Optimization of Triazine Nitriles as Rhodesain Inhibitors: Structure–Activity Relationships,Bioisosteric Imidazopyridine Nitriles,and X‐ray Crystal Structure Analysis with Human Cathepsin L

The cysteine protease rhodesain of Trypanosoma brucei parasites causing African sleeping sickness has emerged as a target for the development of new drug candidates. Based on a triazine nitrile moiety as electrophilic headgroup, optimization studies on the substituents for the S1, S2, and S3 pockets of the enzyme were performed using structure‐based design and resulted in inhibitors with inhibition constants in the single‐digit nanomolar range. Comprehensive structure–activity relationships clarified the binding preferences of the individual pockets of the active site. The S1 pocket tolerates various substituents with a preference for flexible and basic side chains. Variation of the S2 substituent led to high‐affinity ligands with inhibition constants down to 2 nM for compounds bearing cyclohexyl substituents. Systematic investigations on the S3 pocket revealed its potential to achieve high activities with aromatic vectors that undergo stacking interactions with the planar peptide backbone forming part of the pocket. X‐ray crystal structure analysis with the structurally related enzyme human cathepsin L confirmed the binding mode of the triazine ligand series as proposed by molecular modeling. Sub‐micromolar inhibition of the proliferation of cultured parasites was achieved for ligands decorated with the best substituents identified through the optimization cycles. In cell‐based assays, the introduction of a basic side chain on the inhibitors resulted in a 35‐fold increase in antitrypanosomal activity. Finally, bioisosteric imidazopyridine nitriles were studied in order to prevent off‐target effects with unselective nucleophiles by decreasing the inherent electrophilicity of the triazine nitrile headgroup. Using this ligand, the stabilization by intramolecular hydrogen bonding of the thioimidate intermediate, formed upon attack of the catalytic cysteine residue, compensates for the lower reactivity of the headgroup. The imidazopyridine nitrile ligand showed excellent stability toward the thiol nucleophile glutathione in a quantitative in vitro assay and fourfold lower cytotoxicity than the parent triazine nitrile.     

Structure–Activity Relationships of SSAO/VAP‐1 Arylalkylamine‐Based Substrates

SSAO/VAP‐1 substrates may be valuable for the treatment or prevention of diabetes mellitus, as they show insulin‐mimetic properties. This review highlights the importance of studying the relevant steric and electronic features in the development of new ligands with better SSAO/VAP‐1 recognition, enhanced selectivity over other amine oxidases, and improved metabolic behavior.

     

Semi‐Synthetic Ecdysteroids as Gene‐Switch Actuators: Synthesis,Structure–Activity Relationships,and Prospective ADME Properties

The ligand‐inducible, ecdysteroid receptor (EcR) gene‐expression system can add critical control features to protein expression in cell and gene therapy. However, potent natural ecdysteroids possess absorption, distribution, metabolism and excretion (ADME) properties that have not been optimised for use as gene‐switch actuators in vivo. Herein we report the first systematic synthetic exploration of ecdysteroids toward modulation of gene‐switch potency. Twenty‐three semi‐synthetic O‐alkyl ecdysteroids were assayed in both a natural insect system (Drosophila B_II cells) and engineered gene‐switch systems in mammalian cells using Drosophila melanogaster, Choristoneura fumiferana, and Aedes aegypti EcRs. Gene‐switch potency is maintained, or even enhanced, for ecdysteroids methylated at the 22‐position in favourable cases. Furthermore, trends toward lower solubility, higher permeability, and higher blood–brain barrier penetration are supported by predicted ADME properties, calculated using the membrane‐interaction (MI)‐QSAR methodology. The structure–activity relationship (SAR) of alkylated ecdysteroids indicates that 22‐OH is an H‐bond acceptor, 25‐OH is most likely an H‐bond donor, and 2‐OH and 3‐OH are donors and/or acceptors in network with each other, and with the EcR. The strategy of alkylation points the way to improved ecdysteroidal actuators for switch‐activated gene therapy.     

From Structure–Activity to Structure–Selectivity Relationships: Quantitative Assessment,Selectivity Cliffs,and Key Compounds

The exploration of structure–activity relationships (SARs) in chemical lead optimization is mostly focused on activity against single targets. Because many active compounds have the potential to act against multiple targets, achieving a sufficient degree of target selectivity often becomes a major issue during optimization. Herein we report a data analysis approach to explore compound selectivity in a systematic and quantitative manner. Sets of compounds that are active against multiple targets provide a basis for exploring structure–selectivity relationships (SSRs). Compound similarity and selectivity data are analyzed with the aid of network‐like similarity graphs (NSGs), which organize molecular networks on the basis of similarity relationships and SAR index (SARI) values. For this purpose, the SARI framework has been adapted to quantify SSRs. Using sets of compounds with differential activity against four cathepsin thiol proteases, we show that SSRs can be quantitatively described and categorized. Furthermore, local SSR environments are identified, the analysis of which provides insight into compound selectivity determinants at the molecular level. These environments often contain “selectivity cliffs” formed by pairs or groups of similar compounds with significantly different selectivity. Moreover, key compounds are identified that determine characteristic features of single‐target SARs and dual‐target SSRs. The comparison of compounds involved in the formation of selectivity cliffs often reveals chemical modifications that render compounds target selective.     

