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Studies on the Interaction and Organization of Bacterial Proteins on MembranesBrena, Mariana 02 July 2019 (has links)
Bacteria have developed various means of secreting proteins that can enter the host cell membrane. In this work I focus on two systems: cholesterol-dependent cytolysins and Type III Secretion.
Cholesterol is a molecule that is critical for physiological processes and cell membrane function. Not only can improper regulation lead to disease, but also the role cholesterol plays in cell function indicates it is an important molecule to understand. In response to this need, probes have been developed that detect cholesterol molecules in membranes. However, it has been recently shown that there is a need for probes that only respond to cholesterol that is accessible at the membrane surface. Perfringolysin O (PFO) is a toxin secreted by Clostridium perfringens that has been developed into a probe capable of detecting accessible cholesterol. Recently, researchers have been expanding the capabilities of this probe by substituting residues, modifying residues, truncating the probe, or a combination of the three. However, lack of characterization of these new probes has led to controversial results. To understand the role of a conserved Cys residue, here we perform cholesterol binding assays and measure the pore formation activity of a Cys modified PFO derivative.
The Type III Secretion (T3S) system is a syringe-like apparatus used by various pathogens to inject effector proteins into target cells. The apparatus spans both the inner and outer bacterial membrane, extending to make contact with the host cell where it forms a pore known as the translocon. In Pseudomonas aeruginosa, the translocon is made up of two proteins, PopB and PopD. While recent advances have been made on the structure of the needle and injectisome, information on the translocon remains sparse. In this work, the P. aeruginosa T3S translocon is analyzed using both in vivo and in vitro methods.
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Investigation of the role of the toxins perfringolysin O (PFO) and sialidase in Clostridium perfringens gas gangrene infectionsTherit, Blair H. 21 November 2006 (has links)
Clostridium perfringens is the causative agent of gas gangrene. A lethal infection in mice requires a large inoculum suggesting that the immune system is involved in inhibiting disease. Human monocytic cells and neutrophils killed C. perfringens in vitro when complement was present. Macrophages and neutrophils co-localized with C. perfringens in vivo when bacterial numbers were low. Depletion of neutrophils and monocytes in mice revealed that monocytic cells play a role in inhibiting C. perfringens gas gangrene in mice infected with an intermediate dose.
C. perfringens can persist in the tissues and this could be mediated by persistence within macrophages. To examine if the toxin perfringolysin O (PFO) could mediate this, less active variants of PFO were used to examine what occurs between phagosomal escape and cell lysis. The mutant forms of PFO did mediate phagosomal escape in macrophages and were found within macrophages at higher numbers than wild-type C. perfringens. Our data were preliminary but may indicate that less active PFO mediates intracellular persistence.
To investigate the role of sialidase in C. perfringens gas gangrene we made nanI-, nanJ-, and nanI-/nanJ- mutants. We observed that NanI is responsible for the majority of sialidase activity of C. perfringens strain 13, that NanJ is an extracellular sialidase, and that these genes are transcriptionally regulated by sialic acid. Murine infection trials revealed that these sialidases may be protective for mice during infection.
In conclusion, murine monocytes inhibit disease onset and C. perfringens sialidase enhances mouse survival. However, the toxin PFO if less active promotes the survival of C. perfringens with macrophages. / Master of Science
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