 |
|
New nano device detects immune system cell signaling
September 04, 2008Scientists have detected previously unnoticed chemical signals that individual cells in the immune system use to communicate with each other over short distances.
The signals the researchers detected originated in dendritic cells - the sentinels of the immune system that do the initial detection of microscopic invaders - and were received by nearby T-cells, which play a number of crucial roles in the immune system, including coordination of attacks on agents that cause disease or infection.
The chemical signals cells exchange when they come into contact have been studied extensively. But it has not been possible to detect chemical messages that travel between cells that are nearby but not in contact - called paracrine signals - because they are highly localized and they are produced in concentrations that have been below detection levels. A new technology, called a multi-trap nanophysiometer, was required to demonstrate the existence of non-contact signaling. This is one of the first microfluidic devices that has been applied successfully to the study of cell-to-cell signaling in the immune system.
A detailed description of the multi-trap nanophysiometer (MTN) and how it enabled the accidental discovery of paracrine signaling has been published online by the Lab on a Chip journal. The new device was developed by a team of researchers at the Vanderbilt Institute for Integrative Biosystems Research and Education headed by John P. Wikswo, the Gordon A. Cain University Professor at Vanderbilt.
"This is an important advance and potentially very useful technology," says co-author Derya Unutmaz, now an associate professor of microbiology at New York University's School of Medicine. "The ability to study the behavior of single cells may not be as critical if you are studying the heart or muscles, which are mostly formed by uniform cells, but it is crucial for understanding how the immune system functions. The wide surveillance of the body that it conducts requires extensive communication between dozens of different kinds of immune cells."
The reason for this is that the dendritic cells, T-cells and B-cells in the immune system, which tend to concentrate in the lymph nodes spread throughout the body, function as individual, unattached cells. If dendritic cells detect invaders in the body, they rapidly migrate to lymph nodes and have to find the appropriate T-cells to alert them. But how dendritic cells attract the right T-cells among millions of cells within the lymph nodes remains an immunological puzzle.
Scientists have been trying to develop systems for single-cell analysis for a number of years. Because of the difficulty of keeping normal cells alive, they have been forced to use cells that have been genetically altered so they can be cultured indefinitely. Although the alteration "immortalizes" the cells, it also significantly limits their usefulness. The MTN is the first system that can monitor biochemical changes in large numbers of normal or primary cells at the single-cell level for prolonged periods, Unutmaz says.
The new device consists of a series of hair-sized channels molded in a special kind of plastic that is glued onto the bottom of a glass microscope coverslip. A shoebox-sized pump pushes fluid (normally the media used to culture cells) through one channel that opens up into a chamber filled with hundreds of tiny, three-sided wells small enough to trap individual cells. When cells are injected upstream, they are passively trapped in the wells and are held there solely by the fluid flowing out even smaller holes in the well bottoms. By precisely controlling the flow rate, the researchers can keep normal cells alive for longer than 24 hours.
The researchers monitor the cells with a digital camera attached to a standard microscope, typically snapping images every 30 seconds. They have written software that allows them to analyze the movements and reactions of individual cells. They can record various cell behaviors by injecting different fluorescent dyes into the cells. For example, when naive T-cells are primed for an immune response, the concentration of calcium ion in their cytoplasm jumps up. So when the cytoplasm contains a dye that fluoresces when it comes into contact with calcium, it glows brightly enough to be easily detected.
The surprise discovery of paracrine signaling was made by graduate student Shannon Faley, now a postdoctoral research associate at the University of Glasgow, Scotland. She filled up a nanophysiometer chamber with naive human T-cells and then added mature dendritic cells. She was looking for evidence of T-cell activation when the T-cells and dendritic cells were trapped in the same well and came into contact. This contact is part of the process that allows dendritic cells to convey information about potentially infectious invaders to the naive T-cells, which can then begin dividing to produce an army of effector T-cells custom-designed to attack the invaders.
Faley saw what she was looking for, but she also noticed something unexpected: some T-cells that were trapped in wells downstream of those with dendritic cells, which had never been in direct contact with them, were also lighting up. "My reaction when I saw them was, 'What in the world is going on?'" she says.
"When she saw this, Shannon did a very clever thing," says Wikswo. "She took one chamber and filled it with dendritic cells and took a second chamber and filled it with T-cells. Then she hooked the second chamber downstream of the first." When she did so, the T-cells in the second chamber immediately began lighting up, demonstrating that the mature dendritic cells were releasing a chemical factor that activates naive T-cells without coming into contact.
