Browsing by Author "Tan, Xi"
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- ItemOpen AccessThe Lyme disease spirochete can hijack the host immune system for extravasation from the microvasculature(Wiley, 2021-04-23) Tan, Xi; Petri, Björn; DeVinney, Rebekah; Jenne, Craig N; Chaconas, GeorgeLyme disease is the most common tick-transmitted disease in the northern hemisphere and is caused by the spirochete Borrelia burgdorferi and related Borrelia species. The constellation of symptoms attributable to this malady result from vascular dissemination of B. burgdorferi throughout the body to invade various tissue types. However, little is known about the mechanism by which the spirochetes can breach the blood vessel wall to reach distant tissues. We have studied this process by direct observation of spirochetes in the microvasculature of living mice using multilaser spinning-disk intravital microscopy. Our results show that in our experimental system, instead of phagocytizing B. burgdorferi, host neutrophils are involved in the production of specific cytokines that activate the endothelium and potentiate B. burgdorferi escape into the surrounding tissue. Spirochete escape is not induced by paracellular permeability and appears to occur via a transcellular pathway. Neutrophil repurposing to promote bacterial extravasation represents a new and innovative pathogenic strategy.
- ItemOpen AccessStudies on Hematogenous Dissemination of Lyme Disease Spirochetes(2021-08-19) Tan, Xi; Chaconas, George; DeVinney, Rebekah; Jenne, CraigLyme disease (LD), caused by various members of the genus Borrelia, is the most prevalent tick-transmitted illness in North America and Europe (Groshong & Blevins, 2014, Stanek et al., 2011). There is an increasing risk of LD in Canada. In 2014, the Government of Canada launched a national communication campaign to raise social awareness and promote individual preventive behaviors toward LD. Hematogenous dissemination is important for infection by Borrelia burgdorferi (B. burgdorferi). B. burgdorferi can attach to the vascular endothelium and disseminate into a variety of tissue types. B. burgdorferi hematogenous dissemination is a multistep process and consists of several successive stages: transient (tethering plus dragging) interactions, followed by stationary adhesion and/or extravasation (Norman et al., 2008, Coburn et al., 2013). However, the mechanism of borrelial vascular adhesion and extravasation remained unclear. We are using intravital microscopy (IVM) (Kumar et al., 2015, Secklehner et al., 2017, Stolp & Melican, 2016) to identify and characterize B. burgdorferi adhesins, which are believed to be involved in vascular adhesion, transmigration as well as tissue tropism (Coburn et al., 2013, Caine & Coburn, 2016). From the B. burgdorferi side, we have shown that OspC is a dermatan sulfate- (DS-) and fibronectin- (FN-) binding adhesin that is required for vascular transmigration and joint colonization in mice (Lin et al., 2020). We also identified that VlsE, a well-known antigenically variable outer surface lipoprotein, is a DS-binding adhesin that efficiently promotes transient adhesion to the microvasculature via its DS binding activity in vivo. Moreover, on the host side, we have shown that instead of phagocytizing B. burgdorferi, host neutrophils are involved in producing specific cytokines (TNF-α, MCP-1, IL-10) that activate the endothelium and potentiate B. burgdorferi escape into the surrounding tissue. Spirochete escape is not induced by paracellular permeability and appears to occur via a transcellular pathway. Neutrophil repurposing to promote bacterial extravasation represents a new and innovative pathogenic strategy (Tan et al., 2021). Our findings provide insight into the mechanism of Borrelia hematogenous dissemination and how LD spirochetes employ host immune cells for vascular extravasation.