Semisynthetic Strategy Research Articles

Exploring the Nonenzymatic Origin of Duclauxin-like Natural Products.

Chemical-biological efforts to increase the diversity of duclauxin (1)-like molecules for medicinal chemistry purposes unveiled the reactivity of duclauxin (1) toward amines and alcohols. To expand the compound class, a semisynthetic strategy conjugating amines to duclauxin (1) was employed. Insights gained from this approach led to the hypothesis that certain duclauxin-like "natural products" such as talaromycesone B (2), bacillisporin G (3), xenoclauxin (4), bacillisporins F (5/6), bacillisporins J (8/9), bacillisporins I (12/13), and verruculosin A (38) may be isolation artifacts rather than enzymatic products. Further experimentation, involving adsorption of 1 onto silica gel, resulted in the production of 2-6. To gain insights into the conditions that generate such molecules, one-step reactions under mild conditions were set. Outcomes from both experiments confirmed that duclauxin-like molecules are generated via nonenzymatic reactions. This article presents analytical evidence, indicating that these molecules originate from 1, with the epimeric mixture of bacillisporins J (8 and 9) acting as the primary intermediate.

Synthesis of eutigoside C based on salidroside

Eutigoside C has been synthesized starting from commercially available salidroside through a linear reaction sequence of 2 steps with an overall yield of 65.6%. This approach involves selective hydroxy esterification and phenolic hydroxyl oxidation. Up to 11 g of eutigoside C was achieved by this new simple and efficient semi-synthetic strategy, that laid a solid material foundation for further investigation of biological activity.. KEYWORDS :Eutigoside C, Salidroside, Phenylethanoid glycosides, Semi-synthetic.

Stable ubiquitin conjugation for biological interrogation of ubiquitinated tau repeat domain

Protein semisynthesis approaches are key for gaining insights into the effects of post-translational modifications (PTMs) on the structure and function of modified proteins. Among PTMs, ubiquitination involves the conjugation of a small protein modifier to a substrate amino acid residue and is unique in controlling a variety of cellular processes. Interest has grown in understanding the role of ubiquitination in neurodegenerative conditions, including tauopathies. The latter are characterized by the accumulation of the intrinsically disordered protein tau in the form of neurofibrillary tangles in the brains of patients. The presence of ubiquitinated tau in the pathological aggregates suggests that ubiquitination might play a role in the formation of abnormal protein deposits. In this study, we developed a new strategy, based on dehydroalanine chemistry, to install wild type ubiquitin on a tau repeat domain construct with site-specificity. We optimized a three-step reaction which yielded a good amount of highly pure tau repeat domain ubiquitinated in position 353. The structural features of the conjugate were examined by circular dichroism and NMR spectroscopy. The ubiquitinated tau was challenged in a number of assays: fibrils formation under aggregating conditions in vitro, chemical stability upon exposure to a variety of biological media including cell extracts, and internalization into astrocytes. The results demonstrated the wide applicability of the new semisynthetic strategy for the investigation of ubiquitinated substrates in vitro or in cell, and in particular for studying if ubiquitination has a role in the molecular mechanisms that underlie the aberrant transition of tau into pathological aggregates.

Biosynthetic production of anticoagulant heparin polysaccharides through metabolic and sulfotransferases engineering strategies

Heparin is an important anticoagulant drug, and microbial heparin biosynthesis is a potential alternative to animal-derived heparin production. However, effectively using heparin synthesis enzymes faces challenges, especially with microbial recombinant expression of active heparan sulfate N-deacetylase/N-sulfotransferase. Here, we introduce the monosaccharide N-trifluoroacetylglucosamine into Escherichia coli K5 to facilitate sulfation modification. The Protein Repair One-Stop Service-Focused Rational Iterative Site-specific Mutagenesis (PROSS-FRISM) platform is used to enhance sulfotransferase efficiency, resulting in the engineered NST-M8 enzyme with significantly improved stability (11.32-fold) and activity (2.53-fold) compared to the wild-type N-sulfotransferase. This approach can be applied to engineering various sulfotransferases. The multienzyme cascade reaction enables the production of active heparin from bioengineered heparosan, demonstrating anti-FXa (246.09 IU/mg) and anti-FIIa (48.62 IU/mg) activities. This study offers insights into overcoming challenges in heparin synthesis and modification, paving the way for the future development of animal-free heparins using a cellular system-based semisynthetic strategy.

