—muscarinic acetylcholine receptors (mAChRs) and N-methyl-D-aspartic acid receptors (NMDARs). Two-photon imaging microscopy further revealed that activation of the mAChRs during co-stimulation elevated the concentration of calcium ions within astrocytes of the barrel cortex.

The researchers repeated these experiments in mutant mice lacking the receptor that controls the release of calcium ions in astrocytes. Since co-stimulation of whiskers and NBM did not induce plasticity in the mutants, Hirase and colleagues concluded that calcium signaling in astrocytes acts as a ‘gate’ linking the changes in global brain state induced by acetylcholine to activity in local cortical circuits.

Furthermore, the researchers found that stimulation of the NBM led to an increase in the extracellular concentration of the amino acid D-serine in the normal, but not the mutant, mice. D-serine is secreted by astrocytes and activates NMDARs. Hirase’s team had previously shown that astrocytes are electrically silent in living rodents even in the presence of neural activity2. The new findings showed that the biochemical, as opposed to electrical, activation of astrocytes induces them to release the transmitter that modulates synaptic plasticity in the neuronal circuitry.

“Our study is probably the first to show that calcium signaling in astrocytes is related to neuronal circuit plasticity in living animals,” says Hirase. “We are now studying if this type of calcium signaling occurs in all parts of an astrocyte or is restricted to some parts of the cell.”

Provided by RIKEN

Source: medicalxpress.com

May 11, 2012

Even mild head injuries can cause significant abnormalities in brain function that last for several days, which may explain the neurological symptoms experienced by some individuals who have experienced a head injury associated with sports, accidents or combat, according to a study by Virginia Commonwealth University School of Medicine researchers.

These findings, published in the May issue of the Journal of Neuroscience, advance research in the field of traumatic brain injury (TBI), enabling researchers to better understand what brain structural or functional changes underlie posttraumatic disorders – a question that until now has remained unclear.

Previous research has shown that even a mild case of TBI can result in long-lasting neurological issues that include slowing of cognitive processes, confusion, chronic headache, posttraumatic stress disorder and depression.

The VCU team, led by Kimberle M. Jacobs, Ph.D., associate professor in the Department of Anatomy and Neurobiology, demonstrated for the first time, using sophisticated bioimaging and electrophysiological approaches, that mild injury can cause structural disruption of axons in the brain while also changing the way the neurons fire in areas where they have not been structurally altered. Axons are nerve fibers in the brain responsible for conducting electrical impulses. The team used models of mild traumatic brain injury and followed morphologically identified neurons in live cortical slices.

“These findings should help move the field forward by providing a unique bioimaging and electrophysiological approach to assess the evolving changes evoked by mild TBI and their potential therapeutic modulation,” said co-investigator, John T. Povlishock, Ph.D., professor and chair of the VCU School of Medicine’s Department of Anatomy and Neurobiology and director of the Commonwealth Center for the Study of Brain Injury.

According to Povlishock, additional benefit may also derive from the use of this model system with repetitive injuries to determine if repeated insults exacerbate the observed abnormalities.

Provided by Virginia Commonwealth University

Source: medicalxpress.com

May 11th, 2012

Babies born to women with sensitivity to gluten appear to be at increased risk for certain psychiatric disorders later in life, according to research by scientists at Karolinska Institutet in Sweden and Johns Hopkins Children’s Center in Baltimore.

The team’s findings, published in The American Journal of Psychiatry, add to a growing body of evidence that many “adult” diseases may take root before and shortly after birth.

“Lifestyle and genes are not the only factors that shape disease risk, and factors and exposures before, during and after birth can help pre-program much of our adult health,” said investigator Robert Yolken, M.D., a neuro-virologist at Johns Hopkins Children’s Center. “Our study is an illustrative example suggesting that a dietary sensitivity before birth could be a catalyst in the development of schizophrenia or a similar condition 25 years later.”

Maternal infections and other inflammatory disorders during pregnancy have long been linked to greater risk for schizophrenia in the offspring but, the Swedish and U.S. investigators say, this is the first study that points to maternal food sensitivity as a possible culprit in the development of such disorders. The findings establish a strong link but do not mean that gluten sensitivity will invariably cause schizophrenia, the investigators caution. The research, however, does suggest an intriguing new mechanism that may drive up risk and illuminate possible prevention strategies.