E‐64c‐Hydrazide: A Lead Structure for the Development of Irreversible Cathepsin C Inhibitors

Cathepsin C is a papain‐like cysteine protease with dipeptidyl aminopeptidase activity that is thought to activate various granule‐associated serine proteases. Its exopeptidase activity is structurally explained by the so‐called exclusion domain, which blocks the active‐site cleft beyond the S2 site and, with its Asp 1 residue, provides an anchoring point for the N terminus of peptide and protein substrates. Here, the hydrazide of (2S,3S)‐trans‐epoxysuccinyl‐L ‐leucylamido‐3‐methylbutane (E‐64c) (k₂/K_i=140±5 M ^?1 s^?1) is demonstrated to be a lead structure for the development of irreversible cathepsin C inhibitors. The distal amino group of the hydrazide moiety addresses the acidic Asp 1 residue at the entrance of the S2 pocket by hydrogen bonding while also occupying the flat hydrophobic S1′–S2′ area with its leucine‐isoamylamide moiety. Furthermore, structure–activity relationship studies revealed that functionalization of this distal amino group with alkyl residues can be used to occupy the conserved hydrophobic S2 pocket. In particular, the n‐butyl derivative was identified as the most potent inhibitor of the series (k₂/K_i=56 000±1700 M ^?1 s^?1).     

Design,Synthesis and Structure–Activity Relationships Studies on the D Ring of the Natural Product Triptolide

Triptolide is a diterpene triepoxide natural product isolated from Tripterygium wilfordii Hook F, a traditional Chinese medicinal herb. Triptolide has previously been shown to possess antitumor, anti‐inflammatory, immunosuppressive, and antifertility activities. Earlier reports suggested that the five‐membered unsaturated lactone ring (D ring) is essential for potent cytotoxicity, however, to the best of our knowledge, systematic structure–activity relationship studies have not yet been reported. Here, four types of D ring‐modified triptolide analogues were designed, synthesized and evaluated against human ovarian (SKOV‐3) and prostate (PC‐3) carcinoma cell lines. The results suggest that the D ring is essential to potency, however it can be modified, for example to C18 hydrogen bond acceptor and/or donor furan ring analogues, without complete loss of cytotoxic activity. Interestingly, evaluation of the key series of C19 analogues showed that this site is exquisitely sensitive to polarity. Together, these results will guide further optimization of this natural product lead compound for the development of potent and potentially clinically useful triptolide analogues.     

Flavonoid Dimers as Bivalent Modulators for P‐Glycoprotein‐Based Multidrug Resistance: Structure–Activity Relationships

Bivalent modulators of P‐glycoprotein : A small library of flavonoid homodimers and heterodimers was synthesized, and their in vitro activity in reversing paclitaxel resistance was evaluated along with structure–activity relationships. SAR trends indicate that flavonoid dimers with nonpolar, hydrophobic, less bulky substituents generally show more potent reversing activity. This will help guide future efforts in the search for more potent compounds.

     

A Parallel Semisynthetic Approach for Structure–Activity Relationship Studies of Peptide YY

The gut hormone peptide YY (PYY) is postprandially secreted from enteroendocrine L cells and is involved in the regulation of energy homeostasis. The N‐terminal truncated version PYY(3–36) decreases food intake and has potential as an anti‐obesity agent. The anorectic effect of PYY(3–36) is mediated through Y₂ receptors in the hypothalamus, vagus, and brainstem regions, and it is well known that the C‐terminal tetrapeptide sequence of PYY(3–36) is crucial for Y₂ receptor activation. The aim of this work was to develop a semisynthetic methodology for the generation of a library of C‐terminally modified PYY(3–36) analogues. By using an intein‐based expression system, PYY(3–29) was generated as a C‐terminal peptide α‐thioester. Heptapeptides bearing an N‐terminal cysteine and modifications at one of the four C‐terminal positions were synthesized in a 96‐well plate by parallel solid‐phase synthesis. In the plate format, an array of [Ala30]PYY(3–36) analogues were generated by ligation, desulfurization, and subsequent solid‐phase extraction. The generated analogues, in which either Arg33, Gln34, Arg35, or Tyr36 had been substituted with proteinogenic or non‐proteinogenic amino acids, were tested in a functional Y₂ receptor assay. Generally, substitutions of Tyr36 were better tolerated than modifications of Arg33, Gln34, and Arg35. Two analogues showed significantly improved Y₂ receptor selectivity; therefore, these results could be used to design new drug candidates for the treatment of obesity.     

