Hygromycin B is an aminoglycoside antibiotic with a structurally distinctive orthoester linkage. Despite its long history of use in industry and in the laboratory, its biosynthesis remains poorly understood. We show here, by in-frame gene deletion in vivo and detailed enzyme characterization in vitro, that formation of the unique orthoester moiety is catalyzed by the α-ketoglutarate- and non-heme iron-dependent oxygenase HygX. In addition, we identify HygF as a glycosyltransferase adding UDP-hexose to 2-deoxystreptamine, HygM as a methyltransferase responsible for N-3 methylation, and HygK as an epimerase. These experimental results and bioinformatic analyses allow a detailed pathway for hygromycin B biosynthesis to be proposed, including the key oxidative cyclization reactions.
Streptovaricin C is a naphthalenic ansamycin antibiotic structurally similar to rifamycins with potential anti-MRSA bioactivities. However, the formation mechanism of the most fascinating and bioactivity-related methylenedioxy bridge (MDB) moiety in streptovaricins is unclear. Based on genetic and biochemical evidences, we herein clarify that the P450 enzyme StvP2 catalyzes the MDB formation in streptovaricins, with an atypical substrate inhibition kinetics. Furthermore, X-ray crystal structures in complex with substrate and structure-based mutagenesis reveal the intrinsic details of the enzymatic reaction. The mechanism of MDB formation is proposed to be an intramolecular nucleophilic substitution resulting from the hydroxylation by the heme core and the keto-enol tautomerization via a crucial catalytic triad (Asp89-His92-Arg72) in StvP2. In addition, in vitro reconstitution uncovers that C6-O-methylation and C4-O-acetylation of streptovaricins are necessary prerequisites for the MDB formation. This work provides insight for the MDB formation and adds evidence in support of the functional versatility of P450 enzymes.
Gentamicin is an
important aminoglycoside antibiotic used for treatment
of infections caused by Gram-negative bacteria. Although most of the
biosynthetic pathways of gentamicin have been elucidated, a remaining
intriguing question is how the intermediates JI-20A and JI-20B undergo
a dideoxygenation to form gentamicin C complex. Here we show that
the dideoxygenation process starts with GenP-catalyzed phosphorylation
of JI-20A and JI-20Ba. The phosphorylated products are successively
modified by concerted actions of two PLP (pyridoxal 5′-phosphate)-dependent
enzymes: elimination of water and then phosphate by GenB3 and double
bond migration by GenB4. Each of these reactions liberates an imine
which hydrolyses to a ketone or aldehyde and is then reaminated by
GenB3 using an amino donor. Importantly, crystal structures of GenB3
and GenB4 have guided site-directed mutagenesis to reveal crucial
residues for the enzymes’ functions. We propose catalytic mechanisms
for GenB3 and GenB4, which shed light on the already unrivalled catalytic
versatility of PLP-dependent enzymes.
The colinearity of canonical modular polyketide synthases, which creates a direct link between multienzyme structure and the chemical structure of the biosynthetic end‐product, has become a cornerstone of knowledge‐based genome mining. Herein, we report genetic and enzymatic evidence for the remarkable role of an enoylreductase in the polyketide synthase for azalomycin F biosynthesis. This internal enoylreductase domain, previously identified as acting only in the second of two chain extension cycles on an initial iterative module, is shown to also catalyze enoylreduction in trans within the next module. The mechanism for this rare deviation from colinearity appears to involve direct cross‐modular interaction of the reductase with the longer acyl chain, rather than back transfer of the substrate into the iterative module, suggesting an additional and surprising plasticity in natural PKS assembly‐line catalysis.
A bioassay‐guided fractionation led to the isolation of hangtaimycin (HTM) from Streptomyces spectabilis CCTCC M2017417 and the discovery of its hepatoprotective properties. Structure elucidation by NMR suggested the need for a structural revision. A putative HTM degradation product was also isolated and its structure was confirmed by total synthesis. The biosynthetic gene cluster was identified and resembles a hybrid trans‐AT PKS/NRPS biosynthetic machinery whose first PKS enzyme contains an internal dehydrating bimodule, which is usually found split in other trans‐AT PKSs. The mechanisms of such dehydrating bimodules have often been proposed, but have never been deeply investigated. Here we present in vivo mutations and in vitro enzymatic experiments that give first and detailed mechanistic insights into catalysis by dehydrating bimodules.
Eine durch Bioassay geleitete Fraktionierung führte zur Isolierung von Hangtaimycin (HTM) aus Streptomyces spectabilis CCTCC M2017417 und zur Entdeckung seiner hepatoprotektiven Eigenschaften. Die Strukturaufklärung per NMR zeigte die Notwendigkeit einer Strukturrevision. Ein putatives Abbauprodukt von HTM wurde ebenfalls isoliert und dessen Struktur wurde durch Totalsynthese bestätigt. Der Biosynthesegencluster wurde identifiziert und entspricht einer hybriden trans‐AT‐PKS/NRPS Biosynthesemaschinerie, dessen erstes PKS‐Enzym ein internes dehydatisierendes Bimodul enthält, welche in anderen trans‐AT PKSs üblicherweise gespalten vorliegen. Die Mechanismen solcher dehydatisierender Bimodule wurden oft vorgeschlagen, aber niemals genau untersucht. Hier präsentieren wir in vivo‐Mutationen und enzymatische in vitro‐Experimente, die erste und detaillierte Einblicke in die Katalyse durch dehydatisierende Bimodule geben.
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