Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download DF - Dermatology Foundation
Document related concepts
Hygiene hypothesis wikipedia , lookup
Lymphopoiesis wikipedia , lookup
Molecular mimicry wikipedia , lookup
DNA vaccination wikipedia , lookup
Immune system wikipedia , lookup
Polyclonal B cell response wikipedia , lookup
Adaptive immune system wikipedia , lookup
Immunosuppressive drug wikipedia , lookup
Innate immune system wikipedia , lookup
Psychoneuroimmunology wikipedia , lookup
Transcript
A DERMATOLOGY FOUNDATION PUBLICATION ® SPONSORED BY MEDICIS, THE DERMATOLOGY COMPANY VOL. 24 NO. 4 WINTER 2005/6 DERMATOLOGY FOCUS ™ DF Dendritic Cells With the Right Stuff—The Third Generation Anti-Melanoma Vaccine The Challenge: $5 Million in Annual Research Funds by 2008 2005 Honorary Award Profiles: Paul S. Russell, MD; W. Harrison Turner III, MD Fitzpatrick Legacy Fund Welcomes First Six Members Where Are They Now?— Amy S. Paller, MD, Specialty Leader A fter 15 years of disappointingly modest results produced by the first two generations of therapeutic vaccines for melanoma, a third generation is taking giant steps toward success propelled by seminal advances in our understanding of dendritic cell biology. Key among the pioneers in understanding this professional antigenpresenting cell and applying the results to reconfiguring the anti-cancer vaccine is Pawel Kalinski, MD, PhD, who has been with the Department of Surgery and the Cancer Institute at the University of Pittsburgh Cancer Institute since 2000. His dendritic cell-based vaccine is entering clinical trials for both melanoma and cutaneous T-cell lymphoma, with colorectal cancer, glioma, head and neck cancer, and prostate cancer in the wings. The concept of therapeutic vaccines for cancer rests on powerful logic—outsmarting the cancer’s resilient immuno- suppressive abilities by presenting effective cancer antigens to T cells in a way that guarantees recognition, and then identification and killing of tumor cells. This approach is particularly appealing for challenging cancers like melanoma, which is responsible for most (almost 75%) of the 10,600 skin cancer deaths each year. The problem has been in finding an effective way to accomplish this. As modified versions of the earlier vaccines have typically failed to realize their promise, the frustrating reality of a far greater complexity has emerged. The first published account of a therapeutic vaccine in the U.S.—targeting metastatic melanoma—which appeared in 1990, typifies the pattern. Led by Malcolm S. Mitchell, MD (then at USC, now at Wayne State University’s Karmanos Cancer Institute), this first attempt at what became Melacine combined an allogeneic tumor lysate with an immunostimulant mix. Longrange results have remained extremely modest despite attempts to boost its impact by increasing the pool of allogeneic melanoma peptides and adding additional immune stimulants and/or chemoactive agents. Some combinations have also produced severe toxicity. IL-18 induces lymph node-responsive NK cells. Until recently, vaccine IL-18-conditioned NK cells (yellow), highly responsive to lymph node-associated chemokines, migrate to the T-cell zones (blue) development’s artificial jumpof lymph nodes where they can help to polarize potent DC1s to start of the immune system generate Th1 immune responses. Arrows point to yellow cells has focused on two issues: shown in enlargements. (Reprinted with permission from J Exp Med. 2005;202:p.944.) Also In This Issue (Continued on page 2) Focus on Research How Toll-Like Receptors Orchestrate the Immune Response—Learning Through Leprosy Robert L. Modlin, MD Professor and Chief of Dermatology David Geffen School of Medicine at UCLA M odlin’s interest in the immune system’s response to infection found an intriguing focus during his dermatology residency 25 years ago at the USC Medical Center during his required rota- Robert L. Modlin, MD tion through their Hansen’s Disease Clinic. Because leprosy is a spectral disease— with a clear relationship between the localized tuberculoid and disseminated lepromatous ends of the clinical spectrum and immune success or failure, respectively— “I thought it would be a great model for understanding how our immune system fights infection,” he recalls, “and the cutaneous lesions are easily accessible for observation and study.” Leprosy is characterized by the development of granulomatous or neurotrophic lesions in affected tissues. This disease is encountered in the United States primarily among immigrant populations and within tiny pockets in Texas and Louisiana, but it remains a serious (Continued on page 11) (1) the most effective antigens (those common to all tumors of a given type—and if so, which ones—or autologous antigens from the individual tumor’s repertoire), and (2) the most effective way to deliver them to the T cells and increase T cell numbers. Kalinski, however, has homed in on the earliest steps in initiating the desired immune response. He has identified the essential constellation of key elements for effectively activating cell-mediated immunity, beginning with the right dendritic cell phenotype. Without this, providing tumor antigens and immune system boosters cannot adequately surmount cancer-generated immunosuppression. Kalinski finds this crucial dendritic cell phenotype missing from current vaccine attempts, and he has determined, by a careful sequence of studies, how to coax it into being. “Discovering” the Dendritic Cell Kalinski’s passion for improving the efficacy of anti-cancer vaccines dates to the beginning of his medical studies over 20 years ago, and the dendritic cell soon became his focus for doing this. From the start, his primary concern was finding a way to deal with the minimal posttreatment residue in cancer. “Eliminating the majority of the tumor cells is something that we were already doing quite well,” Kalinski says, “with radiotherapy, chemotherapies, and some forms of immunotherapy. But despite a magnificent response to therapy in the majority of patients, most of them relapse and eventually die. The problem is how to take care of those few persistant remaining cells. To my mind,” he adds, “using the immune system has always made the most sense.” Kalinski studied immunology and immunotherapy at the University of Warsaw, where he did his medical studies, and worked in a transplantation laboratory. He eventually spent seven years at the University of Amsterdam in the laboratory of Martien L. Kapsenberg, PhD (Department of Cell Biology and Histology, Academic Medical Center), which explores the pathways between antigen and immune responsiveness. Kalinski developed a background in contact dermatitis and atopic dermatitis, and has been able to apply many of his observations there to revamping the anticancer vaccine paradigm. Kalinski quickly found dendritic cells intriguing to observe, challenging to understand, and above all, compelling in their logic. As the primary antigen-presenting cells, they are carriers of pathogen-related information within the immune system. They make direct contact with the 2 Kalinski had already shown that pathogen in the peripheral tissue, then priming naive Th cells with IL-12-deficient migrate to the lymph node with the specifDC that have been stimulated by bacterial ic antigen they have incorporated, where lipopolysaccharides (LPS)—which northey mature and are able to prime naive T mally provoke a cell-mediated immune cells (see box on page 7), which then initiresponse—generates a mixed cytokine ate an immune response. “Instead of focusresponse instead. These Th0 cells produce ing our immunotherapeutic efforts on final substantial levels of IL-4 and IL-5, and effector cells of the immune response,” also IFN-. Then he demonstrated that Kalinski explains, “I thought we could even partially inhibiting the DC’s IL-12influence immune responsiveness much producing capability—by exposure to more comprehensively by targeting the the immunosuppressive factor PGE2 (the cells that first initiate the train of events.” inflammatory mediator prostaglandin E2) This meant learning the precise steps by before LPS stimulawhich dendritic cells tion—skews priming produce immunoreto Th2 cells. Adding sponsive T cells, and exogenous IL-12 overthen determining ruled this Th2-driving how to ensure that behavior. Pretreating a vaccine recapituDC with glucocorlates these steps ticoids—immunowhen tumor antisuppressives whose gens are made availimpact on DC wasn’t able. Then the effecyet well defined— tor end of the induced Th2 cells process would simPawel Kalinski, MD, PhD producing high levels ply do its job. of IL-5 and the anti-inflammatory/immunoKalinski began to study interactions suppressive cytokine IL-10. Again, the between dendritic cells and lymphocytes pattern reverted to Th1 when IL-12 was and the differentiation of naive helper T supplied from the outside. Pre-exposure cells into the Th1 phenotype (which actiof DCs to the immunosuppressive cytokine vates cellular immunity) and Th2 phenotye IL-10 simply stopped these antigen(which suppresses Th1 activity and initipresenting cells in their tracks, and they ates the humoral immune response), and never matured. progressed to the interactions of dendritic Looking at the normal time course of cells with cytotoxic effectors—natural killer the DC’s IL-12-production while in the (NK) cells and CD8+ T cells. lymph node, Kalinski saw that the initial The Dendritic Cell and IL-12 robust output during their first several Kapsenberg’s lab had already estabhours of interacting with T cells diminishlished the fact that dendritic cells (DC) in es as they mature because the DC loses its humans—once they are stimulated by a ability to respond to IFN-. He had also pathogen—are responsible for the differenseen that mature DCs are impervious to tiation of naive T cells into Th1 or Th2 cells PGE2 and glucocorticoid influence. This (see box on page 7). DC production of ILunderlined the need for influencing DC 12 was known to participate in inducing behavior, and thus Th cell phenotype, the Th1 phenotype. Normally, pathogenvery early in its history. activated DCs transiently increase the The Plastic Dendritic Cell—The intensity of their antigen uptake and begin Third Signal and Polarization moving toward draining lymph nodes, up-regulating their expression of co-stimuA critical early insight for Kalinski and latory molecules that will allow them to his co-workers was their realization “that interact with naive Th cells there. As DCs there are different dendritic cell phenoevolve from antigen-trapping to mature types. Although they all arise from the immunostimulatory cells in the lymph same basic pool of immature cells, a DC node, they begin producing IL-12 when (1) will perform different functions depending the DC’s CD40 receptor binds with its on both its stage of activation and which T-cell–carried ligand, and (2) the type 1 pathogens and cytokines or cells have acticytokine IFN- is also present. Then the vated it (see table on page 3).” The phenostrong IL-12 presence becomes a potent type that evolves under these influences stimulant for IFN- production by the determines what that dendritic cell can Th cell, hallmark of the Th1 phenotype. and cannot do. This fundamental discovThe mature T cell migrates from lymph ery has