Health-Medical-Fitness-Diet-zk: 2012

duminică, 5 august 2012

New Method Could Enable Reprogramming Of Mammalian Cells

Through the assembly of genetic components into "circuits" that perform logical operations in living cells, synthetic biologists aim to artificially empower cells to solve critical problems in medicine, energy and the environment. To succeed, however, they'll need far more reliable genetic components than the small number of "off-the-shelf" bacterial parts now available.

Now a new method developed by Boston University biomedical engineers Ahmad S. Khalil and James J. Collins -- and collaborators at Harvard Medical School, Massachusetts General Hospital and MIT -- could significantly increase the number of genetic components in synthetic biologists' toolkit and, as a result, the size and complexity of the genetic circuits they can build. The development could dramatically enhance their efforts not only to understand how biological organisms behave and develop, but also to reprogram them for a variety of practical applications.

Described in the August 2 online edition of Cell, the method offers a new paradigm for constructing and analyzing genetic circuits in eukaryotes -- or organisms whose cells contain nuclei, which include everything from yeasts to humans. Instead of constructing these circuits with off-the-shelf parts from bacteria and porting them into eukaryotes, as most synthetic biologists do, Khalil and his collaborators have engineered these circuits using modular, functional parts from the eukaryotes themselves.

With funding from the Howard Hughes Medical Institute, the Defense Advanced Research Projects Agency and other sources, the research team built their synthetic genetic circuit parts from a class of proteins, known as zinc fingers, which can be programmed to bind desired DNA sequences. The modularity of the new parts enables a wide range of functions to be engineered, the construction of much larger and more complex genetic circuits than what's now possible with bacteria-based parts, and ultimately, the development of much more powerful applications.

"Our research may lead to therapeutic applications, such as the dynamic modification and control of genes and genetic networks that are important in human disease," said Khalil. Potential medical applications include stem cell therapeutics for a wide variety of injuries and diseases and in-cell devices and circuits for diagnosing early stages of cancer and other diseases. The new method may also equip groups of cells to perform higher-order computational tasks for processing signals in the environment in sensing applications.

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
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New Computer Method Finds New Uses For Old Drugs

With the cost of putting a single new drug on the pharmacy shelves topping a staggering $1 billion, scientists are reporting development of a way to determine if an already-approved drug might be used to treat a different disease. The technique for repurposing existing medicines could cut drug development costs and make new medicine available to patients faster, they report in ACS' Journal of Medicinal Chemistry.

Sivanesan Dakshanamurthy and colleagues explain that drug companies must limit efforts to market new drugs because the current approach is so expensive, time-consuming and prone to failure. Scientists long have known that drugs already approved for one disease might be effective for others. However, existing methods to identify new uses for old drugs lack accuracy and have other disadvantages. So Dakshanamurthy's team developed a comprehensive new computer method called "Train-Match-Fit-Streamline" (TMFS) that uses 11 factors to quickly pair likely drugs and diseases.

They describe using TMFS to discover evidence that Celebrex, the popular prescription medicine for pain and inflammation, has a chemical signature and architecture suggesting that it may work against a difficult-to-treat form of cancer. Likewise, they found that a medicine for hookworm might be repurposed to cut off the blood supply that enables many forms of cancer to grow and spread. "We anticipate that expanding our TMFS method to the more than 27,000 clinically active agents available worldwide across all targets will be most useful in the repositioning of existing drugs for new therapeutic targets," they said.

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our pharma industry / biotech industry section for the latest news on this subject. The authors acknowledge funding from the National Institutes of Health and the Department of Defense.
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Mindfulness: Psychology Of Possibilities Can Enhance Health, Happiness

First-time mothers who pay attention to their emotional and physical changes during their pregnancy may feel better and have healthier newborns than new mothers who don't, according to research to be presented at American Psychological Association's 120th Annual Convention.

"These findings continue more than 40 years of research that has made clear that whether you are mindless or mindful makes a big difference in every aspect of your health and well-being -- from competence to longevity," Ellen Langer, professor of psychology at Harvard University and a pioneer in researching mindfulness, said in an interview. Langer is a past recipient of APA's Award for Distinguished Contributions to Psychology in the Public Interest.

For Langer's recent study, researchers trained women pregnant with their first child in mindfulness with instructions to notice subtle changes in their feelings and physical sensations each day, she said. When compared with two other groups of first-time pregnant mothers who did not have the mindfulness training, these women reported more well-being and positive feelings and less emotional distress. "They had higher self-esteem and life satisfaction during this period of their pregnancy and up to at least a month after birth," Langer said. "And this also had a positive impact on their deliveries and overall health of the newborns."

Teaching mindfulness through attention to variability may be helpful for many disorders, including asthma, depression and learning disabilities, to name a few, according to Langer.

"Noticing even subtle fluctuations in how you feel can counter mindlessness, or the illusion of stability. We tend to hold things still in our minds, despite the fact that all the while they are changing. If we open up our minds, a world of possibility presents itself," she said.

Author of the popular books "Mindfulness," "The Power of Mindful Learning," "On Becoming an Artist: Reinventing Yourself Through Mindful Creativity," and most recently, "Counterclockwise: Mindful Health and the Power of Possibility," Langer is known for her work on the illusion of control, aging, decision-making and mindfulness theory.

