 |
|
Sounding the alarm for infections: EMBL researchers discover rapid-response, interferon-producing cells
February 15, 2002Nearly fifty years ago, researchers discovered that when cells in laboratory cultures are infected by a virus, they secrete a substance that protects other cells from infection. In 1957 Alick Issaks and Jean-Jacques Lindenmann traced this effect to a protein called interferon, a molecule now known to play a key role in the immune system. Human and animal cells produce it in a rapid "first wave" response to infections. Since its discovery, scientists have sought to use this natural substance to cure all sorts diseases, and clinical trials have demonstrated interferon's potential to combat diseases as different as hepatitis C, blood cancers, and multiple sclerosis. Yet many aspects of interferon biology remain a mystery - including what initially prompts the body to produce it. Now Ulrich Kalinke and Winfried Barchet at the European Molecular Biology Laboratory (EMBL) station in Monterotondo, Italy, have identified specific cells in the body able to launch a massive, initial round of interferon production. Their work, reported in the current issue of the Journal of Experimental Medicine, is changing how researchers think of the interferon system and adds a key element to our understanding of how the immune system works.
Interferons have the ability to put the cell on "hold"; they slow down a lot of processes that would otherwise help viruses reproduce very quickly. While many deadly viruses have evolved the means to evade these measures, most are slowed down enough for other phases of the body's immune system to kick into high gear and eradicate them. Animals that are born without the ability to mount an interferon defense are unable to survive even mild infections and they quickly die.
Until now, most scientists have believed that the body produces most of its interferon through a sort of "feedback loop": special proteins called receptors, on the surface of the cell, sense a few "starter" interferon molecules, and this activates a machinery that churns out vast amounts of different types of interferons. These spread through the body as an alarm signal. Studies of infected cells in cell cultures suggested that removing the receptors, and thus the "sensing apparatus," also halted the interferon-production machinery.
"But those experiments primarily used one specific kind of cell," Kalinke says. "Because just about any type of cell starts producing interferon when you stimulate it, not many scientists were excited about looking for specific cells that might produce the majority of IFN in an organism."
Comparing normal mice to animals whose cells didn`t have interferon receptors, the researchers discovered a puzzling fact. Within a few hours of the onset of an infection, they found that levels of interferon rose dramatically in the blood of both types of mice. This couldn't be due to a feedback mechanism, Kalinke reasoned, so somewhere in their bodies, mice must have cells that produce massive quantities of the protein very quickly after virus appears.
He convinced PhD student Winfried Barchet to undertake a search for "interferon-producing cells", or IPCs. It was obviously an exciting experiment to undertake - EMBL's Director General Fotis C. Kafatos told Barchet he was holding onto a "nugget of gold." But the scientists were nervous. "The evidence was out there for everybody to see," Barchet says. "There was a real danger of getting scooped on the story."
However, Barchet and Kalinke found themselves in a unique position to track down the IPCs. The laboratory in Monterotondo, which is an external unit of EMBL's headquarters in Heidelberg, specializes in mouse biology. It also has what Kalinke calls the "Virus Suite," a set of activities capable of studying infectious diseases in both animals and cell cultures.
They began their search for the IPCs in the spleen - an organ which is heavily involved in the body's immune reactions. Experiments performed by collaborator Bernhard Odermatt marked interferon in a purple color helped them zoom in on a "hot zone": an area of the spleen called the marginal zone.
But here they ran into problems. "This region contains a large number of different types of cells, all mixed very closely together," Barchet says. "You can't distinguish them in tissue sections under the microscope. So we approached the group of Marina Cella and Marco Colonna in Basel, who have very sophisticated equipment that can 'sort' cells. We were able to pin early IFN production down to a very specific type called a dendritic cell."
This finding was intriguing because dendritic cells are major players in the "second wave" of the body's immune response. Whereas interferon acts as a sort of a generic weapon that will attack nearly any type of virus, the body has a backup system recognizing antigens, the unique molecular "fingerprints" of pathogens like viruses and bacteria. Dendritic cells acquire these unique markers, activate immune cells, and thus are able to kick off this "second wave" immune response.
"Researchers have been looking for a connection between the first-round, 'innate' immune system, which involves interferon, and the 'adaptive' or second-round immune system," Kalinke says. "It's obviously exciting to find a type of cell known to participate in one system playing an important role in the other. But there are several sub-types of these cells, and we aren't yet sure whether the dendritic cells that produce interferon can also acquire viral antigens."