“Our research not only underscores the importance of maternal nutrition during pregnancy and its lifelong effects on the offspring, but also suggests one potential cheap and easy way to reduce risk if we were to find further proof that gluten sensitivity exacerbates or drives up schizophrenia risk,” said study lead investigator Håkan Karlsson, M.D., Ph.D., a neuroscientist at Karolinska Institutet and former neuro-virology fellow at Johns Hopkins.

The team’s findings are based on an examination of 764 birth records and neonatal blood samples of Swedes born between 1975 and 1985. Some 211 of them subsequently developed non-affective psychoses, such as schizophrenia and delusional disorders.

Using stored neonatal blood samples, the investigators measured levels of IgG antibodies to milk and wheat. IgG antibodies are markers of immune system reaction triggered by the presence of certain proteins. Because a mother’s antibodies cross the placenta during pregnancy to confer immunity to the baby, a newborn’s elevated IgG levels are proof of protein sensitivity in the mother.

Children born to mothers with abnormally high levels of antibodies to the wheat protein gluten had nearly twice the risk of developing schizophrenia later in life, compared with children who had normal levels of gluten antibodies. The link persisted even after researchers accounted for other factors known to increase schizophrenia risk, including maternal age, gestational age, mode of delivery and the mother’s immigration status. The risk for psychiatric disorders was not increased among those with elevated levels of antibodies to milk protein.

The researchers say the suspicion that food sensitivity in the mother can affect her child’s risk for psychiatric disorders stems from an observation made in the wake of the World War II by U.S. Army researcher F. Curtis Dohan, M.D. Dohan noted that food scarcity in post-war Europe and wheat-poor diets led to notably fewer hospital admissions for schizophrenia.  The link was merely observational, but it has piqued the curiosity of scientists ever since.

Researchers in the past also have observed that people diagnosed with schizophrenia have disproportionately high rates celiac disease, a rare autoimmune disorder characterized by gluten sensitivity. Although it is a hallmark of the condition, gluten sensitivity alone is not enough to diagnose celiac disease. Other studies have found that some people with schizophrenia have gluten sensitivity without other signs of celiac disease, the researchers note.

Yolken and Karlsson say the team already is conducting follow-up studies to clarify how gluten or sensitivity to it increases schizophrenia risk and whether it does so only in those genetically predisposed.

Source: Neuroscience News

ScienceDaily (May 10, 2012) — Researchers at the Medical Research Council (MRC) Toxicology Unit at the University of Leicester have identified a major pathway leading to brain cell death in mice with neurodegenerative disease. The team was able to block the pathway, preventing brain cell death and increasing survival in the mice.

Scientists have identified a major pathway leading to brain cell death in mice with neurodegenerative disease. The team was able to block the pathway, preventing brain cell death and increasing survival in the mice. (Credit: © pressmaster / Fotolia)

In human neurodegenerative diseases, including Alzheimer’s, Parkinson’s and prion diseases, proteins “mis-fold” in a variety of different ways resulting in the build up of mis-shapen proteins. These form the plaques found in Alzheimer’s and the Lewy bodies found in Parkinson’s disease.

The researchers studied mice with neurodegeneration caused by prion disease. These mouse models currently provide the best animal representation of human neurodegenerative disorders, where it is known that the build up of mis-shapen proteins is linked with brain cell death.

They found that the build up of mis-folded proteins in the brains of these mice activates a natural defense mechanism in cells, which switches off the production of new proteins. This would normally switch back ‘on’ again, but in these mice the continued build-up of mis-shapen protein keeps the switch turned ‘off’. This is the trigger point leading to brain cell death, as those key proteins essential for nerve cell survival are not made.

By injecting a protein that blocks the ‘off’ switch of the pathway, the scientists were able to restore protein production, independently of the build up of mis-shapen proteins,and halt the neurodegeneration. The brain cells were protected, protein levels and synaptic transmission (the way in which brain cells signal to each other) were restored and the mice lived longer, even though only a very small part of their brain had been treated.

Mis-shapen proteins in human neurodegenerative diseases, such as Alzheimer’s and Parkinson’s diseases, also over-activate this fundamental pathway controlling protein synthesis in the brains of patients, which represents a common target underlying these different clinical conditions. The scientists’ results suggest that treatments focused on this pathway could be protective in a range of neurodegenerative disease in which mis-shapen proteins are building up and causing neurons to die.