In her lecture, Langer will describe her research to test possibilities rather than find out what is typical. "Psychologists have traditionally studied the 'norm' rather than exceptions that could show that we are capable of far more than we currently realize," she said. Among other research, she will describe her work showing how a change in mindset has resulted in weight loss and improved vision and hearing, and how subtle differences in choice of words can improve health.

Langer first demonstrated the psychology of possibilities in her landmark 1981 "counterclockwise" experiment in which a group of elderly men spent time immersed in a retreat created to reflect daily life in the 1950s and where they were told to speak of the past in the present tense. Men in a comparison group reminisced for the week and were given no instructions regarding verb tense. The experimental group showed greater improvement in vision, strength, joint flexibility, finger length (their arthritis diminished and they could straighten their fingers more) and manual dexterity. On intelligence tests, 63 percent of the experimental group improved their scores, compared to 44 percent of the control group, Langer said.

BBC television recently replicated the study with British celebrities in a program that has been viewed in Great Britain, Australia, India and Hong Kong. It's currently being replicated with local celebrities in Germany and the Netherlands, Langer said.

"It is important for people to realize there can be enhanced possibilities for people of all ages and all walks of life," Langer emphasized. "My research has shown how using a different word, offering a small choice or making a subtle change in the physical environment can improve our health and well-being. Small changes can make large differences, so we should open ourselves to the impossible and embrace a psychology of possibility."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our psychology / psychiatry section for the latest news on this subject. Presentation: "The Psychology of Possibility," Ellen J. Langer, PhD, Session 2254, American Psychological Foundation Arthur W. Staats Lecture on Unifying Psychology, Friday, Aug. 3, 2 p.m. to 2:50 p.m., Room W304E, Level III, Orange County Convention Center.
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Awareness, Detection And Treatment Programs Required To Improve Breast Health Care In Pakistan

Among most women in Pakistan, there is limited awareness of breast cancer occurrence, detection, and screening practices, or the importance of self-breast exams and clinical breast exams, according to a study in the August issue of the Journal of the American College of Radiology. In Pakistan, breast cancer is the most common cancer affecting women and the incidence is rising. It is usually diagnosed in later stages and often at a younger age compared with populations in the West.

"Breast cancer care in limited-resource countries generally suffers because of multiple obstacles, including a lack of recognition of breast health as a public health priority, a shortage of trained health care workers and social or cultural barriers. An improved understanding of existing obstacles in breast cancer care is critical to identify those factors that may be correctable and thereby devise effective interventions for improving early breast cancer detection and treatment in disadvantaged countries," said Sughra Raza, MD, co-author of the study.

Questionnaires were developed to address demographics, financial and educational levels, knowledge regarding breast cancer occurrence and treatment, and religious and cultural beliefs that may affect seeking care for breast disease. Using the questionnaires, one-on-one surveys were administered by community health workers in Karachi to 200 women and 100 general practitioners.

Survey results showed that women's knowledge of breast cancer incidence, diagnosis and treatment was proportionate to educational level, while willingness to address breast health issues and interest in early detection were high regardless of education level. Very few women had ever undergone clinical breast examinations or mammography. Among general practitioners, most understood major risk factors and importance of early detection. However, 20 percent did not believe breast cancer occurs in Pakistan, and 30 percent believed that it is a fatal disease. Female general practitioners were more likely to perform clinical breast examinations than male general practitioners.

"Although there is limited awareness regarding breast cancer occurrence, detection, and screening practices, as well as the importance of self-breast exams and clinical breast exams, the majority of women are very keen to learn more, to participate in their own care and to lower their risk," said Raza.

"Awareness and educational activities, including training female clinical health workers to perform clinical breast exams, will be beneficial, as we begin instituting awareness, detection and treatment programs in the face of a rapidly rising incidence and late-stage detection of breast cancer in Pakistan," said Raza.

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
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Improved Diagnosis For Essential Tremor

Researchers at the University of Montreal and its affiliated CHU Sainte-Justine and CHUM hospitals have linked some cases of Essential Tremor (ET) to a specific genetic problem. ET is the most common movement disorder, becoming increasingly frequent with increasing age, which is characterized by an involuntary shaking movement (tremor) that occurs with motion, particularly when doing precise fine movement. The researchers published their findings tomorrow in The American Journal of Human Genetics.

Exactly why this shaking occurs has remained unknown, despite the work of many clinicians and researchers for decades. While it is known that there is a problem with the parts of the brain that control certain muscles, it has been a challenging endeavor to identify what exactly is malfunctioning in the nervous system of affected individuals. Despite strong evidence that the disease has a genetic basis and years of research effort, no actual genetic link had been identified until today.

Scientists already knew that mutations in a gene called FUS (Fused in Sarcoma) cause amyotrophic lateral sclerosis (ALS), a disease of the nerve cells in the brain and spinal cord that control voluntary muscle movement. The ET research team was successful in identifying mutations that cause ET in this gene, and they also proved that the disease mechanisms for ET and ALS FUS mutations are different. "When I started my post-doctoral work in the Rouleau laboratory, I felt compelled to study essential tremor. I saw a great opportunity to identify the first ET gene considering the plethora of families collected for study in the laboratory, and the availability of new sequencing technologies that has revolutionized gene discovery efforts," said lead author Dr. Nancy Merner. "As a proof of principle study, we chose one family to sequence and took a simple approach to overcome particular clinical barriers that have hindered previous gene discovery attempts."

