Posts tagged immune system
Articles and news from the latest research reports.
New immune therapy successfully treats brain tumors in mice
Using an artificial protein that stimulates the body’s natural immune system to fight cancer, a research team at Duke Medicine has engineered a lethal weapon that kills brain tumors in mice while sparing other tissue. If it can be shown to work in humans, it would overcome a major obstacle that has hampered the effectiveness of immune-based therapies.
The protein is manufactured with two arms – one that exclusively binds to tumor cells and another that snags the body’s fighter T-cells, spurring an attack on the tumor. In six out of eight mice with brain tumors, the treatment resulted in cures, according to findings published Dec. 17, 2012, in the Proceedings of the National Academy of Sciences.
"This work represents a revival of a somewhat old concept that targeting cancer with tumor-specific antigens may well be the most effective way to treat cancer without toxicity," said senior author John H. Sampson, M.D., PhD, a neurosurgeon at The Preston Robert Tisch Brain Tumor Center at Duke. "But there have been problems with that approach, especially for brain tumors. Our therapeutic agent is exciting, because it acts like Velcro to bind T-cells to tumor cells and induces them to kill without any negative effects on surrounding normal tissues."
Sampson and colleagues focused on the immune approach in brain tumors, which are notoriously difficult to treat. Despite surgery, radiation and chemotherapy, glioblastomas are universally fatal, with a median survival of 15 months.
Immunotherapies, in which the body’s B-cells and T-cells are triggered to attack tumors, have shown promise in treating brain and other cancers, but have been problematic in clinical use. Treatments have been difficult to administer at therapeutic doses, or have spurred side effects in which the immune system also attacks healthy tissue and organs.
Working to overcome those pitfalls, the Duke-led researchers designed a kind of connector - an artificial protein called a bispecific T-cell engager, or BiTE – that tethers the tumor to its killer. Their newly engineered protein includes fractions of two separate antibodies, one that recruits and engages the body’s fighter T-cells and one that expressly homes in on an antigen known as EGFRvIII, which only occurs in cancers.
Once connected via the new bispecific antibody, the T-cells recognize the tumor as an invader, and mount an attack. Normal tissue, which does not carry the tumor antigen, is left unscathed.
Faulty gene linked to condition in infants
Researchers at King’s College London have for the first time identified a defective gene at the root of Vici syndrome, a rare inherited disorder which affects infants from birth, leading to impaired development of the brain, eyes and skin, and progressive failure of the heart, skeletal muscles and the immune system.
Published in the journal Nature Genetics, the study identified a defect in the EPG-5 gene, indicating a genetic cause of the condition which was previously unknown. Researchers at King’s and Guy’s & St Thomas’ NHS Foundation Trust, part of King’s Health Partners, analysed the DNA of 18 infants with Vici syndrome and identified the inactivity of EPG-5 as a major cause of the condition.
Infants born with Vici syndrome inherit two copies of the defective gene, one from each parent. Although there are only around 50 known cases of the disorder across the world, researchers believe the precise incidence is unknown due to lack of awareness of this condition. Dr Heinz Jungbluth, from the Children’s Neuroscience Centre at St Thomas’ Hospital, who led the study along with Professor Mathias Gautel from the Cardiovascular Division at King’s, said: ‘Vici syndrome is likely to be under-diagnosed as there is potential for misdiagnosis, particularly when you consider the many different organ systems affected by Vici and the significant overlap with other, more common disorders.’
The study also highlighted the ‘autophagy’ process and the role of EPG-5 in causing this mechanism to fail. Autophagy is a highly regulated cellular process that removes damaged or unwanted components, which is crucial for the health of all cell types, including those involved in muscles, the immune system and brain development. Abnormalities in this process have been implicated previously in neurodegenerative conditions, but defects causing disorders of normal development such as Vici syndrome have rarely been reported. The researchers suggest that autophagy could play a key role in causing a range of disorders, offering the potential for treatment of other conditions. Dr Jungbluth said: ‘Although the condition is very rare, it is likely that insights provided by research into Vici syndrome will also be transferable to the diagnosis and therapy of neurodegenerative and neurodevelopmental disorders, and a wider range of primary muscle conditions.’
Professor Gautel added: ‘Having identified where this genetic defect occurs we are now able to explore potential interventions. For instance, there is the possibility of enhancing other pathways unaffected by the EPG-5 gene, or by preventing use of the defective pathway in the first place.’
As the defective gene is inherited from both the mother and father, there is also the possibility of screening families with a known history of Vici syndrome. Professor Gautel said: ‘Mothers could be offered preimplantation diagnosis, which involves removing a cell from an embryo when it is around three days old and testing it for genetic disorders, so that an unaffected embryo can be implanted into the mother’s womb, if necessary.’
