Int J Pharm Pharm Sci, Vol 6, Issue 7, 375-378Original Article

BIOTRANSFORMATION OF DEHYDROABIETIC ACID WITH MICROBIAL CELL CULTURES AND α-GLUCOSIDASE INHIBITORY ACTIVITY OF RESULTING METABOLITES

MUHAMMAD IQBAL CHOUDHARY1, MUHAMMAD ATIF1*, SYED ADNAN ALI SHAH2, 3*, SADIA SULTAN2, 3*, SAIRA ERUM1, SHAMSUN NAHAR KHAN1, ATTA-UR-RAHMAN1

1H. E. J. Research Institute of Chemistry, International Center for Chemical and Biological Sciences, University of Karachi, Karachi 75270, Pakistan, 2Faculty of Pharmacy, Universiti Teknologi MARA (UiTM), Puncak Alam Campus, 42300 Bandar Puncak Alam, Selangor Darul Ehsan, Malaysia, 3Atta-ur-Rahman Institute for Natural Products Discovery (AuRIns), Universiti Teknologi MARA (UiTM), Puncak Alam Campus, 42300 Bandar Puncak Alam, Selangor Darul Ehsan, Malaysia.
Email: atifhamirani@yahoo.com

Received: 31 May 2014 Revised and Accepted: 12 Jul 2014


ABSTRACT

Dehydroabietic acid (DHA, 1), a natural occurring diterpene resin acid, is an abundant resin acid in conifers, representing a natural wood protectant. The aim of this study was to use microbial cell cultures as tools for modification of 1 in order to obtain value-added functional derivatives. A scaled-up biotransformation of 1 by filamentous fungus Cunninghamella elegans, Rhizopus stolonifer, Gibberella fujikuroi, and Cephalosporium aphidicola were conducted for the first time. Three hydroxylated metabolites; 1β-hydroxydehydroabietic acid (2); 15-hydroxy dehydroabietic acid (3); and 16-hydroxy dehydroabietic acid (4). The structure of the hydroxylated metabolites were elucidated by 1-D (1H, 13C) and 2-D NMR (COSY, HMBC, HMQC, NOESY) techniques and MS analyses. Dehydroabietic acid (1) and their transformed products 2-4 exhibited a promising α-Glucosidase inhibitory activity. Compound 1 showed 38 times more active than the standard α-Glucosidase inhibitor, deoxynojirimycin. Compound 1 and its transformed metabolites 2-4 also showed significant antibacterial activities.

Keywords: Microbial transformation, Dehydroabietic acid, Antibacterial activities, α-Glucosidase.

INTRODUCTION

Dehydroabietic acid (Abieta-8,11,13-trien-18-oic acid, 1), a natural occurring diterpenic resin acid, is an abundant resin acid in conifers, representing a natural wood protectant. It is also one of the constituents found in byproducts of the kraft chem. pulping industry. Dehydroabietic acid (DHA, 1) and its derivatives has been found to have properties of enhancing the inhibition activity of anticancer drug in various cells, such as hepatocellular carcinoma cells, cervical carcinoma cells, and breast cancer cells. It has been shown that DHA treatment decreases plasma glucose and insulin levels with plasma triglyceride (TG) and hepatic TG levels. DHA is also a useful food-derived compound for treating obesity-related diseases [1-6].

Microbial transformation has been useful tool for in vitro drug metabolism studies [7-8]. The advantages of using microorganisms such as bacteria and fungi for the production of metabolites are that the cultures are relatively easy to maintain and grow, and that scale-up to produce milligram or gram amounts is readily accomplished. In addition, a variety of metabolites could be obtained by microbial transformations, from which more active metabolites might be found. In recent years, many research works frequently reported to modify the structures of natural products for finding some novel biotransformed reactions, or some new chemical entities with the proper drugability [8-33]. Moreover, microorganisms such as fungi and bacteria can provide better yields of the metabolites when compared with in vivo metabolism studies, producing enough material for toxicological and biological assays. Fungi of the genus Cunninghamella stand out amongst other genera because can catalyze reactions mimicking the mammalian metabolism. Cunninghamella species are capable of metabolizing a wide variety of xenobiotics using both phase I and phase II reactions, oftentimes giving rise to new compounds [8-23]. The microbial-oriented oxidation of terpene under mild conditions appears as an attractive alternative as compared to the traditional chemical methods, have an elevated regio- and enantioselectivity, and do not generate toxic waste products, and the products obtained can be labeled as “natural”source [24-33].