The other members of the research team share her clinical focus. "This discovery has provided the world with the first insight toward the disease mechanism of essential tremor, which is crucial for disease management, particularly for future drug developments. It also presents a logical approach that can be used for additional ET gene discoveries, which we are currently pursuing" said Dr. Guy Rouleau. "There is currently a lack of consensus on the diagnostic criteria of ET thus a genetic diagnosis can be beneficial, especially for familial cases. Transitioning to a genetic diagnosis would cut down on ET misdiagnosis," added Dr. Patrick Dion who is another key researcher on this project. Misdiagnosis occurs in 37-50% of individual cases.

To affected individuals, the tremors are generally annoying and embarrassing, and can interfere with everyday tasks such as working, writing, eating, or drinking, since tremors affecting the hands are the most common and affected individuals can have trouble holding or using small objects. "Our overall goal in this endeavor is to improve the quality of life of affected individuals," said Dr. Merner. "The road is now paved for improvement."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our neurology / neuroscience section for the latest news on this subject. The identification of FUS was performed in the Rouleau laboratory and supported by the Chaire Jeanne-et-J.-Louis-Lévesque en Génétique des Maladies du Cerveau de l'Université de Montréal. The Canadian Institutes of Health Research has also funded the pursuit for additional ET genes.
About the study:
"Exome sequencing identifies FUS mutations as a cause of essential tremor." Authors: Nancy D. Merner, Simon L. Girard, Hélène Catoire, Cynthia V. Bourassa, Veronique V. Belzil, Jean-Baptiste Rivière, Pascale Hince, Annie Levert, Alexandre Dionne-Laporte, Dan Spiegelman, Anne Noreau, Sabrina Diab, Anna Szuto, Hélène Fournier, John Raelson, Majid Belouchi, Michel Panisset, Patrick Cossette, Nicolas Dupré, Geneviève Bernard, Sylvain Chouinard, Patrick A. Dion, and Guy. A Rouleau
About the researchers:
Dr. Guy Rouleau, M.D., PhD, Professor, Faculty of Medicine, Université de Montréal, Director of the CHU Ste-Justine Research Centre, Investigator at the Research Centre of the Centre hospitalier de l'Université de Montréal.
Dr. Nancy Merner, Ph.D., post-doctoral fellow, Faculty of Medicine, Université de Montréal
Dr. Patrick Dion, Ph.D., Research associate, Faculty of Medicine, Université de Montréal
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Alzheimer's Found To Be More Aggressive Among Younger Elderly But Slows In Advanced Age

The greatest risk factor for Alzheimer's disease (AD) is advancing age. By age 85, the likelihood of developing the dreaded neurological disorder is roughly 50 percent. But researchers at the University of California, San Diego School of Medicine say AD hits hardest among the "younger elderly" - people in their 60s and 70s - who show faster rates of brain tissue loss and cognitive decline than AD patients 80 years and older.

The findings, reported online in the journal PLOS One, have profound implications for both diagnosing AD - which currently afflicts an estimated 5.6 million Americans, a number projected to triple by 2050 - and efforts to find new treatments. There is no cure for AD and existing therapies do not slow or stop disease progression.

"One of the key features for the clinical determination of AD is its relentless progressive course," said Dominic Holland, PhD, a researcher at the Department of Neurosciences at UC San Diego and the study's first author. "Patients typically show marked deterioration year after year. If older patients are not showing the same deterioration from one year to the next, doctors may be hesitant to diagnose AD, and thus these patients may not receive appropriate care, which can be very important for their quality of life."

Holland and colleagues used imaging and biomarker data from participants in the Alzheimer's Disease Neuroimaging Initiative, a multi-institution effort coordinated at UC San Diego. They examined 723 people, ages 65 to 90 years, who were categorized as either cognitively normal, with mild cognitive impairment (an intermediate stage between normal, age-related cognitive decline and dementia) or suffering from full-blown AD.

"We found that younger elderly show higher rates of cognitive decline and faster rates of tissue loss in brain regions that are vulnerable during the early stages of AD," said Holland. "Additionally cerebrospinal fluid biomarker levels indicate a greater disease burden in younger than in older individuals."

Holland said it's not clear why AD is more aggressive among younger elderly.

"It may be that patients who show onset of dementia at an older age, and are declining slowly, have been declining at that rate for a long time," said co-author Linda McEvoy, PhD, associate professor of radiology. "But because of cognitive reserve or other still-unknown factors that provide 'resistance' against brain damage, clinical symptoms do not manifest till later age."

Another possibility, according to Holland, is that older patients may be suffering from mixed dementia - a combination of AD pathology and other neurological conditions. These patients might withstand the effects of AD until other adverse factors, such as brain lesions caused by cerebrovascular disease, take hold. At the moment, AD can only be diagnosed definitively by an autopsy. "So we do not yet know the underlying neuropathology of participants in this study," Holland said.