"At this point we don't know what this factor is or what its function is," says Faley. According to Unutmaz, a logical function for this signal would be to attract T-cells to dendritic cells that have important information to give them. This supposition is strengthened by the observation that immature dendritic cells don't produce this factor but mature immunogenic dendritic cells - those that have encountered a pathogen or danger signal - do.
When Faley tried to duplicate this result using standard immunological techniques, however, the result was negative. The standard method consists of growing a culture of dendritic cells in a culture flask, adding T-cells and looking for a reaction. If the cell density is too great, the cells begin poisoning each other, run out of food and die. So the standard practice is to keep the density at a low enough level that the cells remain healthy when the cell media is changed daily.
"This represents a dilution factor of 100 compared to the nanophysiometer," says Wikswo. "So the factor produced by the dendritic cells was too dilute to activate the T-cells." It wasn't until Faley redid the standard test with cell densities 10 times higher than normal that she got the T-cells to activate.
"This represents one of the advantages of the nanophysiometer; it suspends cells in extremely small volumes that are much closer to what they experience in the body and uses slow fluid flow to keep the cells alive," Wikswo says.
Not only is this capability important in improving our knowledge of how the immune system works, but it may also be the key to understanding why the system fails, as it does in cases like cancer and HIV/AIDS, says Dana Marshall, associate professor at the Meharry Medical College. She and the Wikswo group have submitted a proposal to use the technique to study triple-negative breast tumors, one of the most deadly forms of breast cancer.
"The ability to look at the signaling among cancer cells and immune cells is extremely powerful," Marshall says. "According to the evidence, the immune system tries to suppress tumor cells but it fails to do so. It is not clear why it fails. If we can figure that out, then we should be able to develop more effective treatments."
In addition, the multi-trap nanophysiometer could provide a better way to identify the most effective forms of chemotherapy to use for each individual, Marshall suggests. There are enough cells in a typical biopsy to load one chamber with tumor cells and a second chamber with immune-system cells from a patient, subject them to different chemotherapeutic agents and see how the two groups of cells respond. "Often, when therapy fails, the tumor responds to a chemotherapy treatment for a period of time and then it stops. This approach may let us figure out why that happens," Marshall says.
Vanderbilt University
A detailed description of the multi-trap nanophysiometer (MTN) and how it enabled the accidental discovery of paracrine signaling has been published online by the Lab on a Chip journal. The new device was developed by a team of researchers at the Vanderbilt Institute for Integrative Biosystems Research and Education headed by John P. Wikswo, the Gordon A. Cain University Professor at Vanderbilt.
"This is an important advance and potentially very useful technology," says co-author Derya Unutmaz, now an associate professor of microbiology at New York University's School of Medicine. "The ability to study the behavior of single cells may not be as critical if you are studying the heart or muscles, which are mostly formed by uniform cells, but it is crucial for understanding how the immune system functions. The wide surveillance of the body that it conducts requires extensive communication between dozens of different kinds of immune cells."
The reason for this is that the dendritic cells, T-cells and B-cells in the immune system, which tend to concentrate in the lymph nodes spread throughout the body, function as individual, unattached cells. If dendritic cells detect invaders in the body, they rapidly migrate to lymph nodes and have to find the appropriate T-cells to alert them. But how dendritic cells attract the right T-cells among millions of cells within the lymph nodes remains an immunological puzzle.
Scientists have been trying to develop systems for single-cell analysis for a number of years. Because of the difficulty of keeping normal cells alive, they have been forced to use cells that have been genetically altered so they can be cultured indefinitely. Although the alteration "immortalizes" the cells, it also significantly limits their usefulness. The MTN is the first system that can monitor biochemical changes in large numbers of normal or primary cells at the single-cell level for prolonged periods, Unutmaz says.
The new device consists of a series of hair-sized channels molded in a special kind of plastic that is glued onto the bottom of a glass microscope coverslip. A shoebox-sized pump pushes fluid (normally the media used to culture cells) through one channel that opens up into a chamber filled with hundreds of tiny, three-sided wells small enough to trap individual cells. When cells are injected upstream, they are passively trapped in the wells and are held there solely by the fluid flowing out even smaller holes in the well bottoms. By precisely controlling the flow rate, the researchers can keep normal cells alive for longer than 24 hours.
