Chemistry of insect antifeedants from azadirachta indica (part 3): reactions on the C-22,23 enol ether double bond of azadirachtin and conversion to 22,23-dihydro-23-β-methoxyazadirachtin.

Azadirachtin (1) can be converted to the natural product 22,23-dihydro-23β-methoxyazadirachtin (2) via selective bromomethoxylation of the C-22,23 enol ether double bond and tri-n-butyltin hydride reduction; the corresponding acetic acid adduct on pyrolysis affords (1) in high yield. The antifeedant effects of the addition compounds were assessed.     

Synthesis of [2‐aryl‐6‐oxo‐6H‐chromeno[6,7‐d]oxazol‐8‐yl]‐acetic acid ethyl esters

A number of coumarino[6,7‐d]oxazoles (nitrogen analogs of psoralens) have been synthesized from (7‐hydroxy‐2‐oxo‐2H‐chromen‐4‐yl) acetic acid ethyl ester 1 . The synthetic route began with the nitration of 1 with nitric acid in acetic acid to give (6‐nitro‐7‐hydroxy‐2‐oxo‐2H‐chromen‐4‐yl) acetic acid ethyl ester 2 ; (3,6‐dinitro‐7‐hydroxy‐2‐oxo‐2H‐chromen‐4‐yl) acetic acid ethyl ester 3 and (3,6,8‐trinitro‐7‐hydroxy‐2‐oxo‐2H‐chromen‐4‐yl) acetic acid ethyl ester 4 . The reduction of 2 was accomplished with tin(II) chloride, tin, and concentrated hydrochloric acid in ethanol giving (6‐amino‐7‐hydroxy‐2‐oxo‐2H‐chromen‐4‐yl) acetic acid ethyl ester 5 . After the condensation of aminocoumarin 5 with aromatic aldehyde in glacial acetic acid medium, followed the dehydrocyclization to coumarino[6,7‐d]oxazoles 7a‐k . The intermediate Schiff's bases 6a‐k have been obtained from 5 with aromatic aldehyde in ethanol. Antibacterial and antifungal activities of the compounds have been evaluated.     

Novel Synthesis and Antimicrobial Activity of 3‐Substituted 5‐bromo‐7‐methyl‐1,2,4‐triazolo‐[3,4‐b]‐benzothiazoles

4‐Methyl acetanilide ( 1 ) on treatment with bromine in acetic acid, followed by hydrolysis with dilute HCl/NaOH solution, yielded 2‐bromo‐4‐methyl aniline ( 2 ), which on treatment with sodium thiocyanate in acetic acid afforded 2‐amino‐4‐bromo‐6‐methyl benzothiazole ( 3 ). Compound 3 in ethylene glycol was heated at 150°C with 80% hydrazine hydrate to get 4‐bromo‐2‐hydrazino‐6‐methyl benzothiazole ( 4 ). This hydrazino compound 4 on heating with formic acid for 3 h yielded 4‐bromo‐2‐hydrazinoformyl‐6‐methyl benzothiazole ( 5 ). Same compound 4 when heated independently with formic acid for 6 h/urea for 3 h/carbon disulfide in alkali afforded 5‐bromo‐7‐methyl ( 6 )/5‐bromo‐3‐hydroxy‐7‐methyl ( 7 )/5‐bromo‐3‐mercapto‐7‐methyl ( 8 )‐1,2,4‐triazolo‐[3,4‐b]‐benzothiazoles, respectively. Compound 4 on heating with acetic acid/acetic anhydride gave acetyl benzothiazolyl derivative 9 , which on cyclization with orthophosphoric acid yielded 5‐bromo‐3,7‐dimethyl‐1,2,4‐triazolo‐[3,4‐b]‐benzothiazole ( 10 ). All these newly synthesized compounds were screened for antimicrobial activity against Escherichia coli (Gram ?ve), Bacillus subtilis (Gram +ve), Erwinia carotovora, and Xanthomonas citri using ampicillin, streptomycin, and penicillin as a standard for comparison.     