Dendritic cells can be found in many places in the body, and now Kalinke and Barchet will go looking for IPCs elsewhere. "An obvious place to look is in the lungs or in other parts of the body that are first exposed to viruses," Barchet says.
IPCs probably play a major role at the very beginning of an infection; after several hours, most interferon is probably produced through the activation of the feedback mechanism. But the discovery of IPCs may be useful in the search for medical applications for interferon. "Ever since their discovery, people have been interested in medical applications based on these molecules," Kalinke says. "But it has taken many years for basic research to show us the mechanisms by which they really operate. Now we're starting to understand the real biology, which is exciting renewed interest in the innate immune response."
- Russ Hodge
European Molecular Biology Laboratory (EMBL)
"But those experiments primarily used one specific kind of cell," Kalinke says. "Because just about any type of cell starts producing interferon when you stimulate it, not many scientists were excited about looking for specific cells that might produce the majority of IFN in an organism."
Comparing normal mice to animals whose cells didn`t have interferon receptors, the researchers discovered a puzzling fact. Within a few hours of the onset of an infection, they found that levels of interferon rose dramatically in the blood of both types of mice. This couldn't be due to a feedback mechanism, Kalinke reasoned, so somewhere in their bodies, mice must have cells that produce massive quantities of the protein very quickly after virus appears.
He convinced PhD student Winfried Barchet to undertake a search for "interferon-producing cells", or IPCs. It was obviously an exciting experiment to undertake - EMBL's Director General Fotis C. Kafatos told Barchet he was holding onto a "nugget of gold." But the scientists were nervous. "The evidence was out there for everybody to see," Barchet says. "There was a real danger of getting scooped on the story."
However, Barchet and Kalinke found themselves in a unique position to track down the IPCs. The laboratory in Monterotondo, which is an external unit of EMBL's headquarters in Heidelberg, specializes in mouse biology. It also has what Kalinke calls the "Virus Suite," a set of activities capable of studying infectious diseases in both animals and cell cultures.
They began their search for the IPCs in the spleen - an organ which is heavily involved in the body's immune reactions. Experiments performed by collaborator Bernhard Odermatt marked interferon in a purple color helped them zoom in on a "hot zone": an area of the spleen called the marginal zone.
But here they ran into problems. "This region contains a large number of different types of cells, all mixed very closely together," Barchet says. "You can't distinguish them in tissue sections under the microscope. So we approached the group of Marina Cella and Marco Colonna in Basel, who have very sophisticated equipment that can 'sort' cells. We were able to pin early IFN production down to a very specific type called a dendritic cell."
This finding was intriguing because dendritic cells are major players in the "second wave" of the body's immune response. Whereas interferon acts as a sort of a generic weapon that will attack nearly any type of virus, the body has a backup system recognizing antigens, the unique molecular "fingerprints" of pathogens like viruses and bacteria. Dendritic cells acquire these unique markers, activate immune cells, and thus are able to kick off this "second wave" immune response.
"Researchers have been looking for a connection between the first-round, 'innate' immune system, which involves interferon, and the 'adaptive' or second-round immune system," Kalinke says. "It's obviously exciting to find a type of cell known to participate in one system playing an important role in the other. But there are several sub-types of these cells, and we aren't yet sure whether the dendritic cells that produce interferon can also acquire viral antigens."
Dendritic cells can be found in many places in the body, and now Kalinke and Barchet will go looking for IPCs elsewhere. "An obvious place to look is in the lungs or in other parts of the body that are first exposed to viruses," Barchet says.
IPCs probably play a major role at the very beginning of an infection; after several hours, most interferon is probably produced through the activation of the feedback mechanism. But the discovery of IPCs may be useful in the search for medical applications for interferon. "Ever since their discovery, people have been interested in medical applications based on these molecules," Kalinke says. "But it has taken many years for basic research to show us the mechanisms by which they really operate. Now we're starting to understand the real biology, which is exciting renewed interest in the innate immune response."
- Russ Hodge
European Molecular Biology Laboratory (EMBL)
Immune System Current Events and Immune System News RSSSurface bacteria maintain skin's healthy balance
On the skin's surface, bacteria are abundant, diverse and constant, but inflammation is undesirable. Research at the University of California, San Diego School of Medicine now shows that the normal bacteria living on the skin surface trigger a pathway that prevents excessive inflammation after injury.
Gene mismatch influences success of bone marrow transplants
A commonly inherited gene deletion can increase the likelihood of immune complications following bone marrow transplantation, an international team of researchers reports in the November 22 advance online issue of Nature Genetics.
