Synthesis, molecular docking studies, and antimicrobial evaluation of pyrano[2, 3-c]pyrazole derivatives

El-Assaly, S.; Ismail, A.; Bary, H.; Abouelenein, M.

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Current Chemistry Letters

ISSN 1927-730x (Online) - ISSN 1927-7296 (Print) Quarterly Publication Volume 10 Issue 3 pp. 309-328 , 2021

Synthesis, molecular docking studies, and antimicrobial evaluation of pyrano[2, 3-c]pyrazole derivatives Pages 309-328 Download PDF

Authors: Samy A. El-Assaly, Abd El-Hamid A. Ismail, Hamed Abdel Bary, Mohamed G. Abouelenein

DOI: 10.5267/j.ccl.2021.3.003

Keywords: Pyrano[2, 3-c]pyrazole, Spirooxindoles, Pyrimidine, Antimicrobial, Molecular docking

Abstract: A sequence of pyrano[2, 3-c]pyrazoles was constructed through promoting an eco-friendly, green, and efficient approach. M1-M25 derivatives were developed by a base-catalyzed one-pot reaction involving application of hydrazine hydrate 96%, β-keto ester as ethyl acetoacetate or diethyl malonate, aryl/heteroaryl aldehyde or isatin, and enolizable active methylene compounds with isolation of unexpected compound M2. Further on, intramolecular cyclization of compounds M10, M13 with formic acid, acetic anhydride, and formamide leads to the corresponding pyrimidine derivatives M26-M31. Afterwards, the antimicrobial activity of the compounds was evaluated and fortunately, the vast majority of the compounds showed outstanding anti-bacterial results. Besides, the potential mode of action of the synthesized compounds was determined by employing a molecular-docking study against penicillin-binding protein implicated in anti-bacterial action. Compound M21 was one of the most promising anti-bacterial agents with potential binding affinity against the penicillin-binding protein. This study shed light on novel compounds for further antimicrobial drug development.

How to cite this paper

 El-Assaly, S., Ismail, A., Bary, H & Abouelenein, M. (2021). Synthesis, molecular docking studies, and antimicrobial evaluation of pyrano[2, 3-c]pyrazole derivatives.Current Chemistry Letters, 10(3), 309-328.

