Substitution Pattern Research Articles

Structure Revision of the Fungal Phytotoxin Cavoxin and of Its Corresponding Chroman-4-one Cavoxone by X-ray Crystallography.

Cavoxin (1) was isolated as the main phytotoxin produced by Phoma cava Schulzer, a toxigenic fungus isolated from Castanea spp. Its structure was determined by 1D NMR and MS in 1985 along with that of the corresponding chroman-4-one cavoxone (2), an artifact formed by acid treatment of 1. Since that time cavoxin was shown to be phytotoxic, antifungal, antifeedant, herbicidal, and antirust with potential application in agriculture and medicine. During a study aimed at improving cavoxin's production by P. cava, single crystals for X-ray diffractometric analysis were obtained. The X-ray crystallography characterization confirmed only in part the structure proposed for cavoxin (1), revealing a different substitution pattern on the aromatic ring, as depicted in the revised structure 3.

Candidaantarctica Lipase B mediated kinetic resolution: A sustainable method for chiral synthesis of antiproliferative β-lactams

Biocatalysis is a valuable industrial approach in active pharmaceutical ingredient (API) manufacturing for asymmetric induction and synthesis of chiral APIs. Herein, we investigated synthesis of a panel of microtubule-destabilising antiproliferative β-lactam enantiomers employing a commercially available immobilised Candida antarctica lipase B enzyme together with methanol and MTBE. The β-lactam ring remained intact during chiral kinetic resolution reactions, plausibly due to a bulky N-1 phenyl substituent on the β-lactam ring substrate. The predominant reaction mediated by CAL-B was methanol catalysed conversion of the β-lactam 3-acetoxy substituent to a 3-hydroxyl group, with preferential methanolysis of the 3S, 4S enantiomer. The unreacted substrate underwent progressive enantioenrichment to the 3R, 4R enantiomer. Substitution patterns on the B ring C3 meta position of the β-lactam scaffold greatly affected the rate of reaction. Halo substituents (fluoro-, chloro- and bromo-) reduced the rate of conversion compared to unsubstituted analogues, which in turn increased enantiomeric excess (ee). Ee values up to 86 % for the 3S, 4S 3-hydroxyl enantiomer were achieved. A double resolution approach for unreacted substrate yielded high ee values (>99 %) for the 3R, 4R 3-acetoxy enantiomer. CAL-B mediated methanolysis is a more sustainable method for resolution of racemic antiproliferative β-lactams compared to a previous technique of chiral diastereomeric resolution. Yields of β-lactams obtained using CAL-B are far superior than previously described, which will facilitate progression toward pre-clinical and clinical development. Biocatalysis is a useful tool in the toolbox of the medicinal chemist.

Skeletal and Mechanistic Diversity in Ir‐Catalyzed Cycloisomerizations of Allene‐Tethered Pyrroles and Indoles

AbstractPyrroles and indoles bearing N‐allenyl tethers participate in a variety of iridium‐catalyzed cycloisomerization processes initiated by a C−H activation step, to deliver a diversity of synthetically relevant azaheterocyclic products. By appropriate selection of the ancillary ligand and the substitution pattern of the allene, the reactions can diverge from simple intramolecular hydrocarbonations to tandem processes involving intriguing mechanistic issues. Accordingly, a wide range of heterocyclic structures ranging from dihydro‐indolizines and pyridoindoles to tetrahydroindolizines, as well as cyclopropane‐fused tetrahydroindolizines can be obtained. Moreover, by using chiral ligands, these cascade processes can be carried out in an enantioselective manner. DFT studies provide insights into the underlying mechanisms and justify the observed chemo‐ regio‐ and stereoselectivities.

Skeletal and Mechanistic Diversity in Ir-Catalyzed Cycloisomerizations of Allene-Tethered Pyrroles and Indoles.

Pyrroles and indoles bearing N-allenyl tethers participate in a variety of iridium-catalyzed cycloisomerization processes initiated by a C-H activation step, to deliver a diversity of synthetically relevant azaheterocyclic products. By appropriate selection of the ancillary ligand and the substitution pattern of the allene, the reactions can diverge from simple intramolecular hydrocarbonations to tandem processes involving intriguing mechanistic issues. Accordingly, a wide range of heterocyclic structures ranging from dihydro-indolizines and pyridoindoles to tetrahydroindolizines, as well as cyclopropane-fused tetrahydroindolizines can be obtained. Moreover, by using chiral ligands, these cascade processes can be carried out in an enantioselective manner. DFT studies provide insights into the underlying mechanisms and justify the observed chemo- regio- and stereoselectivities.

