Browsing by Subject "alpha-hemolysin"
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Item On the structure and assembly of staphylococcal leukocidin: a study of the molecular architecture of beta-barrel pore-forming toxins(Texas A&M University, 2006-08-16) Miles, Jr., George EmmettStaphylococcal leukocidin pores are formed by the obligatory interaction of two distinct polypeptides, one of class F and one of class S, making them unique in the family of β-barrel pore-forming toxins (β-PFTs). By contrast, other β-PFTs form homooligomeric pores. For example, the staphylococcal α- hemolysin is a homoheptamer. Limited and controversial data exist on the assembly and molecular architecture of the leukocidin pore. In this work, biochemical and biophysical methods were used to characterize the leukocidin pore produced by the LukF (HlgB) and LukS (HlgC) components encoded by Staphylococcus aureus. I demonstrate that LukF and LukS assemble to form an SDS-stable pore on rabbit erythrocyte membranes. In addition, the pore-forming properties of recombinant leukocidin were investigated with planar lipid bilayers. Although leukocidins and staphylococcal α-hemolysin share partial sequence identity and related folds, LukF and LukS produce a pore with a unitary conductance of 2.5 nS (1 M KCl, 5 mM HEPES, pH 7.4), which is over three times greater than that of α-hemolysin measured under the same conditions. The subunit composition and stoichiometry of a leukocidin pore were determined by two independent methods, gel shift electrophoresis and sitespecific chemical modification during single channel recording. Four LukF and four LukS subunits were shown to co-assemble into an octameric transmembrane structure. The existence of an additional subunit in part explains properties of the leukocidin pore, such as its high conductance. Additionally, this is the first time that either technique has been applied successfully to assess the composition of a heteromeric membrane protein. It is also relevant to understanding the mechanism of assembly of β-PFT pores, and suggests new possibilities for engineering these proteins. In additional studies, the HlyII pore encoded by Bacillus cereus was found to form a homoheptameric transmembrane pore with properties conforming in general with those of other members of the class of β-PFTs. HlyII possesses additional properties which make it an attractive candidate for applications in biotechnology, such as an oligomer with a high thermal stability in the presence of SDS and the ability of the pore to remain open at high transmembrane potentials.Item Remodelling the cavity of a transmembrane pore by genetic engineering(Texas A&M University, 2006-08-16) Jung, YunheeThe cavity within the transmembrane staphylococcal α-hemolysin (αHL) pore is roughly a sphere of diameter ~45 ?? (volume ~32,600 ??3). The alpha-hemolysin gene was modified to introduce exogenous polypeptide sequences between positions 105 and 106 of αHL. These modified αHLs were assembled either by themselves or with wild-type (W) subunits to form stable homoheptamers and heteroheptamers, respectively. First, the ability to accommodate Gly/Ser-rich polypeptide sequences in the central cavity was tested. Concatemerized Gly/Ser-containing sequences ("loops", L; L(10n + 5), n = 0 to 21) were inserted by genetic approaches. Detailed analysis of bilayer recordings and electrophoretic migration patterns of assembled pores indicate that the upper capacity of the cavity is ~175 amino acids. Then two different polypeptides were placed in the cavity to introduce novel functional properties to the αHL pore. By introducing tandem repeats of elastin-like polypeptide sequences (VPGGG), αHL pores (E101W6) that featured a temperature-responsive gating mechanism were obtained. The temperature-dependent properties of E101W6 pores were monitored by single-channel current recording in planar lipid bilayers. The amplitude and the frequency of the transient blockades increased as the temperature increased, while their duration decreased. The hydrophobic collapse of the inserted ELP loop is proposed for the source of the observed sigmoidal two-state transition for normalized closed states of E101W6 pores. Lastly, an αHL pore was designed to detect proteins from the cis side of the membrane. The heat-stable protein kinase inhibitor (PKI) sequence was inserted into the mid-position of the Gly/Ser loop, which was generated by previous project (L105 construct). The heteromeric pore with the PKI-containing loop (P1151W6) was able to detect cAMP-dependent protein kinase catalytic subunit (PKA) at single molecular level. These engineered αHL pores provide numerous possibilities as tools for drug delivery, cryopreservation, or molecular sensing.