High stereoselective semisynthesis of kauroxane and beyeroxane compounds

A semisynthetic strategy to access novel kauroxane or beyeroxane compounds from ent‑kauranal or ent‑beyerenal, respectively, is described. A Prins cyclization was used as a key step reaction to synthesize diterpene-tetrahydropyran hybrid compounds with high stereoselectivity by using 3-buten-1-ol as oxane precursor and indium trichloride as the Lewis acid catalyst. The absolute configurations of new compounds were determined by mechanistic means and supported with DFT calculations, as well as considering the stereoselectivity behavior associated with the chiral purity of diterpenes and their conformational restrictions. The structures were elucidated by their physical and spectroscopic data. Finally, the antiproliferative activity of the target molecules was done, being moderately bioactive.

Analysis of protein-protein and protein-membrane interactions by isotope-edited infrared spectroscopy.

The objective of this work is to highlight the power of isotope-edited Fourier transform infrared (FTIR) spectroscopy in resolving important problems encountered in biochemistry, biophysics, and biomedical research, focusing on protein-protein and protein membrane interactions that play key roles in practically all life processes. An overview of the effects of isotope substitutions in (bio)molecules on spectral frequencies and intensities is given. Data are presented demonstrating how isotope-labeled proteins and/or lipids can be used to elucidate enzymatic mechanisms, the mode of membrane binding of peripheral proteins, regulation of membrane protein function, protein aggregation, and local and global structural changes in proteins during functional transitions. The use of polarized attenuated total reflection FTIR spectroscopy to identify the spatial orientation and the secondary structure of a membrane-bound interfacial enzyme and the mode of lipid hydrolysis is described. Methods of production of site-directed, segmental, and domain-specific labeling of proteins by the synthetic, semisynthetic, and recombinant strategies, including advanced protein engineering technologies such as nonsense suppression and frameshift quadruplet codons are overviewed.

Chemical protein synthesis enabled engineering of saccharide oxidative cleavage activity in artificial metalloenzymes

Chemical protein (semi-)synthesis is a powerful technique allowing the incorporation of unnatural functionalities at any desired protein site. Herein we describe a facile one-pot semi-synthetic strategy for the construction of a type 2 copper center in the active site of azurin, which is achieved by substitution of Met121 with unnatural amino acid residues bearing a strong ligand N,N-bis(pyridylmethyl)amine (DPA) to mimic the function of typical histidine brace-bearing copper monooxygenases, such as lytic polysaccharide monooxygenases (LPMOs) involved in polysaccharide breakdown. The semi-synthetic proteins were routinely obtained in over 10-mg scales to allow for spectroscopic measurements (UV–Vis, CD, and EPR), which provides structural evidences for the CuII–DPA-modified azurins. 4-nitrophenyl-β-D-glucopyranoside (PNPG) was used as a model substrate for the H2O2-driven oxidative cleavage reaction facilitated by semi-synthetic azurins, and the CuII–6 complex showed a highest activity (TTN 253). Interestingly, our semi-synthetic azurins were able to tolerate high H2O2 concentrations (up to 4000-fold of the enzyme), making them promising for practical applications. Collectively, we establish that chemical protein synthesis can be exploited as a reliable technology in affording large quantities of artificial metalloproteins to facilitate the transformation of challenging chemical reactions.

Biomimetic Approach to Diverse Coral Diterpenes from a Biosynthetic Scaffold

AbstractThousands of coral terpenes originate from simple scaffolds that undergo oxidative tailoring. While corals are excellent sources of drug leads, the challenge of supplying structurally complex drug leads from marine organisms has sometimes slowed their development. Making this even more challenging, in comparison to other organisms, such as plants and microbes, for which the terpene literature is substantial, very little is known about how the unique coral terpenes are biosynthesized and elaborated in nature. In this study, we used a semisynthetic strategy to produce at gram scale in yeast the eunicellane scaffold that underlies >200 coral compounds. Synthetic oxidation reactions were explored, generating key scaffolds that reflect three of the four structural classes derived from eunicellane and enabling the first asymmetric syntheses of the natural products solenopodin C and klysimplexin Q. Biomimetic methods and detailed mechanistic studies of synthetic reactions shed light on potential enzymological reactivity, including the role of epoxide rearrangement in eunicellane biosynthesis.

Biomimetic Approach to Diverse Coral Diterpenes from a Biosynthetic Scaffold.