Measuring and modeling blood flow in malaria
When people have malaria, they are infected with Plasmodium parasites, which enter the body from the saliva of a mosquito, infect cells in the liver, and then spread to red blood cells.
New cancer target for non-Hodgkin's lymphoma
Physician-scientists from Weill Cornell Medical College have discovered a molecular mechanism that may prove to be a powerful target for the treatment of non-Hodgkin's lymphoma, a type of cancer that affects lymphocytes, or white blood cells.
First reconstitution of an epidermis from human embryonic stem cells
Stem cell research is making great strides. This is yet again illustrated by a study carried out by the I-STEM* Institute (I-STEM/ Inserm UEVE U861/AFM), published in the Lancet on 21 November 2009. The I-STEM team, directed by Marc Peschanski has just succeeded in recreating a whole epidermis from human embryonic stem cells.
New findings suggest strategy to help generate HIV-neutralizing antibodies
New discoveries about anti-HIV antibodies may bring researchers a step closer to creating an effective HIV vaccine, according to a new paper co-authored by scientists at the Vaccine Research Center of the National Institute of Allergy and Infectious Diseases (NIAID), part of the National Institutes of Health.
UAB Researchers Discover Antibody Receptor Identity, Propose Renaming Immune-System Gene
Researchers at the University of Alabama at Birmingham (UAB) have uncovered the genetic identity of a cellular receptor for the immune system's first-response antibody, a discovery that sheds new light on infection control and immune disorders.
New culprit for viral infections among elderly -- an overactive immune response
Researchers at Yale School of Medicine have found that exaggerated responses of the immune system explain why the elderly succumb to viral infections more readily than younger people.
Women at risk from vitamin A deficiency
Almost half of UK women could be suffering from a lack of vitamin A due to a previously undiscovered genetic variation, scientists at Newcastle University have found.
Immune system activated in schizophrenia
Researchers at the Swedish medical university Karolinska Institutet have discovered that patients with recent-onset schizophrenia have higher levels of inflammatory substances in their brains. Their findings offer hope of being able to treat schizophrenia with drugs that affect the immune system.
More Immune System Current Events and Immune System News Articles
 |
The Immune System 3e by Peter Parham (Author) The Immune System, Third Edition emphasizes the human immune system and synthesizes immunological concepts into a comprehensible, up-to-date, and reader-friendly account of how the immune system works. Written for undergraduate, medical, dental, and pharmacy students in immunology courses, it makes generous use of medical examples to illustrate points. The Third Edition has been extensively revised and updated and includes two new chapters on innate and adaptive immunity, which explore the physical, cellular, and molecular principles underlying these responses to infection. It also features enhanced coverage of aspects of innate immunity such as the complement system, Toll-like receptors, defensins, and C-reactive protein; the role of dendritic cells... |
 |
How the Immune System Works (Blackwell's How It Works) by Lauren M. Sompayrac (Author) Understanding the immune system is crucial for both medical and bioscience students, with new research revealing yet more secrets year on year. Many books offer in-depth introductions to the subject, but How the Immune System Works remains uniquely popular for its personable and practical overview of the nuts and bolts of the immune system. This third edition provides a perfect introduction to the essential principles of the immune system, covered in humorous but highly informative 'lectures' accompanied by clear and accessible illustrations. It is perfect for exam preparation or as an enjoyable overview of a difficult subject. Both students and instructors will welcome the clarity and authority that Lauren Sompayrac brings to this timely revision. |
 |
The Immune System Cure: Optimize Your Immune System in 30 Days-The Natural Way! by Kensington (Producer) What causes one person to catch a cold or flu and another to avoid it? Why do serious outbreaks of infectious diseases leave some individuals untouched? What allows someone to be incapacitated by allergies? The answer lies within nature itself-our immune system. The Immune System Cure provides simple techniques for supercharging your immune system to resist and prevent disease. Through diet, exercise, stress reduction and nutritional supplements, including plant sterols and sterolins, you can harness the power of your immune system in just 30 days and help it combat: Antibiotic-resistant bacteria Fibromyalgia Allergies Hepatitis C Tuberculosis Cancer Rheumatoid arthritis and other autoimmune diseases Chronic fatigue syndrome and more Now you can maintain a healthy... |
 |