One‐Pot Syntheses of 2‐(2‐Sulfanyl‐4H‐3,1‐benzothiazin‐4‐yl)acetic Acid Derivatives via Reactions of 3‐(2‐Isothiocyanatophenyl)prop‐2‐enoic Acid Derivatives with Thiols or Sodium Sulfide

Two efficient methods for the preparation of 2‐(2‐sulfanyl‐4H‐3,1‐benzothiazin‐4‐yl)acetic acid derivatives 3 under mild conditions have been developed. The first method is based on the reaction of 3‐(2‐isothiocyanatophenyl)prop‐2‐enoates 1a – 1c with thiols in the presence of Et₃N in THF at room temperature, leading to the corresponding dithiocarbamate intermediates 2 , which underwent spontaneous cyclization at the same temperature by an attack of the S‐atom at the prop‐2‐enoyl moiety in a 1,4‐addition manner (Michael addition) to give 2‐(2‐sulfanyl‐4H‐3,1‐benzothiazin‐4‐yl)acetates in one pot. The second method involves treatment of 3‐(2‐isothiocyanatophenyl)prop‐2‐enoic acid derivatives 1b – 1d with Na₂S leading to the formation of 2‐(2‐sodiosulfanyl‐4H‐3,1‐benzothiazin‐4‐yl)acetic acid intermediates 5 by a similar addition/cyclization sequence, which are then allowed to react with alkyl or aryl halides to afford derivatives 3 . 2‐(2‐Thioxo‐4H‐3,1‐benzothiazin‐4‐yl)acetic acid derivatives 6 can be obtained by omitting the addition of halides.     

(–)‐Parasantonic acid and its enol lactone, (+)‐parasantonide: observation of the rare acid‐to‐acid catemeric hydrogen‐bonding mode in a γ,ɛ‐diketocarboxylic acid

The title diketo acid, (−)‐,3a,7‐tri­methyl‐5,8‐dioxo‐1,4‐ethano­per­hydro­pentalene‐1‐acetic acid, CHO, is shown to aggregate in the solid state as acid‐to‐acid hydrogen‐bonded catemers, whose chains follow 2 screw axes from each carboxyl H atom to the C=O group of a neighboring carboxyl group [O⋯O = 2.672 (4) Å and O⋯H—O = 173°]. Two parallel counterdirectional screw‐related single‐strand hydrogen‐bonded chains pass through the cell in the a direction. Two intermolecular C=O⋯H—C close contacts are present in this compound. Both this diketo acid and its enol lactone, (+)‐parasantonide [systematic name: (−)‐,3a,7‐tri­methyl‐5‐oxo‐1,4‐ethenoper­hydro­pentalene‐1,8‐carbolactone], CHO, have an R configuration at the methyl­ated chiral center adjacent to the carboxyl group, unlike the precursor from which they are derived, viz. (−)‐santonic acid.     

Revelation of ESIPT mechanism for the novel fluorescent system HNIBT in toluene and methanol solvents: A TDDFT study

In this work, we devote to explore excited‐state intramolecular proton transfer (ESIPT) behavior for a novel fluorescent molecule naphthalimide‐based 2‐(2‐hydroxyphenyl)‐benzothiazole (HNIBT) [New J. Chem. 2019, 43, 9152.] in toluene and methanol (MeOH) solvents. Exploring weak interactions, stable HNIBT‐enol, and HNIBT‐MeOH‐enol complex can be found in S₀ state via TDDFT/B3LYP/6‐311+G(d,p) level. Given photoexcitation, intramolecular hydrogen bond O1? H2···N3 of HNIBT‐enol and HNIBT‐MeOH‐enol is dramatically enhanced, which offers impetus for facilitates ESIPT reaction. After repeated comparisons, we verify the unavailability of intermolecular hydrogen bonding effects between HNIBT‐enol and MeOH molecules. In view of excitation, HOMO (π) → LUMO (π*) transition and the changes of electronical densities indeed impulse ESIPT tendency. Via constructing potential energy curves (PECs), for both HNIBT‐enol and HNIBT‐MeOH‐enol complex, the ESIPT could only occur along with intramolecular hydrogen bond O1? H2···N3. Through comparison, the potential barrier falls from 4.124 kcal/mol (HNIBT‐enol) to 2.132 kcal/mol (HNIBT‐MeOH‐enol). Therefore, we confirm that the ESIPT of the HNIBT system happens more easily in the MeOH solvent compared with the toluene solvent.     

