SYNTHETIC ROUTES AND NATURAL SOURCES OF 2-PYRIDONE DERIVATIVES AND THEIR PHARMACOLOGICAL ACTIVITY

PREM SHANKAR  MISHRA; Ravichandiran V; Vijey Aanandhi M

doi:10.22159/ajpcr.2017.v10i7.17989

Authors

PREM SHANKAR MISHRA Department of Pharmaceutical Chemistry and Analysis, Vels University, Chennai - 600 117, Tamil Nadu, India.
Ravichandiran V Department of Pharmaceutical , National Institute of Pharmaceutical Education and Research, Kolkata, West Bengal, India.
Vijey Aanandhi M Department of Pharmaceutical Chemistry and Analysis, Vels University, Chennai - 600 117, Tamil Nadu, India.

DOI:

https://doi.org/10.22159/ajpcr.2017.v10i7.17989

Keywords:

Naturally obtained 2-pyridone derivatives, Synthetic approach, Anticancer activity

Abstract

Objective: 2-pyridone is a well-known heterocyclic ring having significant biological and medical application. The molecular structures and various activities of 2-pyridone derivatives as well as their syntheses and natural occurrence are analyzed and reviewed, and their reactivity toward various nucleophiles is discussed.

Methods: 2-pyridone derivatives, first naturally obtained and described as early as before the 19th century, have been attracting increasing attention in view of their high reactivity as building blocks for the preparation of compounds of various classes due to their selective transformations with different reagents. Much information describing the natural occurrence, synthesis and the significant biological activity of 2-pyridone compounds are scattered throughout the literature. There are short chapters dealing with the synthesis and activity of 2-pyridone derivatives.

Results: After compiling the above material, the abundance of certain heterocyclic ring and nature of typical chemical transformations applied in current drug synthesis. It is likely this results from the abundance of these heterocycles in natural products such as alkaloids and various synthetic derivatives revealing different biological activity. This might suggest a classical approach to drug design where substrate analogs gain inspiration from existing natural ligands.

Conclusions: The data considered in this review clearly demonstrate the high synthetic potential of 2-pyridone derivatives. Many biologically active heterocyclic compounds have been obtained based on this heterocyclic ring. This suggests that 2-pyridone can be used in the design of novel highly effective pharmaceuticals with a broad spectrum of bioresponses.

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Author Biography

Vijey Aanandhi M, Department of Pharmaceutical Chemistry and Analysis, Vels University, Chennai - 600 117, Tamil Nadu, India.

Professor Department of Pharmaceutical Chemistry

References

Ravinder M, Mahendar B, Mattapally S, Hamsini VK, Reddy V, Rohit C, et al. Eco-friendly synthesis of diverse and valuable 2-pyridones by catalyst- and solvent-free thermal multicomponent domino reaction. J Bioorg Med Chem Lett 2012;22:6010.

Jessen HJ, Gademann K. 4-hydroxy-2-pyridone alkaloids: Structures and synthetic approaches. Nat Prod Rep 2010;27(8):1168-85.

Chaube A, Pandeya SN. Pyridine a versatile nucleuse in pharmaceutical field. Asian J Pharm Clin Res 2011;4(4):5-8.

Dansena H, Hj D, Chandrakar K. Pharmacological potentials of pyrimidine derivative: A review. Asian J Pharm Clin Res 2015;8(4):171-7.

Cinelli MA, Morrell A, Dexheimer TS, Scher ES, Pommier Y, Cushman M. Design, synthesis, and biological evaluation of 14-substituted aromathecins as topoisomerase I inhibitors. J Med Chem 2008;51(15):4609-19.

Chen J, Lu MM, Liu B, Chen Z, Li QB, Tao LJ, et al. Cheminform Abstract: A versatile domino process for the synthesis of substituted 3-aminomethylene-chromanones and 2-pyridones catalyzed by CsF. Bioorg Med Chem Lett 2012;22:2300.

Nakao Y, Idei H, Kanyiva KS, Hiyama T. Hydrocarbamoylation of unsaturated bonds by nickel/Lewis-acid catalysis. J Am Chem Soc 2009;131(14):5070-1.

Tuson J. Encyclopedia of the alkaloids. J Chem Soc 1864;17:195.

