video: To understand lymphocyte behavior in the brain, we used two-photon microscopy to visualize effector CD8+ Tcells during toxoplasmic encephalitis. These cells displayed multiple behaviors with two distinct populations of cells apparent: one with a constrained pattern of migration and one with a highly migratory subset. view more
Credit: Chris Hunter, University of Pennsylvania
PHILADELPHIA –- For the first time, a team of researchers at the University of Pennsylvania School of Veterinary Medicine have imaged in real time the body's immune response to a parasitic infection in the brain.
The findings provide unexpected insights into how immune cells are regulated in the brain and have implications for treatment of any inflammatory condition that affects the brain.
Toxoplasma, a common parasite of humans, is found in the brains of approximately 30 percent of the population. Yet, because the brain lacks its own lymphatic system for localized immune response and the blood brain barrier limits antibody entry, researchers have found it provides unique challenges for the immune system to control local infection. Therefore, little is known about the processes by which T cells access the central nervous system during toxoplasma infection or how the immune system keeps this parasite in check.
In this Penn study, researchers aimed to better understand how the immune system is able to control infection in the brain. Using recent advances in two-photon microscopy that allow the visualization of T-cell populations in the brain, Chris Hunter's lab focused on the visualization of effector CD8+ T cells during toxoplasmic encephalitis.
"We found, quite unexpectedly, that the movement of infiltrating T cells was closely associated with an infection-induced reticular system of fibers in the brain," lead author Emma Wilson said. "These structures were not present in normal brain tissue."
"This observation suggests that in the brain, specialized structures are induced by inflammation that guide migration of T cells in this immune-privileged environment and allow them to perform a search-and-destroy type of mission required to find abnormal cells or microbes with the brain," Hunter, professor and chair of the Department of Pathobiology at Penn Vet, said.
The study was supported by a grant from the National Institutes of Health and the Commonwealth of Pennsylvania. The study was performed by Wilson of Penn, now at the Department of Biomedical Sciences at the University of California, Riverside; Tajie H. Harris, Beena John, Elia Tait, Marion Pepper and Hunter of the Department of Pathobiology at Penn Vet; Wolfgang Weninger, Paulus Mrass and E. John Wherry of The Wistar Institute (Weninger and Mrass are now at the Centenary Institute for Cancer Medicine and Cell Biology in Sydney); Florence Dzierzinski of the Institute of Parasitology at McGill University; Philip G. Haydon of the Department of Neuroscience at Tufts University; Gregory F. Wu and Terri M. Laufer of the Department of Medicine at the University of Pennsylvania School of Medicine; and David Roos of the Department of Biology at Penn.
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