Research Summary
Malaria, a disease caused by parasites of Plasmodium species, remains one of the most relevant infectious dis-
eases; in 2013 over 200 millions of individuals had clinical malaria and over 500,000 individuals, mainly children,
died from it. The infection starts when a Plasmodium-infected mosquito injects into the skin a small dose of sporo-
zoites, a speci¿c form of the parasite, which travel via the blood to the liver, infect hepatocytes, and form liver
stages. Several vaccine candidates, including the most recent RTS,S vaccine, are aimed at eliminating sporo-
zoites from the skin, blood, or hepatocytes. However, the low ef¿cacy of such vaccines highlights the problem
with lack of basic understanding of how Plasmodium sporozoites are eliminated by host immunity. CD8 T cells,
a subset of lymphocytes, have been shown to play an important role in preventing clinical malaria by eliminating
Plasmodium liver stages, speci¿cally in radiation attenuated sporozoites (RAS)-based vaccines. Using intravital
imaging, we have recently discovered that activated CD8 T cells form clusters around Plasmodium-infected hep-
atocytes in mice and that these clusters are important in parasite elimination. Mechanisms driving the formation
of such clusters remain poorly de¿ned and how activated CD8 T cells eliminate liver stages from the whole liver
is not well understood. Another layer of complexity arises as the level of immunity needed for protection depends
on a speci¿c host-parasite combination. By combining mathematical modeling and experiments we will provide
quantitative insights into potential mechanisms that explain contribution of CD8 T cells to elimination of Plasmod-
ium liver stages in mice. We will provide such insights via three complementary speci¿c aims. In speci¿c Aim
1, we will discriminate between alternative mechanisms of formation of CD8 T cell clusters around sporozoite-
infected hepatocytes (T-cell intrinsic vs. T-cell extrinsic), de¿ne the role of T cells, speci¿c to irrelevant antigens,
in the formation of clusters, and quantify the impact of T cell cluster size on the ef¿ciency at which liver stages
are eliminated. In speci¿c Aim 2, we will determine the impact of structure of liver sinusoids on the ef¿ciency of
CD8 T search for rare sporozoite-infected hepatocytes and determine the speed at which moving CD8 T cells
can localize the site of infection. Finally, in speci¿c Aim 3 we will discriminate between alternative mechanisms
for a larger number of memory CD8 T cells required for sterilizing protection against exposure to Plasmodium
yoelii sporozoites as compared to Plasmodium berghei sporozoites. Completion of these aims will lead to a better
understanding how CD8 T cells localize and eliminate Plasmodium liver stages from one of the major peripheral
tissues, the liver. This understanding may help in designing more ef¿cient immunization protocols of RAS-based
malaria vaccines. In addition, deeper understanding of the mechanisms by which CD8 T cells eliminate infections
at peripheral sites may be also useful for the improvement of several others CD8 T cell-based vaccines such as
those against HIV, HCV, and HSV.