Biotransformation studies on bioactive compounds: 25 years of interesting research at the ICCBS

Mahwish Siddiqui; Atia-tul-Wahab; M. Iqbal Choudhary; Atta-ur-Rahman

doi:10.20517/cs.2023.02

Chemical Synthesis ›› 2023, Vol. 3 ›› Issue (3) :25 DOI: 10.20517/cs.2023.02

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Biotransformation studies on bioactive compounds: 25 years of interesting research at the ICCBS

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Abstract

Biotransformation of natural, synthetic, and semi-synthetic compounds has emerged as a frontier branch of chemical sciences that is progressively being applied in numerous fields. In the present review, we have summarized our biotransformation studies on bioactive compounds from 1997 to 2022. Various microbial and plant cell cultures were used for biocatalytic structural transformations. We present here an overview of biotransformation of 53 compounds belonging to various classes of natural, synthetic, and semi-synthetic compounds, published in several leading journals. The structures of the resulting metabolites have been elucidated by detailed spectroscopic studies. Oxidation, reduction, dehydrogenation, chlorination, aromatization, methylation, demethylation, rearrangements, etc. were the main reactions that occurred during the biotransformation processes. Many of the biotransformed products exhibited interesting biological activities. Structural transformations in some cases have also led to improved pharmacokinetic profiles. This review is aimed to provide a focused account of extensive work carried out in our laboratories in this field, as well as the immense potential of biocatalytic transformations in organic chemistry.

Keywords

Biotransformation / whole-cell catalysis / terpenes / steroids / steroidal alkaloids / biological activity evaluation

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Mahwish Siddiqui, Atia-tul-Wahab, M. Iqbal Choudhary, Atta-ur-Rahman. Biotransformation studies on bioactive compounds: 25 years of interesting research at the ICCBS. Chemical Synthesis, 2023, 3(3): 25 DOI:10.20517/cs.2023.02

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Feng J,Zhu D.Biotransformation enables innovations toward green synthesis of steroidal pharmaceuticals.ChemSusChem2022;15:e202102399

[2]	Choudhary M,Dhar MK.Endophytic fungi-mediated biocatalysis and biotransformations paving the way toward green chemistry.Front Bioeng Biotechnol2021;9:664705 PMCID:PMC8242341

[3]	Salter R,Colletti SL.Microbial biotransformation - an important tool for the study of drug metabolism.Xenobiotica2019;49:877-86

[4]	Bianchini LF,Vieira SR.Microbial biotransformation to obtain new antifungals.Front Microbiol2015;6:1433 PMCID:PMC4689855

[5]	Birolli WG,Alvarenga N.Biocatalysis and biotransformation in Brazil: an overview.Biotechnol Adv2015;33:481-510

[6]	Banerjee S,Ur Rahman L.Biotransformation studies using hairy root cultures - a review.Biotechnol Adv2012;30:461-8

[7]	Gkantzou E,Fotiadou R.Trends in the development of innovative nanobiocatalysts and their application in biocatalytic transformations.Biotechnol Adv2021;51:107738

[8]	Pervaiz I,Madni MA,Khaliq FH.Microbial biotransformation: a tool for drug designing.Appl Biochem Microbiol2013;49:437-50

[9]	Borges WDS,Bonato PS,Pupo MT.Endophytic fungi: natural products, enzymes and biotransformation reactions.Curr Org Chem2009;13:1137-1163

[10]	Buttgereit F,Strehl C.Will we ever have better glucocorticoids?.Clin Immunol2018;186:64-6

[11]	Hegazy ME,ElShamy AI.Microbial biotransformation as a tool for drug development based on natural products from mevalonic acid pathway: a review.J Adv Res2015;6:17-33 PMCID:PMC4293675

[12]	Basso A.Industrial applications of immobilized enzymes-a review.Mol Catal2019;479:110607

[13]	Britton J,Weiss GA.Continuous flow biocatalysis.Chem Soc Rev2018;47:5891-918 PMCID:PMC6441135

[14]	Choi JM,Kim HS.Industrial applications of enzyme biocatalysis: current status and future aspects.Biotechnol Adv2015;33:1443-54

[15]	Carvalho CC.Enzymatic and whole cell catalysis: finding new strategies for old processes.Biotechnol Adv2011;29:75-83

[16]	Otles S.Biotransformation in the production of secondary metabolites. Bioactive Natural Products. Elsevier; 2021. pp. 435-57.