Refrences

1 Beerappa M., Shivashankar K. (2018) Four component synthesis of highly functionalized pyrano [2, 3-c] pyrazoles from benzyl halides. Synthetic commun., 48 (2) 146-154.
2 Maddila S., Gorle S., Shabalala S., Oyetade O., Maddila S. N., Lavanya P., Jonnalagadda S. B. (2019) Ultrasound mediated green synthesis of pyrano [2, 3-c] pyrazoles by using Mn doped ZrO2. Arab. J. Chem., 12 (5) 671-679.
3 Vasuki G., Kumaravel K. (2008) Rapid four-component reactions in water: synthesis of pyranopyrazoles. Tetrahedron Lett., 49 (39) 5636-5638.
4 Zolfigol M. A., Tavasoli M., Moosavi-Zare A. R., Moosavi P., Kruger H. G., Shiri M., Khakyzadeh V. (2013) Synthesis of pyranopyrazoles using isonicotinic acid as a dual and biological organocatalyst. RSC Adv., 3 (48) 25681-25685.
5 Liang J., Seydimemet M., Ghalip Z., Ablajan K. (2019) InCl3-catalyzed one-pot synthesis of multi-substituted pyrano [2, 3-c] pyrazole-4-carboxylic acid esters under ultrasound irradiation. Mol. Divers., 23 (2) 275-282.
6 Azizi N., Edrisi M. (2017) Multicomponent reaction in deep eutectic solvent for synthesis of substituted 1-aminoalkyl-2-naphthols. Res. Chem. Intermed., 43 (1) 379-385.
7 Ugi I. (2001) Recent progress in the chemistry of multicomponent reactions. Pure Appl. Chem., 73 (1) 187-191.
8 Mamaghani M., Hossein Nia. R. (2019) A review on the recent multicomponent synthesis of pyranopyrazoles. Polycycl. Aromat. Compd., 1-69.
9 Amirnejat S., Nosrati A., Peymanfar R., Javanshir S. (2020) Synthesis and antibacterial study of 2-amino-4 H-pyrans and pyrans annulated heterocycles catalyzed by sulfated polysaccharide-coated BaFe12O19 nanoparticles. Res. Chem. Intermed., 46 3683-3701.
10 Bensaber S. M., Allafe H. A., Ermeli N. B., Mohamed S. B., Zetrini A. A., Alsabri S. G., Erhuma M., Hermann A., Jaeda M. I., Gbaj A. M. (2014) Chemical synthesis, molecular modelling, and evaluation of anticancer activity of some pyrazol-3-one Schiff base derivatives. Med. Chem. Res., 23 (12) 5120-5134.
11 Hojati S. F., Amiri A., Mohamadi S., MoeiniEghbali N. (2018) Novel organometallic nanomagnetic catalyst for multicomponent synthesis of spiroindoline derivatives. Res. Chem. Intermed., 44 (4) 2275-2287.
12 Abd El-Aal R. M., Younis M. (2004) Synthesis and antimicrobial activity of certain novel monomethine cyanine dyes. Dyes Pigm., 60 (3) 205-214.
13 Wei J., Gui W., Cui Y., Zhang Z., Yousif Q. A. (2020) SCMNPs@ Uridine/Zn: An efficient and reusable heterogeneous nanocatalyst for the rapid one-pot synthesis of tricyclic fused pyrazolopyranopyrimidine and 3-methyl carboxylate substituted pyrano [2, 3-c] pyrazole derivatives under solvent-free conditions. Pol. J. Chem. Technol., 22 (2) 20-33.
14 Labana B. M., Brahmbhatt G. C., Sutariya T. R., Parmar N. J., Padrón J. M., Kant R., Gupta V. K. (2017) Efficient synthesis and biological evaluation of new benzopyran-annulated pyrano [2, 3-c] pyrazole derivatives. Mol. Divers., 21(2) 339-354.
15 Sun X., Zhang L., Gao M., Que X., Zhou C., Zhu D., Cai Y. (2019). Nanoformulation of a Novel Pyrano [2, 3-c] Pyrazole Heterocyclic Compound AMDPC Exhibits Anti-Cancer Activity via Blocking the Cell Cycle through a P53-Independent Pathway. Molecules, 24 (3) 624.
16 Maddila S. N., Maddila S., van Zyl W. E., Jonnalagadda S. B. (2017) CeO2/ZrO2 as green catalyst for one-pot synthesis of new pyrano [2, 3-c]-pyrazoles. Res. Chem. Intermed., 43 (8) 4313-4325.
17 Das D., Banerjee R., Mitra A. (2014). Bioactive and pharmacologically important pyrano [2, 3-c] pyrazoles. J. Chem. Pharm. Res., 6 (11) 108-116.