A Divergent Synthesis of Spiropyrazole Derivatives Containing Iminolactone and/or Cyclic Imide Moiety

An approach to spiropyrazole derivatives containing iminolactone and/or cyclic imide moiety starting from 1H‐pyrazole‐4‐acetic acid derivative is described. Hydrolysis of C‐cyanomethylated 1H‐pyrazole‐4‐acetic acid methyl ester ( 1 ), which was easily prepared from 1H‐pyrazole‐4‐acetic acid derivative by a C‐cyanomethylation, led to the C‐cyanomethylated 1H‐pyrazole‐4‐acetic acid ( 2 ). Compound 2 was reacted with ethanol in the presence of tin(IV) chloride in refluxing chloroform to give the key intermediate ethyl imidate ( 3 ). Sodium hydride‐assisted lactonization of 3 in N,N‐dimethylformamide afforded the spiropyrazole derivative containing iminolactone moiety ( 4 ). On the other hand, thermal treatment of 3 with sodium acetate in the absence of solvent caused another intramolecular cyclization to yield the spiropyrazole derivative containing cyclic imide moiety ( 6 ).     

Synthesis,Tautomerism, and Antiradical Activity of Novel Pteridinetrione Derivatives

Synthesis of 1‐methyl‐6‐((2‐(aryl‐(heteryl‐))‐2‐oxoethyl) pteridine‐2,4,7(1H,3H,8H)‐triones via [4 + 2]‐cycloaddition of 1‐methyl‐5,6‐diaminouracil with ethyl 4‐aryl(heteryl)‐2,4‐dioxobutanoates is described in presented work. It was established that the reaction occurs regioselectively and proceeds under refluxing of starting compounds in acetic acid for 60 min. The structures of synthesized compounds were proven by complex of physicochemical methods including infrared, ¹H‐, ¹³C‐NMR spectroscopy, liquid chromatography–mass spectrometry, and electron impact–mass spectrometry. Based on the detail analysis of the correlational NMR spectral data (correlation spectroscopy, heteronuclear single quantum coherence, heteronuclear multiple bond correlation, and Nuclear Overhauser effect spectroscopy), it was determined that in dimethyl sulfoxide solution, the 1‐methyl‐6‐((2‐(aryl‐(heteryl‐))‐2‐oxoethyl)pteridine‐2,4,7(1H,3H,8H)‐triones exist in two tautomeric forms: ketone (A) and enol (B). It was also found that tautomeric behavior of aforementioned compounds in hexadeuterated dimethyl sulfoxide is sensitive to the nature of the aryl or heteryl substituent at the position 6 of ring. The electron donating groups shift equilibrium to the tautomer A, while electron withdrawing – to the tautomer B. The synthesized compounds were tested on antiradical activity. It was found that obtained compounds reveal radical scavenging activity comparable or higher than ascorbic acid.     

