Science Concentrates ANTIBIOTICS
Conjugate attacks Gram-negative bacteria Molecular Trojan horse tricks microbes into unleashing weapon of their own destruction A new drug conjugate tricks Gram-negative bacteria into succumbing to an antibiotic that usually works only against Gram-positive bacteria. Gram-negative bacterial infections are tough to treat because the microbes have an extra outer membrane that is hard for antibiotics to traverse. And the ones that do get in are usually pumped right back out by the cells. To kill these hardy bacteria, Marvin J. Miller and coworkers at the University of Notre Dame have put a twist on a type of drug conjugate called a sideromycin. Such combinations usually consist of a siderophore—a chelating agent bacteria use to grab and collect iron from their surroundings—connected to an antibiotic. Usually there’s only one antibiotic attached, but Miller’s team adds a second one. Their synthetic sideromycin includes a siderophore, a cephalosporin, and an oxazolidinone (J. Med. Chem. 2018,
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antibiotics breach the microbes’ defenses, they can also kill Gram-negative bacteria, including Acinetobacter baumannii, Escherichia coli, and Pseudomonas aeruginosa. The work “highlights the remarkable ability of siderophore transport machinery to deliver complex O molecules and H
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N O O This drug conjugate O contains a siderophore (red), a cephalosporin linker (black), and an oxazolidinone (blue).
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DOI: 10.1021/acs.jmedchem.8b00218). The siderophore gets a bacterium to take up the conjugate. Then the microbe degrades the cephalosporin linker with a β-lactamase enzyme, releasing the oxazolidinone. That enzyme is usually part of the bacterium’s defense against antibiotics, but in this case, it unleashes the weapon of its own destruction. Oxazolidinones usually work only against Gram-positive bacteria. The Notre Dame team shows that once the
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N O F provides a H terrific example N of how microbial enzymes O associated with virulence and antibiotic resistance can be leveraged for new therapeutic strategies,” says Elizabeth M. Nolan of MIT, who also studies siderophore-antibiotic conjugates but wasn’t involved with the new work. “It will be important to determine whether this molecular design provides antibacterial activity against other Gram-negative bacterial pathogens that express β-lactamases.”—CELIA ARNAUD
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Hold it right there This magnet floats in midair thanks to superconductivity. The black disks beneath the magnet are made of yttrium barium copper oxide (YBCO), which acts as a superconductor when it is cooled. When a magnet comes close to cold YBCO (cooled in these photos to –196 °C with liquid nitrogen), electrons in YBCO move around and produce magnetic fields strong enough to push back on the magnet and make it levitate. In most regular conductors, a small amount of resistance in the material puts the brakes on those moving electrons so that the magnet can’t “float.” In superconductors, the electrons keep moving until the material warms above its superconductive temperature—for YBCO, that happens at –180 °C. Professor Ryan Latterman made these YBCO samples in his inorganic chemistry class at Wisconsin Lutheran College by pressing together yttrium(III) oxide, barium carbonate, and copper(II) oxide powders and heating the mixture.—MANNY MORONE Submitted by Ryan Latterman.
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C&EN | CEN.ACS.ORG | APRIL 9, 2018