(Source: kcl.ac.uk)
A direct line through the brain to avoid rotten food
Consuming putrid food can be lethal as it allows bacterial pathogens to enter the digestive system. To detect signs of decay and thus allowing us and other animals to avoid such food poisoning is one of the main tasks of the sense of smell. Behavioural scientists and neurobiologists at the Max Planck Institute for Chemical Ecology in Jena, Germany, have now for the first time decoded the neural mechanisms underlying an escape reflex in fruit flies (Drosophila) activated in order to avoid eating and laying eggs in food infected by toxic microorganisms. A super-sensitive and completely dedicated neural line, from olfactory receptor, via sensory neuron and primary brain neurons, is activated as soon as the tiniest amount of geosmin is in the air. Geosmin is a substance released by bacteria and mold fungi toxic to the fly. This stimulus overrides all other food odour signals, irrespective of how attractive they are on their own. Consequently, geosmin is a full STOP signal that prevents flies from eating and laying eggs in toxic food, similar to when we open the fridge and smell last week’s forgotten dinner.
Combining two genome analysis approaches supports immune system contribution to autism
Researchers using novel approaches and methodologies of identifying genes that contribute to the development of autism have found evidence that disturbances in several immune-system-related pathways contribute to development of autism spectrum disorders. The report published December 4 in the open-access journal PLOS ONE powerfully supports a role for the immune function in autism by integrating analysis of autism-associated DNA sequence variations with that of markers identified in studies of families affected by autism.
"Others have talked about immune function contributions to autism, but in our study immune involvement has been identified through a completely nonbiased approach," says Vishal Saxena, PhD, of the Massachusetts General Hospital (MGH) Department of Neurology, first, corresponding and co-senior author of the PLOS ONE paper. “We let the data tell us what was most important; and most tellingly, viral infection pathways were most important in this immune-related mechanism behind autism.”
Genetic studies of families including individuals with autism have indentified linkages with different locations in the genome. Since traditional interpretation methods implicate the gene closest to a marker site as the cause of a condition, those studies appeared to point to different genes affecting different families. However, Saxena’s team realized that, since autism has typical symptoms and affects the same biological processes, a common molecular physiology must be affecting the different families studied. To search for genetic pathways incorporating these autism-associated sites, they developed a methodology called Linkage-ordered Gene Sets (LoGS) that analyzes all of the genes within a particular distance from marker sites and ranks them according to their distance from the marker.
New research investigates how the common ‘cat parasite’ gets into the brain
The Toxoplasma gondii parasite causes toxoplasmosis. The parasite is common and infects between 30 and 50 per cent of the global population. It also infects animals, especially domestic cats. Human infection is contracted by eating poorly cooked (infected) meat and handling cat feces. Toxoplasmosis first appears with mild flu-like symptoms in adults and otherwise healthy people before entering a chronic and dormant phase, which has previously been regarded as symptom-free. But when the immune system is weakened toxoplasmosis in the brain can be fatal. The fetus can be infected through the mother and because of this risk, pregnant women are recommended to avoid contact with cat litter boxes. Surprisingly, several studies in humans and mice have suggested that even in the dormant phase, the parasite can influence increasing risk taking and infected people show higher incidence of schizophrenia, anxiety and depression, which are broader public health concerns.
In their recent study Fuks et al. showed for the first time how the parasite enters the brain and increases the release of a neurotransmitter called GABA (gaba-Aminobutyric acid), that, amongst other effects, inhibits the sensation of fear and anxiety. In one laboratory experiment, human dendritic cells were infected with toxoplasma. After infection, the cells, which are a key component of the immune defense, began actively releasing GABA), In another experiment on live mice, the team was able to trace the movement of infected dendritic cells in the body after introducing the parasite into the brain, from where it spread and continued to affect the GABA system.
"For toxoplasma to make cells in the immune defense secrete GABA was as surprising as it was unexpected, and is very clever of the parasite," says Antonio Barragan, researcher at the Center for Infectious Medicine at Karolinska Institute and the Swedish Institute for Communicable Disease Control. "It would now be worth studying the links that exist between toxoplasmosis, the GABA systems and major public health threats."
(Image: Maria Sbytova/Shutterstock)
Novel Antibodies for Combating Alzheimer’s and Parkinson’s Disease
Antibodies developed by researchers at Rensselaer Polytechnic Institute are unusually effective at preventing the formation of toxic protein particles linked to Alzheimer’s disease and Parkinson’s disease, as well as Type 2 diabetes, according to a new study.
