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Research Laboratories at Penn Vet


Penn Vet faculty are engaged in ongoing groundbreaking research. Here are examples of faculty laboratories and the projects being investigated, both at our Philadelphia campus and at New Bolton Center.

Scott Laboratory

Dr. Scott's current research is focused on understanding the development, regulation and maintenance of CD4+ and CD8+ T cells in order to design new vaccines and immunotherapies for infectioleishmaniaus diseases.

The laboratory primarily focuses on experimental murine infections with the protozoan parasite, Leishmania, which provides a well-characterized model of T helper cell differentiation.

Contact Information

Phillip Scott

Professor of Microbiology and Immunology, Department of Pathobiology
Associate Dean for Research
Member, Immunology Graduate Group
Cell & Molecular Biology Graduate Group

Office: (215) 898-1602; 898-9793
Fax: (215) 746-2294
Email: pscott@vet.upenn.edu

University of Pennsylvania
School of Veterinary Medicine
3800 Spruce Street
Philadelphia, PA 19104-4539 


Research in Dr. Scott's laboratory is focused on understanding the development, regulation and maintenance of CD4+ and CD8+ T cells in order to design new vaccines and immunotherapies for infectious diseases.

The laboratory primarily focuses on experimental murine infections with the protozoan parasite, Leishmania, which provides a well-characterized model of T helper cell differentiation.

The use of IL-12 as an adjuvant to promote Th1 cell development, as well as the ability of combined drug and IL-12 therapy to promote a Th2 to Th1 switch, was first shown in this laboratory. Both findings have implications for the control and treatment of infectious diseases, autoimmunity and allergy.

While much has been learned about the development of Th1 cells, our understanding of how to maintain Th1 responses is limited. This is highlighted by the fact that there is no vaccine for human leishmaniasis.

Dr. Scott's laboratory is investigating the role of cytokines, antigen-dose, CD8+ T cells, regulatory T cells and antigen persistence in the development of immunologic memory.

Another major interest in this laboratory is to better understand how different species of Leishmania interact with the host immune system, in order to develop new treatments for chronic leishmaniasis.

For example, in contrast to L. major infections, infections with L. mexicana fail to resolve in C57BL/6 mice, and the lab has linked this phenotype to a defect in dendritic cell activation following infection.

On the other hand, infections with L. braziliensis resolve in BALB/c mice, which are susceptible to both L. major and L. mexicana, and studies are underway to elucidate the factors that promote lesion resolution with this parasite.

Most recently, the Scott lab has begun studies in Brazil, funded by a NIH International Collaborations in Infectious Disease Research (ICIDR) grant, to understand the pathogenesis of L. braziliensis in patients.

L. braziliensis can cause disfiguring chronic disease, in spite of the development of a strong immune response and control of the parasites. Thus, the disease is primarily due to immunopathology, including the production of high levels of TNF-a.

One type of monocyte (termed proinflammatory monocytes) is known to produce high levels of TNF-a, and this subset is expanded in L. braziliensis patients. The Scott lab is looking at the how these monocytes are regulated during infection.

Carvalho Lucas P, Petritus Patricia M, Trochtenberg Alyssa L, Zaph Colby, Hill David A, Artis David, Scott PhillipLymph node hypertrophy following Leishmania major infection is dependent on TLR9. Journal of immunology (Baltimore, Md. : 1950) 188(3): 1394-401, Feb 2012.

Kaye Paul, Scott PhillipLeishmaniasis: complexity at the host-pathogen interface. Nature reviews. Microbiology 9(8): 604-15, Aug 2011.

Kaye, P., and P. ScottLeishmaniasis: complexity at the host-pathogen interface. Nat Rev Microbiol 9: 604-615, 2011.

Colpitts, S. L., and P. ScottThe early generation of a heterogeneous CD4+ T cell response to Leishmania major. J Immunol 185: 2416-2423, 2010.

Colpitts, S. L., N. M. Dalton, and P. Scott.IL-7 receptor expression provides the potential for long-term survival of both CD62Lhigh central memory T cells and Th1 effector cells during Leishmania major infection. J Immunol 182: 5702-5711, 2009.

Ng, L. G., A. Hsu, M. A. Mandell, B. Roediger, C. Hoeller, P. Mrass, A. Iparraguirre, L. L. Cavanagh, J. A. Triccas, S. M. Beverley, P. Scott, and W. Weninger.Migratory dermal dendritic cells act as rapid sensors of protozoan parasites. PLoS Pathog 2008.

Carvalho, L. P., E. J. Pearce, and P. Scott. Functional dichotomy of dendritic cells following interaction with Leishmania braziliensis: infected cells produce high levels of TNF-alpha, whereas bystander dendritic cells are activated to promote T cell responses. J Immunol 181: 6473-6480., 2008.

Pakpour, N., Zaph, C., and P. ScottThe central memory CD4+ T cell population generated during Leishmania major infection requires IL-12 to produce IFN-gamma Journal of Immunology 180(12): 8299-8305, June 2008.

Uzonna, Jude E. Joyce, Karen L. Scott, Phillip.Low dose Leishmania major promotes a transient T helper cell type 2 response that is down-regulated by interferon gamma-producing CD8+ T cells. Journal of Experimental Medicine 199(11): 1559-66, Jun 7 2004.

Zaph, Colby. Uzonna, Jude. Beverley, Stephen M. Scott, Phillip.Central memory T cells mediate long-term immunity to Leishmania major in the absence of persistent parasites.[see comment]. Nature Medicine 10(10): 1104-10, Oct 2004.

Scott Laboratory Grants
Funding Agency Grant
  NIH IL-12 As an Immunopotentiator in Leishmaniasis
  NIH Initiation of Immune Response in Chronic Leishmaniasis
  NIH  Myeloid Lineage Cells and Immunopathology in Leishmania