Novel Insights into Structure–Activity Relationships of N‐Terminally Modified PACE4 Inhibitors

PACE4 plays important roles in prostate cancer cell proliferation. The inhibition of this enzyme has been shown to slow prostate cancer progression and is emerging as a promising therapeutic strategy. In previous work, we developed a highly potent and selective PACE4 inhibitor, the multi‐Leu (ML) peptide, an octapeptide with the sequence Ac‐LLLLRVKR‐NH₂. Here, with the objective of developing a useful compound for in vivo administration, we investigate the effect of N‐terminal modifications. The inhibitory activity, toxicity, stability, and cell penetration properties of the resulting analogues were studied and compared to the unmodified inhibitor. Our results show that the incorporation of a polyethylene glycol (PEG) moiety leads to a loss of antiproliferative activity, whereas the attachment of a lipid chain preserves or improves it. However, the lipidated peptides are significantly more toxic when compared with their unmodified counterparts. Therefore, the best results were achieved not by the N‐terminal extension but by the protection of both ends with the d ‐Leu residue and 4‐amidinobenzylamide, which yielded the most stable inhibitor, with an excellent activity and toxicity profile.     

Structure–Activity Relationships of 1,2‐Disubstituted Benzimidazoles: Selective Inhibition of Heme Oxygenase‐2 Activity

Devising ways to up‐ or down‐regulate heme oxygenase activity is attracting much interest as a strategy for the treatment of a variety of disorders. With a view of obtaining compounds that exhibit high potency and selectivity as inhibitors of the heme oxygenase‐2 (HO‐2) isozyme (constitutive) relative to the heme oxygenase‐1 (HO‐1) isozyme (inducible), several 1,2‐disubstituted 1H‐benzimidazoles were designed and synthesized. Specifically, analogues were synthesized in which the C2 substituent was the following: (1H‐imidazol‐1‐yl)methyl, (N‐morpholinyl)methyl, cyclopentylmethyl, cyclohexylmethyl, or (norborn‐2‐yl)methyl. Compounds with the cyclic system in the C2 substituent being a carbocyclic ring, especially cyclohexyl or norborn‐2‐yl, and the N1 substituent being a ring‐substituted benzyl group, especially 4‐chlorobenzyl or 4‐bromobenzyl, best exhibited the target criteria of high potency and selectivity toward inhibition of HO‐2. The new candidates should be useful pharmacological tools and may have therapeutic applications.     

Discovery of Aporphine Analogues as Potential Antiplatelet and Antioxidant Agents: Design,Synthesis, Structure–Activity Relationships,Biological Evaluations,and in silico Molecular Docking Studies

To explore the potential of aporphine alkaloids, a novel series of functionalized aporphine analogues with alkoxy (OCH₃, OC₂H₅, OC₃H₇) functional groups at C1/C2 of ring A and an acyl (COCH₃ and COPh) or phenylsulfonyl (SO₂Ph and SO₂C₆H₄‐3‐CH₃) functionality at the N6 position of ring B of the aporphine scaffold were synthesized and evaluated for their arachidonic acid (AA)‐induced antiplatelet aggregation inhibitory activity and 2,2‐diphenyl‐1‐picrylhydrazyl (DPPH) free‐radical‐scavenging antioxidant activity, with acetylsalicylic acid and ascorbic acid as standard references, respectively. The preliminary structure–activity relationship related to AA‐induced platelet aggregation inhibitory activity results showed that the aporphine analogues 1‐[1,2,9,10‐tetramethoxy‐6a,7‐dihydro‐4H‐dibenzo[de,g]quinolin‐6(5H)‐yl]ethanone and 1‐[2‐(benzyloxy)‐1,9,10‐trimethoxy‐6a,7‐dihydro‐4H‐dibenzo[de,g]quinolin‐6(5H)‐yl]ethanone to be the best compounds of the series. Moreover, the DPPH free‐radical‐scavenging antioxidant activity results demonstrated that the aporphine analogues 1,2,9,10‐tetramethoxy‐6‐(methylsulfonyl)‐5,6,6a,7‐tetrahydro‐4H‐dibenzo[de,g]quinoline, 2‐ethoxy‐1,9,10‐trimethoxy‐6‐(methylsulfonyl)‐5,6,6a,7‐tetrahydro‐4H‐dibenzo[de,g]quinoline, 1‐ethoxy‐2,9,10‐trimethoxy‐6‐(methylsulfonyl)‐5,6,6a,7‐tetrahydro‐4H‐dibenzo[de,g]quinoline, 2,9,10‐trimethoxy‐6‐(methylsulfonyl)‐1‐propoxy‐5,6,6a,7‐tetrahydro‐4H‐dibenzo[de,g]quinoline, and 1‐(benzyloxy)‐2,9,10‐trimethoxy‐6‐(methylsulfonyl)‐5,6,6a,7‐tetrahydro‐4H‐dibenzo[de,g]quinoline were the best compounds of the series. Moreover, in silico molecular docking simulation studies of the active analogues were also performed.     