Clinical trials to find new treatments for AD may be impacted by the differing rates, researchers said. "Our results show that if clinical trials of candidate therapies predominately enroll older elderly, who show slower rates of change over time, the ability of a therapy to successfully slow disease progression may not be recognized, leading to failure of the clinical trial," said Holland. "Thus, it's critical to take into account age as a factor when enrolling subjects for AD clinical trials."

The obvious downside of the findings is that younger patients with AD lose more of their productive years to the disease, Holland noted. "The good news in all of this is that our results indicate those who survive into the later years before showing symptoms of AD will experience a less aggressive form of the disease."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our alzheimer's / dementia section for the latest news on this subject. Co-authors are Rahul S. Desikan, Department of Radiology, UCSD and Anders M. Dale, Departments of Neurosciences and Radiology, UCSD.
Funding for this research came, in part, from the National Institutes of Health (grants R01AG031224, R01AG22381, U54NS056883, P50NS22343 and P50MH08755); the National Institute on Aging (grant K01AG029218) and the National Institute of Biomedical Imaging and Bioengineering (grant T32EB005970).
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Critical Tumor Suppressor Identified For Cancer

Scientists from the Florida campus of The Scripps Research Institute have identified a protein that impairs the development and maintenance of lymphoma (cancer of the lymph nodes), but is repressed during the initial stages of the disease, allowing for rapid tumor growth.

While the study, published in the journal Cell, largely focuses on the role of this new tumor suppressor in lymphoma induced by Myc oncoproteins (the cancer-promoting products of Myc oncogenes), the authors show this circuit is apparently operational in all human tumors with MYC involvement, which is more than half of all human tumor types.

"This opens a new therapeutic avenue to exploit for cancers with Myc involvement - including relapsed metastatic tumors and refractory tumors, those that have not responded to treatment," said John Cleveland, a Scripps Research professor and chair of the Department of Cancer Biology, who led the study.

The Myc family of oncoproteins (c-Myc, N-Myc, and L-Myc) regulate critical pathways that contribute to tumors; c-Myc expression, which is activated in human Burkitt lymphoma, is sufficient to induce the growth of several tumor types in animal models.

In the new study, the scientists focused on precancerous and malignant Myc-expressing B cells, part of the immune system affected in human lymphoma. Using transgenic animal models, Cleveland and his team, led by the efforts of senior postdoctoral fellow Robert Rounbehler, showed that Myc-directed repression of a protein called tristetraprolin (TTP/ZFP36) was important for both the development and maintenance of cancer. The suppression of TTP is a hallmark of human cancers with MYC involvement, Cleveland noted.

The scientists' results showed that overriding this pathway by forced expression of TTP more than doubled the lifespan of Myc transgenic mice. Strikingly, Rounbehler discovered that re-introduction of TTP into Myc-driven lymphoma totally disabled these tumors, indicating an important therapeutic target.

The authors showed that Myc regulates hundreds of genes that contain adenylate-uridylate-rich elements (AU-rich elements), which play an important role in RNA stability and are found in many messenger RNAs (mRNAs) that code for oncogenes, nuclear transcription factors, and cytokines. AU-rich elements direct the mRNA for degradation; they are thought to be vital for controlling expression during cell growth.

"Myc regulates the expression of select AU-binding proteins to control the destruction of certain mRNAs," Cleveland said. "Also, our study strongly suggests that other AU-binding proteins may also, in fact, function as tumor suppressors in other cancers."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our lymphoma / leukemia / myeloma section for the latest news on this subject. The first author of the study, "Tristetraprolin is a Tumor Suppressor That Impairs Myc-Induced Lymphoma and Abolishes the Malignant State," is Robert J. Rounbehler of Scripps Research. Other authors include Mohammad Fallahi, Chunying Yang, Meredith A. Steeves, Weimin Li, Joanne R. Doherty, and Franz X. Schaub of Scripps Research; Sandhya Sanduja and Dan A. Dixon of the University of South Carolina; and Perry J. Blackshear of the National Institute of Environmental Health Sciences.
The study was supported by the National Institutes of Health (grant numbers DK44158, CA167093, F32-CA115075, and CA134609), ThinkPink Kids Foundation, the State of Florida, the National City Charitable Contributions Committee, the Glenn W. Bailey Postdoctoral Fellowship, and the PGA National Women’s Cancer Awareness Days.
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Paralysis In Mice With Multiple Sclerosis Reversed By Alzheimer's Molecule

A molecule widely assailed as the chief culprit in Alzheimer's disease unexpectedly reverses paralysis and inflammation in several distinct animal models of a different disorder - multiple sclerosis, Stanford University School of Medicine researchers have found.

This surprising discovery, which was reported in a study published online as the cover feature in Science Translational Medicine, comes on the heels of the recent failure of a large-scale clinical trial aimed at slowing the progression of Alzheimer's disease by attempting to clear the much-maligned molecule, known as A-beta, from Alzheimer's patients' bloodstreams. While the findings are not necessarily applicable to the study of A-beta's role in the pathology of that disease, they may point to promising new avenues of treatment for multiple sclerosis.

The short protein snippet, or peptide, called A-beta (or beta-amyloid) is quite possibly the single most despised substance in all of brain research. It comes mainly in two versions differing slightly in their length and biochemical properties. A-beta is the chief component of the amyloid plaques that accumulate in the brains of Alzheimer's patients and serve as an identifying hallmark of the neurodegenerative disorder.