Maquenne L, Philippe L, Hebd CR. 4-Hydroxy-2-pyridone alkaloids: Structures and synthetic approaches. Acad Sci 1904;139:840.

Basyouni SH, El Brewer D, Vining LC. Comparative morphology and biology of the fungi. Can J Bot 1968;46:441.

McInnes AG, Smith V, Wat CK, Vining LC, Wright V. Tenellin and bassianin, metabolites of Beauveria species. Structure elucidation with 15N- and doubly 13C-enriched compounds using 13C nuclear magnetic resonance spectroscopy. J Chem Soc Chem Commun 1974;???:281-2.

Casinovi CG, Grandolini G, Mercantini R, Oddo N, Olivieri R, Tonolo A. A new antibiotic produced by a strain of Aspergillus flavipes. Tetrahedron Lett 1968;27:3175-8.

Ando K, Suzuki S, Saehi T, Tamura G, Arima K. Novel tetramic acids and pyridone alkaloids, militarinones B, C, and D, from the insect pathogenic fungus Paecilomyces militaris. J Antibiot 1969;22:189-94.

Hayakawa S, Minato H, Katagiri K. The ilicicolins, antibiotics from Cylindrocladium ilicicola. J Antibiot (Tokyo) 1971;24(9):653-4.

Wolf H, Zâ‚¬ahner H. Protein synthesis elongation factor eftufrom Streptomyces collinus producing kirromycin. Arch Microbiol 1972;83:147-54.

Breinhold J, Ludvigsen S, Rassing BR, Rosendahl CN, Nielsen SE, Olsen CE. Oxysporidinone: A novel, antifungal N-methyl-4-hydroxy- 2-pyridone from Fusarium oxysporum. J Nat Prod 1997;60(1):33-5.

Singh SB, Liu W, Li X, Chen T, Shafiee A, Card D, et al. Antifungal spectrum, in vivo efficacy, and structure-activity relationship of ilicicolin h. ACS Med Chem Lett 2012;3(10):814-7.

Storck P, Aubertinb AM, Grierson DS. Studies on compounds consisting quinoline and 2-pyridone heterocycles. Tetrahedron Lett 2005;46:2919.

Cocco MT, Congiu C, Onnis V. New bis(pyridyl)methane derivatives from 4-hydroxy-2-pyridones: Synthesis and antitumoral activity. Eur J Med Chem 2003;38(1):37-47.

Cocco MT, Congiu C, Onnis V. Synthesis and antitumour activity of 4-hydroxy-2-pyridone derivatives. Eur J Med Chem 2000;35(5):545-52.

Lv Z, Sheng C, Wang T, Zhang V, Liu J, Feng V, et al. Pathologically decreased miR-26a antagonizes apoptosis and facilitates carcinogenesis by targeting MTDH and EZH2 in breast cancer. J Med Chem 2010;53:660.

Wallace EM, Lyssikatos J, Blake JF, Seo J, Yang HW, Yeh TC, et al. Potent and selective mitogen-activated protein kinase kinase (MEK) 1,2 inhibitors 1. 4-(4-bromo-2-fluorophenylamino)-1- methylpyridin- 2(1H)-ones. J Med Chem 2006;49(2):441-4.

Hu E, Tasker A, White RD, Kunz RK, Human J, Chen V, et al. Discovery of aryl aminoquinazoline pyridones as potent, selective, and orally efficacious inhibitors of receptor tyrosine kinase c-Kit. J Med Chem 2008;51(11):3065-8.

Li R, Xue L, Zhu T, Jiang Q, Cui X, Yan Z, et al. Design and synthesis of 5-aryl-pyridone-carboxamides as inhibitors of anaplastic lymphoma kinase. J Med Chem 2006;49(3):1006-15.

Lenaerts AJ, Bitting C, Woolhiser L, Gruppo V, Marietta KS, Johnson CM, et al. Evaluation of a 2-pyridone, KRQ-10018, against Mycobacterium tuberculosis in vitro and in vivo. Antimicrob Agents Chemother 2008;52(4):1513-5.