Synthesis,Structure–Activity Relationship Studies,and ADMET Properties of 3‐Aminocyclohex‐2‐en‐1‐ones as Chemokine Receptor 2 (CXCR2) Antagonists

Herein we describe the synthesis and structure–activity relationships of 3‐aminocyclohex‐2‐en‐1‐one derivatives as novel chemokine receptor 2 (CXCR2) antagonists. Thirteen out of 44 derivatives were found to inhibit CXCR2 downstream signaling in a Tango assay specific for CXCR2, with IC₅₀ values less than 10 μm . In silico ADMET prediction suggests that all active compounds possess drug‐like properties. None of these compounds show significant cytotoxicity, suggesting their potential application in inflammatory mediated diseases. A structure–activity relationship (SAR) map has been generated to gain better understanding of their binding mechanism to guide further optimization of these new CXCR2 antagonists.     

Anti‐Dengue‐Virus Activity and Structure–Activity Relationship Studies of Lycorine Derivatives

Dengue is a systemic viral infection that is transmitted to humans by Aedes mosquitoes. No vaccines or specific therapeutics are currently available for dengue. Lycorine, which is a natural plant alkaloid, has been shown to possess antiviral activities against flaviviruses. In this study, a series of novel lycorine derivatives were synthesized and assayed for their inhibition of dengue virus (DENV) in cell cultures. Among the lycorine analogues, 1‐acetyllycorine exhibited the most potent anti‐DENV activity (EC₅₀=0.4 μM ) with a reduced cytotoxicity (CC₅₀>300 μM ), which resulted in a selectivity index (CC₅₀/EC₅₀) of more than 750. The ketones 1‐acetyl‐2‐oxolycorine (EC₅₀=1.8 μM ) and 2‐oxolycorine (EC₅₀=0.5 μM ) also exhibited excellent antiviral activities with low cytotoxicity. Structure–activity relationships for the lycorine derivatives against DENV are discussed. A three‐dimensional quantitative structure–activity relationship model was established by using a comparative molecular‐field analysis protocol in order to rationalize the experimental results. Further modifications of the hydroxy group at the C1 position with retention of a ketone at the C2 position could potentially lead to inhibitors with improved overall properties.     

Synthesis and Structure–Activity Relationships of 1‐Benzyl‐4,5,6‐trimethoxyindoles as a Novel Class of Potent Antimitotic Agents

Combretastatin A‐4 derivatives : A series of combretastatin A‐4‐derived 1‐benzyl‐4,5,6‐trimethoxyindoles was designed and prepared as a novel class of potent antimitotic agents acting through the colchicine binding site on the microtubule.

     

Semi‐synthesis and Structure–Activity Relationship of Neuritogenic Oleanene Derivatives

(3S,4R)‐23,28‐Dihydroxyolean‐12‐en‐3‐yl (2E)‐3‐(3,4‐dihydroxyphenyl)acrylate ( 1 a ), which possesses significant neuritogenic activity, was isolated from the traditional Chinese medicine (TCM) plant, Desmodium sambuense. To confirm the structure and to assess biological activity, we semi‐synthesized 1 a from commercially available oleanolic acid. A series of novel 1 a derivatives was then designed and synthesized for a structure–activity relationship (SAR) study. All synthetic derivatives were characterized by analysis of spectral data, and their neuritogenic activities were evaluated in assays with PC12 cells. The SAR results indicate that the number and position of the hydroxy groups on the phenyl ring and the triterpene moiety, as well as the length of the (saturated or unsaturated) alkyl chain that links the phenyl ring with the triterpene critically influence neuritogenic activity. Among all the tested compounds, 1 e [(3S,4R)‐23,28‐dihydroxyolean‐12‐en‐3‐yl (2E)‐3‐(3,4,5‐trihydroxyphenyl)acrylate] was found to be the most potent, inducing significant neurite outgrowth at 1 μm .