The researchers monitor the cells with a digital camera attached to a standard microscope, typically snapping images every 30 seconds. They have written software that allows them to analyze the movements and reactions of individual cells. They can record various cell behaviors by injecting different fluorescent dyes into the cells. For example, when naive T-cells are primed for an immune response, the concentration of calcium ion in their cytoplasm jumps up. So when the cytoplasm contains a dye that fluoresces when it comes into contact with calcium, it glows brightly enough to be easily detected.
The surprise discovery of paracrine signaling was made by graduate student Shannon Faley, now a postdoctoral research associate at the University of Glasgow, Scotland. She filled up a nanophysiometer chamber with naive human T-cells and then added mature dendritic cells. She was looking for evidence of T-cell activation when the T-cells and dendritic cells were trapped in the same well and came into contact. This contact is part of the process that allows dendritic cells to convey information about potentially infectious invaders to the naive T-cells, which can then begin dividing to produce an army of effector T-cells custom-designed to attack the invaders.
Faley saw what she was looking for, but she also noticed something unexpected: some T-cells that were trapped in wells downstream of those with dendritic cells, which had never been in direct contact with them, were also lighting up. "My reaction when I saw them was, 'What in the world is going on?'" she says.
"When she saw this, Shannon did a very clever thing," says Wikswo. "She took one chamber and filled it with dendritic cells and took a second chamber and filled it with T-cells. Then she hooked the second chamber downstream of the first." When she did so, the T-cells in the second chamber immediately began lighting up, demonstrating that the mature dendritic cells were releasing a chemical factor that activates naive T-cells without coming into contact.
"At this point we don't know what this factor is or what its function is," says Faley. According to Unutmaz, a logical function for this signal would be to attract T-cells to dendritic cells that have important information to give them. This supposition is strengthened by the observation that immature dendritic cells don't produce this factor but mature immunogenic dendritic cells - those that have encountered a pathogen or danger signal - do.
When Faley tried to duplicate this result using standard immunological techniques, however, the result was negative. The standard method consists of growing a culture of dendritic cells in a culture flask, adding T-cells and looking for a reaction. If the cell density is too great, the cells begin poisoning each other, run out of food and die. So the standard practice is to keep the density at a low enough level that the cells remain healthy when the cell media is changed daily.
"This represents a dilution factor of 100 compared to the nanophysiometer," says Wikswo. "So the factor produced by the dendritic cells was too dilute to activate the T-cells." It wasn't until Faley redid the standard test with cell densities 10 times higher than normal that she got the T-cells to activate.
"This represents one of the advantages of the nanophysiometer; it suspends cells in extremely small volumes that are much closer to what they experience in the body and uses slow fluid flow to keep the cells alive," Wikswo says.
Not only is this capability important in improving our knowledge of how the immune system works, but it may also be the key to understanding why the system fails, as it does in cases like cancer and HIV/AIDS, says Dana Marshall, associate professor at the Meharry Medical College. She and the Wikswo group have submitted a proposal to use the technique to study triple-negative breast tumors, one of the most deadly forms of breast cancer.
"The ability to look at the signaling among cancer cells and immune cells is extremely powerful," Marshall says. "According to the evidence, the immune system tries to suppress tumor cells but it fails to do so. It is not clear why it fails. If we can figure that out, then we should be able to develop more effective treatments."
In addition, the multi-trap nanophysiometer could provide a better way to identify the most effective forms of chemotherapy to use for each individual, Marshall suggests. There are enough cells in a typical biopsy to load one chamber with tumor cells and a second chamber with immune-system cells from a patient, subject them to different chemotherapeutic agents and see how the two groups of cells respond. "Often, when therapy fails, the tumor responds to a chemotherapy treatment for a period of time and then it stops. This approach may let us figure out why that happens," Marshall says.
Vanderbilt University
Science News and Science Current Events Tag Cloud
This tag cloud is a visual representation of term frequencies of random science news topics with common terms grouped together and emphasized by their display size.
Hearing Loss Glaciers Cancer Cells Conservation Tamoxifen Diabetic Retinopathy Gene Expression Acetaminophen Drinking Water Arctic Ocean Anxiety Hysterectomy ALS Sinkhole Combination Therapy Amazon rainforest Chest Pain Amblyopia Flavanols Diversity Stress Nanomaterials Memory Tinnitus Weight Loss
See More: Science News Tags
Dendritic Cells Current Events and Dendritic Cells News RSSStudy identifies biomarker that safely monitors tumor response to new brain cancer treatment
A specific biomarker, a protein released by dying tumor cells, has been identified as an effective tool in an animal model to gauge the response to a novel gene therapy treatment for glioblastoma mulitforme.