been the springboard for Kalinski’s node to tissue to encounter the pathogen. subsequent research. Dermatology Foundation Until this realization, which he published in 1999, the conventional wisdom had regarded all myeloid dendritic cells (the most common type) as capable of inducing Th1 responses, with other types of antigenpresenting cells responsible for induction of Th2 responses. Integrating his research and observations from other labs had made it clear to him that Th1 cells—and thus a cellmediated immune response—can indeed be launched by myeloid DCs, but only by those that have differentiated to an IL-12–producing phenotype. And DCs that have differentiated to an IL-12–poor phenotype will push the naive T cell to a Th2 phenotype. Kalinski used the term polarization to describe the differentiation/maturation process from naive to distinctive phenotype. Once immature sentinel DCs in the peripheral tissue acquire antigen and migrate to the lymph node, they are polarized by IFN- to DC1, or by PGE2 to DC2. Naive Th cells in the lymph node that interact with DC1 are polarized to Th1, and those interacting with DC2 are polarized to Th2. This phenomenon of polarization led Kalinski to his concept of the third signal received by naive Th cells in the lymph node. The first signal—via the antigen—provides information about the pathogen and triggers the T-cell receptor. The second signal—enabling activation—occurs through co-stimulatory molecules. The third signal induces polarization. The primary third signal source for Th1 cells is the cytokine IL-12. The factors that affect the ability of DCs to deliver this third signal are those that modulate IL-12 production, including those that diminish it: PGE2, IL-10, corticosteroids, and interferons. Kalinski explains that “the conditions of DC maturation basically ‘tell’ the DC what to do. Because DCs have a memory— very much as T and B cells do—they are able to ‘teach’ the naive T cells what to do.” This polarization, as it determines the nature of the immune response, became the centerpiece of Kalinski’s revised approach to anti-cancer vaccines. IL-12—All or Nothing Today’s gold standard for DC-based cancer vaccines includes PGE2 in the cytokine cocktail (added to TNF-, IL-1, and IL-6) used to expand and produce mature DCs for current anti-cancer vaccination protocols. One favorable study reported that it synergizes with TNF- to induce production of the IL-12p40 subunit in DCs. Because Kalinski was very familiar with the opposite roles played by the complete IL-12 cytokine and its p40 subunit, he looked carefully to determine whether PGE2-driven stimulation of the p40 subunit is accompanied by transcription of the gene for the p35 component, and by secretion of bioactive IL-12p70. His results—published four years ago— indicated that PGE2’s up-regulation of IL12p40 is an end result. There is no progression to form the complete bioactive protein. An even greater indictment was confirmation that PGE2 actually suppresses production of IL-12p70 that would otherwise be induced by the pathogenassociated LPS, or by binding with the naive Th cell’s CD40L molecule. This agrees with the Th2-promoting activity of PGE2 that Kalinski and others had documented, and argues against any use of this inflammatory mediator in therapeutic vaccines that rely on Th1 activity. In the interests of improved anti-cancer therapy, Kalinski wanted to see if he could stimulate production of the complete IL-12 cytokine and transform Th2 cells into a Th1 population—and thus into effector cells protecting against intracellular infections and cancer. He separated cultured human Th2 cells into several groups, restimulating them under different conditions. Interacting with B cells simply preserved the polarized Th2 phenotype, but DC1s vs Immature DCs and adding exogenous ILStandard (Nonpolarized) Mature DCs 12p70 to this mix shiftStandard ed them to Th1 cells. Immature Mature Polarized Unexpectedly, restimExpression of ulating with already co-stimulatory molecules low high high mature DC1 cells also IL-12–producing capacity low/high* low high reversed their phenoResistance to inhibition low high high type from Th2 to Th1 Migratory responsiveness to cells. Kalinski comlymph node signals absent/low high high ments on the inherent Th1/CTL-inducing function low high very high flexibility of Th2 cells, CTL: cytotoxic T lymphocyte; DC: dendritic cell; DC1: cytokine-matured and NK-matured; pointing out that use NK: natural killer cell; Th: T helper. *Immature DCs can produce high IL-12 levels with the presence of proper co-stimulatory of the appropriate factors and absence of IL-12–suppressive factors. (Revised from Table 1 in P. Kalinski et al. Expert Opin Biol Ther., 2005;5, p.3; reprinted antigen-presenting with permission.) cell after priming can www.dermatologyfoundation.org DF DERMATOLOGY FOCUS A PUBLICATION OF THE DERMATOLOGY FOUNDATION Sponsored by Medicis, The Dermatology Company ® Editors-in-Chief David J. Leffell, MD Professor of Dermatology Yale School of Medicine, New Haven, CT Christina Herrick, MD, PhD Asst Professor of Dermatology Yale School of Medicine, New Haven, CT Executive Director Sandra Rahn Benz Communications Manager Susan K. Schaefer Please address correspondence to: David J. Leffell, MD & Christina Herrick, MD Editors, Dermatology Focus c/o The Dermatology Foundation 1560 Sherman Avenue Evanston, Illinois 60201 Tel: 847-328-2256 Fax: 847-328-0509 e-mail: [email protected] Published for the Dermatology Foundation by Robert Goetz Designer, Production Sheila Sperber Haas, PhD Managing Editor, Writer This issue of Dermatology Focus is distributed without charge through an educational grant from Medicis, The Dermatology Company®. The opinions expressed in this publication do not necessarily reflect those of the Dermatology Foundation or Medicis, The Dermatology Company®. © Copyright 2006 by the Dermatology Foundation repolarize the immune response, “suggesting additional possibilities for the therapeutic induction of Th1 responses.” CD8+ T Cells and NK Cells— Novel Collaborators in Promoting Type 1 DC CD8+ T cells and NK cells are generally regarded only as effector cells. CD8+ T cells, a compartment of cellular immunity, attack intracellular pathogens. NK cells belong to the innate immune system and are known for their ability to kill transformed or infected cells. Kalinski had begun to make other associations that pointed in a new direction. Once he had identified the critical role of IFN- in the maturation of IL-12–producing DC, he made a connection with NK production of IFN- during infections and with the potential of CD8+ T cells to produce it. Contact (Continued on page 7) 3 DF Holding Focus $5 Million in Annual Research Awards Allocation By 2008 In 2003, the Dermatology Foundation challenged the specialty to join in working toward more adequately funding dermatologic research through allocations of $5 million per year. Since that time, allocations have grown from $2.7 million in “The DF has 2003 to $3.5 million in 2005. This $800,000 growth always been about people, and the future. is greatly attributed to the increased membership The Foundation invests support of dermatologists and other individuals in your contributions in the emerging leaders the dermatologic community. Research Awards Program “Dermatology has become such a dynamic specialty that we must be prepared to meet future needs we cannot yet envision.” Increasing Resources throughout medical and surgical dermatology— the people whose careers will continue to improve patient care.” $5 Million/Yr. Bruce U. Wintroub, MD, DF President $3.5 Million/Yr. Current Future On the following pages, we recognize dermatologists who have made new leadership commitments to more fully expand DF funding of research and ensure dermatology’s future. To increase your own participation, contact the Dermatology Foundation by calling (847) 328-2256 or go to the membership page at www.dermatologyfoundation.org DF Shaping the Future of Dermatology 4 Dermatology Foundation Individual Giving Continues to Grow in Support of Stronger Future for Dermatology F I T Z PAT R I C K DF Six Rise to the Top in Personal Financial Commitment Through Fitzpatrick Legacy Fund Each making a commitment of $100,000, members of the Fitzpatrick Legacy Fund personally commit LEGACY FUND to adequate funding for research in dermatology. They will lead the way to an annual DF research award allocation of $5 million within the next three years. The Board of Trustees thanks each of the current members below for their generous support. Fitzpatrick Legacy Fund pledges of $100,000 can be paid in minimum annual payments of $20,000 over as many as five years. Contributions may be made by cash, credit card, or gifts of appreciated stock either annually or on a quarterly basis throughout the year. Anonymous Donor James J. Leyden, MD Jonah Shacknai Charles W. Stiefel Eugene J. Van Scott, MD Ruey J. Yu, PhD, OMD Annenberg Circle Membership Continues to Climb Dermatologists and other individuals concerned about dermatology’s future emerge each year as leaders in the specialty through membership in the Annenberg Circle. Now more than 300 members, the Annenberg Circle has been the backbone of individual giving's growth at the Dermatology Foundation over the past few years. Young Leaders (those joining the Annenberg Circle or the Leaders Society during the first five years out of residency) are in BOLD. Annenberg Circle members receive credit for as much as $10,000 in past Leaders Society giving toward their $25,000 pledges. Membership pledge payments may be made annually or quarterly in the form of cash, credit card charges, or gifts of appreciated stock. (As of December 13, 2005) Susan K. Ailor, MD Matthew D. Barrows, MD David E. Biro, MD Jean L. Bolognia, MD Karen E. Burke, MD, PhD Jennifer C. Cather, MD S. Wright Caughman, MD Mark G. Cleveland, MD, PhD David N. Flieger, MD Michael J. Franzblau, MD www.dermatologyfoundation.org Maria C. Garzon, MD Lillian R. Graf, MD James J. Herrmann, MD Nathan R. Howe, MD, PhD Stuart I. Jacobs, MD Arnold W. Klein, MD Stephen B. Levitt, MD Jennifer M. McNiff, MD John C. Moad, MD Marcy Neuburg, MD Peter B. Odland, MD, PS Desiree Ratner, MD Alain H. Rook, MD William S. Sawchuk, MD John J. Schmidt, MD Joseph J. Shaffer, MD David A. Spott, MD Paul A. Storrs, MD James L. Troy, MD W. Harrison Turner III, MD Patrick Walsh, MD Scott Zahner, MD 5 New Leaders Society Members Respond to Call for Leadership Support NEW YORK Making leadership gifts of $1,500 or more, over 200 dermatologists and other individuals concerned about adequate funding for dermatologic research have added their names to the Leaders Society Roster in 2005. Among them are Young Leaders, dermatologists joining the Leaders Society within five years of finishing residency (denoted in the list in Bold type). As of December 13, 2005 ALABAMA Robert E. Jones, MD Steve L. Mackey, MD Donald F. Thompson, MD CALIFORNIA Marina A. Ball, MD Frederick Beddingfield III, MD Ralph T. Behling, MD Eileen Crowley, MD, PhD Linda M. Globerman, MD Timothy M. Jochen, MD Derek H. Jones, MD Suzanne L. Kilmer, MD Isaac Neuhaus, MD Ronald E. Reece, MD Karen R. Simpson, MD Gaetano Zanelli, MD COLORADO David L. Hurt, MD Brett K. Matheson, MD CONNECTICUT Ronald S. Jurzyk, MD DISTRICT OF COLUMBIA