Characterization of HphA: the First Enzyme in the Homologation Pathway of l-Phenylalanine and l-Tyrosine.

Homologation of amino acids is the insertion or deletion of a methylene group to their side chain, which is a relatively uncommon chemical transformation observed in peptide natural product (NP) structure. Homologated amino acids can potentially make the NP more stable in a biological system, but its biosynthesis is yet to be understood. This study biochemically characterized the first of three unexplored enzymes in the homologation pathway of l-phenylalanine and l-tyrosine. Previously proposed reactions catalyzed by HphA were confirmed by reversed-phase high-performance liquid chromatography and tandem mass spectrometry analysis. The substrate profile and kinetic parameters showed high selectivity for the natural substrates and their close analogs. The comparability of HphA to homologous enzymes in primary metabolic pathways, 2-isopropylmate synthase and homocitrate synthase which are involved in l-leucine and l-lysine biosynthesis, respectively, was validated by bioinformatical and site-directed mutagenesis studies. The knowledge obtained from this study has deepened the understanding of the homologation of amino acids, which can lead to future combinatorial biosynthesis and metabolic engineering studies.

High Electronic Coupling between Cu Complexes and Oxidized Dyes Confirmed by Measurements of Driving Force Dependent Regeneration Kinetics in Minimal Electrolyte System.

We confirm fast regeneration kinetics between copper complexes and oxidized organic dyes and the major contribution of electronic coupling (HDA). The highest efficiency of dye-sensitized TiO2 solar cells has been shown by employing Cu complex redox couples. Various groups have reported a fast regeneration rate of oxidized dyes by Cu complexes giving a low driving force attributed to low reorganization energy (λ), but the effect of HDA has not been evaluated. The values of HDA and λ can be derived from driving force dependent transient absorption (TA) measurements. However, analyzing TA decay using Cu complexes is not trivial because accelerated recombination by the presence of Cu2+ complexes and biphasic TA decay often complicates the analysis. Here we employ 16 Cu1+ and Co2+ complexes and two dyes. To simplify the system, i.e., making a minimal electrolyte system, Cu2+ and Co3+ complexes and a common additive of 4-tert-butylpyridine are not used. From the driving force dependent TA decays of oxidized dyes by both Cu1+ and Co2+ complexes, λ for the combination of the Cu complexes and dyes is found to be about 0.15 eV lower than that of Co complexes. Approximately 3 to 5 times higher HDA values of Cu complexes than those of Co complexes are obtained, which is the dominant factor for faster rates. The values vary with the structure of the molecules, showing the possibility of increasing the HDA values further. The higher HDA values of a Cu complex than that of a Co complex are also reproduced by quantum chemical calculations.

Natural Products That Contain Higher Homologated Amino Acids.

This review focuses on discussing natural products (NPs) that contain higher homologated amino acids (homoAAs) in the structure as well as the proposed and characterized biosynthesis of these non-proteinogenic amino acids. Homologation of amino acids includes the insertion of a methylene group into its side chain. It is not a very common modification found in NP biosynthesis as approximately 450 homoAA-containing NPs have been isolated from four bacterial phyla (Cyanobacteria, Actinomycetota, Myxococcota, and Pseudomonadota), two fungal phyla (Ascomycota and Basidiomycota), and one animal phylum (Porifera), except for a few examples. Amino acids that are found to be homologated and incorporated in the NP structures include the following ten amino acids: alanine, arginine, cysteine, isoleucine, glutamic acid, leucine, phenylalanine, proline, serine, and tyrosine, where isoleucine, leucine, phenylalanine, and tyrosine share the comparable enzymatic pathway. Other amino acids have their individual homologation pathway (arginine, proline, and glutamic acid for bacteria), likely utilize the primary metabolic pathway (alanine and glutamic acid for fungi), or have not been reported (cysteine and serine). Despite its possible high potential in the drug discovery field, the biosynthesis of homologated amino acids has a large room to explore for future combinatorial biosynthesis and metabolic engineering purpose.

Cell polarity linked to gravity sensing is generated by LZY translocation from statoliths to the plasma membrane.