Thousands of coral terpenes originate from simple scaffolds that undergo oxidative tailoring. While corals are excellent sources of drug leads, the challenge of supplying structurally complex drug leads from marine organisms has sometimes slowed their development. Making this even more challenging, in comparison to other organisms, such as plants and microbes, for which the terpene literature is substantial, very little is known about how the unique coral terpenes are biosynthesized and elaborated in nature. In this study, we used a semisynthetic strategy to produce at gram scale in yeast the eunicellane scaffold that underlies >200 coral compounds. Synthetic oxidation reactions were explored, generating key scaffolds that reflect three of the four structural classes derived from eunicellane and enabling the first asymmetric syntheses of the natural products solenopodin C and klysimplexin Q. Biomimetic methods and detailed mechanistic studies of synthetic reactions shed light on potential enzymological reactivity, including the role of epoxide rearrangement in eunicellane biosynthesis.

Nature-Inspired Chemistry of Complex Alkaloids: Combining Targeted Molecular Networking Approach and Semisynthetic Strategy to Access Rare Communesins in a Marine-Derived Penicillium expansum.

Communesins are rare alkaloids isolated from fungi of the genus Penicillium. In this work, the extract of a marine-derived Penicillium expansum strain was studied using targeted molecular networking approach allowing to detect 65 communesins including 55 new ones. A fragmentation pattern for dimethylvinyl communesins was established and a script was implemented allowing to predict the structure and map all communesins in a global molecular network. A semisynthetic strategy was carried out to obtain some minor congeners from the two isolated communesins A and B. Nine communesins were then synthetised: two of them were already described as produced by the studied strain; four are new natural products which occurrence in the extracts was confirmed; three are new semi-synthetic analogues never described so far. These communesins were evaluated for their cytotoxicity on two human cancer cell lines KB and MCF-7 leading to a preliminary study of their structure-activity relationships.

Insertion of unnatural metal ligand in the heme pocket of nitrophorin through protein semi-synthesis: Toward biomimicking binuclear active sites

Herein, we report a semi-synthetic strategy affording a nitrophorin 2 (NP2) variant with a N,N′-bis(2-pyridylmethyl)amine (Dpa) ligand as sidechain selectively installed at position 27, which was assembled from a synthetic peptide thioester bearing the Dpa ligand and an expressed protein segment via native chemical ligation. The semi-synthetic NP2 was able to accept the natural heme b cofactor and the Dpa ligand was able to bind Cu(II)/Fe(III) ions, leading to heteronuclear active site.

6-Gingerol-derived semisynthetic analogs mitigate oxidative stress, and reverse acrylamide induced neurotoxicity in zebrafish

A semisynthetic strategy has been developed for the synthesis of novel 6-gingerol based analogs using simple and robust chemistries.

Beta-Lactamases Inhibitors: A Perspective on the Existing and the Potential Admixtures to Synergize Beta-lactams Versus Resistant Superbugs

β-lactam antibiotics are considered the safest bactericides, and upon wide clinical use of benzyl penicillin G in 1945, outbreaks of resistance came out. The frequent semi-synthetic strategies revealed β-lactam generations that are of broad-spectrum activity. The new agents as well as their concomitant use with known inhibitors of β-lactamases potentiate their effectiveness versus higher numbers of resistant pathogens. However, the extremely resistant pathogens are still representing a burden. Efforts had been continued to find more inhibitors of β-lactamases to combine with β-lactams to provide good management of infections by extremely resistant microbes. The purpose of this work is to overview the conventional and the recently introduced β-lactamases in clinical applications, as well as some reported effective inhibitors of β-lactamases. The review pinpoints the inhibitors that can be mixed and/or merged with the beta-lactam antibiotics to effectively treat the microbial infections producing resistant-β-lactamases. ClogP for these drugs and candidate inhibitors is introduced as suggestions to open a door for developers to admix derivatives with suitable pharmacokinetics.

Semi-synthesis of biotin-bearing activity-based ubiquitin probes through sequential enzymatic ligation, N-S acyl transfer and aminolysis reaction

Activity-based Ubiquitin probes (Ub-ABPs) carrying a reporter group have emerged as effective tools for the investigation of deubiquitinating enzymes (DUBs), such as studying the molecular mechanism of DUBs, profiling new DUBs. But so far, the synthesis of commonly used biotin-bearing Ub-ABPs is a technical challenge. Here, we report a one-pot semi-synthetic strategy for the acquiring of Ub-ABPs carrying a biotin tag through sequential enzymatic ligation, N-S acyl transfer and aminolysis reaction without any purification steps. These probes enable to capture the different family of DUBs for enrichment and immunoblotting using the attached biotin tag.

