This project aims to understand how bacterial proteins penetrate cell membranes and enter the cytoplasm of mammalian cells in order to understand how proteins can cross membranes. The primary subject of study is diphtheria toxin. Its membrane insertion occurs after exposure to the low pH within the lumen of endosomal vacuoles. The A chain of the toxin then translocates into the cytoplasm, aided by the toxin's hydrophobic T domain. To analyze this process, the structure of membrane-inserted A and T subunits will be studied, making use of site-directed mutagenesis combined with in vitro fluorescence-based assays. In addition, function will be evaluated by pore formation, translocation assays and cellular toxicity measurements. The role of the T chain will be analyzed by assessing the effects of blocking the insertion of individual T domain helices on membrane-inserted structure and function. Also, crucial T domain residues will be identified and their effect on structure and function characterized. The translocation mechanism will be studied by examining the role of pore formation, oligomerization, and the covalent link between the A and T chain on translocation. In addition, the role of interactions between the A and T chain in translocation will be analyzed by comparing their topography in the membrane-inserted A-T complex before, after and during translocation. Finally, the hypothesis that the T domain promotes translocation by acting like a relatively non-specific transmembrane chaperone will be tested by assaying the translocation of chimeras with the A chain replaced by proteins that vary in their degree of folding and/or hydrophobicity. Studies will then be extended to the type III translocation system of pathogenic bacteria. Interesting parallels between diphtheria toxin and type III translocation have recently become apparent. Our first target will be the YopB and YopD proteins of Yersinia. They are main components of the membrane-perforating apparatus through which translocating proteins pass. Our first goal will be to understand the relationship of YopB/D function to their topography when in the membrane-inserted state, with a longer-range goal being exploration of how YopB/D interactions with other Yersinia proteins results in the assembly of a functional translocation pore. An ultimate goal is to aid development of therapeutic agents interfering with infection. In a first step, the effects of molecules found to inhibit T domain pore formation upon YobB/D and Yersinia pathogenesis will be tested.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
2R01GM031986-20A1
Application #
6680617
Study Section
Physical Biochemistry Study Section (PB)
Program Officer
Chin, Jean
Project Start
1983-04-01
Project End
2007-03-31
Budget Start
2003-08-01
Budget End
2004-03-31
Support Year
20
Fiscal Year
2003
Total Cost
$200,666
Indirect Cost
Name
State University New York Stony Brook
Department
Biochemistry
Type
Schools of Arts and Sciences
DUNS #
804878247
City
Stony Brook
State
NY
Country
United States
Zip Code
11794
Wang, Jie; London, Erwin (2009) The membrane topography of the diphtheria toxin T domain linked to the a chain reveals a transient transmembrane hairpin and potential translocation mechanisms. Biochemistry 48:10446-56
Lai, Bing; Zhao, Gang; London, Erwin (2008) Behavior of the deeply inserted helices in diphtheria toxin T domain: helices 5, 8, and 9 interact strongly and promote pore formation, while helices 6/7 limit pore formation. Biochemistry 47:4565-74
Fujita, Kentaro; Krishnakumar, Shyam S; Franco, David et al. (2007) Membrane topography of the hydrophobic anchor sequence of poliovirus 3A and 3AB proteins and the functional effect of 3A/3AB membrane association upon RNA replication. Biochemistry 46:5185-99
Buchanan, Susan K; Lukacik, Petra; Grizot, Sylvestre et al. (2007) Structure of colicin I receptor bound to the R-domain of colicin Ia: implications for protein import. EMBO J 26:2594-604
White, Dawn; Musse, Abdiwahab A; Wang, Jie et al. (2006) Toward elucidating the membrane topology of helix two of the colicin E1 channel domain. J Biol Chem 281:32375-84
Wu, Zhengyan; Jakes, Karen S; Samelson-Jones, Ben S et al. (2006) Protein translocation by bacterial toxin channels: a comparison of diphtheria toxin and colicin Ia. Biophys J 91:3249-56
Wang, Jie; Rosconi, Michael P; London, Erwin (2006) Topography of the hydrophilic helices of membrane-inserted diphtheria toxin T domain: TH1-TH3 as a hydrophilic tether. Biochemistry 45:8124-34
Zhao, Gang; London, Erwin (2006) An amino acid ""transmembrane tendency"" scale that approaches the theoretical limit to accuracy for prediction of transmembrane helices: relationship to biological hydrophobicity. Protein Sci 15:1987-2001
Musse, Abdiwahab A; Wang, Jie; Deleon, Gladys P et al. (2006) Scanning the membrane-bound conformation of helix 1 in the colicin E1 channel domain by site-directed fluorescence labeling. J Biol Chem 281:885-95
Zhao, Gang; London, Erwin (2005) Behavior of diphtheria toxin T domain containing substitutions that block normal membrane insertion at Pro345 and Leu307: control of deep membrane insertion and coupling between deep insertion of hydrophobic subdomains. Biochemistry 44:4488-98

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