Organisms have evolved under gravitational force, and many sense the direction of gravity by means of statoliths in specialized cells. In flowering plants, starch-accumulating plastids, known as amyloplasts, act as statoliths to facilitate downstream gravitropism. The gravity-sensing mechanism has long been considered a mechanosensing process by which amyloplasts transmit forces to intracellular structures, but the molecular mechanism underlying this has not been elucidated. We show here that LAZY1-LIKE (LZY) family proteins involved in statocyte gravity signaling associate with amyloplasts and the proximal plasma membrane. This results in polar localization according to the direction of gravity. We propose a gravity-sensing mechanism by which LZY translocation to the plasma membrane signals the direction of gravity by transmitting information on the position of amyloplasts.

The draft genome sequence of the Japanese rhinoceros beetle Trypoxylus dichotomus septentrionalis towards an understanding of horn formation.

The Japanese rhinoceros beetle Trypoxylus dichotomus is a giant beetle with distinctive exaggerated horns present on the head and prothoracic regions of the male. T. dichotomus has been used as a research model in various fields such as evolutionary developmental biology, ecology, ethology, biomimetics, and drug discovery. In this study, de novo assembly of 615 Mb, representing 80% of the genome estimated by flow cytometry, was obtained using the 10 × Chromium platform. The scaffold N50 length of the genome assembly was 8.02 Mb, with repetitive elements predicted to comprise 49.5% of the assembly. In total, 23,987 protein-coding genes were predicted in the genome. In addition, de novo assembly of the mitochondrial genome yielded a contig of 20,217 bp. We also analyzed the transcriptome by generating 16 RNA-seq libraries from a variety of tissues of both sexes and developmental stages, which allowed us to identify 13 co-expressed gene modules. We focused on the genes related to horn formation and obtained new insights into the evolution of the gene repertoire and sexual dimorphism as exemplified by the sex-specific splicing pattern of the doublesex gene. This genomic information will be an excellent resource for further functional and evolutionary analyses, including the evolutionary origin and genetic regulation of beetle horns and the molecular mechanisms underlying sexual dimorphism.

Phosphorus-Based Organocatalysis for the Dehydrative Cyclization of N-(2-Hydroxyethyl)amides into 2-Oxazolines.

A metal-free, biomimetic catalytic protocol for the cyclization of N-(2-hydroxyethyl)amides to the corresponding 2-oxazolines (4,5-dihydrooxazoles), promoted by the 1,3,5,2,4,6-triazatriphosphorine (TAP)-derived organocatalyst tris(o-phenylenedioxy)cyclotriphosphazene (TAP-1) has been developed. This approach requires less precatalyst compared to the reported relevant systems, with respect to the phosphorus atom (the maximum turnover number (TON) ∼ 30), and exhibits a broader substrate scope and higher functional-group tolerance, providing the functionalized 2-oxazolines with retention of the configuration at the C(4) stereogenic center of the 2-oxazolines. Widely accessible ß-amino alcohols can be used in this approach, and the cyclization of N-(2-hydroxyethyl)amides provides the desired 2-oxazolines in up to 99% yield. The mechanism of the reaction was studied by monitoring the reaction using spectral and analytical methods, whereby an 18O-labeling experiment furnished valuable insights. The initial step involves a stoichiometric reaction between the substrate and TAP-1, which leads to the in situ generation of the catalyst, a catechol cyclic phosphate, as well as to a pyrocatechol phosphate and two possible active intermediates. The dehydrative cyclization was also successfully conducted on the gram scale.

Substrate-Dependent Electron-Transfer Rate of Mixed-Ligand Electrolytes: Tuning Electron-Transfer Rate without Changing Driving Force.

To meet various requirements for electron transfer (ET) at the substrate/electrolyte interface, mixed redox couples assigned to different functions have been applied. While in all studies the mixed redox species had different redox potentials, such redox systems inherently lose energy by ET between the species. We report interfacial ET kinetics employing mixed-ligand electrolytes based on Co2+/3+ complexes with mixtures of dimethyl- and dinonyl-substituted bipyridyl (bpy) ligands with the same redox potential. The ET rates of the mixed electrolytes decrease with the increasing ratio of the dinonyl-bpy ligand, with substrates adsorbed by molecules without alkyl chains due to a blocking effect. However, when the molecules on substrates have four alkyl chains, the ET rate between the molecules and the electrolytes with increasing ratio of the dinonyl-bpy ligand is enhanced. The substrate-dependent behavior is explained by selective intermolecular interactions. The results open design flexibility for mixed-redox electrolyte systems to control ET at multi-substrate interfaces and provide a novel means to tune ET rates simultaneously for various ET processes in a system without losing energy by the ET.