18 Abdelrazek F. M., Michael F. A., Mohamed A. E. (2006) Synthesis and Molluscicidal Activity of Some 1, 3, 4‐Triaryl‐5‐chloropyrazole, Pyrano [2, 3‐c] pyrazole, Pyrazolylphthalazine and Pyrano [2, 3‐d] thiazole Derivatives. Arch Pharm: Int. J. Pharm. Med. Chem., 339 (6) 305-312.
19 Dabholkar V. V., Kurade S. K., Badhe K. S. (2016) One Pot Synthesis of 4H-Pyrano[2, 3-c] Pyrazole using Ni-Ferrite Nanoparticles. Heterocycl. Lett., 6 (4) 767-774.
20 Mariappan G., Saha B. P., Sutharson L., Ankits G., Pandey L., Kumar D. (2010) The diverse pharmacological importance of pyrazolone derivatives: A Review. J. Pharm. Res., 3 (12) 2856-2859.
21 Moosavi-Zare A. R., Afshar-Hezarkhani H., Rezaei M. M. (2020) Tandem Four Component Condensation Reaction of Aryl Aldehydes with Ethyl Acetoacetate, Malononitrile, and Hydrazine Hydrate using Boric Acid in Water as an Efficient and Green Catalytic System. Polycycl. Aromat. Compd., 40 (1) 150-158.
22 Maarop M. S., Rashid F. N. A. A., Mohammat M. F., Shaameri Z., Johari S. A., Isa M. M., Low A. L. M. (2020) New Access to Pyrano [2, 3-c] pyrazole-3-carboxylates via Domino Four-Component Reaction and Their Antimicrobial Activity. Indones. J. Chem., 20 (1) 60-71.
23 Ali E., Naimi‐Jamal M. R., Ghahramanzadeh R. (2019) One‐Pot Multicomponent Synthesis of Pyrano [2,3 c] pyrazole Derivatives Using CMCSO3H as a Green Catalyst. Chemistry Select, 4 (31) 9033-9039.
24 Mecadon H., Rohman M. R., Kharbangar I., Laloo B. M., Kharkongor I., Rajbangshi M., Myrboh B. (2011) L-Proline as an efficicent catalyst for the multi-component synthesis of 6-amino-4-alkyl/aryl-3-methyl-2, 4-dihydropyrano [2, 3-c] pyrazole-5-carbonitriles in water. Tetrahedron Lett., 52 (25) 3228-3231.
25 Kiyani H., Samimi H., Ghorbani F., Esmaieli S. (2013) One-pot, four-component synthesis of pyrano [2, 3-c] pyrazoles catalyzed by sodium benzoate in aqueous medium. Curr. Chem. Lett., 2 (4) 197-206.
26 Hafez E. A., Elnagdi M. H., Elagamey A. G., El-Taweel F. M. (1987) Nitriles in heterocyclic synthesis: novel synthesis of benzo[c]-coumarin and of benzo[c]pyrano [3, 2-c] quinoline derivatives. Heterocycles, 26 (4) 903-907.
27 Ahmad M. R., Mohammed A. H. A., Ali Y., Al-Messri Z. A. (2014) Synthesis, Characterization and Evaluation of Some Pyranopyrazoles and Pyranopyrimidines Derivatives as Antioxidants for Lubricating Oils. Iraqi J. Sci., 55 (1) 1-11.
28 Yadav D. K., Quraishi M. A. (2012) Electrochemical investigation of substituted pyranopyrazoles adsorption on mild steel in acid solution. Ind. Eng. Chem. Res., 51 (24) 8194-8210.
29 Fadda A. A., El-Mekabaty A., Elattar K. M. (2013) Chemistry of enaminonitriles of pyrano [2, 3-c] pyrazole and related compounds. Synthetic Commun., 43 (20) 2685-2719.
30 Paul S., Pradhan K., Ghosh S., De S. K., Das A. R. (2014) Uncapped SnO2 quantum dot catalyzed cascade assembling of four components: a rapid and green approach to the pyrano [2, 3-c] pyrazole and spiro-2-oxindole derivatives. Tetrahedron, 70 (36) 6088-6099.
31 Myrboh B., Mecadon H., Rohman M. R., Rajbangshi M., Kharkongor I., Laloo B. M., Kharbangar I., Kshiar B. (2013) Synthetic developments in functionalized pyrano [2, 3-c] pyrazoles. A review. Org. Prep. Proced. Int., 45(4) 253-303.
32 Junek H., Aigner H., Tacconi G., Gatti G., Desimoni G., Messori V. J., Shestopalov A. M., Emeliyanova Y. M., Shestopalov A. A., Rodinovskaya L. A., Niazimbetova Z. I. (1973) Cross-condensation of derivatives of cyanoacetic acid and carbonyl compounds, part 1: Single-stage synthesis of 1′-substituted 6-amino-spiro-4-(piperidine-4′)-2H,4H-pyrano [2, 3-c] pyrazole-5-carbonitriles. Chem. Ber., 106 914-921.
33 Al-Matar H. M., Khalil K. D., Adam A. Y., Elnagdi M. H. (2010) Green one pot solvent-free synthesis of pyrano [2, 3-c]-pyrazoles and pyrazolo [1, 5-a] pyrimidines. Molecules, 15 (9) 6619-6629.
