Bacteria and endothelial cells: a toxic relationship
Highlights•Endothelial targeting is an important part of the pathogenesis of many
bacteria.•Many bacteria kill endothelial cells by releasing pore-forming toxins.•Bacterial
toxins can also disrupt the endothelial barrier by other mechanisms.•Bacterial toxins can
modulate the endothelial recruitment of immune cells.•Gram-negative bacteria target
endothelial cells through outer membrane vesicles.Pathogenic bacteria use the bloodstream
as a highway for getting around the body, and thus have to find ways to enter and exit …
bacteria.•Many bacteria kill endothelial cells by releasing pore-forming toxins.•Bacterial
toxins can also disrupt the endothelial barrier by other mechanisms.•Bacterial toxins can
modulate the endothelial recruitment of immune cells.•Gram-negative bacteria target
endothelial cells through outer membrane vesicles.Pathogenic bacteria use the bloodstream
as a highway for getting around the body, and thus have to find ways to enter and exit …
Highlights
- Endothelial targeting is an important part of the pathogenesis of many bacteria.
- Many bacteria kill endothelial cells by releasing pore-forming toxins.
- Bacterial toxins can also disrupt the endothelial barrier by other mechanisms.
- Bacterial toxins can modulate the endothelial recruitment of immune cells.
- Gram-negative bacteria target endothelial cells through outer membrane vesicles.
Pathogenic bacteria use the bloodstream as a highway for getting around the body, and thus have to find ways to enter and exit through the endothelium. Many bacteria approach this problem by producing toxins that can breach the endothelial barrier through diverse creative mechanisms, including directly killing endothelial cells (ECs), weakening the cytoskeleton within ECs, and breaking the junctions between ECs. Toxins can also modulate the immune response by influencing endothelial biology, and can modulate endothelial function by influencing the response of leukocytes. Understanding these interactions, in both the in vitro and in vivo contexts, is of critical importance for designing new therapies for sepsis and other severe bacterial diseases.
Elsevier