Development of DNA drugs gives hope to lupus patients
A generation of DNA-like compounds, class R inhibitory oligonucleotides (INH-ODNs), have been shown to effectively inhibit cells responsible for the chronic autoimmune condition lupus.
Team develops DNA compounds that could help treat lupus
A research team led by a University of Iowa investigator has generated DNA-like compounds that effectively inhibit the cells responsible for systemic lupus erythematosus -- the most common and serious form of lupus.
Computer simulation captures immune response to flu
Researchers have successfully tested first the first time a computer simulation of major portions of the body's immune reaction to influenza type A, with implications for treatment design and preparation ahead of future pandemics, according to work accepted for publication, and posted online, by the Journal of Virology.
Study reveals current multi-component vaccines may need reworking
Current strategies for designing vaccines against HIV and cancers, for instance, may enable some components in multi-component vaccines to cancel the effect of others on the immune system, eliminating their ability to provide protection, according to an article to be published shortly in the Proceedings of the National Academy of Sciences (PNAS).
Cancer-causing virus associated with higher risk of new HIV infection
Infection with anal human papillomavirus (HPV), a virus that can cause anal and cervical cancers, is associated with a higher risk of new HIV infection in previously HIV-negative men who have sex with men (MSM), according to new UCSF research.
Peregrine's PS-targeting antibodies highlighted in AACR Annual Meeting studies
Peregrine Pharmaceuticals, Inc. (Nasdaq: PPHM), a clinical stage biopharmaceutical company developing monoclonal antibodies for the treatment of cancer and serious virus infections, today reported that two preclinical studies presented during the AACR 100th Annual Meeting 2009 provided further confirmation of the immunomodulatory mechanisms contributing to the anti-tumor activity of its phosphatidylserine (PS) targeting antibodies.
Not just a long distance relationship: immune cells in skin fight off infection better than the rest
Scientists at the University of Melbourne have discovered the local action of immune cells in the skin, which could improve treatment of viral skin infections.
Goodbye needle, hello smoothie
Instead of a dreaded injection with a needle, someday getting vaccinated against disease may be as pleasant as drinking a yogurt smoothie.
Don't be a stranger to yourself
One of the most important tasks of the immune system is to identify what is foreign and what is self. If this distinction fails, then the body's own structures will be attacked, the result of which could be an autoimmune disease such as diabetes mellitus type 1 or multiple sclerosis.
More Dendritic Cells Current Events and Dendritic Cells News Articles
 |
Macrophages and Dendritic Cells: Methods and Protocols (Methods in Molecular Biology) by Neil E. Reiner (Editor) In light of the critical contributions of macrophages and dendritic cells to diverse inflammatory diseases and to immunity and host defense, state-of-the-art approaches to the investigation of their behavior are essential. In "Macrophages and Dendritic Cells: Methods and Protocols", expert researchers contribute laboratory protocols involving these two vital cell types functioning at the junction of the innate and acquired immune systems. The volume delves first into isolation and cell culturing then continues with topics such as phagocytosis, genetic manipulation, macrophage activation, and lipid signaling.Written in the highly successful "Methods in Molecular Biology" series format, chapters include brief introductions to their respective subjects, lists of the necessary materials and... |
 |
Toll-Like Receptors (TLRs) and Innate Immunity by Springer Overall recent research on TLRs has led to tremendous increase in our understanding of early steps in pathogen recognition and will presumably lead to potent TLR targeting therapeutics in the future. This book reviews and highlights our recent understanding on the function and ligands of TLRs as well as their role in autoimmunity, dendritic cell activation and target structures for therapeutic intervention. |
|
Normal Human Dendritic Cells () by Cambrex NHDC Dendritic Cells Cryopreserved Test negative for HIV-I hepatitis-B and C mycoplasma bacteria yeast and fungi Isolated from peripheral blood by apheresis and density gradient centrifugation | |
 |
Dendritic Cell Protocols (Methods in Molecular Medicine) by Stephen P. Robinson (Editor), Andrew J. Stagg (Editor) Stephen P Robinson, MD, PhD, and Andrew Satgg, PhD, have brought together a wide range of time-proven methods for studying these dendritic cells. Many of these readily reproducible techniques deal with the problem of obtaining sufficient dendritic cells for analysis, whether by isolation from a wide vareity of tissues, or from various progenitor cell populations. Other methods describe in step-by-step fashion the techniques commonly used for analyzing aspects of dendritic cells, ranging from cell migration to antigen uptake and T cell stimulation. In addition, a few techniques explore the practical challenges involved in using dendritic cells in a clinical setting to develop novel immunotherapeueutics. |