The Immune System by Peter Parham (Author) The Immune System, Second Edition has been designed for use in immunology courses for undergraduate, medical, dental, and pharmacy students. This class-tested and successful textbook synthesizes the established facts of immunology into a comprehensible, coherent, and up-to-date account of how the immune system works, rather than presenting immunology as a chronology of experiments and discoveries. Emphasizing the human immune system the text has been designed to break down the barriers which often divide basic and clinical immunology. The reader-friendly text, section and chapter summaries, and full-color illustrations make the book accessible and easily understandable to students. The Immune System is adapted from Immunobiology by Janeway, Travers & Walport. New in... |
 |
In Defense of Self: How the Immune System Really Works by William R. Clark (Author) We live in a sea of seething microbial predators, an infinity of invisible and invasive microorganisms capable of setting up shop inside us and sending us to an early grave. The only thing keeping them out? The immune system. William Clark's In Defense of Self offers a refreshingly accessible tour of the immune system, putting in layman's terms essential information that has been for too long the exclusive province of trained specialists. Clark explains how the immune system works by using powerful genetic, chemical, and cellular weapons to protect us from the vast majority of disease-causing microbes-bacteria, viruses, molds, and parasites. Only those microbes our bodies need to help us digest food and process vitamins are admitted. But this same system can endanger us by... |
 |
90-Day Immune System Makeover by Janet C. Maccaro (Author) No matter how your health has been in the past, there is something you can do right now—a complete makeover to give you the vitality and energy to embrace life at your best! In just ninety days, Janet Maccaro will enable you to build and strengthen your immune system to bring your body into proper balance and experience disease-free living. Birthed out of Maccaro’s twenty-year struggle with poor health and immune dysfunction, this book provides time-tested natural alternatives to strengthen your body, mind, and spirit. If you’re tired of being sick and tired, and if you’re ready for a complete immune system makeover, this easy-to-follow guide to renewed health can show you how! |
 |
The Top 100 Immunity Boosters: 100 Recipes to Keep Your Immune System Fighting Fit by Charlotte Haigh (Author) Eat well today for a healthier tomorrow! With proper nutrition, we can actually bolster our immune system—and, as these 100 recipes prove, it’s not only easy to do, it’s also delicious. Here are foods rich in important vitamins, such as A, B complex, C, and E; in minerals, including zinc, selenium, and calcium; in Omega-3 and -6 fatty acids; and in protein and fiber. For each choice, there’s a tasty recipe, and information on its beneficial nutrients. Enjoy a sweet potato summer salad (with lots of betacarotene); cholesterol-lowering guacamole; broccoli stir-fry (a potential cancer-fighter); and a tasty blueberry smoothie. An ailment directory makes it simple to locate the right food for any problem. |
 |
Maximum Healing: Improve Your Immune System and Optimize Your Natural Ability to Heal by H. Robert Silverstein (Author), Tom Monte (Author) If you suffer from—allergies, asthma, high blood pressure or cholesterol, cancer, chronic fatigue, headaches, heart disease, joint pain, skin disorder, or rheumatoid arthritis—then this may be the most important book you will ever read. Inspiring case histories demonstrate successful treatment and prevention of these and many other illnesses. |
 |
Supercharge Your Immune System: 100 Ways to Help Your Body Fight Illness - One Glass at a Time by Ellen Brown (Author), Karen Konopelski (Author) It's now an accepted medical fact that the nutrients in certain fruits and vegetables make them "super foods" because they are the highest in the vitamins and other nutrients that naturally build our immune systems. Smoothies --frosty, thick, luscious drinks--are a way that all members of the family can gleefully boost their nutrition and maintain strong immune systems, and Supercharge Your Immune System is a book that allows them to do so deliciously. One hundred recipes for special smoothies include a delicious assortment of food and flavors, take minutes to prepare, and are packed with the vitamins, antioxidants, and minerals that fight autoimmune disorders. Most importantly, they taste great-because readers won't benefit from what they don't drink. Includes recipes that are... |
 |
Boost Your Immune System Naturally: A Lifestyle Action Plan for Strengthening Your Natural Defences by Beth MacEoin (Author) Today many of us are faced with extremely high levels of pollution, allergens, and other threats to our health in the form of certain strains of bacteria that are immune to antibiotics. Boost Your Immune System Naturally shows you how to improve your overall health to ward off illness and keep you in optimal health. Written by an expert in nutrition and naturopathy, these easy-to-follow diet, lifestyle and supplement plans provide a totally natural way to strengthen your natural defenses. |
| © 2009 BrightSurf.com |