A-beta deposits also build up during the normal aging process and after brain injury. Concentrations of the peptide, along with those of the precursor protein from which it is carved, are found in multiple-sclerosis lesions as well, said Lawrence Steinman, MD, the new study's senior author. In a lab dish, A-beta is injurious to many types of cells. And when it is administered directly to the brain, A-beta is highly inflammatory.

Yet little is known about the physiological role A-beta actually plays in Alzheimer's - or in MS, said Steinman, a professor of neurology and neurological sciences and of pediatrics and a noted multiple-sclerosis researcher. He, first author Jacqueline Grant, PhD, and their colleagues set out to determine that role in the latter disease. (Grant was a graduate student in Steinman's group when the work was done.)

Multiple sclerosis, an inflammatory autoimmune disease, occurs when immune cells invade the brain and spinal cord and attack the insulating coatings of nerve cells' long, cable-like extensions called axons. Damage to these coatings, composed largely of a fatty substance called myelin, disrupts the transmission of signals that ordinarily travel long distances down axons to junctions with other nerve cells. This signal disruption can cause blindness, loss of muscle control and difficulties with speech, thought and attention.

Previous research by Steinman, who is also the George A. Zimmerman Professor, and others showed that both A-beta and its precursor protein are found in MS lesions. In fact, the presence of these molecules along an axon's myelinated coating is an excellent marker of damage there.

Given the peptide's nefarious reputation, Steinman and his associates figured that A-beta was probably involved in some foul play with respect to MS. To find out, they relied on a mouse model that mimics several features of multiple sclerosis - including the autoimmune attack on myelinated sections of the brain that causes MS.

Steinman had, some years ago, employed just such a mouse model in research that ultimately led to the development of natalizumab (marketed as Tysabri), a highly potent MS drug. That early work proved that dialing down the activation and proliferation of immune cells located outside the central nervous system (which is what natalizumab does) could prevent those cells from infiltrating and damaging nerve cells in the CNS.

Knowing that immunological events outside the brain can have such an effect within it, the Stanford scientists were keen on seeing what would happen when they administered A-beta by injecting it into a mouse's belly, rather than directly to the brain.

"We figured it would make it worse," Steinman said.

Surprisingly, the opposite happened. In mice whose immune systems had been "trained" to attack myelin, which typically results in paralysis, A-beta injections delivered before the onset of symptoms prevented or delayed the onset of paralysis. Even when the injections were given after the onset of symptoms, they significantly lessened the severity of, and in some cases reversed, the mice's paralysis.

Steinman asked Grant to repeat the experiment. She did, and got the same results.

His team then conducted similar experiments using a different mouse model: As before, they primed the mice's immune cells to attack myelin. But rather than test the effects of A-beta administration, the researchers harvested the immune cells about 10 days later, transferred them by injection to another group of mice that did not receive A-beta and then analyzed this latter group's response. The results mirrored those of the first set of experiments, proving that A-beta's moderating influence on the debilitating symptoms of the MS-like syndrome has nothing to do with A-beta's action within the brain itself, but instead is due to its effect on immune cells before they penetrate the brain.

Sophisticated laboratory tests showed that A-beta countered not only visible symptoms such as paralysis, but also the increase in certain inflammatory molecules that characterizes multiple-sclerosis flare-ups. "This is the first time A-beta has been shown to have anti-inflammatory properties," said Steinman.

Inspection of the central nervous systems of the mice with the MS-resembling syndrome showed fewer MS-like lesions in the brains and spinal cords of treated mice than in those not given A-beta. There was also no sign of increased Alzheimer's-like plaques in the A-beta-treated animals. "We weren't giving the mice Alzheimer's disease" by injecting A-beta into their bellies, said Grant.

In addition, using an advanced cell-sorting method called flow cytometry, the investigators showed A-beta's strong effects on the immune system composition outside the brain. The numbers of immune cells called B cells were significantly diminished, while those of two other immune-cell subsets - myeloid cells and memory T-helper cells - increased.

"At this point we wanted to find out what would happen if we tried pushing A-beta levels down instead of up," Grant said. The researchers conducted a different set of experiments, this time in mice that lacked the gene for A-beta's precursor protein, so that they could produce neither the precursor nor A-beta. These mice, when treated with myelin-sensitized immune cells to induce the MS-like state, developed exacerbated symptoms and died faster and more frequently than normal mice who underwent the same regimen.

Lennart Mucke, MD, director of the Gladstone Institute of Neurological Disease in San Francisco and a veteran Alzheimer's researcher, noted that while A-beta's toxicity within the brain has been established beyond reasonable doubt, many substances made in the body can have vastly different functions under different circumstances.

"A-beta is made throughout our bodies all of the time. But even though it's been studied for decades, its normal function remains to be identified," said Mucke, who is familiar with Steinman's study but wasn't involved in it. "Most intriguing, to me, is this peptide's potential role in modulating immune activity outside the brain."

The fact that the protection apparently conferred by A-beta in the mouse model of multiple sclerosis doesn't require its delivery to the brain but, rather, can be attributed to its immune-suppressing effect in the body's peripheral tissues is likewise intriguing, suggested Steinman.

