Hiroshi Yoneyama scite author profile

The OprM lipoprotein of Pseudomonas aeruginosa is a member of the MexAB-OprM xenobiotic-antibiotic transporter subunits that is assumed to serve as the drug discharge duct across the outer membrane. The channel structure must differ from that of the porintype open pore because the protein facilitates the exit of antibiotics but not the entry. For better understanding of the structure-function linkage of this important pump subunit, we studied the x-ray crystallographic structure of OprM at the 2.56-Å resolution. The overall structure exhibited trimeric assembly of the OprM monomer that consisted mainly of two domains: the membrane-anchoring ␤-barrel and the cavity-forming ␣-barrel. OprM anchors the outer membrane by two modes of membrane insertions. One is via the covalently attached NH 2 -terminal fatty acids and the other is the ␤-barrel structure consensus on the outer membrane-spanning proteins. The ␤-barrel had a pore opening with a diameter of about 6 -8 Å, which is not large enough to accommodate the exit of any antibiotics. The periplasmic ␣-barrel was about 100 Å long formed mainly by a bundle of ␣-helices that formed a solvent-filled cavity of about 25,000 Å 3 . The proximal end of the cavity was tightly sealed, thereby not permitting the entry of any molecule. The result of this structure was that the resting state of OprM had a small outer membrane pore and a tightly closed periplasmic end, which sounds plausible because the protein should not allow free access of antibiotics. However, these observations raised another unsolved problem about the mechanism of opening of the OprM cavity ends. The crystal structure offers possible mechanisms of pore opening and pump assembly.

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Crystal Structure of the Membrane Fusion Protein, MexA, of the Multidrug Transporter in Pseudomonas aeruginosa

Akama

Matsuura

Kashiwagi

et al. 2004

Journal of Biological Chemistry

231

211

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The MexAB-OprM efflux pump of Pseudomonas aeruginosa is central to multidrug resistance of this organism, which infects immunocompromised hospital patients. The MexA, MexB, and OprM subunits were assumed to function as the membrane fusion protein, the body of the transporter, and the outer membrane channel protein, respectively. For better understanding of this important xenobiotic transporter, we show the xray crystallographic structure of MexA at a resolution of 2.40 Å. The global MexA structure showed unforeseen new features with a spiral assembly of six and seven protomers that were joined together at one end by a pseudo 2-fold image. The protomer showed a new protein structure with a tandem arrangement consisting of at least three domains and presumably one more. The rod domain had a long hairpin of twisted coiled-coil that extended to one end. The second domain adjacent to the rod ␣-helical domain was globular and constructed by a cluster of eight short ␤-sheets. The third domain located distal to the ␣-helical rod was globular and composed of seven short ␤-sheets and one short ␣-helix. The 13-mer was shaped like a woven rattan cylinder with a large internal tubular space and widely opened flared ends. The 6-mer and 7-mer had a funnel-like structure consisting of a tubular rod at one side and a widely opened flared funnel top at the other side. Based on these results, we constructed a model of the MexAB-OprM pump assembly. The three pairs of MexA dimers interacted with the periplasmic ␣-barrel domain of OprM via the ␣-helical hairpin, the second domain interacted with both MexB and OprM at their contact site, and the third and disordered domains probably interacted with the distal domain of MexB. In this fashion, the MexA subunit connected MexB and OprM, indicating that MexA is the membrane bridge protein.

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Polyaniline film-coated electrodes as electrochromic display devices

Kobayashi

Yoneyama

Tamura

1984

Journal of Electroanalytical Chemistry and Interfacial Electroc

689

207

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Antibiotic Resistance in Bacteria and Its Future for Novel Antibiotic Development

Yoneyama

Katsumata

2006

Bioscience, Biotechnology, and Biochemistry

241

196

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The constraint effective potential

1986

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