In present work, biotransformation of Dehydroabietic acid (1) by filamentous fungus Cunninghamella elegans TSY 0865, Rhizopus stolonifer ATCC-10404, Gibberella fujikuroi ATCC-10704 and Cephalosporium aphidicola IMI-68689 were carried out for the first time (Scheme 1). Three hydroxylated transformed products were isolated and identified in the biotransformation process of 1. In addition, the α-glucosidase inhibitory activity and antibacterial activities of metabolites 2-4 were evaluated (Table 1 and 2).

MATERIALS AND METHODS

General

Dehydroabietic acid (1) was purchased from sigma-aldrich (USA). Melting points were determined on a Yanaco MP-S3 apparatus. UV spectra were measured on a Shimadzu UV 240 spectrophotometer. JASCO DIP–360 Digital polarimeter was used to measure the optical rotations in chloroform by using 10 cm cell tube. FTIR-8900 Spectrophotometer was used to record IR spectra in CHCl3. The 1H-NMR and 2D NMR spectra were recorded on a Bruker Avance III 500 spectrometer, while 13C-NMR spectra were recorded on Bruker Avance III 500 spectrometer operating at 125 MHz using CDCl3 as solvent. chemical shifts were reported in δ (ppm), relative to SiMe4 as internal standard, and coupling constants (J) were measured in Hz. The HREI MS were measured on Jeol HX 110 mass spectrometer. TLC was performed on Si gel precoated plates (PF254, 20 × 20, 0.25 mm, Merck, Germany). Ceric sulphate in 10% H2SO4 spraying reagent was used for the staining of compounds on TLC. All reagents used were of analytical grades.

Fungi and culture conditions

Microbial cultures of the Cunninghamella elegans TSY 0865 was grown on Potato dextrose agar (PDA) at 25 C and stored at 4 C. Cunninghamella elegans TSY 0865 medium was prepared by adding Glucose (10.0 g), peptone (5.0 g), KH2PO4 (5.0 g), yeast extract (5.0 g), NaCl (5.0 g) and glycerol (10 mL) into distilled water (1 L) and maintained pH at 5.6.

Microbial cultures of the Rhizopus stolonifer ATCC-10404 was grown on Potato dextrose agar (PDA) at 25 C and stored at 4 C. Medium for Rhizopus stolonifer was prepared by mixing Glucose (20.0 g), Peptone (5.0 g), Yeast extract (3.0 g) and KH2PO4 (5.0 g) into distilled water (1 L) and maintained pH at 5.6.

Microbial cultures of the Gibberella fujikuroi ATCC-10704 was grown on Potato dextrose agar (PDA) at 25 C and stored at 4 C. Medium for Gibberella fujikuroi was prepared by mixing Glucose (80.0 g), NH4NO3 (1.0 g), KH2PO4 (5.0 g), MgSO4.7H2O (1.0 g) and Gibberella trace element solution (2.0 mL) into distilled water (1 L) and maintained pH at 5.6.