Beverly A. Johnson, MD FLORIDA Joseph A. Arena, MD Monica K. Bedi, MD Kenneth R. Beer, MD Lisa M. Castellano-Howard, MD James B. Connors, MD Garry B. Gewirtzman, MD Richard S. Greene, MD Michael S. Henner, MD Stephen N. Horwitz, MD Kathleen W. Judge, MD J. Matthew Knight, MD Ronald C. Knipe, MD Adele A. Moreland, MD Mark S. Nestor, MD, PhD Layne D. Nisenbaum, DO Jeffrey D. Parks, MD Harold S. Rabinovitz, MD Marta I. Rendon, MD Richard M. Rubenstein, MD Stanley V. Schwartz, MD 6 Joseph F. Seber, MD David M. Sharaf, MD Sharon Stokes, MD Thomas J. Sultenfuss, MD Jennifer L. Vesper, MD Joel M. Wilentz, MD Daniel J. Wolf, MD GEORGIA Linda M. Benedict, MD Leslie C. Gray, MD John D. Kayal, MD Candance K. Kimbrough-Green, MD David B. Pharis, MD Kevin L. Smith, MD Nhu-Linh T. Tran, MD Stewart E. Wiegand, MD HAWAII Wayne H. Fujita, MD IOWA Richard K. Scupham, MD, PhD ILLINOIS Wayne J. Blaszak, MD James B. Grossweiner, MD Nancy C. Lichon, MD Vladimir V. Panine, MD Melanie Zahner, MD INDIANA Robert H. Huff, MD Brian J. Williams, MD KANSAS Joseph E. Gadzia, MD Matthew P. Shaffer, MD MASSACHUSETTS Marie-France Demierre, MD Kay S. Kane, MD Stephen O. Kovacs, MD Brian W. Lester, MD Paul Nghiem, MD, PhD Thomas E. Rohrer, MD Valori D. Treloar, MD MARYLAND Elizabeth M. Burke, MD Anthony A. Gaspari, MD Grace F. Kao, MD Margaret A. Weiss, MD MICHIGAN Richard J. Ashack, MD Karen L. Chapel, MD Linda C. Chung-Honet, MD Michael A. Dorman, MD S.L. Husain Hamzavi, MD Martin E. Tessler, MD Thomas P. Waldinger, MD William F. Weston, MD Yuelin Xu, MD Mary Yurko, MD, PhD MINNESOTA Michael J. Ebertz, MD MISSOURI Darrell Griffin, MD MONTANA Charles T. Burton, MD Gail A. Kleman, MD NORTH CAROLINA KENTUCKY Sue Ellen Cox, MD Marvin E. Bishop, MD W. Dean Henrichs, MD John L. Buker, MD James B. Patterson, MD Laurie G. Rendleman Massa, MD Elizabeth Faircloth Rostan, MD Michael W. McCall, MD David S. Rubenstein, MD, PhD Mark J. Zalla, MD Jon C. Ter Poorten, MD Val Pierre Vallat, MD LOUISIANA NEW JERSEY John B. Brantley, MD Laurie H. Harrington, MD Deborah C. Hilton, MD Sharon S. Meyer, MD Maureen A. Olivier, MD William F. Cosulich, MD Sharon A. Galvin, MD Melvin S. Gruber, MD Jerry Rothenberg, MD Marc R. Avram, MD Rena S. Brand, MD Michael S. Cohen, MD David Cooper, MD, PhD Daniel R. Foitl, MD Paul J. Frank, MD Francesca J. Fusco, MD Edward R. Heilman, MD Rosemarie Ingleton, MD Eileen K. Lambroza, MD Vicki J. Levine, MD Cynthia A. Loomis, MD, PhD Julian M. Mackay-Wiggan, MD Timothy D. Mattison, MD Janet A. Moy, MD Laurie J. Polis, MD Jeffrey M. Weinberg, MD Michael B. Whitlow, MD, PhD Gladys H. Telang, MD Caroline S. Wilkel, MD SOUTH CAROLINA Marguerite A. Germain, MD SOUTH DAKOTA Lycia A. Scott, MD TENNESSEE Robert L. Jackson, MD Julie M. Pena, MD Raymond J. Wesley, MD TEXAS Kent S. Aftergut, MD Mary E. Archer, MD Angela G. Bowers, MD Michael W. Braden, MD Vivian W. Bucay, MD David F. Butler, MD Holly H. Clark, MD OHIO Lucius P. Cook, MD Neera Agarwal-Antal, MD Steven A. Davis, MD G. Scott Drew, DO Kevin J. Flynn, MD Bruce P. Guido, MD Aubrey C. Hartmann, MD Curtis W. Hawkins, MD Richard H. Hope, MD Paul G. Hazen, MD Leslie S. Ledbetter, MD Samir B. Patel, MD Lester F. Libow, MD Patrick L. Shannon, MD Carolyn B. Lyde, MD Judith J. Walker, MD Denise W. Metry, MD Melinda J. Woofter, MD Jerold D. Michaelson, MD OKLAHOMA Stephen Miller, MD Gregory A. Nikolaidis, MD Mark D. Lehman, MD Robert L. Ochs, MD OREGON Brent R. Paulger, MD Jay Y. Park, MD F. Charles Petr, Jr, MD Curtis T. Thompson, MD Howard A. Rubin, MD Dale G. Schaefer, MD PENNSYLVANIA Michael H. Simpson, MD Ercem S. Atillasoy, MD Lori D. Stetler, MD Robert Bitterman Premalatha Vindhya, MD Jacqueline M. Junkins-Hopkins, MD Mark B. Weinstein, MD Michael S. Lehrer, MD Renee J. Mathur, MD UTAH Regis W. McHugh, MD John S. Blake, MD Andrew K. Pollack, MD Douglass W. Forsha, MD Stephen M. Purcell, DO VIRGINIA Michael S. Rabkin, MD Hilary L. Reich, MD Howard D. Rosenman, MD John T. Seykora, MD, PhD Marion M. Vujevich, MD Richard D. Wortzel, MD, PhD RHODE ISLAND Michael A. Bharier, MD M. Kathleen Carney-Godley, MD Vincent Falanga, MD Nomate Kpea, DO Thomas P. Long, MD Charles J. McDonald, MD Jennie J. Muglia, MD Moses Albert, MD Allison K. Divers, MD Lawrence J. Finkel, MD VERMONT Daniel P. McCauliffe, MD WASHINGTON Daniel B. Dietzman, MD WISCONSIN Bradley T. Straka, MD U.S. MILITARY Keira Barr, MD Dermatology Foundation dermatitis, involving a Th1 response, has a substantial CD8+ cell infiltrate. Kalinski also knew that atopic dermatitis—a Th2 pathology—involves no CD8+ T cells and NK cells only minimally, and some patients have a deficit in NK cell function. In general, most Th1-predominant pathologies involve CD8+ T cells and/or NK cells. They are either absent in a Th2 pattern, or they suppress it. Integrating these facts with observations from other labs led him to suspect an unacknowledged helper role for these cells—that they interact with DC, with Th cells, and with each other to help polarize DC1 cells and establish a Th1 immune response. If so, this would expand the useful tools available for constructing an effective cancer vaccine. Kalinski’s research group carried out a series of experiments to test his hypothesis. To observe CD8+ T cells, they harvested and cultured immature DCs, stimulating (pre-activating) some of them overnight with TNF-. They co-cultured various cell combinations that included: pre-activated DCs and naive Th cells with or without naive CD8+ T cells, with or without various cytokine stimulants, with or without various antigens. Some were transwell experiments, in which a small-pore membrane separates the different cell populations but permits their expressed cytokines to cross through. Kalinski’s team was able to show that naive CD8+ T cells—unlike naive Th cells—are able to produce IFN- at the earliest points in their priming. Their unique ability to produce this necessary co-factor for inducing DCs to express bioactive IL-12 when interacting with naive Th cells means that—when appropriate antigenic peptides are present—the two types of T cells synergize in enhancing this IL-12 production, and thus in promoting primary Th1 responses. These observations confirmed Kalinski’s suspicion of a novel helper role for CD8+ T cells, which he believed “may have implications for the design of vaccination strategies against melanoma and for optimizing the character of DC-induced anti-tumor responses.” Studying NK cells for a possible helper role involved various combinations of young DC, naive NK (some pre-activated via IL-2), NK target cells (the leukemia cell line K562), naive Th cells, CD8+ T cells, Epstein-Barr viral antigen, and cytokine stimulants that included IL-2, IL-18, and IFN-. Kalinski learned that NK cell production of IFN- requires the simultaneous activation by a target cell and the presence of IFN-. He also learned that these IFN-–producing NK cells do not destroy DC, but instead they single-handedly initiate their maturation as DC1 that robustly produce the full bioactive IL-12. These NKmatured DC are subsequently able to polarize www.dermatologyfoundation.org The ABCs of Immunoresponsiveness I L-12—a heterodimer combining the two subunits termed p35 and p40, and referred to as IL-12p70—is expressed primarily by antigenpresenting cells. Production of the complete molecule requires two signals—stimulation from naive T cells carrying the molecule CD40L (L stands for ligand, as it binds with the CD40 molecule) and the concomitant presence of either IFN- or such pathogen-derived factors as LPS. The IL-12p70 heterodimer (as opposed to just its subunit) is critical for propagating Th1 immune responses and cell-mediated immunity, and it stimulates NK cells and CD8+ T cells (also called cytotoxic T lymphocytes, or CTLs). In contrast, the p40 subunit—either in monomeric form or as a p40–p40 homodimer—is inactive (the homodimer) or antagonistic to the IL-12 receptor and cell-mediated immunity. It correlates with enhanced production of Th2-driving factors that include the classic immunosuppressants IL-10 and PGE2. Kalinski prefers to call this molecule IL-12RA (IL-12 receptor antagonist) instead of IL-12p40. IL-12RA overproduction has been documented in several tumor models and in chronic inflammatory states, and as an early event in UV-induced immunosuppression. The presence of IL-12p70, then, is essential in ensuring an effective anti-cancer vaccine, and IL-12RA should be avoided. Priming is the process by which antigen-specific T cells evolve from their naive state—before they have ever experienced antigen—to the point at which they are ready for action. “For antigen-specific T cells, priming is the most important decision—or moment,” Kalinski says. The naive T cell travels to its respective lymph node, remaining there until it encounters an antigen-carrying DC. The T cell–DC interaction enables it to proliferate, clonally expand, and then acquire its effector abilities. This includes expression of the specific chemokine receptors that now enable it to leave its lymph node and respond to come-hither signals from inflamed tissue. In the tissue, after the effector phase of the immune response most of the T cells die, and those remaining persist as memory cells. Th1—T helper cells (also referred to as CD4+ T cells) with a type 1 phenotype. They are induced by the bioactive form of the cytokine IL-12, and then induce cell-mediated immunity once they leave the lymph node by activating cytotoxic and phagocytic functions in effector cells (CTLs, NK cells, macrophages). Th2—T helper cells (also referred to as CD4+ T cells) with a type 2 phenotype. They are induced in the absence of IL-12p70, and then induce humoral immunity—producing cytokines that support B-cell production of antigen-specific antibodies—while also actively suppressing the induction of Th1 cells. naive Th cells to Th1 cells and induce antigenspecific, IFN-–producing CD8+ T cells, even when the NK–DC interaction occurs before the DC migrate to the lymph nodes. Kalinski applies this lesson to understanding the poor effectiveness of spontaneous immune responses against cancer. “During an early phase of tumor growth, NK cells can naturally contribute to the elimination of transformed tumor cells,” he says, “but due to the absence of a second, eg, IFN-– dependent, signal, the NK cells are not induced to exert any ‘helper’ activity. Thus they do not activate or polarize local DC and so cannot support the development of tumorspecific type 1 immunity, which results in the eventual loss of control over tumor growth.” Integrating these observations, Kalinski speaks of the positive feedback loop—involving CD8+ T cells, NK cells, and Th1 cells—promoting type 1 immunity (see illustration on page 9). “The most important implication here is that the appropriate polarization of Th1 responses can occur independently of any ‘correct’ recognition of the character of the pathogen,” he points out. Looking ahead to the impact of this new awareness on redesigning the cancer vaccine, Kalinski explained at the time that “the current observations suggest that increasing the availability of IFN- at the tumor site, promoting the interactions of vaccine-carrying DC with NK cells, and/or (Continued on page 9) 7 “The DF identifies, encourages, and supports dermatologic researchers who seek to fulfill their professional