news of the week MAY 9, 20 1 1 EDITED BY KIMBERLY R. TWAMBLY & EMILY BONES
JOLTING THE DIELSALDERASE HUNT
may keep side products from forming, he explains. “This enzyme’s the first of its kind,” says John C. Vederas of the University of Alberta, Edmonton. A handful of other proteins, including one his team discovered, have been flagged as likely Diels-Alderases, but all of them have catalyzed other reactions too, Vederas says. Extra functions make it tough to subject DielsAlderase contenders to detailed studies of mechanism, so SpnF could offer the clearest answer to whether Diels-Alder reactions occur in nature, writes Georgia Institute of Technology chemist Wendy L. Kelly in MULTITASKERS a commentary accompaThese enzymes seem to mediate nying the study (Nature, [4+2] cycloadditions as well as catalyze DOI: 10.1038/473035a). other reactions Liu says his team hasn’t yet determined SpnF’s ENZYME ALSO CATALYZES mechanism. For SpnF to Lovastatin nonaketide synthase Polyketide synthesis be a bona fide Diels-AlderSolanapyrone synthase Hydroxyl oxidation ase, its mechanism must Riboflavin synthase Hydride transfer be concerted—forming Macrophomate synthasea Decarboxylation two carbon-carbon bonds a An alternative, non-[4+2] mechanism has been proposed at the same time with no for this enzyme. SOURCES: ChemBioChem, Journal of the transient intermediates. American Chemical Society, Journal of Biological Chemistry “My gut feeling is this is a
BIOCHEMISTRY: Newly discovered enzyme could help determine whether Diels-Alder reaction occurs in nature
T
HE SEARCH may be nearing an end for an en-
zyme that can catalyze one of chemistry’s most recognizable transformations—the Diels-Alder reaction (Nature, DOI: 10.1038/nature09981). A new study establishes how the insecticide spinosyn A is made in nature and introduces the first enzyme that exclusively catalyzes a [4+2] cycloaddition, a class of reactions that includes the Diels-Alder reaction. Since its debut 83 years ago, the Diels-Alder reaction, which forms a cyclohexene ring from a conjugated diene and an alkene or alkyne, has become a powerful way to build industrial and pharmaceutical chemicals. For almost as long, researchers have wondered whether nature is also capable of this chemistry. Now, Hung-wen (Ben) Liu and coworkers at the University of Texas, Austin, have found an enzyme
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ONE JOB The enzyme SpnF exclusively catalyzes a [4+2] cycloaddition en route to spinosyn A. called SpnF that might put that question to rest. SpnF is encoded by one of four genes Liu’s team studied, from a gene cluster that the microbe Saccharopolyspora spinosa uses to make spinosyn A, which Dow Agrosciences markets as an insecticide. Liu’s team purified proteins from each of the four genes and tested their activity on spinosyn precursors. They used nuclear magnetic resonance and mass spectrometry to identify products and high-performance liquid chromatography to track reaction kinetics. It turned out that SpnF performs one job exclusively: accelerating [4+2] cyclization to form a cyclohexene. The reaction occurs on its own, but with SpnF it takes 20 minutes rather than 2 hours, Liu says. Swift cyclization
Diels-Alder reaction,” Liu says. “But we don’t have the evidence yet.” His group is collaborating with an X-ray crystallographer to determine what SpnF looks like and is preparing isotopically labeled versions of spinosyn A precursors for more kinetic studies. The enzyme’s catalytic activity is low but not unheard of, says Forrest E. Michael, a University of Washington organic chemistry professor who last year helped design an enzyme that catalyzes a Diels-Alder reaction (C&EN, July 19, 2010, page 5). The interest now lies in figuring out how SpnF works, he says. “As synthetic organic chemists, we have many ways of accelerating these kinds of cyclizations. It’ll be exciting to see what nature chose.”—CARMEN DRAHL
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