Decoding molecular plasticity of the dark proteome

The mechanisms by which intrinsically disordered proteins (IDPs) engage in rapid and highly selective binding is a subject of considerable interest and represents a central paradigm to nuclear pore complex (NPC) function. Nuclear transport receptors (NTRs) can move through the central channel of the NPC which is filled with hundreds of phenylalanine‐glycine‐rich nucleoporins (FG‐Nups) reaching millimolar concentrations with elusive conformational plasticity. Since site‐specific labeling of proteins with small but highly photostable fluorescent dyes inside cells remains the major bottleneck for directly studying protein dynamics in the cellular interior, we have now developed a semi‐synthetic strategy based on novel artificial amino acids that are easily and site‐specifically introduced into any protein by the natural machinery of the living cell via a newly developed thin‐film synthetic organelle that equips the living cell with up to three genetic codes. This allowed us to develop an experimental approach combining site‐specific fluorescent labeling of IDPs in non‐fixed cells with fluorescent lifetime imaging microscopy (FLIM) to directly decipher the plasticity of FG‐Nups via FRET. Our study enabled a conformational look on the condensated IDPs in the sub‐resolution (roughly (50 nm)3 small cavity) cavity of the NPC. By measuring the end‐to‐end distances of different segments of the labeled FG‐Nups using FLIM‐FRET, we can extract the scaling exponent, which directly describes the conformations of FG‐Nups at their functional status as well as the solvent quality in the cellular and even inner NPC environment.Reinkemeier CD, Lemke EA. Dual film‐like organelles enable spatial separation of orthogonal eukaryotic translation. Cell. 2021 Sep 16;184(19):4886‐4903.e21Celetti G, Paci G, Caria J, VanDelinder V, Bachand G, Lemke EA. The liquid state of FG‐nucleoporins mimics permeability barrier properties of nuclear pore complexes. J Cell Bio. (2020) Jan 6;219(1).Reinkemeier CD, Estrada Girona G, Lemke EA, 2019 Designer membraneless organelles enable codon reassignment of selected mRNAs in eukaryotes. Science, Mar 29;363(6434)Nikić I, Estrada Girona G, Kang JH, Paci G, rei S, Koehler C, Shymanska NV, Ventura Santos C, Spitz D, Lemke EA, Debugging Eukaryotic Genetic Code Expansion for Site‐Specific Click‐PAINT Super‐Resolution Microscopy. Angew Chem Int Ed Engl. (2016) Dec 23;55(52):16172‐16176

Glycosaminoglycan-like sulfated polysaccharides from Vibrio diabolicus bacterium: Semi-synthesis and characterization

Sulfated glycosaminoglycan (GAG) analogues derived from plant, algae or microbial sourced polysaccharides are highly interesting in order to gain bioactivities similar to sulfated GAGs but without risks and concerns derived from their typical animal sources. Since the exopolysaccharide (EPS) produced by the bacterium Vibrio diabolicus HE800 strain from deep-sea hydrothermal vents is known to have a GAG-like structure with a linear backbone composed of unsulfated aminosugar and uronic acid monomers, its structural modification through four different semi-synthetic sulfation strategies has been performed. A detailed structural characterization of the six obtained polysaccharides revealed that three different sulfation patterns (per-O-sulfation, a single N-sulfation and a selective primary hydroxyls sulfation) were achieved, with molecular weights ranging from 5 to 40 kDa. A Surface Plasmonic Resonance (SPR) investigation of the affinity between such polysaccharides and a set of growth factors revealed that binding strength is primarily depending on polysaccharide sulfation degree.

A Unified Strategy to Access 2- and 4-Deoxygenated Sugars Enabled by Manganese-Promoted 1,2-Radical Migration.

The selective manipulation of carbohydrate scaffolds is challenging due to the presence of multiple, nearly chemically indistinguishable O-H and C-H bonds. As a result, protecting-group-based synthetic strategies are typically necessary for carbohydrate modification. Here we report a concise semisynthetic strategy to access diverse 2- and 4-deoxygenated carbohydrates without relying on the exhaustive use of protecting groups to achieve site-selective reaction outcomes. Our approach leverages a Mn2+-promoted redox isomerization step, which proceeds via sugar radical intermediates accessed by neutral hydrogen atom abstraction under visible light-mediated photoredox conditions. The resulting deoxyketopyranosides feature chemically distinguishable functional groups and are readily transformed into diverse carbohydrate structures. To showcase the versatility of this method, we report expedient syntheses of the rare sugars l-ristosamine, l-olivose, l-mycarose, and l-digitoxose from commercial l-rhamnose. The findings presented here validate the potential for radical intermediates to facilitate the selective transformation of carbohydrates and showcase the step and efficiency advantages attendant to synthetic strategies that minimize a reliance upon protecting groups.

Carbohydrate-Based Macromolecular Biomaterials.