dreams.” A recent past president Dr. Mandy teaches at the “The Dermatology of the American Society of University of Miami and has a Foundation has the Dermatologic Surgery (ASDS), private practice with offices in infrastructure and years Dr. Mandy was delighted when, Miami and Miami Beach. “It is of experience in funding in 2002, the Dermatology difficult to quantify the impact research awards,” said Foundation established the of the DF on those of us in Stephen H. Mandy, MD, career development award private practice, as much a dermatologic surgeon (CDA) in dermatologic surgery. of what we do every day is based in southern Florida. as a result of DF The CDAs “We need to build on this funding. Clinical in dermatologic success and be careful practitioners do surgery provide not to diffuse this good appreciate the researchers work through duplication work of our col$55,000 per of effort in the specialty.” leagues in the year for up to academic arena.” three years to research projects In keeping up that will further with the advances the practice of being made in the dermatologic field, Dr. Mandy surgery, and cites the value of Stephen H. Mandy, MD develop the DF publications to teaching, research, and leadprivate practitioners. “Progress ership careers of dermatologic in Dermatology alone is worth surgeons. the price of membership with the DF,” he said. Since 2002, the DF has contributed $1 million in funding for dermatologic “It is difficult to quantify the impact surgery research and is of the DF on those of us in private committed to increasing practice, as much of what we do this funding to $2 million every day is as a result of DF funding.” in the near future. For Dr. Mandy, he said he The Dermatology can’t imagine a wiser investFoundation supports advances ment for dermatologists and across the specialty by helping corporations than the DF’s to fund research and the Research Awards Program. advancement of dermatologic “DF funding serves as a researchers not yet eligible to ‘bootstrap’ to young dermaapply for federal funding. tologists choosing to go into research. It benefits us all.” “Young researchers need to be encouraged to ‘pursue their art,’” Dr. Mandy stressed. Dermatologic Surgeon Encourages Peers to Join DF 8 Dermatology Foundation using activated NK cells or their soluble products to modulate DC ex vivo before their use as a vaccine may constitute effective strategies in the immunotherapy of cancer patients.” Final Pieces After Kalinski arrived at the University of Pittsburgh from Amsterdam, one of his first efforts was the successful culture of effective type 1 DC in a serum-free environment, in preparation for clinical testing of a DC-based cancer vaccine. It had been a highly frustrating 3-year search for the right formula, which ultimately combined IL-1, TNF-, IFN-, IFN-, and the synthetic double-stranded RNA polyinosinic:polycytidylic acid (p-I:C), an agonist of Toll-like receptor 3 that induces the production of several interferons. Kalinski terms the result DC1s. For ability to activate and expand melanoma-specific CD8+ T cells in vitro, this newest mature DC population dramatically outperforms DC that represent the current gold standard in DC-based cancer vaccines—DC matured with PGE2 instead of IFN-. As Kalinski has demonstrated, the immune response induced by PGE2-matured DC does not involve the cellular behavior required against a tumor. As part of this series of experiments, Kalinski compared two groups of CD8+ T cells after their sensitization to three melanoma-associated antigens: MART-1, gp100, and tyrosinase. One group of CD8+ T cells was sensitized via his DC1s, the other by the current PGE2matured DC. Just a single round of exposure to his DC1s induced up to 40-fold more long-lived antigen-specific CD8+ T cells (see graph below). In addition to this highly effective induction of large numbers of functional cytotoxic T cells, Kalinski has preliminary data indicating their ability to enter the tumor and kill it. Number of Ag-specific cells/1x105 CD8+ T cells 600 1000 Total Responses Positive feedback between NK cells and DC1s. Activated NK cells induce activation of DC1s and promote their ability to produce the cytokines that drive a Th1 immune response. These DC1s also produce additional factors that enhance NK cell functions. Their successful cooperation can be supported further by cytokines produced by other cells. (MDC: myeloid DC; PDC: plasmacytoid DC; IPC: interferon-producing cell.) (Reprinted with permission from Expert Opin Biol Ther. 2005;5:p.5.) Despite the indications that TNF- and IFN- are key mediators of the DC activating and polarizing activity of NK cells, Kalinski is convinced that additional factors are likely to be involved. So he continues to search. Most recently, he and his research team have discovered the value of IL-18, which provides the perfect influence for ensuring NK cells that commit to a life of helping rather than killing, and display high migratory responsiveness to lymph nodeassociated chemokines (see photos on cover). They produce substantial amounts of IFN- when they are exposed to DC- or Th-related signals, and show a potent ability to promote IL-12p70 production by DCs and the consequent development of Th1 immune responses (see graphs on page 10). IL-18 is the sole NK-activating factor able to achieve this, and—logically—it is blocked by PGE2. Mart-1 (27-35) gp100 (154-162) gp100 (209-217) Tyrosinase (368-376) 500 300 0 0 sDC sDC DC1 DC1 DC1 superior melanoma response. DC1 sensitizes far more CD8+ T-cells against melanoma antigens than the current “gold standard” DC (sDC), seen in representative results for a patient with stage IV disease. Inset: total number of melanoma antigen-specific CD8+ T cells. (Reprinted with permission from Cancer Res. 2004;64:p.5936.) www.dermatologyfoundation.org The Third Generation DC-Based Vaccine: DC1s for Melanoma, CTCL The first generation of melanoma vaccines had focused on providing melanoma antigens, or signal one. The next generation of vaccines took into account the importance of appropriate co-stimulation as the necessary second signal in achieving vaccine efficacy. And now the third generation is designed to include the essential signal three, using DCs tailored to launch an effective anti-tumor response characterized not only by its high magnitude—but also by its optimal cancer-fighting character. Kalinski works closely with the groups led by John Kirkwood, MD, a pioneer in the clinical application of interferons and the current head of the UPCI Melanoma Center, and by Louis Falo, MD, PhD, chair of the University of Pittsburgh Department of Dermatology, who has long been committed to developing an effective melanoma vaccine (see 1997; Vol. 15, No. 4). In addition to organizing a trial of Kalinski’s DC1-based vaccine for CTCL patients, Falo recently used the B16 melanoma mouse model for testing this vaccine’s initial efficacy. He chose the B16 model “because it is a formidable model tumor for evaluating immunotherapeutic strategies due to its multiple well-established mechanisms of tolerance induction and immune evasion. It models the most challenging tumor escape mechanisms thus far described for a variety of human tumors,” Falo observes. It down-regulates MHC class I molecules and antigenprocessing machinery; produces vascular endothelial growth factor that inhibits DC function and T-cell immunity; and produces galectin-1, a negative regulator of T-cell activation and survival. Regulatory T cells contribute their own inhibition of effective CD8+ T-cell responses. Falo’s team injected DC1s loaded with B16 melanoma cells into these tumorbearing mice. And despite the resident tumor’s immune challenges, the DC1s induced Th1-skewed tumor-specific cells and achieved a significant reduction in tumor growth. The anti-tumor immune response was characterized by tumor9 Secondary Stimuli No Stimuli NK Cell Treatment Control << IL-18 << 0 IFN- IL-2 IL-12 << 1 2 0 2.5 6 << 0 5 10 0 10 20 IFN- (ng/ml) Secondary Stimuli No Stimuli NK Cell Treatment Control << IL-18 << IL-18+PGE2 (early) << IL-18+PGE2 (late) << 0 IFN- IL-2 << 1 2 0 IL-12 << 2 4 0 << 1 2 0 5 10 IFN- (ng/ml) IL-18–primed helper NK cells. NK cells treated with IL-18 for 24 h produce high levels of Th1-supportive IFN- on contact with secondary stimuli IL-2, IFN-, IL-12 (top). IL-18 for 48 h is negated by the simultaneous presence of Th2-driving PGE2 but unaffected when PGE2 is added at 24 h, reflecting the stability of the initial exposure (bottom). (Reprinted with permission from J Exp Med. 2005;202:p.946.) specific IFN-–producing T cells and “brisk tumor infiltrates containing Th1 cells and macrophages,” Falo says. In addition to confirming the ability of these polarizing antigen-presenting cells to overcome the the B16 melanoma’s profound immune inhibition, this successful murine model of ex vivo engineered DC1s now provides a needed model for aiding continued vaccine progress. Kalinski and Kirkwood are about to begin the first of their melanoma trials in January 2006. This initial trial will involve 28 patients with advanced melanoma. Kalinski’s total funding will ultimately allow the treatment of 93 patients—70 with melanoma and 23 with colorectal cancer— and a protocol for prostate cancer is in the design stage. Falo’s group is beginning a formal trial of this vaccine in advanced CTCL patients following preliminary observations of highly encouraging results. These initial trials all center around the DC1, but a clinical trial using NK-induced DC1s is planned for the spring of 2006. Kalinski is also working on a way to induce DC1 in vivo. “We have some very strong mouse data showing that with our current manipulation of DCs in vivo, we induce cells with similar functions that dramatically enhance the rate of tumor rejection.” He adds his hope that “very soon we will be translating this observation into clinical trials.” In the trials getting underway now, one phenomenon that Kalinski is hoping 10 to observe is epitope spreading. This involves an expansion, by natural processes, of the tumor antigens initially used by the DC1 cells in the vaccination. He explains that tumor cells killed by the vaccine-induced immune attack will release all of their antigenic material, including highly immunogenic tumor antigens that had not been part of the vaccine. DCs are particularly good at picking up antigens from dead cells. If epitope spreading occurs, then immune effector cells will be primed for these additional antigens. Kalinski says that “based on the data from Dr. Falo’s initial patients, we expect that this will take place.” Primarily, he will be looking for solid evidence that his third generation vaccine will successfully overcome the formidable resistance that melanoma mounts to inhibit immune cells or render them highly dysfunctional. “By removing the dendritic cells from the context of melanoma, and culturing them and then instructing them what to do ex vivo, we hope to bypass this immune dysfunction by allowing them to develop into fully potent immunostimulatory cells free of the melanoma-enriched environment,” Kalinski comments. “We hope that when we inject them into patients, they will be able to enter the lymph node, and then do the job that naturally occurring DCs are unable to do.” Call For Patients Kalinski, Falo, Kirkwood, and their co-workers would welcome patients in their melanoma and CTCL trials who come from outside their institution. The more rapidly they assemble their patient rosters, the more rapidly they will be able to assess the efficacy of this third generation cancer vaccine. Interested dermatologists can contact Pawel Kalinski at [email protected], and Louis Falo at [email protected]. Suggested Readings Kalinski P, Hilkens CMU, Wierenga EA, et al. “T-cell priming by type 1 and type 2 polarized dendritic cells: The concept of a third signal.” Immunol Today. 