[17]	Kebamo S,Geleta B.The role of biotransformation in drug discovery and development.J Drug Metab Toxicol2015;6:1000196

[18]	Liu JH.Biotransformation of bioactive natural products for pharmaceutical lead compounds.COC2010;14:1400-06

[19]	Pratush A,Yang Q.Biotransformation strategies for steroid estrogen and androgen pollution.Appl Microbiol Biotechnol2020;104:2385-409

[20]	Parales RE,Schmid A.Biodegradation, biotransformation, and biocatalysis (b3).Appl Environ Microbiol2002;68:4699-709 PMCID:PMC126401

[21]	Farooq A,Choudhary MI.Biotransformation of (-)-a-pinene by botrytis cinerea.Z Naturforsch C J Biosci2002;57:303-6

[22]	Farooq A,Tahara S.The microbial oxidation of (-)-beta-pinene by botrytis cinerea.Z Naturforsch C J Biosci2002;57:686-90

[23]	Farooq A,Atta-ur-Rahman .Detoxification of terpinolene by plant pathogenic fungus botrytis cinerea.Z Naturforsch C J Biosci2002;57:863-6

[24]	Atta-ur-Rahman Au,Farooq A.Fungal transformation of (1R,2S,5R)-(-)-menthol by cephalosporiumaphidicola.J Nat Prod1998;61:1340-2

[25]	Musharraf SG,Ali RA.Hydroxylation of (+)-menthol by Macrophomina phaseolina.Biocatal Biotransfor2011;29:77-82

[26]	Mohammad MY,Al-Bakain R,Choudhary MI.New monoterpenoid by biotransformation of thymoquinone using Aspergillus niger.Bioorg Chem2018;80:212-5

[27]	Choudhary M,Khan M.Microbial Transformation of Isolongifolen-4-one.HCA2003;86:3450-60

[28]	Choudhary MI,Nawaz SA.Microbial transformation of (-)-isolongifolol and butyrylcholinesterase inhibitory activity of transformed products.Bioorg Med Chem2005;13:1939-44

[29]	Musharraf SG,Khan S.Microbial transformation of 5α-hydroxycaryophylla-4(12), 8(13)-diene with Macrophomina phaseolina.J Mol Catal B-Enzym2010;66:156-60

[30]	Choudhary MI,Khan S.Biotransformation of (–)-caryophyllene oxide by cell suspension culture of catharanthus roseus.Zeitschrift für Naturforschung B2006;61:197-200

[31]	Choudhary MI,Nawaz SA.Microbial transformation and butyrylcholinesterase inhibitory activity of (-)-caryophyllene oxide and its derivatives.J Nat Prod2006;69:1429-34

[32]	Choudhary MI,Siddiqui ZA.Microbial Metabolism Of (+)-Cycloisolongifol-5β-Ol.Zeitschrift für Naturforschung B2006;61:1035-8

[33]	Choudhary MI,Sami A.Microbial transformation of sesquiterpenes, (-)-ambrox, and (+)-sclareolide.HCA2004;87:2685-94

[34]	Nasib A,Hussain S.Biotransformation of (-)-ambrox by cell suspension cultures of Actinidia deliciosa.J Nat Prod2006;69:957-9

[35]	Musharraf SG,Najeeb A,Choudhary MI.Biotransformation of perfumery terpenoids, (-)-ambrox® by a fungal culture Macrophomina phaseolina and a plant cell suspension culture of Peganum harmala.Chem Cent J2012;6:82

[36]	Musharraf SG,Akhter M.Biotransformation of an antimalarial drug, artemether by plant and fungal cell cultures.J Mol Catal B-Enzym2012;82:80-5

[37]	Farooq A.Microbial transformation of sclareolide.J Nat Prod1997;60:1038-40

[38]	Choudhary MI,Atif M,Atta-Ur-Rahman .Microbial transformation of (-)-guaiol and antibacterial activity of its transformed products.J Nat Prod2007;70:849-52

[39]	Choudhary MI,Hussain S.Atta-ur-RahmanStructure elucidation and antibacterial activity of new fungal metabolites of sclareol.Chem Biodivers2006;3:54-61

[40]	Sultan S,Ali SAS. metabolism of an anti-HIV and anti-malarial natural product andrographolide. Available from: https://innovareacademics.in/journals/index.php/ijpps/article/view/2799/9253 [Last accessed on 26 Apr 2023]

[41]	Choudhary MI,Shah SAA. Biotransformation of dehydroabietic acid with microbial cell cultures and α-glucosidase inhibitory activity of resulting metabolites. Available from: https://innovareacademics.in/journals/index.php/ijpps/article/view/2016 [Last accessed on 26 Apr 2023]

[42]	Choudhary MI,Atta-Ur-Rahman .Hydroxylation of the sesterterpene leucosceptrine by the fungus Rhizopus stolonifer.Phytochemistry2006;67:439-43