Substituent effects on enol nitrosation of 1,3‐diketones

The keto–enol tautomerism of 3‐chloro‐pentane‐2,4‐dione (ClPD) was studied in aqueous micellar solutions of cationic, anionic, and nonionic surfactants. The enol of ClPD tautomerizes rapidly in water to the equilibrium proportions of the keto form, K_E=0.55; whereas the keto–enol conversion of 3‐ethyl‐pentane‐2,4‐dione (EPD) is a much slower reaction than the enol nitrosation. Kinetics of enol –nitrosation of both ClPD and EPD in aqueous acid medium using nitrous acid shows first‐order dependence upon [ketone] and linear or curve relationships of the observed rate constant, k_o, as a function of [nitrite] or [H⁺]; the observed behavior depends on the molecular structure of diketone and varies with the experimental conditions. The reaction is strongly catalyzed by Cl^?, Br^?, or SCN^?, and the observed rate constant shows a curve dependence on [Br^?] or [SCN^?], which is more pronounced at high acidity. The results are consistent with a reaction mechanism in which the nitrosation occurs initially on the enol–oxygen and releasing a proton to form a chelate–nitrosyl complex intermediate in steady state. Fine differences on the mechanistic spectrum of enols nitrosation are considered on the basis of the molecular structure of the diketone. © 2012 Wiley Periodicals, Inc. Int J Chem Kinet 44: 668–679, 2012     

Acid anhydrides as alternatives to acid chlorides in the palladium‐catalyzed reaction with silacyclobutanes

The palladium‐catalyzed reaction of acid anhydrides with silacyclobutane gives a mixture of cyclic silyl enol ether, carboxy(propyl)silane, and 3‐(carboxysilyl)ketone. In the presence of N,N‐dicyclohexylcarbodiimido (DCC), the reaction preferentially provides a cyclic silyl enol ether in a good yield. In addition, the palladium‐catalyzed reaction of benzoic acid with silacyclobutane in the presence of two equivalents of DCC also affords a cyclic silyl enol ether in a moderate yield. Copyright © 2001 John Wiley & Sons, Ltd.     

Theoretical study on keto–enol tautomerism and isomerization in pyruvic acid

Isomerization and tautomerism of 12 isomers of pyruvic acid including 4 keto and 8 enol forms were studied at the MP2 and B3LYP levels of theory using 6‐311++G(2df,p) basis set, separately. Activation energy (E_a), imaginary frequency (υ), and Gibbs free energy (ΔG^#) of the considered isomerization and tautomerism reactions were calculated. Interconversion of the enol forms proceeds through two paths: (i) proton transfer and (ii) internal rotation. Activation energies for the proton transfer paths were in the range of 125–145 kJ/mol and for the internal rotation paths were in the range of 5–45 kJ/mol. Keto–enol tautomerism of pyruvic acid proceeds only through proton transfer route and their activation energies were in the range of 200–300 kJ/mol. Effect of microhydration on the transition state structures and activation energies was also investigated. It was found that the presence of a water molecule catalyzes the isomerization and tautomerism reactions of pyruvic acid so that the activation energies decrease. © 2013 Wiley Periodicals, Inc.     

A modified bischler-napieralski reaction. Synthesis of 2,3,4,9- tetrahydro-1H-pyrido[3,4-B]indole derivatives and their base-catalyzed transformation to N-acetyl-N-[2-[1 -acetyl-2-[1 -(acetyloxy)-1-propenyl]- 1H-indol-3-yl]ethyl]acetamides

The treatment of N-[2-(1H-indol-3-yl)ethyl]alkanamide, 1 (1), with phosphorus oxychloride under controlled conditions gave l-alkyl-2,3,4,9-tetrahydro-1H-pyrido[3,4-b]indol-1-ol, 2 . The reaction of 2 with acetic anhydride or with methyl isocyanate at room temperature resulted in the formation of amido carbinol 3 and urea carbinol 7, respectively. The former was transformed into amido ester 4 by boiling acetic anhydride. When the reaction of 3 with acetic anhydride was carried out in the presence of excess triethylamine at 105°, C-N bond cleavage of the tetrahydropyridine ring took place with concurrent bis(N-acetylation) to give the enol ester derivative 5 . The structures of all compounds are consistent with chemical and spectral evidence.     