1999;20:561–7. Kalinski P, Vieira PL, Schuitemaker JHN, et al. “Prostaglandin E2 is a selective inducer of interleukin-12 p40 (IL-12p40) production and an inhibitor of bioactive IL12p70 heterodimer.” Blood. 2001;97:3466–9. Mailliard RB, Egawa S, Cai Q, et al. “Complementary dendritic cell-activating function of CD8+ and CD4+ T cells: Helper role of CD8+ T cells in the development of T helper type 1 responses.” J Exp Med. 2002;195:473–83. Kalinski P, Giermasz A, Nakamura Y, et al. “Helper role of NK cells during the induction of anticancer responses by dendritic cells.” Mol Immunol. 2005;42:535–9. Hokey DA, Larregina AT, Erdos G, et al. “Tumor cell loaded type 1 polarized dendritic cells induce Th1-mediated tumor immunity.” Cancer Res. 2005; 65:10059–67. ■ Dermatology Foundation Focus on Research (Continued from cover) health problem just south of us, in Mexico. Tuberculoid patients (T-lep)—with a relatively successful immune response that keeps their infection under control— lie at one end of the clinical spectrum. Their few cutaneous lesions contain the rare presence of Mycobacterium leprae, and evaluation shows them able to mount a strong cell-mediated immune response to this organism. Lepromatous patients (L-lep) are at the other end, with an ineffective immune response and rampant infection. Disseminated skin lesions contain large numbers of bacilli. Their immune response is mediated primarily through humoral pathways, and their T cells are selectively unresponsive to M. leprae. Modlin’s earlier explorations of these contrasting immune responses (see 1998; Vol. 17, No. 3) included his observation that Th1 cytokines (IFN-, IL-12, IL-18, GM-CSF) dominate the successful immune response, and Th2 cytokines (IL-4, IL-10) predominate in disseminated disease. He had also discovered the involvement of the endogenous cell-lysing antimicrobial granulysin as an additional weapon in successful immune control. Now that he had identified the immune response elements that differentiate the clinical presentations in T-lep and L-lep patients, Modlin wanted to understand how these different cytokines are regulated—and that is when Toll-like receptors entered the picture. cell-mediated and humoral immune responses. “So we knew that mycobacteria induce IL-12,” Modlin adds, “but we had no idea at that point how they do it. We wanted to find out what molecules accomplish this, and by what mechanism.” Modlin and his co-workers began their exploration with the more available M. tuberculosis, breaking it down into smaller and smaller segments that they tested against an IL-12–producing human leukemic monocyte cell line. The initial round of subcellular components point- ed to soluble cell wall proteins as responsible for most of the mycobacterium’s IL-12p40–inducing capacity, the most easily inducible segment of the larger IL-12 molecule (IL-12p70). Fractionating this soluble cell wall protein component and purifying its individual constituents singled out two in particular as responsible for inducing their cultured monocytes to produce IL-12p40. By far the most potent of the two was a 19-kD lipoprotein. Its IL-12–inducing effect was the same in healthy human monocytes. TLR2 T-lep L-lep TLR1 Toll-like Receptors “We were trying to understand the factors that influence the Th1 vs the Th2 cytokine response,” Modlin notes. “It was known that the key factor for inducing a Th1 cytokine response is IL-12, which is a powerful signal for generating the Th1 and cytolytic T-cell responses required to eliminate intracellular pathogens, including Mycobacterium tuberculosis. We also knew that people with mutations affecting IL-12 receptor function have an increased susceptibility to mycobacterial infection. And,” he continues, “IL-12 was known to be produced by the innate immune system—by dendritic cells (DCs) and monocytes—as a way of influencing the nature of the adaptive T-cell response, meaning the specific pattern of cytokines expressed by the T cells.” Besides causing disease, mycobacteria had long been recognized for their powerful ability to augment both www.dermatologyfoundation.org T-lep L-lep Few TLRs in L-lep lesions. TLR2 was strongly expressed in tuberculoid leprosy lesions (T-lep, top row), but sparse in lepromatous leprosy lesions (L-lep, 2nd row). TLR1 was also strongly expressed in tuberculoid leprosy lesions (T-lep, 3rd row), but weakly present in lepromatous leprosy lesions (L-lep, bottom row). (Reprinted with permission from Nat Med. 2003;9:p.528.) 11 T-lep L-lep RR CD1b DC-SIGN L-lep lesions lack antigen-presenting cells. TLR2/1 induces monocyte differentiation to macrophages (labeled DC-SIGN), which capture bacilli, and DCs (labeled CD1b), which present antigen to induce adaptive Th1 immunity. Both cell types are abundant in tuberculoid leprosy lesions (T-lep). Lepromatous lesions (L-lep) contain only macrophages. L-lep patients undergoing reversal reaction (RR) show both cell types in frequencies that resemble T-lep lesions. (Reprinted with permission from Nat Med. 2005;11:p.658.) Their next step was to identify the membrane-bound receptor on responsive cells that transduces the signal for this 19-kD lipoprotein. “The Toll-like receptors (TLRs) had very recently been discovered in humans,” Modlin says. They had been identified in Drosophila just several years earlier, and their presence in mammals as well indicates that the Toll proteins represent a host defense mechanism that has been conserved over hundreds of millions of years of evolution. In mammals, TLRs provide the innate immune system with the ability to react to different classes of microbial biochemicals and to signal activation of adaptive immunity. “TLR2 had been shown to be the receptor that mediates the response to lipopolysaccharides,” Modlin says. He contacted the investigator of that study, and they established a collaboration to see if lipoproteins might also trigger TLR2. Modlin describes six intense weeks of nonstop experiments, by the end of which “we had figured out that, in fact, TLR2 clearly was the trigger for microbial lipoproteins.” He and his colleagues duplicated this observation with lipoproteins from both Borrelia burgdorferi (the cause of Lyme disease) and Treponema pallidum (which causes syphilis), both of which induced monocyte production of IL-12 exclusively via TLR2. When a monoclonal antibody for TLR2 was added to the mix—preventing it from functioning—cultured human monocytes exposed to the 19-kD lipoprotein from M. tuberculosis no longer produced IL-12. 12 As a side note, the characterization of TLR2 as the responding molecule for lipopolysaccharides turned out to be inaccurate. The original preparations were discovered to have been contaminated with lipoprotein, and the lipopolysaccharide receptor was eventually—and accurately— identified as TLR4. Mouse and Human— Vive la Différence Modlin next wanted to know whether the TLR signaling pathway stimulated by microbial lipoproteins could be linked to a known monocyte antimicrobial mechanism. The answer turned out to be a partial yes, because his observations held only for mice, not humans. Modlin and his co-workers looked at the induction of inducible nitric oxide synthase (iNOS) and consequent release of nitric oxide (NO), which was the only known effective monocyte/macrophage mycobactericidal mechanism and represents a powerful antimycobacterial defense mechanism in mice. First they documented the ability of their 19-kD lipoprotein, and the comparable lipoprotein from T. pallidum, to impair the viability of M. tuberculosis in a murine macrophagelike cell line. This activity was abrogated when a pharmacologic inhibitor of iNOS was added. Then they used the 19-kD lipoprotein from M. tuberculosis to stimulate infected macrophages from normal mice, and from mice lacking TLR2. Macrophages from normal mice produced NO, and viability of the intracellular microbes was substantially diminished. Little happened in the infected macrophages from the TLR2-deficient mice—NO production was marginal, and intracellular organisms were unaffected. When Modlin placed M. tuberculosisinfected human monocytes and alveolar macrophages under the spotlight, once again the 19-kD protein impaired the intracellular microbes, and—as in mice—the effect was mediated through TLR2. But the similarity stopped there. The big surprise was that TLR2 stimulation failed to activate the NO pathway. “The presence of TLR2 on cells of the monocyte/macrophage lineage in lesions of human tuberculosis infection indicates that activation of TLR2 could contribute to host defense at the site of disease activity,” Modlin points out. But these results showed that the microbicidal activity initiated in human cells by TLR2 relies on a mechanism other than NO. This fundamental difference between the TLR2-triggered mechanisms in mice and humans reminds us that observations in animals represent merely a starting point for human exploration, not an expectation of results. This disconnect between the mouse and human results sent Modlin on another successful search, this time for the microbicidal pathway activated in humans when microbial lipoproteins are recognized by TLR2. Although it is premature to announce the results, Modlin does acknowledge at this point that his observations were completely unexpected, and take his investigations in humans into a highly unanticipated area of cell function. The TLR2-triggered pathways in humans appear to be far more complex than they had initially appeared. The LIR Family Modlin decided to compare the two forms of leprosy via gene expression profiling as a different approach to shedding further light on the clinical and immunologic differences between T-lep and L-lep patients. He collected skin biopsy specimens (6 from T-lep patients, 5 from L-lep patients) and found that each group clustered together based on a similar gene expression pattern. This difference was statistically significant despite the small patient numbers, with an accuracy that enabled an unknown patient sample to be correctly assigned. Modlin found that genes belonging to the leukocyte immunoglobulin-like receptor (LIR) family—especially LIR-7—were significantly up-regulated in L-lep lesions. (Continued on page 15) Dermatology Foundation We Choose Plexion Cloths Over Cleansers ® W NE 3 Out of 4 Women Said1: More Moisturizing Easier to Use More Convenient Safety Information: Although rare, local irritation has been reported with topical sodium sulfacetamide and sulfur therapy. Plexion® Cloths are contraindicated for use by patients with hypersensitivity to sulfur or sulfonamides, and patients with kidney disease. Rx ONLY DESCRIPTION: Sodium sulfacetamide is a sulfonamide with antibacterial activity while sulfur acts as a keratolytic agent. Chemically