Membrane Topography of the T Domain of Diphtheria Toxin Probed with Single Tryptophan Mutants

The membrane insertion and translocation of diphtheria toxin, which is induced in vivo by low pH, is thought to be directed by the hydrophobic α-helices of its transmembrane (T) domain. In this study the structure of membrane-associated T domain was examined. Site-directed mutants of the T domain wi...

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Bibliographic Details
Published in:Biochemistry (Easton) 1998-12, Vol.37 (51), p.17915-17922
Main Authors: Malenbaum, Susan E, Collier, R. John, London, Erwin
Format: Article
Language:English
Subjects:
Corynebacterium diphtheriae
Dimyristoylphosphatidylcholine - chemistry
Diphtheria Toxin - chemistry
Diphtheria Toxin - genetics
Fluorescence Polarization
Hydrogen-Ion Concentration
Membrane Proteins - chemistry
Membrane Proteins - genetics
Membranes, Artificial
Models, Chemical
Mutagenesis, Site-Directed
Phosphatidylcholines - chemistry
Phosphatidylcholines - genetics
Protein Binding - genetics
Protein Conformation
Protein Structure, Tertiary
Solutions
Spectrometry, Fluorescence
Tryptophan - chemistry
Tryptophan - genetics
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Summary:The membrane insertion and translocation of diphtheria toxin, which is induced in vivo by low pH, is thought to be directed by the hydrophobic α-helices of its transmembrane (T) domain. In this study the structure of membrane-associated T domain was examined. Site-directed mutants of the T domain with single Trp residues were prepared at the two naturally occurring positions, 206 (near the N-terminal end of helix TH1) and 281 (within helix TH5), as well as at three residues in helix TH9, in which the substitutions F355W (near the N-terminal end of TH9), I364W (close to the center of TH9), and Y375W (near the C-terminal end of TH9) were made. All these mutants were found to undergo the low-pH-induced conformational change observed with wild-type T domain and insert into model membranes at low pH. The location of Trp residues relative to the lipid bilayer was characterized in model membrane vesicles by fluorescence emission and by quenching with nitroxide-labeled phospholipids. In TH9, residue 375 was shallowly inserted, residue 364 deeply inserted, and residue 355 located at an intermediate depth. Residues 206 and 281 exhibited moderately deep insertion. It was also found, in agreement with our previous study using bimane-labeled protein (Wang et al. (1997) J. Biol. Chem. 272, 25091−25098), that TH9 switches from a relatively shallowly inserted state to a more deeply inserted state when the concentration of the T domain in the membrane is increased or the thickness of the membrane bilayer is decreased. In particular, the depth of residue 355 was found to increase under the conditions giving deeper insertion. In contrast, residue 375 remained shallowly located in both states, as predicted from its location on the polar C-terminus of TH9. It is concluded that TH1 and TH5 insert into the lipid bilayer in both T domain conformations. In addition, Trp depths suggest that even in the shallowly inserted state there is a significant degree of insertion of TH9. These results suggest regions of the T domain in addition to the hydrophobic TH8/TH9 hairpin insert into membranes. Models for the structure of the membrane-inserted T domain are discussed.
ISSN:0006-2960
1520-4995
DOI:10.1021/bi981230h