"There probably is a multiple-sclerosis drug in all this somewhere down the line," he said.

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our multiple sclerosis section for the latest news on this subject. Additional Stanford co-authors were associate professor of neurology and neurological sciences Katrin Andreasson, MD; professor of genetics Leonore Herzenberg, DSc; emeritus professor of genetics Leonard Herzenberg, PhD; postdoctoral scholars Eliver Ghosn, PhD, Robert Axtell, PhD, Hedwich Kuipers, PhD, and Katja Herges, MD; and graduate student Nathan Woodling.
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The Immune System Enables HIV-Infected T Cells To Transport The Virus Throughout The Body

A new study has discovered one more way the human immunodeficiency virus (HIV) exploits the immune system. Not only does HIV infect and destroy CD4-positive helper T cells - which normally direct and support the infection-fighting activities of other immune cells - the virus also appears to use those cells to travel through the body and infect other CD4 T cells. The study from Massachusetts General Hospital (MGH) investigators, which will appear in the journal Nature and has received advance online release, is the first to visualize the behavior of HIV-infected human T cells within a lymph node of a live animal, using a recently developed "humanized" mouse model of HIV infection.

"We have found that HIV disseminates in the body of an infected individual by 'hitching a ride' on the T cells it infects," says Thorsten Mempel, MD, PhD, of the MGH Center for Immunology and Inflammatory Diseases, who led the study. "Infected T cells continue doing what they usually do, migrating within and between tissues such as lymph nodes, and in doing so they carry HIV to remote locations that free virus could not reach as easily. There are drugs that can manipulate the migration of T cells that potentially could be used to help control the spread of virus within a patient."

When HIV is introduced into blood or tissues, the virus binds to CD4 molecules on the surface of helper T cells, injecting its contents into cells and setting off a process that leads to the assembly and release of new virus particles. It has long been assumed that these free virus travel by diffusion through tissue fluids to encounter new cells that can be infected. But recent studies have suggested that HIV can also pass directly from cell to cell when structures called virological synapses form during long-lasting interactions between T cells. Since CD4 T cells usually migrate quickly and form only transient contacts with other cells, the current study was designed to examine whether HIV alters the migration of infected T cells, allowing the kind of persistent contact that facilitates the spread of infection.

The team's experiments used the humanized BLT mouse model, which has what is essentially a human immune system and is the only non-primate that can be infected with HIV. After first confirming that human T cells enter and normally migrate within the animals' lymph nodes - known to be important sites of HIV replication - the researchers injected the animals with HIV engineered to express green fluorescent protein (GFP), allowing them to track the movement of infected cells within living animals using a method called intravital microscopy. They first observed that, within two days, infected T cells continued to migrate and were uniformly distributed within lymph nodes but remained in nodes closest to the site of injection.

While the HIV-infected cells actively moved within lymph nodes, they did not move as quickly as comparable but uninfected T cells. In addition, 10 to 20 percent of the HIV-infected T cells formed abnormally long and thin extensions that appeared to trail behind moving cells, often exhibiting branches.

The researchers hypothesized that the HIV envelope protein, which is expressed on the surface of infected T cells before they release new virus particles, might cause infected cells to form tethering contacts with uninfected cells, producing these extensions. A series of experiments verified that the elongated shape of some infected cells requires the presence of the envelope protein and that many of the elongated cells contained multiple nuclei, suggesting they had been formed by the fusion of several cells.

To test the role of T cell migration in HIV infection, the researchers injected another group of BLT mice with HIV and at the same time treated them with an agent that prevents T cells from leaving lymph nodes. Two months later, levels of HIV in the bloodstream and in lymph nodes distant from the site of injection were much lower than in untreated HIV-infected animals, supporting the importance of T cell migration to carry virus throughout the body. Treatment with the migration-suppressing agent, however, did not reduce viral levels in animals with already established HIV infection.

"While our observation of tethering interactions between infected and uninfected CD4-expressing cells suggest that HIV may be transmitted between T cells by direct contact, we will have to clearly show this in future studies and explore how important it is relative to the transmission by free virus," explains Mempel, an assistant professor of Medicine at Harvard Medical School. He adds that the availability of the BLT mouse was instrumental in their ability to carry out this study. "This approach provides a new vantage point to investigate previously unexplored aspects of HIV pathogenesis."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our hiv / aids section for the latest news on this subject. Lead author of the Nature paper is Thomas Murooka, PhD, of the MGH Center for Immunology and Inflammatory Diseases (CIID). Additional co-authors are Maud Deruaz, PhD, Francesco Marangoni, PhD, Vladimir Vrbanac, DVM, Edward Seung, PhD, Andrew Tager, MD, and Andrew Luster, MD, PhD, MGH CIID; and Ulrich von Andrian, Harvard Medical School. The study was supported by grants from the National Institutes of Health and the Ragon Institute of MGH, MIT and Harvard.
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First Genome-Wide Analysis Of Peripheral T-cell Lymphomas Identifies 13 Novel Alterations In This Aggressive Blood Cancer

How Protein Component That Enables Cell Replication Gets Ferried To Chromosome Tips

Stem cells are special. Nestled in muscle and skin, organ and bone, they bide their time over years or decades until called to replace damaged or lost tissue. One secret to their longevity is an enzyme called telomerase, which stills the relentless ticking of the molecular clock that limits the life span of other cells.