sodium sulfacetamide is N-[(4-aminophenyl) sulfonyl]-acetamide, monosodium salt, monohydrate. The structural formula is: Na NH2 SO2NCOCH3 H2O Each gram of Plexion‚ (sodium sulfacetamide USP 10% and sulfur USP 5%) Cleanser contains 100 mg of Sodium Sulfacetamide USP and 50 mg of Sulfur USP in a cleanser base containing: Purified Water USP, Sodium Methyl Oleyltaurate, Sodium Cocoyl Isethionate, Disodium Oleamido MEA Sulfosuccinate, Cetyl Alcohol NF, Glyceryl Stearate (and) PEG-100 Stearate, Stearyl Alcohol NF, PEG-55 Propylene Glycol Oleate, Magnesium Aluminum Silicate NF, Methylparaben NF, Edetate Disodium USP, Butylated Hydroxytoluene NF, Sodium Thiosulfate USP, Fragrance, Xanthan Gum NF, and Propylparaben NF. Each cloth of Plexion‚ (sodium sulfacetamide USP 10% and sulfur USP 5%) Cleansing Cloths is coated with a cleanser-based formulation. Each gram of this cleanser-based formulation contains 100 mg of sodium sulfacetamide USP and 50 mg of sulfur USP. The cleanser base consists of: Purified Water USP, Sodium Methyl Oleyltaurate, Sodium Cocoyl Isethionate, Disodium Laureth Sulfosuccinate (and) Sodium Lauryl Sulfoacetate, Disodium Oleamido MEA Sulfosuccinate, Glycerine USP, Sorbitan Monooleate NF, Glyceryl Stearate (and) PEG-100 Stearate, Stearyl Alcohol NF, Propylene Glycol (and) PEG-55 Propylene Glycol Oleate, Cetyl Alcohol NF, Edetate Disodium USP, Methylparaben NF, PEG-150 Pentaerythrityl Tetrastearate, Butylated Hydroxytoluene NF, Sodium Thiosulfate USP, Aloe Vera Gel Decolorized, Allantoin, Alpha Bisabolol Natural, Fragrance, Propylparaben NF. Each gram of Plexion SCT‚® (sodium sulfacetamide USP 10% and sulfur USP 5%) contains 100 mg of Sodium Sulfacetamide USP and 50 mg of Sulfur USP in a cream containing: Purified Water USP, Kaolin USP, Glyceryl Stearate (and) PEG-100 Stearate, Witch Hazel USP, Silicon Dioxide NF, Magnesium Aluminum Silicate NF, Benzyl Alcohol NF, Water (and) Propylene Glycol (and) Quillaja Saponaria Extract, Xanthan Gum NF, Sodium Thiosulfate USP, Fragrance. Each gram of Plexion‚® (sodium sulfacetamide USP 10% and sulfur USP 5%) Topical Suspension contains 100 mg of Sodium Sulfacetamide USP and 50 mg of Sulfur USP in a suspension containing: Purified Water USP , Propylene Glycol USP, Isopropyl Myristate NF, Light Mineral Oil NF, Polysorbate 60 NF, Sorbitan Monostearate NF, Cetyl Alcohol NF, Hydrogenated Coco-Glycerides USP, Stearyl Alcohol NF, Fragrances, Benzyl Alcohol NF, Glyceryl Stearate (and) PEG-100 Stearate, Dimethicone NF, Zinc Ricinoleate, Xanthan Gum NF, Edetate Disodium USP, and Sodium Thiosulfate USP. CLINICAL PHARMACOLOGY: The most widely accepted mechanism of action of sulfonamides is the Woods-Fildes theory, which is based on the fact that sulfonamides act as competitive antagonists to para-aminobenzoic acid (PABA), an essential component for bacterial growth. While absorption through intact skin has not been determined, sodium sulfacetamide is readily absorbed from the gastrointestinal tract when taken orally and excreted in the urine, largely unchanged. The biological half-life has variously been reported as 7 to 12.8 hours. The exact mode of action of sulfur in the treatment of acne is unknown, but it has been reported that it inhibits the growth of Propionibacterium acnes and the formation of free fatty acids. INDICATIONS: PLEXION Cleanser, PLEXION Cleansing Cloths, PLEXION SCT and PLEXION TS are indicated in the topical control of acne vulgaris, acne rosacea and seborrheic dermatitis. CONTRAINDICATIONS: Plexion Cleanser, PLEXION Cleansing Cloths, PLEXION SCT and PLEXION TS are contraindicated for use by patients having known hypersensitivity to sulfonamides, sulfur or any other component of this preparation. These PLEXION,® brand products are not to be used by patients with kidney disease. WARNINGS: Although rare, sensitivity to sodium sulfacetamide may occur. Therefore, caution and careful supervision should be observed when prescribing this drug for patients who may be prone to hypersensitivity to topical sulfonamides. Systemic toxic reactions such as agranulocytosis, acute hemolytic anemia, purpura hemorrhagica, drug fever, jaundice, and contact dermatitis indicate hypersensitivity to sulfonamides. Particular caution should be employed if areas of denuded or abraded skin are involved. FOR EXTERNAL USE ONLY. Keep away from eyes. Keep out of reach of children. Keep container tightly closed. PRECAUTIONS: General - If irritation develops, use of the product should be discontinued and appropriate therapy instituted. Patients should be carefully observed for possible local irritation or sensitization during long-term therapy. The object of this therapy is to achieve desquamation without irritation, but sodium sulfacetamide and sulfur can cause reddening and scaling of the epidermis. These side effects are not unusual in the treatment of acne vulgaris, but patients should be cautioned about the possibility. Information for Patients: Avoid contact with eyes, eyelids, lips and mucous membranes. If accidental contact occurs, rinse with water. If excessive irritation develops, discontinue use and consult your physician. Carcinogenesis, Mutagenesis and Impairment of Fertility - Long-term studies in animals have not been performed to evaluate carcinogenic potential. Pregnancy Category C – Animal reproduction studies have not been conducted with PLEXION Cleanser, PLEXION Cleansing Cloths, PLEXION TS or PLEXION SCT. It is also not known whether these PLEXION brand products can cause fetal harm when administered to a pregnant woman or can affect reproduction capacity. These PLEXION® brand products should be given to a pregnant woman only if clearly needed. Nursing Mothers - It is not known whether sodium sulfacetamide is excreted in the human milk following topical use of Plexion Cleanser, Plexion Cleansing Cloths, PLEXION SCT or PLEXION TS. However, small amounts of orally administered sulfonamides have been reported to be eliminated in human milk. In view of this and because many drugs are excreted in human milk, caution should be exercised when these PLEXION brand products are administered to a nursing woman. Pediatric Use - Safety and effectiveness in children under the age of 12 have not been established. ADVERSE REACTIONS: Although rare, sodium sulfacetamide may cause local irritation. DOSAGE AND ADMINISTRATION: PLEXION Cleanser: Wash affected areas once or twice daily, or as directed by your physician. Avoid contact with eyes or mucous membranes. Wet skin and liberally apply to areas to be cleansed, massage gently into skin for 10-20 seconds working into a full lather, rinse thoroughly and pat dry. If drying occurs, it may be controlled by rinsing cleanser off sooner or using less often. PLEXION Cleansing Cloths: Wash affected areas with cleansing cloth once or twice daily, or as directed by your physician. Wet face with water. Wet cloth with a little water and work into a full lather. Cleanse face with cloth for 10-20 seconds avoiding eyes. Rinse thoroughly and pat dry. Throw away cloth. Do not flush. PLEXION SCT: Use once daily or as directed by your physician. Wet skin. Apply in a film to entire face, avoiding contact with eyes or mucous membranes. Wait 10 minutes or until dry. Rinse thoroughly with water and pat dry. PLEXION TS: Cleanse affected areas. Apply a thin film of PLEXION TS to affected areas 1 to 3 times daily, or as directed by a physician. HOW SUPPLIED: Plexion‚® (sodium sulfacetamide 10% and sulfur 5%) Cleanser is available in 6 oz. (170.3 g) tube (NDC 99207-741-06) and 12 oz. (340.2 g) bottle (NDC 99207-741-12). Plexion‚® (sodium sulfacetamide 10% and sulfur 5%) Cleansing Cloths are available in boxes of 30 cloths (3.7 g) (NDC 99207-745-30). Plexion SCT‚® (sodium sulfacetamide 10% and sulfur 5%) is available in a 4 oz. tube (NDC 99207-744-04). Plexion‚® (sodium sulfacetamide 10% and sulfur 5%) Topical Suspension is available in 30 g tube (NDC 99207-743-30). Store at 15º - 25ºC (59º - 77ºF). Manufactured for: MEDICIS, The Dermatology Company® Scottsdale, AZ 85258 by: Tapemark West St. Paul, MN 55118 Prescribing information as of Jan 2004 Patent Pending 74530-08C References: 1. Data on file, MEDICIS® Pharmaceutical Corporation. © 2004 MEDICIS® Pharmaceutical Corporation PLX04031 Another lab had found a reciprocal expression pattern of TLR and LIR-7 in leprosy lesions, prompting Modlin to carry out functional studies in monocytes. He learned that LIR-7 suppresses innate host defense mechanisms in two different ways. It shifts cytokine production from IL-12, which induces cell-mediated immunity, toward IL-10, which suppresses it. LIR-7 also blocks the antimicrobial activity triggered by TLRs. “We were able to define gene expression patterns associated with an ongoing immune response in these lesions,” Modlin says. “Our data support the view that modern genomics can reveal the sets of genes that correlate with protective responses or inappropriate responses leading to disease progression and tolerance, and this provides unanticipated insights into pathogenesis and targets for therapy. And,” he adds, “the development of reliable biomarkers may improve patient diagnosis and classification.” TLRs in Human Leprosy Before long, TLR research provided awareness of a more extensive TLR family and a more precise understanding of their specificity in mediating responses to defined bacterial ligands. This included the realization that TLR2 could join with others to function as a larger unit. TLR2 alone and as a heterodimer with TLR1 mediates the response to microbial triacylated lipoproteins, TLR3 to double-stranded viral RNA, TLR4 to lipopolysaccharide, TLR5 to bacterial flagellin, the TLR2–TLR6 heterodimer to diacylated lipopeptides, TLR7 and TLR8 to imidazoquinolines, and TLR9 to bacterial CpG DNA sequences. Modlin used leprosy to investigate the expression and activation of these TLRs and relevant mechanisms of innate and adaptive immunity. He and his research team used human cell lines that expressed each of the individual TLRs, or each of the heterodimers involving TLR2 (TLR2/1, TLR2–TLR6, TLR2–TLR10), and activated them with killed M. leprae. Among the homodimers, only TLR2 was able to mediate responsiveness toward this mycobacterium. Among the heterodimers, co-expression of TLR1 dramatically enhanced this impact. Their next step was to search the M. leprae genome for putative lipoproteins, which led them to a pool of 31 candidates. Two were selected for further study. The 19kD ML1966 shares substantial amino acid sequence identity with the 19-kD lipoprotein from M. tuberculosis that Modlin had www.dermatologyfoundation.org identified in his initial research. ML0603 was selected because of direct evidence that it triggers cytokine release in monocytes. Each lipopeptide stimulated the release of IL-12p40 in both freshly harvested human monocytes and monocytederived dendritic cells from healthy donors. This activation was blocked when TLR2 was neutralized using antibody. The next step took a reverse perspective, looking to see if the type 1 cytokines present in T-lep lesions and the type 2 cytokines found in L-lep lesions are able to influence TLR2/1 mediated activation of monocytes and DCs from normal human cells. Without M. leprae stimulation, these cytokines had no effect. Without cytokines, M. leprae had no effect. Then Modlin stimulated