Professor Giovanna Mallucci, who led the team, said, “What’s exciting is the emergence of a common mechanism of brain cell death, across a range of different neurodegenerative disorders, activated by the different mis-folded proteins in each disease. The fact that, in mice with prion disease, we were able to manipulate this mechanism and protect the brain cells means we may have a way forward in how we treat other disorders. Instead of targeting individual mis-folded proteins in different neurodegenerative diseases, we may be able to target the shared pathways and rescue brain cell degeneration irrespective of the underlying disease.”

Professor Hugh Perry, chair of the MRC’s Neuroscience and Mental Health Board, said, “Neurodegenerative diseases such as Alzheimer’s and Parkinson’s are debilitating and largely untreatable conditions. Alzheimer’s disease and related disorders affect over seven million people in Europe, and this figure is expected to double every 20 years as the population ages across Europe. The MRC believes that research such as this, which looks at the fundamental mechanisms of these devastating diseases, is absolutely vital. Understanding the mechanism that leads to neuronal dysfunction prior to neuronal loss is a critical step in finding ways to arrest disease progression.”

Source: Science Daily

May 10th, 2012

Glial cells pass on metabolites to neurons.

Around 100 billion neurons in the human brain enable us to think, feel and act. They transmit electrical impulses to remote parts of the brain and body via long nerve fibres known as axons. This communication requires enormous amounts of energy, which the neurons are thought to generate from sugar. Axons are closely associated with glial cells which, on the one hand, surround them with an electrically insulating myelin sheath and, on the other hand support their long-term function. Klaus Armin and his research group from the Max Planck Institute of Experimental Medicine in Göttingen have now discovered a possible mechanisms by which these glial cells in the brain can support their associated axons and keep them alive in the long term.

Oligodendrocytes are a group of highly specialised glial cells in the central nervous system. They are responsible for the formation of the fat-rich myelin sheath that surrounds the nerve fibres as an insulating layer. The comparison with the coating on electricity cables is an obvious one; however, myelin can do much more than act as the insulating layer on electricity cables: it increases the transmission speed of the axons and also reduces ongoing energy consumption. The extreme importance of myelin for a functioning nervous system is shown by the diseases that arise from a defective insulating layer, such as multiple sclerosis

Interestingly, the function of the oligodendrocytes goes far beyond the mere provision of myelin. Klaus-Armin Nave and his team at the Max Planck Institute in Göttingen already succeeded in demonstrating years ago that healthy glial cells are also essential for the long-term function and survival of the axons themselves, irrespective of myelination. “The way in which the oligodendrocytes functionally support their associated axons was not clear to us up to now,” says Nave. In a new study, the researchers were able to show that the glial cells are involved in, among other things, the replenishment of energy in the nerve fibres. “They could be described as the petrol stations on the data highway of the axons,” says Nave, explaining the results.

Electron microscope cross-section image of the nerve fibres (axons) of the optic nerve. Axons are surrounded by special glial cells, the oligodendrocytes, wrapping themselves around the axons in several layers. Between the axons, there are extensions of astrocytes, another type of glial cells. © K.-A.Nave/MPI f. Experimental Medicine

But how does the energy refuelling work? Is there a metabolic connection between the oligodendrocytes and axons? To find out, Ursula Fünfschilling generated genetically modified mice: the function of the mitochondria was deliberately disrupted in the oligodendrocytes through the inactivation of the Cox10 gene. This affects the final stages of sugar breakdown taking place in the mitochondria where energy is harnessed – a process known as the respiratory chain. If a link in this chain is missing, in this instance cytochrome oxidase, which is only functional when cells have the enzyme Cox10, the glial cells gradually lose the capacity for cell respiration in their mitochondria. “Without independent breathing, the manipulated glial cells of the nervous systems should have died,” explains the scientist. That is, unless the low level of energy harnessed from the splitting of the glucose to form pyruvate or milk acid, a process known as glycolysis, is sufficient for them.

And this is precisely what the scientists observed in their mice: the animals’ myelin was initially formed in the normal way. The loss of the mitochondrial respiratory chain, which started at this point, did not appear to affect the glial cells in the central nervous system. Even one year later, there were no neurodegenerative changes in the brain to be observed. The scientists assume that in the early weeks of life – a phase characterised by maximum energy requirement – the mutated oligodendrocytes still rely on many intact mitochondria. All of the more mature oligodendrocytes later appear to reduce the mitochondrial respiration and set it to energy generation through increased glycolysis. This has the advantage in healthy glial cells that the metabolic products which arise during the breaking down of glucose can be used as components for myelin synthesis. In addition, the lactic acid that arises in the oligodendrocytes can be given to the axons where it can be used to produce energy with the help of the axon’s own mitochondria.