Unimodular Methylation by Adenylation-Thiolation Domains Containing an Embedded Methyltransferase.

Nonribosomal peptides (NRPs) are natural products that are biosynthesized by large multi-enzyme assembly lines called nonribosomal peptide synthetases (NRPSs). We have previously discovered that backbone or side chain methylation of NRP residues is carried out by an interrupted adenylation (A) domain that contains an internal methyltransferase (M) domain, while maintaining a monolithic AMA fold of the bifunctional enzyme. A key question that has remained unanswered is at which step of the assembly line mechanism the methylation by these embedded M domains takes place. Does the M domain methylate an amino acid residue tethered to a thiolation (T) domain on same NRPS module (in cis), or does it methylate this residue on a nascent peptide tethered to a T domain on another module (in trans)? In this study, we investigated the kinetics of methylation by wild-type AMAT tridomains from two NRPSs involved in biosynthesis of anticancer depsipeptides thiocoraline and echinomycin, and by mutants of these domains, for which methylation can occur only in trans. The analysis of the methylation kinetics unequivocally demonstrated that the wild-type AMATs methylate overwhelmingly in cis, strongly suggesting that this is also the case in the context of the entire NRPS assembly line process. The mechanistic insight gained in this study will facilitate rational genetic engineering of NRPS to generate unnaturally methylated NRPs.

Lessons learned in engineering interrupted adenylation domains when attempting to create trifunctional enzymes from three independent monofunctional ones.

Interrupted adenylation (A) domains are fascinating examples of multifunctional enzymes. They are found in nonribosomal peptide synthetases (NRPSs), which biosynthesize nonribosomal peptides (NRPs), a major class of medically relevant natural products (NPs). Interrupted A domains contain the catalytic portion of another domain within them, typically a methylation (M) domain, thus combining both adenylation and methylation capabilities. In recent years, interrupted A domains have demonstrated tremendous enzyme engineering potential as they are able to be constructed artificially in a laboratory setting by combining the A and M domains of two separate NRPS proteins. A recent discovery and characterization of a naturally occurring interrupted A domain that harbored two M domains back-to-back, a trifunctional protein, showed the ingenuity of Nature to both N- and O-methylate amino acids, the building blocks of NRPs. Since we have shown that a single M domain could be added to an uninterrupted A domain to create an artificial interrupted A domain, we set out to investigate if: (i) an A domain could be engineered to contain two back-to-back M domains and (ii) the added M domains would have to reflect the pattern in Nature, a side chain (O-) methylating M domain (Ms) followed by a backbone (N-) methylating M domain (Mb), or if the order of the M domains could be reversed. To address these questions, we set out to create our own AMsMbA and AMbMsA engineered interrupted A domains. We evaluated these engineered proteins connected (in cis) and/or disconnected (in trans) from the native thiolation (T) domain, through a series of radiometric assays, high performance liquid chromatography (HPLC), and mass spectrometry (MS) for adenylation, loading, and methylation ability. We found that although adenylation activity was preserved in both versions (AMsMbA and AMbMsA), addition of the M domains, in natural and unnatural order, did not result in the desired added methylation capability. This study offers valuable insights into the limits of constructing engineered interrupted A domains as potential tools for modifications of NRPs.

A thorough analysis and categorization of bacterial interrupted adenylation domains, including previously unidentified families.

Interrupted adenylation (A) domains are key to the immense structural diversity seen in the nonribosomal peptide (NRP) class of natural products (NPs). Interrupted A domains are A domains that contain within them the catalytic portion of another domain, most commonly a methylation (M) domain. It has been well documented that methylation events occur with extreme specificity on either the backbone (N-) or side chain (O- or S-) of the amino acid (or amino acid-like) building blocks of NRPs. Here, through taxonomic and phylogenetic analyses as well as multiple sequence alignments, we evaluated the similarities and differences between interrupted A domains. We probed their taxonomic distribution amongst bacterial organisms, their evolutionary relatedness, and described conserved motifs of each type of M domain found to be embedded in interrupted A domains. Additionally, we categorized interrupted A domains and the M domains within them into a total of seven distinct families and six different types, respectively. The families of interrupted A domains include two new families, 6 and 7, that possess new architectures. Rather than being interrupted between the previously described a2-a3 or a8-a9 of the ten conserved A domain sequence motifs (a1-a10), family 6 contains an M domain between a6-a7, a previously unknown interruption site. Family 7 demonstrates that di-interrupted A domains exist in Nature, containing an M domain between a2-a3 as well as one between a6-a7, displaying a novel arrangement. These in-depth investigations of amino acid sequences deposited in the NCBI database highlighted the prevalence of interrupted A domains in bacterial organisms, with each family of interrupted A domains having a different taxonomic distribution. They also emphasized the importance of utilizing a broad range of bacteria for NP discovery. Categorization of the families of interrupted A domains and types of M domains allowed for a better understanding of the trends of naturally occurring interrupted A domains, which illuminated patterns and insights on how to harness them for future engineering studies.