these cells with the 19-kD lipopeptide from M. leprae and either type 1 cytokines (IFN-, IL-12, IL-18, GM-CSF) or type 2 cytokines (IL-4, IL-10). Type 1 cytokines enhanced this lipopeptide’s ability to trigger monocyte release of the immune-stimulating cytokine TNF-. The type 2 cytokines substantially inhibited this. IFN- had the same up-regulating effect on lipopeptide-induced release of IL12p40 from DCs, which—again—was inhibited by IL-4 and IL-10. Modlin also learned that the cytokine milieu influences the density of TLR2 surface expression. The type 2 cytokine IL-4 substantially decreases the TLR2 presence on monocytes and DCs. In contrast, type 1 cytokines up-regulate the expression of TLR1. “It is well known that the innate immune response serves an instructional role in shaping the adaptive immune response,” Modlin points out. “And our data here indicate that the adaptive immune response—by releasing T-cell cytokines that regulate TLR activation—can also influence the magnitude of the innate immune response.” The current flows in both directions. And this raises one of those “which came first” issues. On the one hand, an activated TLR2 induces the expression of type 1 cytokines in the cell. On the other, the presence of type 1 cytokines in the cell up-regulates the presence of TLR2 and enhances its activities. Where did it start? “We don’t yet know the answer,” Modlin says. “For a disease like leprosy, which has such a long incubation time, no one knows whether TLR2, and thus IL-12, have to come first to get a Th1 immune response, or whether the presence of a small Th1 population will help induce an effective TLR2 presence, or whether there is actually some sort of synergistic amplification of this process.” Whatever the explanation turns out to be, Modlin sees potential therapeutic benefit from recognizing that the immune response in leprosy is shaped in part by the influence of the local cytokine environment on the regulated expression and activation of TLR2 and TLR1. “This means it should be possible to design therapeutic agents that regulate TLR expression and activation.” The application is far broader than leprosy. When Modlin and his research team turned to cells from leprosy patients, measuring the amount of TLR2 and TLR1 expression on peripheral monocytes was unproductive. TLR2 levels were the same in T-lep and L-lep patients and TLR1 was undetectable. Assessing circulating monocytes and DCs for IL-12p40 production after exposing them to the 19-kD lipopeptide still showed no difference between the two groups. In circulating blood, therefore, both T-lep and L-lep patients can mount a functionally equivalent TLR2/1 response. The critical step was examining cells taken from lesional skin, the site of disease activity, where “the battle between host immune response and microbial pathogens in leprosy is enjoined,” Modlin comments. “We wanted to determine whether the expression of TLR2 and TLR1 in these lesions correlates with the local cytokine pattern characteristic of the different forms of this disease.” Biopsy specimens revealed notable differences in frequency and distribution (see photos on page 11). Both TLR2 and TLR1 were strongly expressed in T-lep lesions, but only weakly expressed in L-lep lesions. Most of the cells expressing TLR2 were of monocyte/macrophage lineage, with DCs the remainder. Expression of TLR1 co-localized with TLR2, indicating that most cells expressed the TLR2/1 heterodimer. Leprosy patients with a competent immune response were clearly shown to express substantially more TLR2s and TLR1s, and on the appropriate cells, compared to patients at the other end of the spectrum. How TLR2 Orchestrates an Effective Immune Response The innate immune system has two clearly distinctive functions, triggering both direct and indirect effector pathways to combat microbial pathogens. It mediates the immediate host response by acting directly to localize the invading pathogen so it can be destroyed by antimicrobial mechanisms. It acts indirectly—through cytokine release and up-regulation of (Continued on page 18) 15 Dermatology Foundation Annual Awards Honor Outstanding Dermatologists The Dermatology Foundation will recognize two of dermatology’s leaders at its Annual Meeting on March 4, 2006, in San Francisco. This tradition of honoring dermatology’s formative leaders, teachers, and role models began in 1971 with the Clark W. Finnerud Award to recognize an exemplary private practitioner who also epitomizes commitment to the specialty as a part-time teacher. The Practitioner of the Year Award, initiated in 1976, recognizes dermatologists dedicated to the highest levels of clinical care. 2005 Clark W. Finnerud Award: Paul S. Russell, MD Dr. Russell, Clinical Professor Emeritus, both the challenge of the bright young people Oregon Health & Science University, Portland, coming into the residency program every year, OR, will be honored for his long and distinand teaching the medical students as well,” guished career in dermatology combining Dr. Russell says. dedication to patients in a private practice He went into private practice in 1969 with setting with a devotion to teaching. Frederick A. J. Kingery, MD. Their practice was devoted to medical dermatology, and Dr. He chose the specialty of dermatology only Russell observes that they always felt lucky after he had become a practicing physician, to be practicing the specialty of presiding over his family practice in dermatology. the small Texas town of Levelland where he had grown up. “After six Commenting on Dr. Russell’s years of delivering babies, fixing contributions as a clinical educator, broken bones, sewing up car Neil A. Swanson, MD, Chair of wrecks, and doing a little bit of Dermatology at OHSU—noting everything else, I realized that I did that “Paul has been part of the not want to continue doing that long clinical faculty here since he term,” he recalls. “I had had suffibegan practicing in Portland in the cient experience with dermatology late ‘60s”—adds that “he was the during those six years to know that prime organizer of Grand Rounds for the department and is a superb I enjoyed it.” Dr. Russell and his late Paul S. Russell, MD teacher. He continues to chair wife, Tomi Jean, chose Portland, the weekly clinical morphology conference.” OR, as the ideal place to spend his residency years and were delighted with his acceptance Throughout his career, Dr. Russell found in the department at Oregon Health & Science time for leadership roles in the Dermatology University. They never left. Foundation, American Academy of Dermatology, the American Dermatological Dr. Russell owes his initial motivation to Association, and the Accreditation Council for volunteer for part-time teaching to Dr. Walter Graduate Medical Education. Lobitz, then chair of the Department of Dermatology. “It was always his teaching that Dr. Russell comments that “I went into partdermatologists should give back to the spetime volunteer teaching because I enjoyed it, cialty, and I found that very appealing,” he and I thought that giving something back to explains. “I wanted to make a contribution to my specialty was the proper thing to do. I had my specialty. Then I discovered that I really no thought of gaining recognition, and I am enjoyed my time at the medical school— honored and delighted to receive this Award!” 16 Dermatology Foundation 2005 Practitioner of the Year Award: W. Harrison Turner III, MD Dr. Turner has been affiliated with the produced a standard-setting successful result. Greensboro, NC, dermatologic community “That was a time of doom and gloom,” he since completing his residency at Duke recalls. “The fear was that the gatekeeper Medical Center, Durham, in 1976, and he would eliminate our specialty.” The PPO type has been a central figure in the wider health of format they developed maintained direct care and general communities there for patient access to specialists. Dr. Turner headalmost as many years. ed the organization until 1995 and chaired the AAD’s Managed Ironically, gastroenterology was Health Care Committee from Dr. Turner’s initial goal after receiv1990 to 1993, remaining as ing his MD from the Medical consultant for two more years. College of Virginia in 1968. His medical residency was scheduled Dr. Turner has also been an to begin in 1972, after his internabiding presence in the life of ship at MCV and three years in Greensboro itself and received the Air Force. “But on my military Greensboro’s Distinguished base in England, I was temporarily Citizen Award in 2003. The assigned to triage dermatology honor of being the DF’s 2005 W. Harrison Turner III, MD patients once each week. This Practitioner of the Year joins included afternoon rounds and that award as “the two things in patient presentation at Cambridge at the time my life I am most proud of,” Dr. Turner says. that noninfectious cutaneous diseases were In nominating Dr. Turner, Elise Olsen, MD, just beginning to be approached in precise a colleague at Duke University Medical immunologic rather than descriptive terms. Center, calls Dr. Turner “a remarkable man ... I was stimulated by dermatology and fascinatan excellent physician, both in his scope of ed with this view—and I fell in love with the knowledge and in his compassionate care of T cell!” Dr. Turner recalls. his patients. He is an amazing example of a He returned to the U.S. and was introduced well-rounded dermatologist and a credit to to Dr. J. Lamar Callaway, chief of dermatology our profession.” at Duke University. This meeting was the clincher. Dr. Turner did his dermatology resi2005 Lifetime Career dence under Dr. Callaway, who remains an inspiration for him. Educators Named One of the pleasures that Dr. Turner finds At its March 4, 2006 Annual Meeting, in his practice is his patients. They span all the Dermatology Foundation will also honor ages, and “once you see one member of a family, the spouse, their children, their parents, Amal K. Kurban, MD, Professor of Dermatology, and any siblings who live in the area eventuBoston University School of Medicine, and ally become your patients too.” Since 2002, Fred D. Malkinson, MD, DMD, Chairman Emeritus, Dr. Turner has been named one of North Department of Dermatology, Rush-PresbyterianCarolina’s Best Doctors in an annual survey St. Luke’s Medical Center, Chicago, as Lifetime compiled for a statewide publication. Career Educators. Coverage of this award and Dr. Turner’s commitment to patient care details of their outstanding careers, which have has motivated him to be involved in wider been dedicated to educating residents and health care issues. In 1983, he chaired a fellows, will appear in the Spring 2006 issue. steering committee to explore the possibility of an HMO in the Greensboro region and www.dermatologyfoundation.org 17 DF Welcomes New Multi-Year Corporate Commitments Partners in Ensuring Excellence for All of Dermatology Two of the Dermatology Foundation’s corporate partners— Allergan Dermatology and Abbott— have stepped up to the level of Gold Benefactor ($100,000) with new multi-year commitments. These investments will support the continuation of the DF’s successful mission to provide the specialty with a stronger scientific base and emerging leaders in research and teaching who guarantee quality patient care, and a strong future