Halogenases for biosynthetic pathway engineering : toward new routes to naturals and non-naturals

This paper explores the implications for international development policy and practice - specifically within the sectors of building security and justice after conflict - of the departure of those assuming caring roles, predominantly women who become mothers. More broadly, this paper explores how personal life stories impact the choices we make in our professional lives, including where, when and how we engage, in this instance, in international development, and the subsequent implications for the field. These choices (the personal) have an impact on policy and practice (the professional), and inform how knowledge is created, circulated, legitimised and becomes expert knowledge (the political). This paper thus explores the implications of an epistemic community being predominantly male (in part as a consequence of the lack of support for social reproductive work) on how security and justice in post-conflict environments are conceived and, ultimately, rebuilt. The authors reflect upon their engagement in conflict-affected environments – Nature’s repertoire of bio-halogenase enzymes is intriguing with halogenases from various natural product biosynthetic clusters that carry out site and regio specific halogenation of diverse bioactive precursors and molecules. Currently, we have a comprehensive catalogue of cryptic and non-cryptic halogenases that act on simple to complex aliphatic and aromatic molecular scaffolds. This will open up further synthetic and biosynthetic opportunities for C-H activation, ring formation and functionalization of different molecular structures. In fact, halogenases were exploited over the years for these potential applications, to replace traditional chemical halogenation chemistries towards creating economical and environmentally benign methodologies and also for biosynthetic pathways. This review will discuss our advances in utilizing bio-halogenases to generate both in vivo and in vitro biosynthetic pathways; summarizing all naturals and non-naturals that are synthesized with a direct bio-halogenase incorporation

Versatile and facile one-pot biosynthesis for amides and carboxylic acids in E. coli by engineering auxin pathways of plant microbiomes

The development of enzymatic routes toward amide and carboxylic acid bond formation in bioactive molecular scaffolds using aqueous conditions is a major challenge for biopharmaceutical and fine chemical industrial sectors. We report biocatalytic and kinetic characterization of two indole-3-acetamide (IAM) pathway enzymes, tryptophan-2-monooxygenase (iaaM) and indole-3-acetamide hydrolase (iaaH), present in plant microbiomes that produce indole-3-acetic acid (IAA). In this pathway, tryptophan is converted to indole-3-acetamide by the monooxygenase activity of iaaM, followed by its hydrolysis to form carboxylic acid by iaaH enzyme. Since IAA or auxin is an essential natural plant hormone and an important synthon for fine chemicals, the developed monooxygenase-based bioconversion route has a wider scope compared to currently available synthetic and biocatalytic methods to produce synthetic auxins and a range of amides and carboxylic acids for agrochemical and pharmaceutical applications. To display this, one-pot multienzyme biosynthetic cascades for preparative-scale production of IAA derivatives were performed by incorporating tryptophan synthase and tryptophan halogenase enzymes. We also report the creation of an efficient de novo biosynthesis for IAA and its derivatives from glucose or indoles via a reconstructed IAM pathway in Escherichia coli

Assembling a plug-and-play production line for combinatorial biosynthesis of aromatic polyketides in Escherichia coli

