Laura M. K. Dassama scite author profile

Metal homeostasis poses a major challenge to microbes, which must acquire scarce elements for core metabolic processes. Methanobactin, an extensively modified copper-chelating peptide, was one of the earliest natural products shown to enable microbial acquisition of a metal other than iron. We describe the core biosynthetic machinery responsible for the characteristic posttranslational modifications that grant methanobactin its specificity and affinity for copper. A heterodimer comprising MbnB, a DUF692 family iron enzyme, and MbnC, a protein from a previously unknown family, performs a dioxygen-dependent four-electron oxidation of the precursor peptide (MbnA) to install an oxazolone and an adjacent thioamide, the characteristic methanobactin bidentate copper ligands. MbnB and MbnC homologs are encoded together and separately in many bacterial genomes, suggesting functions beyond their roles in methanobactin biosynthesis.

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Structural Basis for Assembly of the Mn^IV/Fe^III Cofactor in the Class Ic Ribonucleotide Reductase from Chlamydia trachomatis

Dassama

Krebs

Bollinger

et al. 2013

Biochemistry

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The class Ic ribonucleotide reductase (RNR) from Chlamydia trachomatis (Ct) employs a MnIV/FeIII cofactor in each monomer of its β2 subunit to initiate nucleotide reduction. The cofactor forms by reaction of MnII/FeII-β2 with O2. Previously, in vitro cofactor assembly from apo β2 and divalent metal ions produced a mixture of two forms, with Mn in site 1 (MnIV/FeIII) or site 2 (FeIII/MnIV), of which the more active MnIV/FeIII product predominates. Here we have addressed the basis for metal site-selectivity by solving X-ray crystal structures of apo, MnII, and MnII/FeII complexes of Ct β2. A structure obtained anaerobically with equimolar MnII, FeII, and apo protein reveals exclusive incorporation of MnII in site 1 and FeII in site 2, in contrast to the more modest site-selectivity achieved previously. Site-specificity is controlled thermodynamically by the apo protein structure, as only minor adjustments of ligands occur upon metal binding. Additional structures imply that, by itself, MnII binds in either site. Together the structures are consistent with a model for in vitro cofactor assembly in which FeII specificity for site 2 drives assembly of the appropriately configured heterobimetallic center, provided that FeII is substoichiometric. This model suggests that use of an MnIV/FeIII cofactor in vivo could be an adaptation to FeII limitation. A 1.8 Å resolution model of the MnII/FeII-β2 complex reveals additional structural determinants for activation of the cofactor, including a proposed site for side-on (η2) addition of O2 to FeII and a short (3.2 Å) MnII-FeII interionic distance, promoting formation of the MnIV/FeIV activation intermediate.

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Methanobactin transport machinery

Dassama

Kenney

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Methanotrophic bacteria use methane, a potent greenhouse gas, as their primary source of carbon and energy. The first step in methane metabolism is its oxidation to methanol. In almost all methanotrophs, this chemically challenging reaction is catalyzed by particulate methane monooxygenase (pMMO), a copper-dependent integral membrane enzyme. Methanotrophs acquire copper (Cu) for pMMO by secreting a small ribosomally produced, posttranslationally modified natural product called methanobactin (Mbn). Mbn chelates Cu with high affinity, and the Cu-loaded form (CuMbn) is reinternalized into the cell via an active transport process. Bioinformatic and gene regulation studies suggest that two proteins might play a role in CuMbn handling: the TonB-dependent transporter MbnT and the periplasmic binding protein MbnE. Disruption of the gene that encodes MbnT abolishes CuMbn uptake, as reported previously, and expression of MbnT in Escherichia coli confers the ability to take up CuMbn. Biophysical studies of MbnT and MbnE reveal specific interactions with CuMbn, and a crystal structure of apo MbnE is consistent with MbnE's proposed role as a periplasmic CuMbn transporter. Notably, MbnT and MbnE exhibit different levels of discrimination between cognate and noncognate CuMbns. These findings provide evidence for CuMbn–protein interactions and begin to elucidate the molecular mechanisms of its recognition and transport.

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Rational targeting of a NuRD subcomplex guided by comprehensive in situ mutagenesis

et al. 2019

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Developmental silencing of fetal globins serves as both a paradigm of spatiotemporal gene regulation and an opportunity for β-hemoglobinopathy therapeutic intervention. The NuRD chromatin complex participates in γ-globin repression. Here we use pooled CRISPR screening to comprehensively disrupt NuRD protein coding sequences in human adult erythroid precursors. We find essential for fetal hemoglobin (HbF) control a nonredundant subcomplex of NuRD protein family paralogs, whose composition we corroborate by affinity chromatography and proximity labeling mass spectrometry proteomics. Mapping top functional guide RNAs identifies key protein interfaces where in-frame alleles result in loss-of-function due to destabilization or altered function of subunits. We ascertain mutations of CHD4 that dissociate its requirement for cell fitness from HbF repression in both primary human erythroid precursors and transgenic mice. Finally we demonstrate that sequestering CHD4 from NuRD phenocopies these mutations. This work indicates a generalizable approach to discover protein complex features amenable to rational biochemical targeting.

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Laura M. K. Dassama

The biosynthesis of methanobactin

Structural Basis for Assembly of the Mn^IV/Fe^III Cofactor in the Class Ic Ribonucleotide Reductase from Chlamydia trachomatis

Methanobactin transport machinery

Rational targeting of a NuRD subcomplex guided by comprehensive in situ mutagenesis

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About

Laura M. K. Dassama

The biosynthesis of methanobactin

Structural Basis for Assembly of the MnIV/FeIII Cofactor in the Class Ic Ribonucleotide Reductase from Chlamydia trachomatis

Methanobactin transport machinery

Rational targeting of a NuRD subcomplex guided by comprehensive in situ mutagenesis

Contact Info

Product

Resources

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Structural Basis for Assembly of the Mn^IV/Fe^III Cofactor in the Class Ic Ribonucleotide Reductase from Chlamydia trachomatis