for medical and surgical dermatology. Their increased giving reflects solid confidence in the Foundation’s ability to transform its mission into reality. Their commitment to consecutive years of generosity supports the DF’s own emphasis on multi-year funding of recipients as the most effective way to ensure their career development. co-stimulatory molecules—to instruct the adaptive immune response to induce Tand B-cell responses. In the context of the TLR2 system that Modlin has come to know, he determined that the immediate response appears to be handled by macrophages via their intake and phagocytosis of antigens. The instructive function is realized by the dendritic cell through its ability to present antigens to the adaptive immune system. Modlin was guided in these studies by the use of gene expression data and a computational algorithm that enabled him to make tentative assertions, then test them out. After developing distinctive profiles of molecular markers to identify the phagocytic vs. the antigen-presenting cell types that would be derived from peripheral monocytes, first he found them expressed on distinct, nonoverlapping cell populations in human lymphoid tissue, and then among monocyte-derived cells already activated by stimulated Toll receptors. Next, he used IL-15 stimulation to induce monocytes to differ- IFN- (pg/ml) 3,000 3H incorporation (c.p.m.) 2,500 3,000 2,000 2,500 1,500 2,000 1,000 1,500 500 1,000 0 0.01 500 0 0.01 0.1 1 10 10-kDa protein (µg/ml) CD1b+ DC-SIGN+ After TLR2/1 activation, monocyte-derived DCs (labeled CD1b+) were far more potent producers of Th1 cytokines IL-12 and TNF- compared to monocyte-derived macrophages (labeled DC-SIGN+). (Reprinted with permission from Nat Med. 2005; 11:p.657.) 18 0.1 1 10 10-kDa protein (µg/ml) CD1b+ DC-SIGN+ Presenting antigen to an MHC-class II-restricted T-cell clone that recognizes a M. leprae peptide (10-kD protein), monocyte-derived DCs (labeled CD1b+) triggers 20–50-fold more T-cell proliferation and 10-fold more IFN- production compared to the monocyte-derived macrophages (labeled DC-SIGN+), despite similar levels of MHCII on the cell surface. (Reprinted with permission from Nat Med. 2005; 11:p.657.) entiate into phagocytic cells with the right molecular profile, and GM-CSF stimulation to induce differentiation into the antigenpresenting DCs he had profiled. Monocytes exposed simultaneously to both cytokines differentiated into the mixed population similar to that found after normal TLR2/1 activation. The two different monocytederived cells behaved very differently (see graphs below). When activated by TLR2/1, the antigen-presenting DCs produced far higher levels of Th1 cytokines. And when they presented antigen to an appropriate T cell, the DCs triggered far more T cell proliferation and IFN- production. When Modlin used biopsied skin from T-lep and L-lep patients to test the in vivo relevance of these differentiation pathways— searching for the respective presence of the two different molecular profiles—the results were startling—and fully in line with the patients’ immunologic and clinical differences (see photos, page 12). Cells representing each of the monocyte-derived molecular profiles—macrophage and DC—were present in lesions from T-lep patients, accounting for their strong Th1 response to the bacillus. L-lep lesions, on the other hand, contained only cells with the macrophage-associated molecular profile. They were devoid of DCs. There were no dendritic antigen-presenting cells to instruct and initiate Th1 cell activity after the macrophages had taken the mycobacteria into custody. The one exception was in those L-lep patients undergoing reversal reaction. In these cases, both cell types were detected and at frequencies similar to T-lep lesions. This was consistent with their temporary observed gain of cell-mediated immunity and local Th1 responses. “Because M. leprae was found to be abundant in the macrophages populating L-lep lesions,” Modlin says, “we infer that the innate immune system can mediate its direct effect in these patients, phagocytosing the bacteria into macrophages, but then is unable to mediate its indirect effect, inducing dendritic cells to stimulate the adaptive T-cell response required to kill these intracellular pathogens.” Given the reversal reactions characterized by a clearance of bacilli, an influx of Th1 cells, and the appearance of dendritic cells, “the ability of TLR activation to regulate differentiation of monocytes into dendritic cells is likely to be a key immunologic event for host defense,” Modlin concludes. TLR2 and Acne Treatment The TLRs have also initiated productive research on acne. Modlin’s lab initially carried out a pioneering series of studies under the direction of Jenny Kim, MD, PhD, that Dermatology Foundation documented the involvement of TLR2 in this skin pathology (see 2004, Vol. 23, No. 1). (Kim was funded by a 3-year Clinical Career Development Award and 1-year Research Grant from the Dermatology Foundation.) Before this investigation, the molecular mechanism by which Propionibacterium acnes induces inflammation was unknown. Then the awareness that microbial agents trigger cytokine responses via TLRs prompted them to see if TLR2 mediates the P. acnesinduced production of inflammatory cytokines in acne. Transfecting TLR2 into a cell line that normally does not respond to P. acnes endowed it with responsiveness. Mice engineered to lack TLR2 lost the ability to respond to this microbe. And when acne lesions were examined, TLR2 was in the right place—on the cell surface of macrophages surrounding the pilosebaceous follicles. All of these macrophages also expressed the CD14 molecule, the telltale evidence that they had been derived from monocytes. The clear conclusion was that P. acnes triggers inflammatory cytokine responses in acne by its activation of TLR2. The thought at the time was that this receptor might provide a novel treatment target for this common skin disease. “Because all-trans retinoic acid (ATRA) decreases inflammation in acne, we decided to see whether it acts by regulating TLR2 expression and function,” Modlin explains. Treating freshly isolated human monocytes with ATRA resulted in the down-regulation of TLR2 and its co-receptor, the CD14 molecule. Other possible TLR candidates did not play any role. ATRA appears to achieve its anti-inflammatory effect in acne by preventing TLR2 from triggering monocyte cytokine release in response to P. acnes stimulation. Modlin concludes from these observations that “agents targeting TLR expression and function represent a novel strategy to treat inflammation in humans.” Suggested Readings Thoma-Uszynski S, Stenger S, Takeuchi O, et al. “Induction of direct antimicrobial activity through mammalian Toll-like receptors.” Science. 2001;291:1544–7. Krutzik SR, Ochoa MT, Sieling PA, et al. “Activation and regulation of Toll-like receptors 2 and 1 in human leprosy.” Nat Med. 2003;9:525–32. Krutzik SR, Tan B, Li H, et al. “TLR activation triggers the rapid differentiation of monocytes into macrophages and dendritic cells.” Nat Med. 2005;11:653–60. Liu PT, Krutzik SR, Kim J, et al. “Cutting edge. All-trans retinoic acid downregulates TLR2 expression and function.” J Immunol. 2005;174:2467–70. ■ www.dermatologyfoundation.org Dermatology Foundation 2005 Corporate Honor Society Partners in Shaping Dermatology’s Future Cornerstone Benefactor ($500,000 to $1,000,000 annually) Astellas Pharma US, Inc.* Platinum Benefactor ($200,000 to $499,999 annually) Dermik Laboratories, Inc.* Galderma Laboratories, L.P.* Medicis, The Dermatology Company® OrthoNeutrogena* Gold Benefactor ($100,000 to $199,999 annually) Abbott Allergan Dermatology Connetics Corporation Novartis Pharmaceuticals Corporation Stiefel Laboratories, Inc.* Unilever Home & Personal Care – U.S.A. Silver Benefactor ($50,000 to $99,999 annually) 3M Pharmaceuticals Amgen, Inc. Avon Products, Inc. Coria Laboratories, Ltd. L’Oréal Recherche Mary Kay Inc. Pfizer Consumer Healthcare Valeant Pharmaceuticals International *$1 million pledge 19 Where Are They Now?—DF Profiles Research Award Recipients Early Springboard for Specialty Leader Wise investments produce outstanding returns. “Where Are They Now?” chronicles the returns for dermatology from the DF’s wise investments in talented people. This collective investment—by individual dermatologists, industry, and specialty societies—ensures the health of our patients and our specialty. Former DF award recipient Amy S. Paller, MD, praises the DF as “the major contributor to fostering research in dermatology of all types, and a critical springboard for starting young dermatologists in their careers.” She speaks from direct Amy S. Paller, MD experience. Each of her awards has translated into the continued funding and progress that have enabled her to become an outstanding benchtop scientist, a prominent clinical specialist in immunologic and genetic diseases, and a noted teacher and academic leader. Her own career path is a clear example of the value generated by the DF’s investment in the best and brightest. Dr. Paller was awarded her first Dermatology Foundation grant in 1986 when she was a new assistant professor of dermatology and pediatrics at Rush-Presbyterian-St. Luke’s Medical Center, for a project involving graft-vs-host disease. With DF funding, she pursued her new interest in disorders involving an altered immune status and “developed a strong clinical interest in them,” Dr. Paller says. This evolved into substantial clinical trials work and regular contributions to the literature. DF Dr. Paller’s second DF grant in 1990—for investigating the role of gangliosides in squamous cell carcinoma—“was a very early and very critical grant for me.” Results led to several million dollars in cumulative NIH funding and what rapidly became “the major focus of my lab.” Her research has generated significant progress in skin biology, plus potential therapeutic targets in skin cancers that she is currently exploring. Dr. Paller’s 1996 grant—targeting the use of gene therapy to treat life-threatening hemangiomas—stimulated her continuing focus on inhibiting pathologic angiogenesis. Beyond the laboratory, the DF’s investment in Dr. Paller has paid significant specialty-wide dividends. As Chief for 16 years of the Division of Dermatology at Children’s Memorial Hospital—part of the Northwestern University system—Dr. Paller developed the pediatric dermatology program to international renown. In 2004 she was named Chair of Dermatology at Northwestern’s Feinberg School of Medicine. The DF’s successful career support now has second-generation impact—five of Dr. Paller’s numerous postgraduate fellows have themselves won critically timed DF Awards. DF President Dr. Bruce Wintroub underlines the value of the DF’s investment in people like Dr. Paller: “These people are having, and will continue to have, an enormous impact on the specialty. They are the thought leaders who will continue the vitality and growth of the specialty in all its diversity.” Dermatology Focus c/o Dermatology Foundation 1560 Sherman Avenue Evanston, Illinois 60201-4808 Non-Profit U.S. Postage PAID Permit No. 566 Utica, NY ADDRESS SERVICE REQUESTED A DERMATOLOGY FOUNDATION PUBLICATION ® SPONSORED BY MEDICIS, THE DERMATOLOGY COMPANY VOL. 24 NO. 4 WINTER 2005/6