Polyketides are a class of specialised metabolites synthesised by both eukaryotes and prokaryotes. These chemically and structurally diverse molecules are heavily used in the clinic and include frontline antimicrobial and anticancer drugs such as erythromycin and doxorubicin. To replenish the clinicians’ diminishing arsenal of bioactive molecules, a promising strategy aims at transferring polyketide biosynthetic pathways from their native producers into the biotechnologically desirable host Escherichia coli. This approach has been successful for type I modular polyketide synthases (PKSs); however, despite more than 3 decades of research, the large and important group of type II PKSs has until now been elusive in E. coli. Here, we report on a versatile polyketide biosynthesis pipeline, based on identification of E. coli–compatible type II PKSs. We successfully express 5 ketosynthase (KS) and chain length factor (CLF) pairs—e.g., from Photorhabdus luminescens TT01, Streptomyces resistomycificus, Streptoccocus sp. GMD2S, Pseudoalteromonas luteoviolacea, and Ktedonobacter racemifer—as soluble heterodimeric recombinant proteins in E. coli for the first time. We define the anthraquinone minimal PKS components and utilise this biosynthetic system to synthesise anthraquinones, dianthrones, and benzoisochromanequinones (BIQs). Furthermore, we demonstrate the tolerance and promiscuity of the anthraquinone heterologous biosynthetic pathway in E. coli to act as genetically applicable plug-and-play scaffold, showing it to function successfully when combined with enzymes from phylogenetically distant species, endophytic fungi and plants, which resulted in 2 new-to-nature compounds, neomedicamycin and neochaetomycin. This work enables plug-and-play combinatorial biosynthesis of aromatic polyketides using bacterial type II PKSs in E. coli, providing full access to its many advantages in terms of easy and fast genetic manipulation, accessibility for high-throughput robotics, and convenient biotechnological scale-up. Using the synthetic and systems biology toolbox, this plug-and-play biosynthetic platform can serve as an engine for the production of new and diversified bioactive polyketides in an automated, rapid, and versatile fashion

Kinetic and mechanistic studies of the light activated enzyme Protochlorophyllide oxidoreductase (POR) by protein engineering

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The missing colours of chemistry

Ingrained prejudices and a lack of action addressing discrimination are some of the main reasons why academic chemistry is overwhelmingly white. Data and discussions on racial inequalities are often greeted with scepticism and cynicism within the community, yet they are necessary to fight racism — and anti-Black racism in particular

Conformational events during ternary enzyme-substrate complex formation are rate limiting in the catalytic cycle of the light-driven enzyme protochlorophyllide oxidoreductase

The light-driven enzyme, protochlorophyllide oxidoreductase (POR), has proven to be an excellent model system for studying the role of protein motions during catalysis. POR catalyzes the trans addition of hydrogen across the C17−C18 double bond of protochlorophyllide (Pchlide), which is a key step in chlorophyll biosynthesis. While we currently have a detailed understanding of the initial photochemical events and the subsequent hydrogen transfer reactions, there remains a lack of information about the slower substrate binding events leading to the formation of the catalytically active ternary complex. As POR is light-activated, it is relatively straightforward to isolate the ternary enzyme−substrate complex in the dark prior to catalysis, which has facilitated the use of a variety of spectroscopic and kinetic probes to study the binding of both substrates. Herein, we provide a detailed kinetic and thermodynamic description of these processes and show that the binding events are complex, involving multiple conformational states en route to the formation of a ternary complex that is primed for photoactivation. The initial binding of NADPH involves three distinct steps, which appear to be necessary for the optimal alignment of the cofactor in the enzyme active site. This is followed by the binding of the Pchlide substrate and subsequent substrate-induced conformational changes within the enzyme that occur prior to the formation of the final “poised” conformational state. These studies, which provide important information on the formation of the reactive conformation, reveal that ternary complex formation is the rate-limiting step in the overall reaction and is controlled by slow conformational changes in the protein

Cryogenic and Laser Photoexcitation Studies Identify Multiple Roles for Active Site Residues in the Light-driven Enzyme Protochlorophyllide Oxidoreductase*

The light-activated enzyme NADPH-protochlorophyllide oxidoreductase (POR) catalyzes the trans addition of hydrogen across the C-17–C-18 double bond of protochlorophyllide (Pchlide), a key step in chlorophyll biosynthesis. Similar to other members of the short chain alcohol dehydrogenase/reductase family of enzymes, POR contains a conserved Tyr and Lys residue in the enzyme active site, which are implicated in a proposed reaction mechanism involving proton transfer from the Tyr hydoxyl group to Pchlide. We have analyzed a number of POR variant enzymes altered in these conserved residues using a combination of steady-state turnover, laser photoexcitation studies, and low temperature fluorescence spectroscopy. None of the mutations completely abolished catalytic activity. We demonstrate their importance to catalysis by defining multiple roles in the overall reaction pathway. Mutation of either residue impairs formation of the ground state ternary enzyme-substrate complex, pointing to a key role in substrate binding. By analyzing the most active variant (Y193F), we show that Tyr-193 participates in proton transfer to Pchlide and stabilizes the Pchlide excited state, enabling hydride transfer from NADPH to Pchilde. Thus, in addition to confirming the probable identity of the proton donor in Pchlide reduction, our work defines additional roles for these residues in facilitating hydride transfer through stabilization of the ground and excited states of the ternary enzyme complex