Characterization of a Unique Interrupted Adenylation Domain That Can Catalyze Three Reactions.

Interrupted adenylation (A) domains contain auxiliary domains within their structure and are a subject of growing interest in the field of nonribosomal peptide biosynthesis. They have been shown to possess intriguing functions and structure as well as promising engineering potential. Here, we present the characterization of an unprecedented type of interrupted A domain from the columbamides biosynthetic pathway, ColG(AMsMbA). This interrupted A domain contains two back-to-back methylation (M) domains within the same interruption site in the A domain, whereas previously, naturally occurring reported and characterized interrupted A domains harbored only one M domain. By a series of radiometric and mass spectrometry assays, we show that the first and second M domains site specifically methylate the side-chain oxygen and backbone nitrogen of l-Ser after the substrate is transferred onto a carrier thiolation domain, ColG(T). This is the first reported characterization of a dimethylating back-to-back interrupted A domain. The insights gained by this work lay the foundation for future combinatorial biosynthesis of site specifically methylated nonribosomal peptides.

Publisher Correction: Unusual substrate and halide versatility of phenolic halogenase PltM.

The original version of this Article contained an error in Fig. 1, in which the labels 'NADP+' and 'NADPH + H+' were incorrectly given as 'NADPH' and 'NADPH+ + H+', respectively. This has been corrected in both the PDF and HTML versions of the Article.

Unusual substrate and halide versatility of phenolic halogenase PltM.

Controlled halogenation of chemically versatile substrates is difficult to achieve. Here we describe a unique flavin-dependent halogenase, PltM, which is capable of utilizing a wide range of halides for installation on a diverse array of phenolic compounds, including FDA-approved drugs and natural products, such as terbutaline, fenoterol, resveratrol, and catechin. Crystal structures of PltM in complex with phloroglucinol and FAD in different states yield insight into substrate recognition and the FAD recycling mechanism of this halogenase.

Probing the limits of interrupted adenylation domains by engineering a trifunctional enzyme capable of adenylation, N-, and S-methylation.

The adenylation (A) domains found in nonribosomal peptide synthetases (NRPSs) exhibit tremendous plasticity. Some A domains have been shown to display the ability to contain within them the catalytic portion of an auxiliary domain, most commonly that of a methyltransferase (M) enzyme. This unique feature of A domains interrupted by M domains allows them to possess bifunctionality, where they can both adenylate and methylate an amino acid substrate. Additionally, these types of inserted M domains are able to selectively carry out either backbone or side chain methylation of amino acids. Interruptions with M domains are naturally found to occur either between the a2-a3 or the a8-a9 of the ten conserved motifs of A domains. Herein, we set out to answer the following question: Can one A domain support two different M domain interruptions occurring in two different locations (a2-a3 and a8-a9) of the A domain and possess the ability to adenylate an amino acid and methylate it on both its side chain and backbone? To answer this question we added a backbone methylating M3S domain from TioS(A3aM3SA3b) between the a8-a9 region of a mono-interrupted A domain, TioN(AaMNAb), that already contained a side chain methylating MN domain between its a2-a3 region. We evaluated the di-interrupted A domain TioN(AMNAM3SA) with a series of radiometric and mass spectrometry assays and found that this engineered enzyme was indeed capable of all three activities. These findings show that production of an active trifunctional di-interrupted A domain is possible and represents an exciting new avenue for future nonribosomal peptide (NRP) derivatization.

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Exploiting Intermolecular Interactions between Alkyl-Functionalized Redox-Active Molecule Pairs to Enhance Interfacial Electron Transfer.

