News Release

UCLA scientists identify novel pathway for T-cell activation in leprosy

Finding may help develop new treatments for infectious diseases, cancer

Peer-Reviewed Publication

University of California - Los Angeles Health Sciences

Human Dendritic Cells in Leprosy

image: The presence of dendritic cells in human leprosy lesions correlates with a potent cell-mediated immune response, greater in the tuberculoid than lepromateous form of leprosy. Shown here is a microscopic image of a dendritic cell in a tuberculoid leprosy lesion, showing co-expression of (labeled in red) the intracellular receptor NOD2 and cell surface IL-32 (labeled in green). view more 

Credit: UCLA

UCLA researchers pinpointed a new mechanism that potently activates T-cells, the group of white blood cells that play a major role in fighting infections.

Published March 25 online in Nature Medicine, the team specifically studied how dendritic cells, immune cells located at the site of infection, become more specialized to fight the leprosy pathogen known as Mycobacterium leprae. Dendritic cells, like scouts in the field of a military operation, deliver key information about an invading pathogen that helps activate the T-cells in launching a more effective attack.

It was previously known that dendritic cells were important for a strong immune response and the number of such cells at an infection site positively correlated with a robust reaction. However, until now it was poorly understood how dendritic cells become more specialized to address specific types of infections.

The researchers found that a protein called NOD2 triggers a cell-signaling molecule called interleukin-32 that induces general immune cells called monocytes to become specialized information-carrying dendritic cells.

"This is the first time that this potent infection-fighting pathway with dendritic cells has been identified, and demonstrated to be important in fighting human disease," said the study's first author Mirjam Schenk, postdoctoral scholar, division of dermatology, David Geffen School of Medicine at UCLA.

In conducting the study, scientists used monocytes taken from the blood of healthy donors and leprosy patients and incubated the cells with the pathogen M. Leprae or specific parts of the mycobacteria, known to trigger NOD2 and TLR2, both associated with immune system activation.

Scientists wanted to investigate how these proteins might trigger mechanisms that turn on different immune receptors that recognize specific parts of the microbe in an infection. The NOD2 interleukin-32 pathway was the most effective and caused monocytes to develop into dendritic cells that carry critical information about the pathogen to the T-cells.

The team studied the gene expression profiles of the protein-triggered pathways and then also examined how the monocytes of leprosy patients responded to NOD2. Scientists found that NOD2 worked to induce moncytes to dendritic cells in tuberloid leprosy, a milder infection that is more easily contained. The NOD2 pathway was inhibited and could not be activated in lepromatous leprosy, which is more serious and causes widespread infection throughout the body.

"We were surprised to find the high potency of the dendritic cells in triggering certain specific T-cell responses, which may be useful in developing new therapeutic strategies for infectious diseases and cancer," said senior investigator Dr. Robert Modlin, UCLA's Klein Professor of Dermatology and chief of dermatology at the Geffen School of Medicine.

Leprosy, one of the world's oldest known diseases, is a chronic infectious disease that affects the skin, the peripheral nerves, the upper respiratory tract and the eyes and can lead to disfigurement of the hands, face and feet. In 2008, approximately 249,000 new cases of leprosy were reported worldwide, according to the World Health Organization.

Modlin adds that leprosy is a good model to study immune mechanisms in host defense since it presents as a clinical spectrum that correlates with the level and type of immune response of the pathogen.

The next stage of research will involve trying to further understand how to manipulate the innate immune system to induce a potent immune response in human infections and possibly for cancer immunotherapy as well.

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The study was funded by the NIH's National Institute of Allergy and Infectious Diseases and National Institute of Arthritis and Musculoskeletal and Skin Diseases. (Grant numbers: RO1s AI022553, AR040312 and AI047868.)

Additional authors include: Stephan R Krutzik, Peter A Sieling, Delphine J. Lee, Rosane M. B. Teles, and Maria Teresa Ochoa from the Division of Dermatology, Department of Medicine, David Geffen School of Medicine at UCLA; Genhong Cheng, Department of Microbiology, Immunology and Molecular Genetics, David Geffen School of Medicine at UCLA; Evangelia Komisopoulou and Thomas G. Graeber, Crump Institute for Molecular Imaging, Institute for Molecular Medicine, Jonsson Comprehensive Cancer Center, California NanoSystems Institute, Department of Molecular and Medical Pharmacology, UCLA; Euzenir N. Sarno, Department of Mycobacteriosis, Oswaldo Cruz Foundation, Rio de Janeiro, Brazil; Thomas H. Rea, Department of Dermatology, University of Southern California School of Medicine, Los Angeles, California and Soohyun Kim, Department of Biomedical Science and Technology, Konkuk University, Seoul Korea.


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