Recently Adopted Synthetic Protocols for Piperazines: A Review

Piperazines, a class of heterocyclic compounds, have garnered significant attention in the field of organic synthesis due to their diverse pharmacological activities and widespread applications in medicinal chemistry. This review provides a comprehensive overview of the recent advancements in the synthesis of piperazines, highlighting innovative methodologies, novel reagents, and green synthesis approaches adopted by researchers. The synthesis of piperazines has witnessed remarkable progress, with a focus on developing efficient and sustainable synthetic routes. Various strategies, such as transition-metal-catalyzed reactions, microwave-assisted synthesis, photo-redox reactions, and bio-inspired methods, have emerged as powerful tools for constructing piperazine scaffolds. The review also encompasses discussions on the stereochemistry and regioselectivity issues associated with piperazine synthesis, shedding light on the intricacies of achieving specific substitution patterns. The impact of newly synthesized piperazines in drug discovery and development is also explored, emphasizing the therapeutic potential of these compounds in various disease areas. In conclusion, this review provides a comprehensive and up-to-date account of the recent advancements in piperazine synthesis, offering insights into the current state of the field and guiding future research directions. The integration of innovative methodologies and the exploration of sustainable practices underscore the ongoing efforts to streamline the synthesis of piperazines, contributing to the expansion of their applications in medicinal chemistry and related disciplines.

Iron(II)-Catalyzed 1,2-Diamination of Styrenes Installing a Terminal NH2 Group Alongside Unprotected Amines.

1,2-Diamination of alkenes represents an attractive way to generate differentiated vicinal diamines, which are prevalent motifs in biologically active compounds and catalysts. However, existing methods are usually limited in scope and produce diamines where one or both nitrogens are protected, adding synthetic steps for deprotection and further N-functionalization to reach a desired target. Furthermore, the range of amino groups that can be introduced at the internal position is fairly limited. Here we describe a 1,2-diamination of styrenes that directly installs a free amino group at the terminal position and a wide variety of unprotected nitrogen nucleophiles (primary or secondary alkyl or aromatic amines, sulfoximines, N-heterocycles, and ammonia surrogate) at the internal position. Two complementary sets of conditions encompass electronically activated and deactivated styrenes with diverse substitution patterns and functional groups. Moreover, this strategy can be extended to the 1,2-aminothiolation of styrenes.

Iron(II)‐Catalyzed 1,2‐Diamination of Styrenes Installing a Terminal NH2 Group Alongside Unprotected Amines

1,2‐Diamination of alkenes represents an attractive way to generate differentiated vicinal diamines, which are prevalent motifs in biologically active compounds and catalysts. However, existing methods are usually limited in scope and produce diamines where one or both nitrogens are protected, adding synthetic steps for deprotection and further N‐functionalization to reach a desired target. Furthermore, the range of amino groups that can be introduced at the internal position is fairly limited. Here we describe a 1,2‐diamination of styrenes that directly installs a free amino group at the terminal position and a wide variety of unprotected nitrogen nucleophiles (primary or secondary alkyl or aromatic amines, sulfoximines, N‐heterocycles, and ammonia surrogate) at the internal position. Two complementary sets of conditions encompass electronically activated and deactivated styrenes with diverse substitution patterns and functional groups. Moreover, this strategy can be extended to the 1,2‐aminothiolation of styrenes.