This cellular fountain of youth prevents the progressive shortening of the tips of our chromosomes that occurs with each cell division. But the presence of telomerase can be a double-edged sword: The same activity that ensures long life for stem cells can also keep a cancer cell dividing long after its aging neighbors have thrown in the towel. Conversely, a malfunction can prevent stem cells from doing their job and lead to devastating diseases.

Now, for the first time, researchers at the Stanford University School of Medicine have identified how telomerase is recruited to chromosome ends - and figured out a way to block it.

"If telomerase is unable to maintain the ends of the chromosomes, cells will stop multiplying," said professor of medicine Steven Artandi, MD, PhD. "This would be advantageous in cancer cells, but in normal stem cells it can cause severe dysfunction and lead to diseases such as pulmonary fibrosis, aplastic anemia and a genetic condition called dyskeratosis congenita. We want to understand how telomerase works, and to develop therapies for cancer and these other diseases."

Artandi is the senior author of the research, which was published in Cell. He is also a member of the Stanford Cancer Institute. Graduate student Franklin Zhong is the first author of the study.

Telomerase is normally expressed in adult stem cells and immune cells, as well as in cells of the developing embryo. In these cells, the enzyme caps off the ends of newly replicated chromosomes, allowing unfettered cell division. Without telomerase, cells stop dividing or die when the ends - called telomeres - fall below a minimum length. Unfortunately, the enzyme is also active in nearly all cancer cells.

Earlier research in Artandi's lab identified a protein called TCAB1 that brings the telomerase complex (actually a large clump of many proteins) to a processing area in the cell's nucleus called a Cajal body. But no one knew how the complex was then ferried to the ends of telomeres, and research was stymied by the complex's large size, multiple components and relative scarcity.

"This problem has been really intractable," said Artandi. "The enzyme is extremely hard to study. But we've now found that telomerase is recruited to the telomeres through an interaction with a protein called TPP1 that coats the ends of chromosomes." What's more, the researchers have identified the exact region of TPP1 to which telomerase binds - a section called an OB-fold.

"When we mutated this site in TPP1," said Artandi, "we blocked the interaction between the two proteins and prevented telomerase from going to the telomeres. And when we interfered with this interaction in human cancer cells, the telomeres began to shorten." The researchers are now assessing whether the life span of the cancer cells, and their ability to divide unchecked, will also be affected by the treatment.

To confirm their finding, Artandi and his colleagues used cells from patients with pulmonary fibrosis - a debilitating scarring or thickening of lung tissue associated with telomerase mutations. The disease had been troubling to researchers and clinicians, however, because the patients' mutated telomerase seemed to be fully active when tested in the laboratory. Zhong and Artandi found that the disease-associated mutations occurred in the portion of telomerase that interacted with TPP1, and interfered with their binding. As a result the enzyme, although active, couldn't get to where it was needed.

"It was impossible to even begin to understand this mechanism before we knew how these two molecules interact," said Artandi. "But now that we're getting a handle on this, we can begin to think about developing inhibitors - maybe in the form of peptides or small molecules - that can mimic this disruption. This could be very valuable in cancer therapies."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our genetics section for the latest news on this subject. In addition to Zhong and Artandi, other Stanford researchers involved in the work include postdoctoral scholars Luis Batista, PhD, and Adam Freund, PhD; graduate student Matthew Pech; and former graduate student Andrew Venteicher, PhD.
The research was supported by Singapore's Agency for Science, Technology and Research, the California Institute for Regenerative Medicine, the National Science Foundation, the Leukemia and Lymphoma Society, the Glenn Foundation for Medical Research and the National Institutes of Health.
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'Antisense' Compound Rids Muscle Cells Of Toxic RNA: A Promising Step Toward Muscular Dystrophy Treatment

Scientists have reversed symptoms of myotonic muscular dystrophy in mice by eliminating a buildup of toxic RNA in muscle cells. The work, carried out by scientists at the University of Rochester Medical Center, Isis Pharmaceuticals Inc. and Genzyme, is published in Nature.

After experimental antisense compounds were administered to mice twice a week for four weeks, symptoms of the disease were reduced for up to one year - a significant portion of a mouse's lifespan.

The investigators say that while the work is an encouraging step forward against myotonic dystrophy, one of the most common forms of muscular dystrophy, it's too soon to know whether the approach will work in patients. But they are cautiously optimistic, noting that the compound is extremely effective at reversing the disease - whose genetic underpinnings make it particularly vulnerable to an antisense approach - in a mouse model.

"These results give us strong encouragement about the possibility of developing a treatment that could fundamentally alter the disease. It's an important step on a long path," said senior author Charles Thornton, M.D., a neurologist at the University of Rochester Medical Center who has been pursuing new treatments for the disease for more than two decades.

"But, it's too early to know if this treatment will work as well in people as it did in the laboratory. Unfortunately, in biomedical research there are previous examples of compounds that worked in mice but not in people," added Thornton, the Saunders Family Distinguished Professor in Neuromuscular Research.