The onset of these devastating diseases is associated with the inappropriate clumping of proteins into particles that are harmful to cells in the brain (Alzheimer’s disease and Parkinson’s disease) and pancreas (Type 2 diabetes). Antibodies, which are commonly used by the immune system to target foreign invaders such as bacteria and viruses, are promising weapons for preventing the formation of toxic protein particles. A limitation of conventional antibodies, however, is that high concentrations are required to completely inhibit the formation of toxic protein particles in Alzheimer’s, Parkinson’s, and other disorders.
To address this limitation, a team of researchers led by Rensselaer Professor Peter Tessier has developed a new process for creating antibodies that potently inhibit formation of toxic protein particles. Conventional antibodies typically bind to one or two target proteins per antibody. Antibodies created using Tessier’s method, however, bind to 10 proteins per antibody. The increased potency enables the novel antibodies to prevent the formation of toxic protein particles at unusually low concentrations. This is an important step toward creating new therapeutic molecules for preventing diseases such as Alzheimer’s and Parkinson’s.
“It is extremely difficult to get antibodies into the brain. Less than 5 percent of an injection of antibodies into a patient’s blood stream will enter the brain. Therefore, we need to make antibodies as potent as possible so the small fraction that does enter the brain will completely prevent formation of toxic protein particles linked to Alzheimer’s and Parkinson’s disease,” said Tessier, assistant professor in the Howard P. Isermann Department of Chemical and Biological Engineering at Rensselaer. “Our strategy for designing antibody inhibitors exploits the same molecular interactions that cause toxic particle formation, and the resulting antibodies are more potent inhibitors than antibodies generated by the immune system.”
Results of the new study, titled “Rational design of potent domain antibody inhibitors of amyloid fibril assembly,” were published online last week by the journal Proceedings of the National Academy of Sciences (PNAS).
Double Duty: Immune System Regulator Found to Protect Brain from Effects of Stroke
A small molecule known to regulate white blood cells has a surprising second role in protecting brain cells from the deleterious effects of stroke, Johns Hopkins researchers report. The molecule, microRNA-223, affects how cells respond to the temporary loss of blood supply brought on by stroke — and thus the cells’ likelihood of suffering permanent damage.
“We set out to find a small molecule with very specific effects in the brain, one that could be the target of a future stroke treatment,” says Valina Dawson, Ph.D., a professor in the Johns Hopkins University School of Medicine’s Institute for Cell Engineering. “What we found is this molecule involved in immune response, which also acts in complex ways on the brain. This opens up a suite of interesting questions about what microRNA-223 is doing and how, but it also presents a challenge to any therapeutic application.” A report on the discovery is published in the Nov. 13 issue of the Proceedings of the National Academy of Sciences.
RNA is best known as a go-between that shuttles genetic information from DNA and then helps produce proteins based on that information. But, Dawson explains, a decade ago researchers unearthed a completely different class of RNA: small, nimble fragments that regulate protein production. In the case of microRNA, one member of this class, that control comes from the ability to bind to RNA messenger molecules carrying genetic information, and thus prevent them from delivering their messages. “Compared with most ways of shutting genes off, this one is very quick,” Dawson notes.
Reasoning that this quick action, along with other properties, could make microRNAs a good target for therapy development, Dawson and her team searched for microRNAs that regulate brain cells’ response to oxygen deprivation.
To do that, they looked for proteins that increased in number in cells subjected to stress, and then examined how production of these proteins was regulated. For many of them, microRNA-223 played a role, Dawson says.
In most cases, the proteins regulated by microRNA-223 turned out to be involved in detecting and responding to glutamate, a common chemical signal brain cells use to communicate with each other. A stroke or other injury can lead to a dangerous excess of glutamate in the brain, as can a range of diseases, including autism and Alzheimer’s.
Because microRNA-223 is involved in regulating so many different proteins, and because it affects glutamate receptors, which themselves are involved in many different processes, the molecule’s reach turned out to be much broader than expected, says Maged M. Harraz, Ph.D., a research associate at Hopkins who led the study. “Before this experiment, we didn’t appreciate that a single microRNA could regulate so many proteins,” he explains.
This finding suggests that microRNA-223 is unlikely to become a therapeutic target in the near future unless researchers figure out how to avoid unwanted side effects, Dawson says.
(Source: hopkinsmedicine.org)
Trichuris suis ova (porcine whipworm eggs) as treatment for autism
Autism spectrum disorders are characterized by impairments in three core domains: social interaction, communication and restricted or repetitive behaviors. These impairments are frequently accompanied by disruptive behaviors, such as marked irritability, aggression, self-injury, impulsivity and temper tantrums. There is no treatment for the core symptoms, and only one class of medication — atypical antipsychotics — is approved by the U.S. Food and Drug Administration for treating these disruptive behaviors.