Quamtum Mechanical Study on Structural and Electronic Properties of Tert-Butyl Based Bridged Dithiophene Oxide Derivatives

Computational modeling is vital to designing and creating organic semiconductors used in solar cells, organic field-effect transistors, and other areas. This work studied the structural and electronic features of a group of substituted tert-butyl bridged dithiophene oxide derivatives using Density Functional Theory (DFT) calculations. Geometry improvements were carried out using the B3LYP hybrid functional and the 6-31G(d,p) basis set in Gaussian 09. Molecular shapes, bond lengths, bond angles, and dihedral angles were studied to find out how substitution patterns change the packing and conformation of molecules. Energy levels, distribution, and makeup of frontier molecular orbitals were found. This calculation also included finding other electronic qualities, such as electronic charges, dipole moments, and polarizabilities. Findings show that tert-butyl substitution makes the molecular backbone stiffer and limits its ability to twist compared to similar molecules that have not been replaced. The chemical geometry stays mostly the same when electron-withdrawing or electron-donating substituents are added to the tert- butyl groups. Nevertheless, the strength and location of substituents have a significant impact on frontier orbital energies. The HOMO-LUMO gap grew significantly when the nitro or cyano groups firmly pulled electrons away from derivatives. For successful charge transport, electron density plots show that the HOMO and LUMO are mainly located on the thiophene and substituent moieties, respectively. Molecular dipole moments are also strongly affected by the electronic features of substituents. This research shows how to change the optoelectronic properties of tert-butyl-based dithiophene oxide derivatives and how their structure-property relationships can be improved. The results help makes new organic semiconductors that work better in various electronic and optoelectronic uses.

Pd-Catalyzed Ring-Opening Polymerization of Cyclobutanols through C(sp3)-C(sp3) Bond Cleavage.

A new approach to ring-opening polymerization (ROP) based on C(sp3)-C(sp3) bond cleavage is reported. This process is based on the ability of Pd to promote both the β-carbon elimination of a bifunctional cyclobutanol precursor and the C-C coupling process with the resulting Pd-alkyl intermediate. Consequently, novel polyketone materials are obtained. Owing to the modular synthesis of the used cyclobutanol monomers, the present ROP reaction allows the introduction of substitution patterns in the polymeric chain that are not accessible by current polyketone synthesis methodologies. We have explored in detail the initiation, propagation, and termination steps of this new polymerization process.

Synthesis and anti-leishmanial activities of uniflorol analogues

AbstractChromanones are a subset of the benzopyran family, and display diverse biological activities, both as natural products and synthetic derivatives. Among these, we selected the natural product uniflorol, a 4-chromanone with an α,β-unsaturated ketone side chain, as a lead compound due to its reported anti-leishmanial properties. We designed and synthesised four series of novel compounds, varying the substitution patterns around the benzopyran core, and evaluated the compounds for anti-leishmanial activity against amastigotes of L. infantum. We prepared and characterised 24 novel compounds; upon screening, 12 compounds demonstrated activity values of <50 μM, with the most potent compound, 16d, having an IC50 of 7.29 μM. Activity was favoured in compounds bearing a phenylalkenyl motif, such as cinnamyl, styryl or a more lipophilic extension, and amide analogues retained activity. Uniflorol analogues display promise as novel architectures towards the development of potential anti-leishmanial agents.

1,4-Pyrazolyl-Containing SAFit-Analogues are Selective FKBP51 Inhibitors With Improved Ligand Efficiency and Drug-Like Profile.

The FK506 binding protein 51 (FKBP51) is an appealing drug target due to its role in several diseases such as depression, anxiety, chronic pain and obesity. Towards this, selectivity versus the close homolog FKBP52 is essential. However, currently available FKBP51-selective ligands such as SAFit2 are too large and lack drug-like properties. Here, we present a structure activity relationship (SAR) analysis of the pipecolic ester moiety of SAFit1 and SAFit2, which culminated in the discovery of the 1,4-pyrazolyl derivative 23 d, displaying a binding affinity of 0.077 μM for FKBP51, reduced molecular weight (541.7 g/mol), lower hydrophobicity (cLogP=3.72) and higher ligand efficiency (LE=0.25). Cocrystal structures revealed the importance of the 1,4- and 1,3,4- substitution patterns of the pyrazole ring versus the 1,4,5 arrangement.

Structural influences of the substituents of tridentate triazole-based ligands – more than just a minor role in the solid-state structure

Abstract New triazole-based tridentate ligands were synthesized, and their crystal structures determined. Through comparison with the crystal structures of the starting materials and related published ligands, dependencies of intermolecular interactions based on the substitution patterns of the triazole motif were identified. In addition to π-stacking interactions, hydrogen bonding, and C–H···π interactions emerged as key players in intermolecular interactions. The observed variations in these interactions will aid in the design of platinum(II) complexes with specific properties.