Dragovich PS, Prins TJ, Zhou R, Johnson TO, Hua Y, Luu HT, et al. Structure-based design, synthesis, and biological evaluation of irreversible human rhinovirus 3C protease inhibitors. 8. Pharmacological optimization of orally bioavailable 2-pyridone-containing peptidemimetics. J Med Chem 2003;46(21):4572-85.

Cheney IW, Yan S, Appleby T, Walker H, Vo T, Yao N, et al. Identification and structure-activity relationships of substituted pyridones as inhibitors of Pim-1 kinase. Bioorg Med Chem Lett 2007;17(6):1679-83.

SchrÃ¶der P, FÃ¶rster T, Kleine S, Becker C, Richters A, Ziegler S, et al. Neuritogenic militarinone-inspired 4-hydroxypyridones target the stress pathway kinase MAP4K4. Angew Chem Int Ed Engl 2015;54(42):12398-403.

Schmidt K, GÃ¼nther W, Stoyanova S, Schubert B, Li Z, Hamburger M. Militarinone A, a neurotrophic pyridone alkaloid from Paecilomyces militaris. Org Lett 2002;4(2):197-9.

Wagenaar MM, Gibson DM, Clardy J. Akanthomycin, a new antibiotic pyridone from the entomopathogenic fungus Akanthomyces gracilis. Org Lett 2002;4(5):671-3.

Isaka M, Tanticharoen M, Kongsaeree P, Thebtaranonth Y. Structures of cordypyridones A-D, antimalarial N-hydroxy- and N-methoxy-2- pyridones from the insect pathogenic fungus Cordyceps nipponica. J Org Chem 2001;66(14):4803-8.

Jegorov A, Matha V, Husak M, Kratochvil B, Stuchilik J, Sedmera P, et al. Structures of cordypyridones A-D, antimalarial N-hydroxy-and N-methoxy-2-pyridones from the insect pathogenic fungus cordyceps nipponica. J Chem Soc Dalton Trans 1993;AQ2 ???:1287.

TePaske MR, Gloer JB, Wicklow DT, Dowd PF. Chromatography of mycotoxins: Techniques and applications. Tetrahedron Lett 1991;32:5687.

Snider BB, Lu Q. Formal synthesis of 15-acetoxypallescensin-A. Synth Commun 2001;31:2667.

Henry AA, Yu C, Romesberg FE. Determinants of unnatural nucleobase stability and polymerase recognition. J Am Chem Soc 2003;125(32):9638.

Li L, Degardin M, Lavergne T, Malyshev DA, Dhami K, Ordoukhanian P, et al. Natural-like replication of an unnatural base pair for the expansion of the genetic alphabet and biotechnology applications. J Am Chem Soc 2014;136(3):826-9.

Chen Y, Wang F, Jia A, Li X. Encyclopedia of reagents for organic synthesis. Chem Sci 2012;3:3231.

Cheng D, Gallagher T. Direct and regioselective C-H alkenylation of tetrahydropyrido[1,2-a]pyrimidines. Org Lett 2009;11(12):2639-41.

Ortiz-de-Elguea V, Sotomayor N, Lette E. Palladium-catalyzed direct alkenylation of 4-hydroxy-2-pyridones. Adv Synth Catal 2015;357:463.

Nakatani A, Hirano K, Satoh T, Miura V. Nickel-catalyzed direct alkylation of heterocycles with Î±-bromo carbonyl compounds: C3- selective functionalization of 2-pyridones. Chem Eur J 2013;19:7691.

Modak A, Rana S, Maiti D. Iron-catalyzed regioselective direct arylation at the C-3 position of N-Alkyl-2-pyridone. J Org Chem 2015;80(1):296-303.

Nakatani A, Hirano K, Satoh T, Miura M. A concise access to (polyfluoroaryl)allenes by Cu-catalyzed direct coupling with propargyl phosphates. J Org Chem 2014;79:1377.

Tamura R, Yamada Y, Nakao Y, Hiyama T. Quinoline-fused heterocycles via rhodium(III)-Catalyzed Câˆ’C/Câˆ’N coupling of bifunctional substrates. Chem Int Ed 2012;51:5679.

Nakao Y, Idei H, Kanyiva KS, Hiyama T. Direct alkenylation and alkylation of pyridone derivatives by Ni/AlMe3 catalysis. J Am Chem Soc 2009;131:15996.