Carbohydrates are the most abundant and one of the most important biomacromolecules in Nature. Except for energy-related compounds, carbohydrates can be roughly divided into two categories: Carbohydrates as matter and carbohydrates as information. As matter, carbohydrates are abundantly present in the extracellular matrix of animals and cell walls of various plants, bacteria, fungi, etc., serving as scaffolds. Some commonly found polysaccharides are featured as biocompatible materials with controllable rigidity and functionality, forming polymeric biomaterials which are widely used in drug delivery, tissue engineering, etc. As information, carbohydrates are usually referred to the glycans from glycoproteins, glycolipids, and proteoglycans, which bind to proteins or other carbohydrates, thereby meditating the cell-cell and cell-matrix interactions. These glycans could be simplified as synthetic glycopolymers, glycolipids, and glycoproteins, which could be afforded through polymerization, multistep synthesis, or a semisynthetic strategy. The information role of carbohydrates can be demonstrated not only as targeting reagents but also as immune antigens and adjuvants. The latter are also included in this review as they are always in a macromolecular formulation. In this review, we intend to provide a relatively comprehensive summary of carbohydrate-based macromolecular biomaterials since 2010 while emphasizing the fundamental understanding to guide the rational design of biomaterials. Carbohydrate-based macromolecules on the basis of their resources and chemical structures will be discussed, including naturally occurring polysaccharides, naturally derived synthetic polysaccharides, glycopolymers/glycodendrimers, supramolecular glycopolymers, and synthetic glycolipids/glycoproteins. Multiscale structure-function relationships in several major application areas, including delivery systems, tissue engineering, and immunology, will be detailed. We hope this review will provide valuable information for the development of carbohydrate-based macromolecular biomaterials and build a bridge between the carbohydrates as matter and the carbohydrates as information to promote new biomaterial design in the near future.

A New Chemoenzymatic Semisynthetic Approach Provides Insight into the Role of Phosphorylation beyond Exon1 of Huntingtin and Reveals N-Terminal Fragment Length-Dependent Distinct Mechanisms of Aggregation.

Huntington's disease is a neurodegenerative disorder caused by the expansion of a polyglutamine repeat (>36Q) in the N-terminal domain of the huntingtin protein (Htt), which renders the protein or fragments thereof more prone to aggregate and form inclusions. Although several Htt N-terminal fragments of different lengths have been identified within Htt inclusions, most studies on the mechanisms, sequence, and structural determinants of Htt aggregation have focused on the Httexon1 (Httex1). Herein, we investigated the aggregation properties of mutant N-terminal Htt fragments of various lengths (Htt171, Htt140, and Htt104) in comparison to mutant Httex1 (mHttex1). We also present a new chemoenzymatic semisynthetic strategy that enables site-specific phosphorylation of Htt beyond Httex1. These advances yielded insights into how post-translational modifications (PTMs) and structured domains beyond Httex1 influence aggregation mechanisms, kinetics, and fibril morphology of longer N-terminal Htt fragments. We demonstrate that phosphorylation at T107 significantly slows the aggregation of mHtt171, whereas phosphorylation at T107 and S116 accelerates the aggregation, underscoring the importance of crosstalk between different PTMs. The mHtt171 proteins aggregate via a different mechanism and form oligomers and fibrillar aggregates with morphological properties that are distinct from that of mHttex1. These observations suggest that different N-terminal fragments could have distinct aggregation mechanisms and that a single polyQ-targeting antiaggregation strategy may not effectively inhibit the aggregation of all N-terminal Htt fragments. Finally, our results underscore the need for further studies to investigate the aggregation mechanisms of Htt fragments and how the various fragments interact with each other and influence Htt toxicity and disease progression.

Ion channel engineering using protein trans-splicing.

Conventional site-directed mutagenesis and genetic code expansion approaches have been instrumental in providing detailed functional and pharmacological insight into membrane proteins such as ion channels. Recently, this has increasingly been complemented by semi-synthetic strategies, in which part of the protein is generated synthetically. This means a vast range of chemical modifications, including non-canonical amino acids (ncAA), backbone modifications, chemical handles, fluorescent or spectroscopic labels and any combination of these can be incorporated. Among these approaches, protein trans-splicing (PTS) is particularly promising for protein reconstitution in live cells. It relies on one or more split inteins, which can spontaneously and covalently link flanking peptide or protein sequences. Here, we describe the use of PTS and its variant tandem PTS (tPTS) in semi-synthesis of ion channels in Xenopus laevis oocytes to incorporate ncAAs, post-translational modifications or metabolically stable mimics thereof. This strategy has the potential to expand the type and number of modifications in ion channel research.