34 Reddy M. M., Jayashankara V. P., Pasha M. A. (2010) Glycine-catalyzed efficient synthesis of pyranopyrazoles via one-pot multicomponent reaction. Synthetic Commun., 40 (19) 2930-2934.
35 Gogoi S., Zhao C. G. (2009) Organocatalyzed enantioselective synthesis of 6-amino-5-cyanodihydropyrano [2, 3-c] pyrazoles. Tetrahedron lett., 50 (19) 2252-2255.
36 Shestopalov A. M., Emeliyanova Y. M., Shestopalov A. A., Rodinovskaya L. A., Niazimbetova Z. I., Evans D. H. (2002) One-Step Synthesis of Substituted 6-Amino-5-cyanospiro-4-(piperidine-4′)-2 H, 4 H-dihydropyrazolo [3, 4-b] pyrans. Organic lett., 4 (3) 423-425.
37 Khazdooz L., Zarei, A. (2016) Brönsted acidic ionic liquid as a recyclable catalyst for the one pot four-component synthesis of substituted pyrano [2, 3-c] pyrazoles. Iran. J. Catal., 6 (1) 69-74.
38 Yanfang S., Hualai W., Hui B. (2020) A coumarin-based turn-on chemosensor for selective detection of Zn (II) and application in live cell imaging. Spectrochim. Acta Part A: Mol. Biomol. Spectrosc., 228, 117746.
39 Ahadi S., Yasaei Z., Bazgir A. (2010) A clean and one‐pot synthesis of spiroindoline‐pyranopyrazoles. J. Heterocyclic Chem., 47 (5) 1090-1094.
40 Guo R. Y., An Z. M., Mo L. P., Yang S. T., Liu H. X., Wang S. X., Zhang Z. H. (2013) Meglumine promoted one-pot, four-component synthesis of pyranopyrazole derivatives. Tetrahedron., 69 (47) 9931-9938.
41 Fadda A. A., Etman H. A., El‐Seidy M. Y., Elattar K. M. (2012) Utility of enaminonitriles in heterocyclic synthesis: synthesis of some new pyrazole, pyridine, and pyrimidine derivatives. Am. J. Org. Chem., 49 (4) 774-781.
42 Roma G., Di Braccio M., Carrieri A., Grossi G., Leoncini G., Signorello M. G., Carotti A. (2003) Coumarin, chromone, and 4 (3H)-pyrimidinone novel bicyclic and tricyclic derivatives as antiplatelet agents: synthesis, biological evaluation, and comparative molecular field analysis. Bioorg. Med. Chem., 11 (1) 123-138.
43 Ghate M., Kusanur R. A., Kulkarni M. V. (2005) Synthesis and in vivo analgesic and anti-inflammatory activity of some bi heterocyclic coumarin derivatives. Eur. J. Med. Chem., 40 (9) 882-887.
44 Zgoda J. R., Porter J. R. (2001) A convenient microdilution method for screening natural products against bacteria and fungi. Pharm. Biol., 39 (3) 221-225.
45 Chougala B. M., Samundeeswari S., Holiyachi M., Shastri L. A., Dodamani S., Jalalpure S., Dixit S. R., Joshi S. D., Sunagar V. A. (2017) Synthesis, characterization and molecular docking studies of substituted 4-coumarinylpyrano [2, 3-c] pyrazole derivatives as potent antibacterial and anti-inflammatory agents. Eur. J. Med. Chem., 125, 101-116.
46 Krčméry V., Matejička F., PichňovÁ E., Jurga Ĺ., Sulcova M., Kunová A., West D. (1999) Documented fungal infections after prophylaxis or therapy with wide spectrum antibiotics: relationship between certain fungal pathogens and particular antimicrobials? J. chemother., 11(5) 385-390.
47 Pedretti A., Villa L., Vistoli G. (2004) VEGA–an open platform to develop chemo-bio-informatics applications, using plug-in architecture and script programming. J. Comput. Aided Mol. Des., 18 (3) 167-173.
48 Vina A. (2010) Improving the speed and accuracy of docking with a new scoring function, efficient optimization, and multithreading Trott, Oleg; Olson, Arthur J. J. Comput. Chem., 31 (2) 455-461.
49 Pettersen, E. F., Goddard, T. D., Huang, C. C., Couch, G. S., Greenblatt, D. M., Meng, E. C., Ferrin, T. E. (2004) UCSF Chimera—a visualization system for exploratory research and analysis. J. comput. Chem., 25 (13) 1605-1612.