[43]	Choudhary MI,Khan SN.Microbial transformation of oleanolic acid by Fusarium lini and alpha-glucosidase inhibitory activity of its transformed products.Nat Prod Res2008;22:489-94

[44]	Choudhary M,Ahmed Nawaz S.Microbial transformation of 18beta-glycyrrhetinic acid by Cunninghamella elegans and Fusarium lini, and lipoxygenase inhibitory activity of transformed products.Nat Prod Res2009;23:507-13

[45]	Rahman AU,Asif F,Yaqoob M.Microbial transformations of testosterone. Nat Prod Lett1998;12:255-61

[46]	Al-Aboudi A,Musharraf SG,Atta-ur-Rahman .Microbial transformation of testosterone by Rhizopus stolonifer and Fusarium lini.Nat Prod Res2008;22:1498-509

[47]	Atif M,Sultan S.Solid phase microbial fermentation of anabolic steroid, dihydrotestosterone with ascomycete fungus Fusarium oxysporum.Int J Pharm Pharm Sci2015;7:104-107

[48]	Choudhary MI,Farooq A.Fungal transformations of steroids by cephalosporium aphidicola and trichothecium roseum. Nat Prod Lett2000;14:217-24

[49]	Atif M,Shah SAA.Solid phase microbial reactions of sex hormone, trans-androsterone with filamentous fungi.Int J Pharm Pharm Sci2015;7:385-8

[50]	Choudhary MI,Musharraf SG,Atta-Ur-Rahman .Microbial transformation of dehydroepiandrosterone.Nat Prod Res2003;17:215-20

[51]	Azizuddin,Ali K.Biotransformation of dehydroepiandrosterone by cell suspension culture of codiaeum variegatum.Chem Nat Compd2014;50:669-72

[52]	Choudhary MI,Khan NT.Biotransformation of dehydroepiandrosterone with macrophomina phaseolina and β-glucuronidase inhibitory activity of transformed products.J Enzyme Inhib Med Chem2012;27:348-55

[53]	Choudhary MI,Shaheen F.Microbial transformation of (+)-androsta-1 ,4-diene-3,17-dione by cephalosporium aphidicola.Nat Prod Lett2002;16:377-82

[54]	Musharraf SG,Choudhary MI.Microbial transformation of (+)-adrenosterone.Nat Prod Lett2002;16:345-9

[55]	Choudhary MI,Musharraf SG,Atta-Ur-Rahman .Biotransformation of adrenosterone by filamentous fungus, cunninghamella elegans.Steroids2007;72:923-9

[56]	Choudhary M,Shah A,Atta-Ur-Rahman.Microbial oxidation of anabolic steroids.Nat Prod Res2008;22:1289-96

[57]	Baydoun E,Atia-tul-Wahab .Microbial transformation of nandrolone with cunninghamella echinulata and cunninghamella blakesleeana and evaluation of leishmaniacidal activity of transformed products.Steroids2014;88:95-100

[58]	Choudhary MI,Musharraf SG,Al-Aboudi A.New oxandrolone derivatives by biotransformation using Rhizopus stolonifer.Steroids2009;74:1040-4

[59]	Smith C,Khan MS.Microbial transformation of oxandrolone with macrophomina phaseolina and cunninghamella blakesleeana.Steroids2015;102:39-45

[60]	Siddiqui M,Naveed Shaikh N,Atta-ur-rahman .Biocatalytic transformation of steroidal drugs oxandrolone and ganaxolone, and aromatase inhibitory activity of transformed products.Phytochem Lett2021;44:137-41

[61]	Choudhary MI,Jalil S.Atta-ur-RahmanMicrobial transformation of mesterolone.Chem Biodivers2005;2:392-400

[62]	Ahmad MS,Bibi M.Biotransformation of androgenic steroid mesterolone with cunninghamella blakesleeana and macrophomina phaseolina.Steroids2014;82:53-9

[63]	Ahmad MS,Hussain N.Three new analogues of androgenic drug mesterolone through biotransformation with Cunninghamella blakseleeana.J Mol Catal B-Enzym2016;133:S395-9

[64]	Siddiqui M,Wahab AT.Biotransformation of a potent anabolic steroid, mibolerone, with cunninghamella blakesleeana, C. echinulata, and Macrophomina phaseolina, and biological activity evaluation of its metabolites.PLoS One2017;12:e0171476 PMCID:PMC5325191

[65]	Siddiqui M,Jabeen A.Whole-cell fungal-mediated structural transformation of anabolic drug metenolone acetate into potent anti-inflammatory metabolites.J Adv Res2020;24:69-78 PMCID:PMC7076145