The strategies to enhance electron transfer rates between redox-active, light-harvesting molecules attached to semiconductor surfaces and redox mediators in solution by modifying molecular structure are not fully investigated yet. Therefore, the design of molecules with controlled electron transfer rates remains a challenge. The aims of this work are to quantify the effect of long alkyl chain substitution on the electron transfer from cobalt(II/III) tris(2,2'-bipyridine) to organic molecules containing carbazole and thiophene and to demonstrate that alkyl chains can be used to enhance electron transfer between donor-acceptor pairs. To this end, we study the effect of using a combination of donor and acceptor molecules with and without alkyl chains on electron transfer kinetics. Using transient absorption spectroscopy, we show that when only the molecules or the mediators have long alkyl chains, electron transfer is slightly blocked as expected. Counterintuitively, electron transfer is up to 13 times faster when long alkyl chains are attached to both the redox-active molecules and the redox mediators. The faster electron transfer is explained by an alkyl-alkyl chain interaction between the donor/acceptor, leading to the proximity (trapping) of the redox mediators close to the π-conjugated backbone of the molecules. These results suggest that intermolecular interactions can be used to enhance the electron transfer rates significantly even with well-established insulating alkyl chains attached to molecules without changing the electrochemical driving force.

Using MbtH-Like Proteins to Alter the Substrate Profile of a Nonribosomal Peptide Adenylation Enzyme.

MbtH-like proteins (MLPs) are required for soluble expression and/or optimal activity of some adenylation (A) domains of nonribosomal peptide synthetases. Because A domains can interact with noncognate MLP partners, how the function of an A domain, TioK, involved in the biosynthesis of the bisintercalator thiocoraline, is altered by noncognate MLPs has been investigated. Measuring TioK activity with 12 different MLPs from a variety of bacterial species by using a radiometric assay suggested that the A domain substrate promiscuity could be altered by foreign MLPs. Kinetic studies and bioinformatics analysis expanded the complexity of MLP functions and interactions.

Structural basis for backbone N-methylation by an interrupted adenylation domain.

Interrupted adenylation domains are enigmatic fusions, in which one enzyme is inserted into another to form a highly unusual bifunctional enzyme. We present the first crystal structure of an interrupted adenylation domain that reveals a unique embedded methyltransferase. The structure and functional data provide insight into how these enzymes N-methylate amino acid precursors en route to nonribosomal peptides.

Engineering Bifunctional Enzymes Capable of Adenylating and Selectively Methylating the Side Chain or Core of Amino Acids.

Nonribosomal peptides (NRPs) are known sources of therapeutics. Some nonribosomal peptide synthetase assembly lines contain unique functional interrupted adenylation (A) domains, where nature has combined two different functional domains into one bifunctional enzyme. Most often these interrupted A domains contain a part of a methylation (M) domain embedded in their sequence. Herein, we aimed to emulate nature and create fully functional interrupted A domains by inserting two different noncognate M domains, KtzH(MH) and TioS(M3S), into a naturally occurring uninterrupted A domain, Ecm6(A1T1). We evaluated the engineered enzymes, Ecm6(A1aMHA1bT1) and Ecm6(A1aM3SA1bT1), by a series of radiometric assays and found that not only do they maintain A domain activity, but also they gain the site-specific methylation patterns observed in the parent M domain donors. These findings provide an exciting proof-of-concept for generating interrupted A domains as future tools to modify NRPs and increase the diversity and activity of potential therapeutics.

Deciphering Nature's Intricate Way of N,S-Dimethylating l-Cysteine: Sequential Action of Two Bifunctional Adenylation Domains.

Dimethylation of amino acids consists of an interesting and puzzling series of events that could be achieved, during nonribosomal peptide biosynthesis, either by a single adenylation (A) domain interrupted by a methyltransferase (M) domain or by the sequential action of two of such independent enzymes. Herein, to establish the method by which Nature N,S-dimethylates l-Cys, we studied its formation during thiochondrilline A biosynthesis by evaluating TioS(A3aM3SA3bT3) and TioN(AaMNAb). This study not only led to identification of the exact pathway followed in Nature by these two enzymes for N,S-dimethylation of l-Cys, but also revealed that a single interrupted A domain can N,N-dimethylate amino acids, a novel phenomenon in the nonribosomal peptide field. These findings offer important and useful insights for the development and engineering of novel interrupted A domain enzymes to serve, in the future, as tools for combinatorial biosynthesis.