About 35,000 Americans have myotonic dystrophy, an inherited disorder that is marked by progressive muscle weakness and stiffness; eventually many patients have difficulty walking, swallowing, and breathing. The disease can also affect the eyes, the heart, and the brain. While there are medications to treat some of the disease symptoms, there is no drug to stop its progression.

The recent progress comes about a decade after several scientists, including Thornton, discovered that the genetic defect that causes the disease works quite differently than most other inherited diseases. In many diseases, a genetic flaw means that an important protein is not made correctly, or not made at all.

But in myotonic dystrophy, the defect results in the creation of an abnormal messenger RNA, which accumulates in the nucleus, getting in the way and stopping other proteins from doing their jobs. One of those proteins is MBNL1, which helps create chloride channels that are important for electrical control of muscles. When that process is thwarted, muscles send errant electrical signals, causing symptoms.

The approach outlined in the Nature paper exploits the roots of the defect, harnessing an enzyme whose usual job is to cut RNA into pieces. Working closely with the Rochester and Genzyme teams, scientists at Isis created synthetic compounds - short snippets of chemically modified DNA - that bind to the toxic RNA, modifying it in such a way that it was targeted for destruction by one of the body's own enzymes, RNase H.

With the team's most effective compounds, symptoms in the mice were reversed. The level of toxic RNA was reduced by more than 80 percent; stiffness in muscles eased dramatically; the microscopic structure of muscle was improved; and electrical signaling in muscles returned to normal.

The possibility of targeting "toxic RNA" - a buildup of abnormal RNA causing cellular processes to go awry - makes myotonic dystrophy an excellent target for antisense drugs, said Thornton.

The compounds are called "antisense" because their genetic code is the mirror image of the target RNA strand, known in scientific parlance as the "sense" molecule. The antisense compound will only stick to the precise RNA that is part of the myotonic dystrophy gene, leaving thousands of other vitally important RNAs alone.

While antisense technology has been in development for a couple of decades, it has not been effective at eliminating RNA in muscle cells until now. Results like those in the Nature paper are creating enthusiasm particularly among scientists who study neurodegenerative diseases, Thornton says. He points to promising work by a team from the University of California at San Diego on Huntington's disease, as well as research out of Cold Spring Harbor Laboratory on spinal muscular atrophy.

"For 20 years we studied myotonic dystrophy, hoping that someday we would learn enough to spot its Achilles heel," said Thornton. "This work comes close to doing that.

"I know it is unscientific for me to think so, but I can't help but see a little glimmer of 'medical justice' in this approach. For the same reason that the toxic RNA makes people sick, by hanging around too long in the nucleus and gumming up the works, it also becomes more susceptible to antisense drugs, because these drugs seem to work extraordinarily well against RNA in the nucleus," he added.

"Based upon these exciting preclinical data, we have initiated a drug discovery project for myotonic dystrophy with Dr. Thornton's team to identify an antisense drug to begin clinical testing," said C. Frank Bennett Ph.D., Senior Vice President, Research at Isis Pharmaceutical, Inc. "Myotonic dystrophy represents an ideal opportunity for an antisense drug as the disease-causing gene produces a toxic RNA that is not easily targeted with other therapeutic approaches. In just a few years, we have been able to expand our severe and rare disease franchise and maintain a broad research program, in which we are evaluating many different diseases that could be treated with an antisense drug."

Thornton was inspired to create a robust research effort to address the disease largely because of his experience treating patients. He is co-director of the Medical Center's Wellstone Muscular Dystrophy Cooperative Research Center, one of the world's top centers for the treatment of muscular dystrophy. He is also a scientist in the Center for Neural Development and Disease, where he runs a laboratory looking at the roots of the disease and exploring new treatments. On any given day, he is both seeing patients coping with conditions like myotonic dystrophy, as well as running laboratory experiments aimed at stopping the disease altogether.

As the research progressed, Thornton struck up a collaboration with Isis Pharmaceuticals Inc., the creator of the only antisense medication on the market, and Genzyme, a company with experience treating muscle diseases. Earlier this summer Isis announced an agreement with Biogen Idec Inc. to explore antisense treatments for myotonic dystrophy - an effort closely linked to Thornton's work.

Now scientists at Isis and the University of Rochester are working to improve their lead compound further, developing antisense compounds with stronger activity against the toxic RNA, but with minimal effects on the rest of the body. An unknown factor at this point, Thornton says, is whether the compounds will also improve the muscle-wasting aspect of the disease. That symptom, which causes great difficulty for patients, has been hard for scientists to create in mice, and so it's difficult to predict how it might respond to antisense knockdown technology.

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our muscular dystrophy / als section for the latest news on this subject. The first author of the paper is Thurman Wheeler, M.D., assistant professor of Neurology at the University of Rochester Medical Center, who conducted many of the experiments. Other authors include Masayuki Nakamori, now at the University of Osaka in Japan; Sanjay Pandey, A. Robert MacLeod, and C. Frank Bennett of Isis Pharmaceuticals; and Andrew Leger, Seng Cheng, and Bruce Wentworth of Genzyme.
The work was funded by the National Institute of Neurological Disorders and Stroke, the National Institute of Arthritis and Musculoskeletal and Skin Diseases, the Saunders Family Neuromuscular Research Fund, Run America, the Muscular Dystrophy Association, and the Uehara Memorial Foundation.
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