Mild and General Protocol for Selective Deacetylation of Acetyl/Benzoyl-Protected Carbohydrates.

Herein, we report a mild and general protocol for chemoselective deacetylation of mixed acetyl- and benzoyl-protected carbohydrates under mild acidic conditions. The protocol allows quick access to partially protected carbohydrates, which serve as versatile synthetic intermediates during the total synthesis of various mono- and oligosaccharide targets. The applicability of the developed protocol was successfully demonstrated on a range of carbohydrate substrates of various configurations and substitution patterns featuring functionalized aliphatic and aromatic aglycones. The protocol has shown excellent compatibility with the widely used O-anomeric protecting groups, prespacer aglycones, and thioglycoside glycosyl donors.

Ring Contraction of Saturated Cyclic Amines and Rearrangement of Acyclic Amines Through Their Corresponding Hydroxylamines

Compared to modifications at the molecular periphery, skeletal adjustments present greater challenges. Within this context, skeletal rearrangement technology stands out for its significant advantages in rapidly achieving structural diversity. Yet, the development of this technology for ring contraction of saturated cyclic amines remains exceedingly rare. While most existing methods rely on specific substitution patterns to achieve ring contraction, there is a persistent demand for a more general strategy for substitution‐free cyclic amines. To address this issue, we report a B(C6F5)3‐catalyzed skeletal rearrangement of hydroxylamines with hydrosilanes. This methodology, when combined with the N‐hydroxylation of amines, enables the regioselective ring contraction of cyclic amines and proves equally effective for rapid reorganization of acyclic amine skeletons. By this, the direct scaffold hopping of drug molecules and the strategic deletion of carbon atoms are achieved in a mild manner. Based on mechanistic experiments and density functional theory calculations, a possible mechanism for this process is proposed.

Ring Contraction of Saturated Cyclic Amines and Rearrangement of Acyclic Amines Through Their Corresponding Hydroxylamines.

Compared to modifications at the molecular periphery, skeletal adjustments present greater challenges. Within this context, skeletal rearrangement technology stands out for its significant advantages in rapidly achieving structural diversity. Yet, the development of this technology for ring contraction of saturated cyclic amines remains exceedingly rare. While most existing methods rely on specific substitution patterns to achieve ring contraction, there is a persistent demand for a more general strategy for substitution-free cyclic amines. To address this issue, we report a B(C6F5)3-catalyzed skeletal rearrangement of hydroxylamines with hydrosilanes. This methodology, when combined with the N-hydroxylation of amines, enables the regioselective ring contraction of cyclic amines and proves equally effective for rapid reorganization of acyclic amine skeletons. By this, the direct scaffold hopping of drug molecules and the strategic deletion of carbon atoms are achieved in a mild manner. Based on mechanistic experiments and density functional theory calculations, a possible mechanism for this process is proposed.

A Fundamental Perspective on the Selective Zn Substitution in Ternary Ordered Intermetallic Compound Cu6Zn2Sb2

AbstractThe unique site substitution of Zn in the structure of tetragonal and atomically ordered Cu6Zn2Sb2, followed by the formation of Cu5Zn3Sb2, has been addressed from fundamental perspectives. First principles energy calculations, and semi‐empirical electronic structure calculations using the density of states, crystal orbital Hamilton population, crystal orbital bond index and Mulliken population analysis were performed to understand the observed substitution pattern and the narrow homogeneity range of the titled compound. Mulliken and Löwdin's approach of charge analysis explain the experimentally proved ‘coloring’, based on the ‘site energy’ argument. The concept of ‘topological charge stabilization’ has been introduced in this context. Valence electron concentration and the optimization of the partially covalent Cu−Sb interactions also play pivotal role in the electronic stability of the titled phase.