There is evidence for activation of pro-inflammatory processes and a positive family history of autoimmune illness in people with autism spectrum disorders. Therefore, a hygiene hypothesis has emerged for both autoimmune illness and autism, suggesting that in urban hygienic environments where there is a paucity of certain parasites that dampen immune activation, there is an increase in autoimmune processes.
People with autism have also been reported to improve when they have fevers. Given that fever is an immune-inflammatory response, Eric Hollander and his colleagues are investigating the use of immunomodulatory treatments such as Trichuris suis ova (TSO), or porcine whipworm eggs, for treating symptoms of autism. TSO has been shown to be effective in autoimmune disorders such as Crohn’s disease, ulcerative colitis and allergic rhinitis. A case series has also shown it to be effective in reducing symptoms of autism.
The researchers plan to complete a 28-week randomized crossover trial of TSO, including 12 weeks of TSO treatment, 12 weeks of placebo and a 4-week washout period. The investigators plan to compare the effects of TSO versus placebo on repetitive behaviors, aggression and irritability, and global functioning. They also plan to explore the relationship among clinical features, immune mechanisms and treatment response.
Work with immunomodulatory treatments such as TSO may be one way to test both the hygiene hypothesis as well as the fever hypothesis, and to develop alternative treatments for core and associated symptoms of autism spectrum disorders.
(Image credit: Wikimedia Commons)
Alzheimer’s Disease in Mice Alleviated Promising Therapeutic Approach for Humans
Pathological changes typical of Alzheimer’s disease were significantly reduced in mice by blockade of an immune system transmitter. A research team from Charité - Universitätsmedizin Berlin and the University of Zurich has just published a new therapeutic approach in fighting Alzheimer’s disease in the current issue of Nature Medicine. This approach promises potential in prevention, as well as in cases where the disease has already set in.
The accumulation of particular abnormal proteins, including amyloid-ß (Aβ) among others, in patients’ brains plays a central role in this disease. Prof. Frank Heppner from the Department of Neuropathology at Charité and his colleague Prof. Burkhard Becher from the Institute for Experimental Immunology at the University of Zurich were able to show that turning off particular cytokines (immune system signal transmitters) reduced the Alzheimer’s typical amyloid-ß deposits in mice with the disease. As a result, the strongest effects were demonstrated after reducing amyloid-ß by approximately 65 percent, when the immune molecule p40 was affected, which is a component of the cytokines interleukin (IL)-12 and -23.
Breakthrough nanoparticle halts multiple sclerosis
In a breakthrough for nanotechnology and multiple sclerosis, a biodegradable nanoparticle turns out to be the perfect vehicle to stealthily deliver an antigen that tricks the immune system into stopping its attack on myelin and halt a model of relapsing remitting multiple sclerosis (MS) in mice, according to new Northwestern Medicine research.
The new nanotechnology also can be applied to a variety of immune-mediated diseases including Type 1 diabetes, food allergies and airway allergies such as asthma.
In MS, the immune system attacks the myelin membrane that insulates nerves cells in the brain, spinal cord and optic nerve. When the insulation is destroyed, electrical signals can’t be effectively conducted, resulting in symptoms that range from mild limb numbness to paralysis or blindness. About 80 percent of MS patients are diagnosed with the relapsing remitting form of the disease.
The Northwestern nanotechnology does not suppress the entire immune system as do current therapies for MS, which make patients more susceptible to everyday infections and higher rates of cancer. Rather, when the nanoparticles are attached to myelin antigens and injected into the mice, the immune system is reset to normal. The immune system stops recognizing myelin as an alien invader and halts its attack on it.
"This is a highly significant breakthrough in translational immunotherapy," said Stephen Miller, a corresponding author of the study and the Judy Gugenheim Research Professor of Microbiology-Immunology at Northwestern University Feinberg School of Medicine. "The beauty of this new technology is it can be used in many immune-related diseases. We simply change the antigen that’s delivered."
"The holy grail is to develop a therapy that is specific to the pathological immune response, in this case the body attacking myelin," Miller added. "Our approach resets the immune system so it no longer attacks myelin but leaves the function of the normal immune system intact."
The nanoparticle, made from an easily produced and already FDA-approved substance, was developed by Lonnie Shea, professor of chemical and biological engineering at Northwestern’s McCormick School of Engineering and Applied Science.
"This is a major breakthrough in nanotechnology, showing you can use it to regulate the immune system," said Shea, also a corresponding author. The paper was published Nov. 18 in the journal Nature Biotechnology.