“The complete loss of the respiratory chain in the deliberately modified oligodendrocytes probably elevates a developmental step that unfolds naturally,” explains Nave. Thus the loss of glial mitochondria does not result in the deterioration of the energy supply to the axons but, conversely, to an oversupply of exploitable lactic acid. The affected nerve pathways themselves have no problem demonstrably in metabolising the lactic acid from oligodendrocytes. Transport proteins ensure the rapid transfer of the lactic acid between the oligodendrocytes and their myelinated axons.

This finding provides a new understanding of the role of oligodendrocytes: in addition to their known significance for myelinisation [aka myelination], they can directly provide the axons with glucose products that can be used as fuel with the help of axonal mitochondria in periods of high activity. This coupling of glial cells could explain, among other things, why in many myelin diseases, for example multiple sclerosis, the affected demyelinised axons often suffer irreversible damage.

Source: Neuroscience News

ScienceDaily (May 10, 2012) — Research into hearing loss after exposure to loud noises could lead to the first drug treatments to prevent the development of tinnitus.

Researchers in the University of Leicester’s Department of Cell Physiology and Pharmacology have identified a cellular mechanism that could underlie the development of tinnitus following exposure to loud noises. The discovery could lead to novel tinnitus treatments, and investigations into potential drugs to prevent tinnitus are currently underway.

Tinnitus is a sensation of phantom sounds, usually ringing or buzzing, heard in the ears when no external noise is present. It commonly develops after exposure to loud noises (acoustic over-exposure), and scientists have speculated that it results from damage to nerve cells connected to the ears.

Although hearing loss and tinnitus affect around ten percent of the population, there are currently no drugs available to treat or prevent tinnitus.

University of Leicester researcher Dr Martine Hamann, who led the study published in the journal Hearing Research, said: “We need to know the implications of acoustic over exposure, not only in terms of hearing loss but also what’s happening in the brain and central nervous system. It’s believed that tinnitus results from changes in excitability in cells in the brain — cells become more reactive, in this case more reactive to an unknown sound.”

Dr Hamann and her team, including PhD student Nadia Pilati, looked at cells in an area of the brain called the dorsal cochlear nucleus — the relay carrying signals from nerve cells in the ear to the parts of the brain that decode and make sense of sounds. Following exposure to loud noises, some of the nerve cells (neurons) in the dorsal cochlear nucleus start to fire erratically, and this uncontrolled activity eventually leads to tinnitus.

Dr Hamann said “We showed that exposure to loud sound triggers hearing loss a few days after the exposure to the sound. It also triggers this uncontrolled activity in the neurons of the dorsal cochlear nucleus. This is all happening very quickly, in a matter of days”

In a key breakthrough in collaboration with GSK who sponsored Dr Pilati’s PhD, the team also discovered the specific cellular mechanism that leads to the neurons’ over-activity. Malfunctions in specific potassium channels that help regulate the nerve cell’s electrical activity mean the neurons cannot return to an equilibrium resting state.

Ordinarily, these cells only fire regularly and therefore regularly return to a rest state. However, if the potassium channels are not working properly, the cells cannot return to a rest state and instead fire continuously in random bursts, creating the sensation of constant noise when none exists.

Dr Hamann explained: “In normal conditions the channel helps to drag down the cellular electrical activity to its resting state and this allows the cell to function with a regular pattern. After exposure to loud sound, the channel is functioning less and therefore the cell is constantly active, being unable to reach its resting state and displaying those irregular bursts.”

Although many researchers have investigated the mechanisms underlying tinnitus, this is the first time that cellular bursting activity has been characterised and linked to specific potassium channels. Identifying the potassium channels involved in the early stages of tinnitus opens up new possibilities for preventing tinnitus with early drug treatments.

Dr Hamann’s team is currently investigating potential drugs that could regulate the damaged cells, preventing their erratic firing and returning them to a resting state. If suitable drug compounds are discovered, they could be given to patients who have been exposed to loud noises to protect them against the onset of tinnitus.

These investigations are still in the preliminary stages, and any drug treatment would still be years away.

Source: Science Daily

ScienceDaily (May 10, 2012) — By comparing the testosterone levels of five-month old pairs of twins, both identical and non-identical, University of Montreal researchers were able to establish that testosterone levels in infancy are not inherited genetically but rather determined by environmental factors.