[66]	Hussain Z,Hussain S.Aspergillus niger-mediated biotransformation of methenolone enanthate, and immunomodulatory activity of its transformed products.Steroids2016;112:68-73

[67]	Baydoun E,Mehmood H.Microbial transformation of danazol with Cunninghamella blakesleeana and anti-cancer activity of danazol and its transformed products.Steroids2016;105:121-7

[68]	Khan NT,Noreen S.Biotransformation of dianabol with the filamentous fungi and β-glucuronidase inhibitory activity of resulting metabolites.Steroids2014;85:65-72

[69]	Ahmad MS,Atia-Tul-Wahab .Biotransformation of anabolic compound methasterone with Macrophomina phaseolina, Cunninghamella blakesleeana, and Fusarium lini, and TNF-α inhibitory effect of transformed products.Steroids2017;128:75-84

[70]	Aamer M,Jabeen A.Structural transformation of methasterone with Cunninghamella blakesleeana and Macrophomina phaseolina.RSC Adv2022;12:9494-500

[71]	Atia-Tul-Wahab ,Ibrahim I.Cunninghamella blakesleeana-mediated biotransformation of a contraceptive drug, desogestrel, and anti-MDR-Staphylococcus aureus activity of its metabolites.Bioorg Chem2018;77:152-8

[72]	Choudhary MI,Khan MT.Microbial transformation of 17alpha-ethynyl- and 17alpha-ethylsteroids, and tyrosinase inhibitory activity of transformed products.Steroids2005;70:798-802

[73]	Aziz A,Atia-Tul-Wahab .Microbial transformation of oral contraceptive ethisterone by aspergillus niger and cunninghamella blakesleeana.Steroids2020;154:108467

[74]	Choudhary MI,Siddiqui ZA.Microbial transformation of mestranol by cunninghamella elegans.Chem Pharm Bull2005;53:1011-3

[75]	Zafar S,Yousuf S.New metabolites from fungal biotransformation of an oral contraceptive agent: methyloestrenolone.Steroids2013;78:418-25

[76]	Baydoun E,Iqbal S,Choudhary MI.Biotransformation of drospirenone, a contraceptive drug, with Cunninghamella elegans.Steroids2017;126:30-4

[77]	Baydoun E,Shoaib N.Microbial transformation of contraceptive drug etonogestrel into new metabolites with cunninghamella blakesleeana and cunninghamella echinulata.Steroids2016;115:56-61

[78]	Zafar S,Kayani HA.Biotransformation of oral contraceptive ethynodiol diacetate with microbial and plant cell cultures.Chem Cent J2012;6:109 PMCID:PMC3496622

[79]	Baydoun E,Iqbal MA.Microbial transformation of anti-cancer steroid exemestane and cytotoxicity of its metabolites against cancer cell lines.Chem Cent J2013;7:57 PMCID:PMC3637571

[80]	Baydoun S,Bano S,Choudhary MI.Microbial-catalysed derivatization of anti-cancer drug exemestane and cytotoxicity of resulting metabolites against human breast adenocarcinoma cell line (MCF-7) in vitro.. Steroids2016;115:67-74

[81]	Baydoun S,Bano S,Choudhary MI.Microbial-catalysed derivatization of anti-cancer drug exemestane and cytotoxicity of resulting metabolites against human breast adenocarcinoma cell line (MCF-7) in vitro.Steroids2016;115:67-74

[82]	Hussain Z,Hussain N.Seven new metabolites of drostanolone heptanoate by using Beauveria bassiana, and Macrophomina phaseolina cell suspension cultures.RSC Adv2019;10:451-60 PMCID:PMC9048210

[83]	Javed S,Jabeen A.Fungal mediated biotransformation of melengestrol acetate, and T-cell proliferation inhibitory activity of biotransformed compounds.Bioorg Chem2020;104:104313

[84]	Bano S,Yousuf S.New anti-inflammatory metabolites by microbial transformation of medrysone.PLoS One2016;11:e0153951 PMCID:PMC4841542

[85]	Choudhary MI,Ashraf M. Microbial transformations of hypolipemic E-guggulsterone.J Nat Prod1998;61:428-31

[86]	Choudhary MI,Sami A,Shaheen F.Atta-ur-RahmanFungal metabolites of (E)-guggulsterone and their antibacterial and radical-scavenging activities.Chem Biodivers2005;2:516-24

[87]	Choudhary MI,Samreen .Biotransformation of physalin H and leishmanicidal activity of its transformed products.Chem Pharm Bull (Tokyo)2006;54:927-30