A Novel Concept for Combinatorial Chemistry in Solution: Synthesis of Highly Substituted Pyrrolidines by Multicomponent Domino Reactions

The multicomponent domino Knoevenagel hetero‐Diels? Alder hydrogenation process of N‐[(benzyloxy)carbonyl(Cbz)‐protected amino aldehydes with N,N‐dimethylbarbituric acid and the trimethylsilyl enol ethers 1 – 3 leads to the formation of the substituted pyrrolidines 12 – 15 . Under the same conditions, reaction of the trimethylsilyl enol ether 4 , obtained from acetophenone, gave the primary amines 18a , b probably due to a hydrogenolytic cleavage of the intermediately formed pyrrolidines. The zwitterionic products were obtained in high purity simply by precipitation with Et₂O.     

Selective Synthesis of New Tetracyclic Coumarin‐fused Pyrazolo[3,4‐b]pyridines and Pyrazolo[3,4‐b]pyridin‐6(7H)‐ones

A three‐component reaction for the synthesis of new coumarin‐fused tetracyclic system from 4‐hydroxycoumarin, aldehydes, and 5‐aminopyrazoles/5‐aminoisoxazole is described. In the presence of acetic acid, 4,7‐dihydro‐1H‐pyrazolo[3,4‐b]pyridines ( 4 ) and pyrazolo[3,4‐b]pyridines ( 5 ) were obtained in acetonitrile and dimethylsulfoxide medium, respectively. The reaction gave rise to 4,5‐dihydro‐1H‐pyrazolo[3,4‐b]pyridin‐6(7H)‐ones ( 6 ) in acetic acid–ethanol combination system, which involved the C–O bond cleavage. 4‐Hydroxy‐6‐methyl‐2H‐pyran‐2‐one and acenaphthylene‐1,2‐dione were also examined, affording the corresponding C–O bond cleavage products. Mechanism indicates that the reaction is reversible in acetic acid–ethanol combination system.     

Mechanism of Gold(I)‐Catalyzed Conia‐ene Reaction of β‐Ketoesters with Alkynes: A DFT Study

Density functional calculations have been performed to comparatively investigate two possible pathways of Au(I)‐catalyzed Conia‐ene reaction of β‐ketoesters with alkynes. Our studies find that, under the assistance of trifluoromethanesulfonate (TfO), the β‐ketoester is the most likely to undergo Model II to isomerize into its enol form, in which TfO plays a proton transfer role through a 6‐membered ring transition state. The coordination of the Au(I) catalyst to the alkynes triple bond can enhance the eletrophilic capability and reaction activity of the alkynes moiety, which triggers the nucleophilic addition of the enol moiety on the alkynes moiety to give a vinyl‐Au intermediate. This cycloisomerizaion step is exothermal by 21.3 kJ/mol with an energy barrier of 56.0 kJ/mol. In the whole catalytic process, the protonation of vinyl‐Au is almost spontaneous, and the formation of enol is a rate‐limiting step. The generation of enol and the activation of Au(I) catalyst on the alkynes are the key reasons why the Conia‐ene reaction can occur in mild condition. These calculations support that Au(I)‐catalyzed Conia‐ene reactions of β‐ketoesters with alkynes go through the pathway 2 proposed by Toste.     

Reaction of α,β‐unsaturated ketones using cerium (IV) sulfate tetrahydrate in acetic acid

The reaction of α,β‐unsaturated ketones with cerium (IV) sulfate tetrahydrate [Ce(SO₄)₂·4H₂O, CS] in acetic acid gave the corresponding β‐acetoxy ketones. In the case of 2‐cyclohexen‐1‐one with CS in acetic acid, benzobicyclo[2.2.2]octen‐2‐one was obtained. The reaction mechanism also was proposed. Moreover, we report the aromatization and esterification of (R)‐(?)‐carvone by CS in acetic acid. Copyright © 2007 John Wiley & Sons, Ltd.     

