Summary
The FhuA protein in the outer membrane of Escherichia coli serves as a multifunctional receptor for the phages T5, T1, ϕ80, for colicin M, for ferrichrome (Fe3+-siderophore) and for the structurally related antibiotic, albomycin. To determine structural domains required for these receptor functions and for export, a fusion protein between FhuA and Iut (receptor for Fe3+-aerobactin and cloacin DF13) was constructed. In the FhuA′-′Iut hybrid protein, 24 amino acids of FhuA were replaced by 19 amino acids, 18 of which were from Iut. The number of plaque forming units of phage T5 and T1 on cells expressing FhuA′-′Iut was nearly as high as on cells expressing plasmid-encoded wild-type FhuA. However, 107-fold higher concentrations of phage ϕ80 and 103 times more colicin M were required to obtain a zone of growth inhibition. Truncated FhuA′ proteins in which the last 24 amino acids at the carboxy-terminus were replaced by 16 (FhuA′2) or 3 (FhuA′T) amino acids could hardly be detected on polyacrylamide electrophoretograms of outer membrane proteins, due to proteolytic degradation. Sensitivity of cells expressing FhuA′2 to phage T5 and T1 was reduced by several orders of magnitude and sensitivity to phage ϕ80 and colicin M was totally abolished. In contrast, cells expressing FhuA′T were nearly as sensitive to phage T5, T1, and ϕ80 and to colicin M as cells containing FhuA′-′Iut. None of the constructs could grow on ferrichrome as sole iron source and none was sensitive to albomycin. Ferrichrome did not inhibit binding of T5 to TonB− cells expressing FhuA′-′Iut (as it did in FhuA+ cells) due to the lack of ferrichrome binding. It is concluded that very small deletions (relative to the size of FhuA with 714 amino acids) at the C-terminal end render FhuA susceptible to proteolytic cleavage. The C-terminal alterations affect sensitivity to FhuA-specific agents very differently. Apparently, the C-terminus is a very important part of FhuA regarding stability and activity. Expression of active FhuA and partially inactive FhuA derivatives in the same cell revealed no negative complementation, suggesting a FhuA monomer as functional unit.
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Schultz, G., Ullrich, F., Heller, K.J. et al. Export and activity of hybrid FhuA′-′Iut receptor proteins and of truncated FhuA′ proteins of the outer membrane of Escherichia coli . Mol Gen Genet 216, 230–238 (1989). https://doi.org/10.1007/BF00334361
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DOI: https://doi.org/10.1007/BF00334361