 |
Immunostimulatory DNA Sequences by Springer Univ. of California, San Diego. Provides wide and current coverage of topics on the biology and on the applications of immunostimulatory DNA. Chapters include: an introduction, its discovery, mechanisms of immune stimulation by bacterial DNA, activation of NK cell and skin dendritic cells, response of human B lymphocytes to oligodeoxynucleotides, and more. |
 |
Dendritic Cells in Cancer by Michael R. Shurin (Editor), Russell D. Salter (Editor) This work covers all aspects of DC generation, function, survival and antitumor activity in the tumor environment both in vivo and in experimental in vitro systems. The goal in focusing on a spectrum of issues related to DC in cancer is to provide an extensive and expansive review rather than a collection of independent analyses from different authors. Specific topics to be covered include analysis of DC behavior in the tumor microenvironment, including endogenous and exogenous DC, multiple DC populations, molecular pathways responsible for DC dysfunction, tumor-derived factors altering DC polarization and activation, mechanisms of DC alterations, and the role of DC in tumor escape from immune recognition and elimination. Furthermore, additional chapters provide extensive analysis of the... |
 |
Dendritic Cells by Michael T. Lotze (Editor), Angus W. Thomson (Editor) Dendritic Cells, 2nd Edition is the new edition of the extremely successful book published in 1998. With the volume of literature on dendritic cells doubling every year, it is almost impossible to keep up. This book provides the most up-to-date synthesis of the literature, written by the very best authors. It is essential reading for any scientist working in immunology, cell biology, infectious diseases, cancer, transplantation, genetic engineering, or the pharmaceutical/biotechnology industry. * An entirely new section on DC biology is included in this edition. Also new to this edition are chapters on: * Imaging * Interaction of dendritic cells with viruses * Dendritic cells and dendrikines, chemokines and the endothelium * Molecules expressed in dendritic cells *... |
 |
From Innate Immunity to Immunological Memory by Springer The ability to remember an antigenic encounter for several decades, even for a life time, is one of the fundamental properties of the immune system. This phenomenon known as "immunological memory," is the foundation upon which the concept if vaccination rests. Therefore, understanding the mechanisms by which immunological memory is regulated is of paramount importance. Recent advances in immunology, particularly in the field of innate immunity, suggest that the innate immune system plays fundamental roles in influencing immunological memory. Indeed, emerging evidence suggests that events that occur early, within hours if not minutes of pathogen or vaccine entry profoundly shape the quantity, quality and duration of immunological memory. The present volume assembles a collection of essays... |
 |
Handbook of Dendritic Cells: Biology, Diseases and Therapies (3 Volume ) by Manfred B. Lutz (Editor), Nikolaus Romani (Editor), Alexander Steinkasserer (Editor), Ralph M. Steinman (Editor) This is the most comprehensive handbook on dendritic cells, featuring an introduction by Ralph M. Steinman and written by top experts. In three volumes, it covers all aspects from molecular cell biology to clinical applications, highlighting the role of dendritic cells in fighting cancer, virus infections, and autoimmune diseases. The first section on cell biology looks at dendritic cell development, circulating cells, T cell priming, Th1 and Th2 decision and CTL priming. A second part on dendritic cells in disease deals with parasites, bacteria, viruses, autoimmunity, allergies, asthma and cancer. The final section on therapeutic applications includes viral infections and antigen delivery. |
 |
Tumor-Induced Immune Suppression: Mechanisms and Therapeutic Reversal by Springer There is now a pressing need to discuss the already described and newly emerging mechanisms to see how they can be put together in more or less cohesive structure and how they can help to improve immune response to tumors. This monograph will, for the first time, present a comprehensive overview of different mechanisms of immune dysfunction in cancer as well as therapeutic approaches to their correction. It will discuss a number of new mechanisms that have never been discussed in a monograph before: T-cell inhibitory molecules, regulatory tolerogenic DCs, and signaling pathways in antigen-presenting cells involved in T-cell tolerance. |
| © 2009 BrightSurf.com |