The bacterial enzyme 5 0 -methylthioadenosine/S-adenosylhomocysteine nucleosidase (MTAN) plays a central role in three essential metabolic pathways in bacteria: methionine salvage, purine salvage, and polyamine biosynthesis. Recently, its role in the pathway that leads to the production of autoinducer II, an important component in quorum-sensing, has garnered much interest. Because of this variety of roles, MTAN is an attractive target for developing new classes of inhibitors that influence bacterial virulence and biofilm formation. To gain insight toward the development of new classes of MTAN inhibitors, the interactions between the Helicobacter pyloriencoded MTAN and its substrates and substrate analogs were probed using X-ray crystallography. The structures of MTAN, an MTAN-Formycin A complex, and an adenine bound form were solved by molecular replacement and refined to 1.7, 1.8, and 1.6 Å , respectively. The ribose-binding site in the MTAN and MTAN-adenine cocrystal structures contain a tris [hydroxymethyl]aminomethane molecule that stabilizes the closed form of the enzyme and displaces a nucleophilic water molecule necessary for catalysis. This research gives insight to the interactions between MTAN and bound ligands that promote closing of the enzyme active site and highlights the potential for designing new classes of MTAN inhibitors using a link/grow or ligand assembly development strategy based on the described H. pylori MTAN crystal structures.
MTAN (5′-methylthioadenosine nucleosidase) catalyzes the hydrolysis of the N-ribosidic bond of a variety of adenosine-containing metabolites. The Helicobacter pylori MTAN (HpMTAN) hydrolyzes 6-amino-6-deoxyfutalosine in the second step of the alternative menaquinone biosynthetic pathway. Substrate binding of the adenine moiety is mediated almost exclusively by hydrogen bonds, and the proposed catalytic mechanism requires multiple protontransfer events. Of particular interest is the protonation state of residue D198, which possesses a pK a above 8 and functions as a general acid to initiate the enzymatic reaction. In this study we present three corefined neutron/X-ray crystal structures of wildtype HpMTAN cocrystallized with S-adenosylhomocysteine (SAH), Formycin A (FMA), and (3R,4S)-4-(4-Chlorophenylthiomethyl)-1-[(9-deazaadenin-9-yl)methyl]-3-hydroxypyrrolidine (p-ClPh-Thio-DADMe-ImmA) as well as one neutron/X-ray crystal structure of an inactive variant (HpMTAN-D198N) cocrystallized with SAH. These results support a mechanism of D198 pKa elevation through the unexpected sharing of a proton with atom N7 of the adenine moiety possessing unconventional hydrogen-bond geometry. Additionally, the neutron structures also highlight active site features that promote the stabilization of the transition state and slight variations in these interactions that result in 100-fold difference in binding affinities between the DADMe-ImmA and ImmA analogs.neutron diffraction | enzyme mechanism | proton transfer | nucleosidase | Helicobacter
The bacterial 5’-methylthioadenosine/S-adenosylhomocysteine nucleosidase (MTAN) enzyme is a multifunctional enzyme that catalyzes the hydrolysis of the N-ribosidic bond of at least four different adenosine-based metabolites: S-adenosylhomocysteine (SAH), 5’methylthioadenosine (MTA), 5’-deoxyadenosine (5’-DOA) and 6-amino-6-deoxyfutalosine. These activities place the enzyme at the hub of seven fundamental bacterial metabolic pathways: S-adenosylmethionine (SAM) utilization, polyamine biosynthesis, the purine salvage pathway, the methionine salvage pathway, the SAM radical pathways, autoinducer-2 biosynthesis, and menaquinone biosynthesis. The last pathway makes MTAN essential for H. pylori viability. Although structures of various bacterial and plant MTANs have been described, the interactions between the homocysteine moiety of SAH and the 5’-alkylthiol binding site of MTAN have never been resolved. We have solved crystal structures of an inactive mutant form of Helicobacter pylori MTAN bound to MTA and SAH to 1.63 and 1.20 Å, respectively. The active form of MTAN was also crystallized in the presence of SAH allowing structure determination of a ternary enzyme-product complex resolved at 1.50 Å. These structures identify interactions between the homocysteine moiety and the 5’-alkylthiol binding site of the enzyme. This information can be leveraged for the development of species-specific MTAN inhibitors that prevent the growth of H. pylori.
S-Adenosylmethionine (AdoMet)-dependent methyltransferases (MTases) are an essential superfamily of enzymes that catalyze the transfer of a methyl group to several biomolecules. Alterations in the methylation of cellular components crucially impact vital biological processes, making MTases attractive drug targets for treating infectious diseases and diseases caused by overactive human-encoded MTases. Several methods have been developed for monitoring the activity of MTases, but most MTase assays have inherent limitations or are not amenable for high-throughput screening. We describe a universal, competitive fluorescence polarization (FP) assay that directly measures the production of S-adenosylhomocysteine (AdoHcy) from MTases. Our developed assay monitors the generation of AdoHcy by displacing a fluorescently labeled AdoHcy molecule complexed to a catalytically inert 5′-methylthioadenosine nucleosidase (MTAN-D198N) variant performed in a mix-and-read format. Producing the fluorescently labeled molecule involves a one-pot synthesis by combining AdoHcy with an amine-reactive rhodamine derivative, which possesses a Kd value of 11.3 ± 0.7 nM to MTAN-D198N. The developed competitive FP assay expresses a limit of detection for AdoHcy of 6 nM and exhibits a 34-fold preference to AdoHcy in comparison to AdoMet. We demonstrate the utility of the developed assay by performing a pilot screen with the NIH Clinical Collection as well as determining the kinetic parameters of l-histidine methylation for EgtD from Mycobacterium tuberculosis. Additionally, the developed assay is applicable to other AdoMet-dependent and ATP-dependent enzymes by detecting various adenosine-containing molecules including 5′-methylthioadenosine, AMP, and ADP.
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