Polyfunctional fused heterocyclic compounds via indene‐1,3‐diones

2‐Dimethylaminomethylene‐ and 2‐ethoxymethylene‐1,3‐indendione 1a,b react with 6‐amino‐2‐thioxopyrimidin‐4(3H)‐one 2 in boiling acetic acid to give 2‐thioxo‐1,3‐dihydroindeno[3,2‐d]pyrimidino[4,5‐b]pyridine‐4,9‐dione ( 4 ). The latter compound reacts with hydrazonoyl chlorides 5a–c to afford products 12a–c . Formamidine 15 reacts with indene‐1,3‐dione in boiling ethanol to give acyclic compound 16 , which cyclizes to 12a in boiling glacial acetic acid. Also, enaminone 1a reacts with heterocyclic amines 17a–e in boiling ethanol, affording the corresponding substitution products 18a–c , respectively. The latter products 18a–c cyclize in glacial acetic acid to give 19a–c , respectively. The structures of the newly synthesized compounds are established on the basis of chemical and spectroscopic evidence. © 2003 Wiley Periodicals, Inc. Heteroatom Chem 14:491–497, 2003; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/hc.10166     

1H‐Pyrrolo[2,3‐b]pyridine‐3‐acetic acid as a molecular probe for use in auxin physiology

The structural characterization of 1H‐pyrrolo­[2,3‐b]­pyridine‐3‐acetic acid (alternative name: 7‐aza­indole‐3‐acetic acid), C₉H₈N₂O₂, reveals similar molecular geometry, i.e. with the side chain perpendicular to the 7‐aza­indole ring, to that of the natural plant growth hormone indole‐3‐acetic acid (auxin) and its alkyl­ated and halogenated derivatives.     

Bifunctional coumarin derivatives in solution and solid phase synthesis of fluorogenic enzyme substrates

The use of the fluorescent bifunctional compounds 7‐amino‐4‐coumarinyl‐acetic acid 1 , 7‐hydroxy‐4‐coumarinyl‐acetic acid 2 and ethyl 7‐amino‐4‐coumarinyl‐acetate 3 in solution and solid phase synthesis of fluorogenic enzyme substrates was examined. The intramolecularly quenched fluorogenic substrate N‐(7‐amino‐4‐coumarinyl‐acetyl)‐L‐phenylalanyl‐p‐nitroanilide 5 , and the fluorogenic one ethyl 7‐(glutaryl‐L‐phenylalanilamido)‐4‐coumarinyl‐acetate 8 , both suitable for chymotrypsin and/or chymotrypsin like enzymes determination, were prepared in solution. The substrates 7‐oleyloxy‐4‐coumarinyl‐acetic acid 13 and 7‐palmitoyloxy‐4‐coumarinyl‐acetic acid 14 , suitable for the enzymatic study of lipases, were prepared by solid phase technique using 2‐chloro‐chlorotrityl‐resin. The study of the fluorescence properties of the fluorophores 1, 2, 3 , and substrates 5, 8,13,14 showed that the examined bifunctional coumarin derivatives are suitable markers for solution and solid phase synthesis of fluorogenic enzyme substrates.     

Oxidation of E,E‐bis(3‐bromo‐1‐chloro‐1‐propen‐2‐yl) chalcogenides and use of E,E‐bis(3‐bromo‐1‐chloro‐1‐propen‐2‐yl)sulfone in heterocyclization with primary amines

Oxidation of E,E‐bis(3‐bromo‐1‐chloro‐1‐propen‐2‐yl) sulfide and selenide with hydrogen peroxide in chloroform/acetic acid or acetic acid affords previously unknown E,E‐bis(3‐bromo‐1‐chloro‐1‐propen‐2‐yl) sulfoxide, selenoxide, and sulfone. The reaction of E,E‐bis(3‐bromo‐1‐chloro‐1‐propen‐2‐yl) sulfone with primary amines in ethanol in the presence of NaHCO₃ or Na₂CO₃ is found to lead not only to heterocyclization but also to alcoholysis of the chloromethylidene groups in the intermediate bis(chloromethylidene) derivatives of thiomorpholine‐1,1‐dioxides to afford N‐organyl‐2(E),6(E)‐bis(ethoxymethylidene) thiomorpholine‐1,1‐dioxides as final products.