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Abstract: Cut-and-paste DNA transposons of the mariner/Tc1 family are useful tools for genome engineering and are inserted specifically at TA target sites. A crystal structure of the mariner transposase Mos1 (derived from Drosophila mauritiana), in complex with transposon ends covalently joined to target DNA, portrays the transposition machinery after DNA integration. It reveals severe distortion of target DNA and flipping of the target adenines into extra-helical positions. Fluorescence experiments confirm dynamic base flipping in solution. Transposase residues W159, R186, F187 and K190 stabilise the target DNA distortions and are required for efficient transposon integration and transposition in vitro. Transposase recognises the flipped target adenines via base-specific interactions with backbone atoms, offering a molecular basis for TA target sequence selection. Our results will provide a template for re-designing mariner/Tc1 transposases with modified target specificities.

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Abstract: Methane-oxidizing bacteria (methanotrophs) require large quantities of copper for the membrane-bound (particulate) methane monooxygenase1, 2. Certain methanotrophs are also able to switch to using the iron-containing soluble methane monooxygenase to catalyse methane oxidation, with this switchover regulated by copper3, 4. Methane monooxygenases are nature’s primary biological mechanism for suppressing atmospheric levels of methane, a potent greenhouse gas. Furthermore, methanotrophs and methane monooxygenases have enormous potential in bioremediation and for biotransformations producing bulk and fine chemicals, and in bioenergy, particularly considering increased methane availability from renewable sources and hydraulic fracturing of shale rock5, 6. Here we discover and characterize a novel copper storage protein (Csp1) from the methanotroph Methylosinus trichosporium OB3b that is exported from the cytosol, and stores copper for particulate methane monooxygenase. Csp1 is a tetramer of four-helix bundles with each monomer binding up to 13 Cu(I) ions in a previously unseen manner via mainly Cys residues that point into the core of the bundle. Csp1 is the first example of a protein that stores a metal within an established protein-folding motif. This work provides a detailed insight into how methanotrophs accumulate copper for the oxidation of methane. Understanding this process is essential if the wide-ranging biotechnological applications of methanotrophs are to be realized. Cytosolic homologues of Csp1 are present in diverse bacteria, thus challenging the dogma that such organisms do not use copper in this location.

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Abstract: We report an engineered panel of ene-reductases (ERs) from Thermus scotoductus SA-01 (TsER) that combines control over facial selectivity in the reduction of electron deficient Cdouble bondC double bonds with thermostability (up to 70 °C), organic solvent tolerance (up to 40 % v/v) and a broad substrate scope (23 compounds, three new to literature). Substrate acceptance and facial selectivity of 3-methylcyclohexenone was rationalized by crystallisation of TsER C25D/I67T and in silico docking. The TsER variant panel shows excellent enantiomeric excess (ee) and yields during bi-phasic preparative scale synthesis, with isolated yield of up to 93 % for 2R,5S-dihydrocarvone (3.6 g). Turnover frequencies (TOF) of approximately 40 000 h−1 were achieved, which are comparable to rates in hetero- and homogeneous metal catalysed hydrogenations. Preliminary batch reactions also demonstrated the reusability of the reaction system by consecutively removing the organic phase (n-pentane) for product removal and replacing with fresh substrate. Four consecutive batches yielded ca. 27 g L−1 R-levodione from a 45 mL aqueous reaction, containing less than 17 mg (10 μM) enzyme and the reaction only stopping because of acidification. The TsER variant panel provides a robust, highly active and stereocomplementary base for further exploitation as a tool in preparative organic synthesis.

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Abstract: Bacterial microcompartments (BMCs) are proteinaceous metabolic compartments found in a wide range of bacteria, whose function it is to encapsulate pathways for the breakdown of various carbon sources, whilst retaining toxic and volatile intermediates formed from substrate breakdown. Examples of these metabolic processes are the 1,2- propanediol-breakdown pathway in Salmonella enterica (Pdu microcompartment), as well as the ethanolamine breakdown pathway in Clostridium difficile (Eut microcompartment). Some of the major challenges to exploiting BMCs as a tool in biotechnology are understanding how enzymes are targeted to microcompartments, as well as being able to engineer the protein shell of BMCs to make synthetic microcompartments that allow specific enzyme pathways to be targeted to their interior. Finally, the metabolic burden imposed by the production of large protein complexes requires a detailed knowledge of how the expression of these systems are controlled. This project explores the structure and biochemistry of an essential BMC pathway enzyme, the acylating propionaldehyde dehydrogenase. With crystal structures of the enzyme with the cofactors in the cofactor binding site and biochemical data presented to confirm the enzyme’s substrate. The project also focuses on the creation of synthetic biology tools to enable BMC engineering with a modular library of BMC shell protein parts; forward engineered ribosome binding sites (RBS) fused to BMC aldehyde dehydrogenase localisation sequences. The parts for this library were taken from the BMC loci found in Clostridium phytofermentans and Salmonella enterica. Using a synthetic biology toolkit will allow the rapid prototyping of BMC constructs for use in metabolic engineering. The shell protein parts were used to generate a number of transcriptional units, to assess the effect of overexpression of individual BMC shell components on the morphology of BMCs and the effect these had on their host chassis. Different strength forward engineered RBS and localisation constructs have been designed to assess the possibility of controlling the levels of heterologous proteins targeted to the interior of microcompartment shell to allow metabolic engineering of encapsulated pathways. Along with looking at overexpression of a single shell protein, to assess viability of BMCs as scaffold-like structures, recombinant BMCs can be explored for their utility in bioengineering and their potential role in generating biofuels.

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Abstract: The enzymatic cleavage of β-1,4-mannans is achieved by endo-β-1,4-mannanases, enzymes involved in germination of seeds and microbial hemicellulose degradation, and which have increasing industrial and consumer product applications. β-Mannanases occur in a range of families of the CAZy sequence-based glycoside hydrolase (GH) classification scheme including families 5, 26, and 113. In this work we reveal that β-mannanases of the newly described GH family 134 differ from other mannanase families in both their mechanism and tertiary structure. A representative GH family 134 endo-β-1,4-mannanase from a Streptomyces sp. displays a fold closely related to that of hen egg white lysozyme but acts with inversion of stereochemistry. A Michaelis complex with mannopentaose, and a product complex with mannotriose, reveal ligands with pyranose rings distorted in an unusual inverted chair conformation. Ab initio quantum mechanics/molecular mechanics metadynamics quantified the energetically accessible ring conformations and provided evidence in support of a 1C4 → 3H4‡ → 3S1 conformational itinerary along the reaction coordinate. This work, in concert with that on GH family 124 cellulases, reveals how the lysozyme fold can be co-opted to catalyze the hydrolysis of different polysaccharides in a mechanistically distinct manner.