Anagnostaki EE, Fotiadou AD, Demertzidou V, Zografos AL. Palladium catalyzed C3-arylation of 4-hydroxy-2-pyridones. Chem Commun (Camb) 2014;50(52):6879-82.

Sugandha C, Jigar SD, Aditya A, Preetesh M. JAK/STAT as a novel target for treatment of leukemia. Int J Pharm Pharm Sci 2014;6(1):1-7.

Partha GS, Manna K, Udayan B, Manik D, Priyatosh S. Synthetic strategies and pharmacology of 2-Oxo-3-cyanopyridine derivatives: A review. Int J Pharm Pharm Sci 2014;6(4):39-42.

Karam C, Suchita P, Rakesh KT, Shirazi AN, Sumit K, Keykavous P, et al. Synthesis and evaluation of c-Src kinase inhibitory activity of pyridin-2(1H)-one derivatives. Bioorg Chem 2014;53:75-82.

Mijin DZ, Markovic JM, Brkovic DV, Aleksandar D. Marinkovic microwave-assisted synthesis of 2-pyridone and 2-pyridone-based compounds. Hem Ind 2014;68(1):1-14.

Seifi M, Rabori MK, Sheibani H. Highly efficient method for synthesis of N-amino-2-pyridone derivatives in the presence of catalysts such as magnesium oxide (MgO) and bismuth(III) nitrate pentahydrate (Bi(NO3)3â€¢5H2O). Mod Res Catal 2013;2:8-12.

Mehrparvar S, Balalaie S,â€¢Rabbanizadeh M, Ghabraie E, Rominger F. An efficient tandem approach for the synthesis of functionalized 2-pyridone-3-carboxylic acids using three-component reaction in aqueous media. Mol Divers 2013;???:25-34.

Al-Abdullah ES. Synthesis and anticancer activity of some novel tetralin- 6-yl-pyrazoline, 2-thioxopyrimidine, 2-oxopyridine, 2-thioxo-pyridine and 2-iminopyridine derivatives. Molecules 2011;16(4):3410-9.

Lv Z, Sheng C, Wang T, Zhang Y, Liu J, Feng J, et al. Design, synthesis, and antihepatitis B virus activities of novel 2-pyridone derivatives. J Med Chem 2010;53(2):660-8.

Tkachova VP, Gorobets NY, Tkachov RP, Dyachenko OD, Rusanov EB, Dyachenko VD. Reactions of diethyl 2-(ethoxymethylene)malonate with 2-cyanoacetanilides: Unexpected transfer of the ethoxymethylene moiety. ARKIVOC 2010;XI:254-64.

Jacinto DA, Valente VM, Barbosa LC, Rathi AH, Donohoe TJ, Thompson AL. Synthesis and phytotoxic activity of new pyridones derived from 4-hydroxy-6-methylpyridin-2(1H)-one. Molecules 2009;14:4973-86.

Tugusheva NZ, Alekseeva LM, Shashkov V, Chernyshev V, Granika V. Synthesis and functionalization of 4 arylamino2-pyridone derivatives. Russ Chem Bull Int Ed 2006;55(8):1475-86.

Yu N, Behrooz G, Belaj F. Carbon bond formation via rhodium (III)- catalyzed oxidative C-H activation. Tetrahedron 2006;60:8633-44.

Ando M, Wada T, Sato N. Facile one-pot synthesis of N-difluoromethyl- 2-pyridone derivatives. Org Lett 2006;8:3805-8.

Kajal C, Devakumar C. Quantitative structure-activity relationship analysis as a tool to evaluate the mode of action of chemical hybridizing agents for wheat (Triticum aestivum L.) J Agric Food Chem 2005;53:3468-75.

Desai NC, Shihory NR, Kotadiya GM. Facile synthesis of benzimidazole bearing 2-pyridone derivatives as potential antimicrobial agents. Chin Chem Lett 2014;25(2):305-7.

Fischer CB, Polborn K, Steininger H, Zipse H. Synthesis and solid-state structures of alkyl-substituted 3-cyano-2-pyridones. Z Naturforsch 2004;59:1121-31.