Development of In-Water Scalable Process for the Preparation of [2-(3-Bromo-2-methylphenyl)-7-chloro-1,3-benzoxazol-5-yl]methanol, a Key Intermediate in the Synthesis of Potent PD-1/PD-L1 Inhibitors

AbstractWe propose a synthetic process for the preparation of a benzoxazole building block for a programmed death-ligand 1 inhibitor that is a candidate currently under clinical investigation for cancer treatment. Our research focused on searching for mild, scalable, and ecofriendly conditions for the synthesis of benzoxazoles. To reduce the use of toxic reagents or solvents and to minimize the production of organic wastes, the cyclization reaction was performed in an aqueous micellar medium. This in-water benzoxazole synthesis gave comparable yields to previously reported processes, and was applied to a broad range of benzoxazoles with various substitution patterns, showcasing its effectiveness in ecofriendly benzoxazole cyclization reactions.

Unveiled reactivity of masked diformylmethane with enamines forming resonance-assisted hydrogen bonding leads to di-meta-substituted pyridines

Pyridine, an essential structure in drug development, shows a wide array of bioactivities according to its substitution patterns. Among the bioactive pyridines, meta-substituted pyridines suffer from limited synthetic approaches despite their significance. In this study, we present a condensation-based synthetic method enabling the facile incorporation of biologically relevant functional groups at the meta position of pyridine. This methodology unveiled the concealed reactivity of 3-formyl(aza)indoles as diformylmethane analogs for synthesizing dissymmetric di-meta-substituted pyridines without ortho and para substitutions. Furthermore, we uncovered resonance-assisted hydrogen bonding (RAHB) as the requirement for the in situ generation of enamines, the key intermediates of this transformation. Successful development of the designed methodology linked to wide applications—core remodeling of natural products, drug–natural product conjugation, late-stage functionalization of drug molecules, and synthesis of the regioisomeric CZC24832. Furthermore, we discovered anti-inflammatory agents through the functional evaluation of synthesized bi-heteroaryl analogs, signifying the utility of this methodology.

Synthesis and Enzymatic Evaluation of a Small Library of Substituted Phenylsulfonamido-Alkyl Sulfamates towards Carbonic Anhydrase II.

A small library of 79 substituted phenylsulfonamidoalkyl sulfamates, 1b-79b, was synthesized starting from arylsulfonyl chlorides and amino alcohols with different numbers of methylene groups between the hydroxyl and amino moieties yielding intermediates 1a-79a, followed by the reaction of the latter with sulfamoyl chloride. All compounds were screened for their inhibitory activity on bovine carbonic anhydrase II. Compounds 1a-79a showed no inhibition of the enzyme, in contrast to sulfamates 1b-79b. Thus, the inhibitory potential of compounds 1b-79b towards this enzyme depends on the substituent and the substitution pattern of the phenyl group as well as the length of the spacer. Bulkier substituents in the para position proved to be better for inhibiting CAII than compounds with the same substituent in the meta or ortho position. For many substitution patterns, compounds with shorter spacer lengths were superior to those with long chain spacers. Compounds with shorter spacer lengths performed better than those with longer chain spacers for a variety of substitution patterns. The most active compound held inhibition constant as low as Ki = 0.67 μM (for 49b) and a tert-butyl substituent in para position and acted as a competitive inhibitor of the enzyme.

Unraveling the unique structural motifs of glucuronoxylan from hybrid aspen wood

Xylan is a fundamental structural polysaccharide in plant secondary cell walls and a valuable resource for biorefinery applications. Deciphering the molecular motifs of xylans that mediate their interaction with cellulose and lignin is fundamental to understand the structural integrity of plant cell walls and to design lignocellulosic materials. In the present study, we investigated the pattern of acetylation and glucuronidation substitution in hardwood glucuronoxylan (GX) extracted from aspen wood using subcritical water and alkaline conditions. Enzymatic digestions of GX with β-xylanases from glycosyl hydrolase (GH) families GH10, GH11 and GH30 generated xylo-oligosaccharides with controlled structures amenable for mass spectrometric glycan sequencing. We identified the occurrence of intramolecular motifs in aspen GX with block repeats of even glucuronidation (every 2 xylose units) and consecutive glucuronidation, which are unique features for hardwood xylans. The acetylation pattern of aspen GX shows major domains with evenly-spaced decorations, together with minor stretches of highly acetylated domains. These heterogenous patterns of GX can be correlated with its extractability and with its potential interaction with lignin and cellulose. Our study provides new insights into the molecular structure of xylan in hardwood species, which has fundamental implications for overcoming lignocellulose recalcitrance during biochemical conversion.