Development of halogenase enzymes for use in synthesis

Nature has evolved halogenase enzymes to regioselectively halogenate a diverse range of biosynthetic precursors, with the halogens introduced often having a profound effect on the biological activity of the resulting natural products. Synthetic endeavors to create non-natural bioactive small molecules for pharmaceutical and agrochemical applications have also arrived at a similar conclusion: halogens can dramatically improve the properties of organic molecules for selective modulation of biological targets in vivo. Consequently, a high proportion of pharmaceuticals and agrochemicals on the market today possess halogens. Halogenated organic compounds are also common intermediates in synthesis and are particularly valuable in metal-catalyzed cross-coupling reactions. Despite the potential utility of organohalogens, traditional nonenzymatic halogenation chemistry utilizes deleterious reagents and often lacks regiocontrol. Reliable, facile, and cleaner methods for the regioselective halogenation of organic compounds are therefore essential in the development of economical and environmentally friendly industrial processes. A potential avenue toward such methods is the use of halogenase enzymes, responsible for the biosynthesis of halogenated natural products, as biocatalysts. This Review will discuss advances in developing halogenases for biocatalysis, potential untapped sources of such biocatalysts and how further optimization of these enzymes is required to achieve the goal of industrial scale biohalogenation

Multiple active site residues are important for photochemical efficiency in the light-activated enzyme protochlorophyllide oxidoreductase (POR)

Protochlorophyllide oxidoreductase (POR) catalyzes the light-driven reduction of protochlorophyllide (Pchlide), an essential, regulatory step in chlorophyll biosynthesis. The unique requirement of the enzyme for light has provided the opportunity to investigate how light energy can be harnessed to power biological catalysis and enzyme dynamics. Excited state interactions between the Pchlide molecule and the protein are known to drive the subsequent reaction chemistry. However, the structural features of POR and active site residues that are important for photochemistry and catalysis are currently unknown, because there is no crystal structure for POR. Here, we have used static and time-resolved spectroscopic measurements of a number of active site variants to study the role of a number of residues, which are located in the proposed NADPH/Pchlide binding site based on previous homology models, in the reaction mechanism of POR. Our findings, which are interpreted in the context of a new improved structural model, have identified several residues that are predicted to interact with the coenzyme or substrate. Several of the POR variants have a profound effect on the photochemistry, suggesting that multiple residues are important in stabilizing the excited state required for catalysis. Our work offers insight into how the POR active site geometry is finely tuned by multiple active site residues to support enzyme-mediated photochemistry and reduction of Pchlide, both of which are crucial to the existence of life on Earth

Structure and biocatalytic scope of coclaurine N-methyltransferase

Benzylisoquinoline alkaloids (BIAs) are a structurally diverse family of plant secondary metabolites, which have been exploited to develop analgesics, antibiotics, antitumor agents, and other therapeutic agents. Biosynthesis of BIAs proceeds via a common pathway from tyrosine to (S)‐reticulene at which point the pathway diverges. Coclaurine N‐methyltransferase (CNMT) is a key enzyme in the pathway to (S)‐reticulene, installing the N‐methyl substituent that is essential for the bioactivity of many BIAs. In this paper, we describe the first crystal structure of CNMT which, along with mutagenesis studies, defines the enzymes active site architecture. The specificity of CNMT was also explored with a range of natural and synthetic substrates as well as co‐factor analogues. Knowledge from this study could be used to generate improved CNMT variants required to produce BIAs or synthetic derivatives