We propose to study membrane-active proteins and peptides that cause configurational changes in cell membranes, including pore formation and membrane fusion. Pore-forming peptides are animals'(including human's) gene-encoded innate antimicrobials that kill microbes by forming pores in their membranes. Clarification of their molecular mechanisms will facilitate their therapeutic applications. Our studies of this problem have led to a free energy description of peptide-lipid interactions.
In specific aim 1 we will extend such studies to the kinetics of pore-formation. Studies of these relatively simple peptides have also contributed to the development of experimental methods that can be used for more complex protein-membrane interactions. Pore-forming proteins include apoptosis regulating proteins, in particular Bax which is soluble in the cytosol under normal conditions, but in the presence of apoptotic stimuli, it translocates to the outer mitochondrial membrane and induces cytochrome c release by forming pores.
In specific aim 2, we will analyze the molecular mechanism of pore formation by Bax. The viral fusion protein (hemagglutinin or HIV gp41) inserts the N-terminal fusion peptide into the target membrane to initiate membrane fusion.
In specific aim 3 we will study the effect of fusion peptides on the first step of membrane fusion. The molecular mechanisms of membrane-peptide (or -protein) interactions must have a structural basis. Obtaining the structural information for each system is our primary goal. Using oriented membranes containing peptides, we have developed methods for measuring the orientation of the peptides, measuring the membrane thickness as a function of peptide-lipid ratio, detecting and measuring the size of transmembrane pores, and resolving the structures of the peptide-induced pores. We will extend these methods to study pore-forming proteins. The biological functions of membrane-active proteins and peptides will be simulated in kinetic experiments with giant unilamellar vesicles (GUVs). The surface area change and the volume change of the GUV in the kinetic process will be measured. We will then interpret the kinetic results in terms of the structural basis. PHS 398/259 (Rev. 11/07) Page Continuation Format Page
We study an important protein Bax that controls the initiation of programmed cell death called apoptosis. It is known that disruption of the apoptosis pathway would increase the likelihood of the cell becoming cancerous or diseased. Using Bax to induce cell death in cancer cells is in clinical trials.
Lee, Ming-Tao; Hung, Wei-Chin; Hsieh, Meng-Hsuan et al. (2017) Molecular State of the Membrane-Active Antibiotic Daptomycin. Biophys J 113:82-90 |
Faust, Joseph E; Yang, Pei-Yin; Huang, Huey W (2017) Action of Antimicrobial Peptides on Bacterial and Lipid Membranes: A Direct Comparison. Biophys J 112:1663-1672 |
Hung, Wei-Chin; Lee, Ming-Tao; Chung, Hsien et al. (2016) Comparative Study of the Condensing Effects of Ergosterol and Cholesterol. Biophys J 110:2026-33 |
Sun, Yen; Sun, Tzu-Lin; Huang, Huey W (2016) Mode of Action of Antimicrobial Peptides on E. coli Spheroplasts. Biophys J 111:132-9 |
Sun, Yen; Hung, Wei-Chin; Lee, Ming-Tao et al. (2015) Membrane-mediated amyloid formation of PrP 106-126: A kinetic study. Biochim Biophys Acta 1848:2422-9 |
Faust, Joseph E; Desai, Tanvi; Verma, Avani et al. (2015) The Atlastin C-terminal tail is an amphipathic helix that perturbs the bilayer structure during endoplasmic reticulum homotypic fusion. J Biol Chem 290:4772-83 |
Chen, Yen-Fei; Sun, Tzu-Lin; Sun, Yen et al. (2014) Interaction of daptomycin with lipid bilayers: a lipid extracting effect. Biochemistry 53:5384-92 |
Sun, Yen; Sun, Tzu-Lin; Huang, Huey W (2014) Physical properties of Escherichia coli spheroplast membranes. Biophys J 107:2082-90 |
Lee, Ming-Tao; Sun, Tzu-Lin; Hung, Wei-Chin et al. (2013) Process of inducing pores in membranes by melittin. Proc Natl Acad Sci U S A 110:14243-8 |
Sun, Tzu-Lin; Sun, Yen; Lee, Chang-Chun et al. (2013) Membrane permeability of hydrocarbon-cross-linked peptides. Biophys J 104:1923-32 |
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