Angry boy. Testosterone levels in infancy are not inherited genetically but rather determined by environmental factors, new research suggests. (Credit: © crestajohnson / Fotolia)

"Testosterone is a key hormone for the development of male reproductive organs, and it is also associated with behavioural traits, such as sexual behaviour and aggression," said lead author Dr. Richard E. Tremblay of the university’s Research Unit on Children’s Psychosocial Maladjustment. "Our study is the largest to be undertaken with newborns, and our results contrast with the findings gained by scientists working with adolescents and adults, indicating that testosterone levels are inherited."

The findings were presented in an article published inPsychoneuroendocrinology on May 7, 2012.

The researchers took saliva samples from 314 pairs of twins and measured the levels of testosterone. They then compared the similarity in testosterone levels between identical and fraternal twins to determine the contribution of genetic and environmental factors. Results indicated that differences in levels of testosterone were due mainly to environmental factors. “The study was not designed to specifically identify these environmental factors which could include a variety of environmental conditions, such as maternal diet, maternal smoking, breastfeeding and parent-child interactions.”

"Because our study suggests that testosterone levels in infants are determined by the circumstances in which the child develops before and after birth, further studies will be needed to find out exactly what these influencing factors are and to what extent they change from birth to puberty," Tremblay said.

Source: Science Daily

May 10th, 2012

A recently evolved pattern of gene activity in the language and decision-making centers of the human brain is missing in a disorder associated with autism and learning disabilities, a new study by Yale University researchers shows.

“This is the cost of being human,” said Nenad Sestan, associate professor of neurobiology, researcher at Yale’s Kavli Institute for Neuroscience, and senior author of the paper. “The same evolutionary mechanisms that may have gifted our species with amazing cognitive abilities have also made us more susceptible to psychiatric disorders such as autism.”

The findings are reported in the May 11 issue of the journal Cell.

In the Cell paper, Kenneth Kwan, the lead author, and other members of the Sestan laboratory identified the evolutionary changes that led the NOS1 gene to become active specifically in the parts of the developing human brain that form the adult centers for speech and language and decision-making. This pattern of NOS1 activity is controlled by a protein called FMRP and is missing in Fragile X syndrome, a disorder caused by a genetic defect on the X chromosome that disrupts FMRP production. Fragile X syndrome, the leading inherited form of intellectual disability, is also the most common single-gene cause of autism. The loss of NOS1 activity may contribute to some of the many cognitive deficits suffered by those with Fragile X syndrome, such as lower IQ, attention deficits, and speech and language delays, the authors say.

The pattern of NOS1 activity in these brain centers does not occur in the developing mouse brain — suggesting that it is a more recent evolutionary adaptation possibly involved in the wiring of neural circuits important for higher cognitive abilities. The findings of the Cell paper support this hypothesis. The study also provides insights into how genetic deficits in early development, a time when brain circuits are formed, can lead to disorders such as autism, in which symptoms appear after birth.

“This is an example of where the function of genetic changes that likely drove aspects of human brain evolution was disrupted in disease, possibly reverting some of our newly acquired cognitive abilities and thus contributing to a psychiatric outcome,” Kwan said.

Artist representation of early developmental brain cells that when disrupted cause Fragile X syndrome. Adapted from Yale University press release image.

By Bill Hathaway

Source: Neuroscience News

May 10, 2012

(Medical Xpress) — A new mathematical model predicting how nerve fibres make connections during brain development could aid understanding of how some cognitive disorders occur.

The model, constructed by scientists at the Queensland Brain Institute (QBI) and School of Mathematics and Physics at the University of Queensland (UQ), gives new insight into how changing chemical levels in nerve fibres can modify nerve wiring underpinning connections in the brain.

Professor Geoff Goodhill says that while scientists have long known that changing these chemical levels can change where nerve fibres grow, only now are they understanding why this is the case.

“Our mathematical model allows us to predict precisely how these chemical levels control the direction in which nerve fibres grow, during both neural development and regeneration after injury,” he said.

Correct brain wiring is fundamental for normal brain function.

Recent discoveries suggest that wiring problems may underpin a number of nervous system disorders including autism, dyslexia, Down syndrome, Tourette’s syndrome and Parkinson’s disease.

The new model, published in the prestigious cell journal Neurondemonstrates the important role mathematics can play in understanding how the brain develops, and perhaps ultimately preventing such disorders. 

Provided by University of Queensland 

Source: medicalxpress.com