Microbial cultures of the Cephalosporium aphidicola IMI-68689 was grown on Potato dextrose agar (PDA) at 25 C and stored at 4 C. Medium for Cephalosporium aphidicola was prepared by mixing Glucose (50.0 g), KH2PO4 (1.0 g), MgSO4.7H2O (2.0 g), Glycin (2.0 g), KCl (1.0 g) and Gibberella trace element solution (2.0 mL) into distilled water (1 L) and maintained pH at 5.6.

general stage ii fermentation and extraction procedure

The fungal media were transferred into 250 mL conical flasks (100 mL each) and autoclaved at 120 C. Seed flasks were prepared from three-day old slant and fermentation was allowed for two days on a shaker at 25 C. The remaining flasks were inoculated from seed flasks. After one days, Dehydroabietic acid (1) (1 g) was dissolved in 20 mL of acetone and transferred in each flask and the clear solution was evenly distributed among the 40 flasks, containing 24-h-old stage-II cultures. Fermentation was carried out for 12 days on a rotatory shaker (200 rpm) at 25° C. For TLC analysis, the content of one flask each was harvested every second day. The culture media and mycelium were separated by filtration. The mycelium was washed with CH2Cl2 (1.5 L), and the filtrate was extracted with CH2Cl2 (12 L). The resulting brown gummy extracts (1.48, 1.62, 1.49, and 1.51 g for R. stolonifer, C. elegans, G. fujikuroi and C.aphidicola, respectively) were purified by repeated column chromatography (petroleum ether/EtOAc gradients). From these extracts, following compounds were isolated: 2 (8.1 mg); PE/ EtOAc (81:19), 3 (11.3 mg); PE/ EtOAc (82:18), and 4 (13.8 mg); PE/ EtOAc (85:15).

1β-hydroxy dehydroabietic acid (2):

amorphous material (8.1 mg); [α]25D: +14° (c = 0.24, CHCl3); Rf: 0.5 (Pet. Ether/EtOAc 82:18); EI-MS m/z (rel. int., %): m/z 316 [M+] (24), 302 (59), 218 (21), 170 (14), 154 (67), 86 (32), 70 (61), 43 (100); HREI-MS (mol. formula, calcd value): m/z 316.1528 (C20H28O3, 316.1536); 1H-NMR (CDCl3, 500 MHz) δ: See [24]; 13C-NMR (CDCl3, 125 MHz) δ: See [25].

15-hydroxydehydroabietic acid (3):

white solid (11.3 mg); [α]25D: +31° (c = 0.24, CHCl3); Rf: 0.5 (Pet. Ether/EtOAc 82:18); EI-MS m/z (rel. int., %): m/z 316 [M+] (62), 302 (12), 218 (61), 170 (38), 154 (52), 86 (62), 70 (48), 43 (100); HREI-MS (mol. formula, calcd value): m/z 316.1479 (C20H28O3, 316.1492); 1H-NMR (CDCl3, 500 MHz) δ: See [25], 13C-NMR (CDCl3, 125 MHz) δ: See [26].

16-hydroxydehydroabietic acid (4):

amorphous material (13.8 mg); [α]25D: +68° (c = 0.24, MeOH); Rf: 0.5 (Pet. Ether/EtOAc 82:18); EI-MS m/z (rel. int., %): m/z 316 [M+] (62), 302 (19), 218 (51), 170 (19), 154 (37), 86 (52), 70 (100); HREI-MS (mol. formula, calcd value): m/z 316.1528 (C20H28O3, 316.1536); 1H-NMR (CDCl3, 500 MHz) δ: See [26]; 13C-NMR (CDCl3, 125 MHz) δ: See [27].

α-Glucosidase enzyme inhibition assay

α-Glucosidase (E.C.3.2.1.20) enzyme inhibition assay has been performed according to the slightly modified method of Matsui et al. α-Glucosidase (E.C.3.2.1.20) from Saccharomyces sp. Was purchased from Wako Pure Chemical Industries Ltd. (Wako 076-02841). The inhibition was measured spectrophotometrically at pH 6.9 and at 37° C using 0.7mM p-nitrophenyl α-D glucopyranoside (PNP-G) as a substrate and 250 m units/mL enzyme in 50mM sodium phosphate buffer containing 100mM NaCl. 1- Deoxynojirimycin (0.425mM) and acarbose (0.78mM) were used as positive controls. The increment in absorption at 400nm due to the hydrolysis of PNP-G by α-glucosidase was monitored continuously with the spectrophotometer (Molecular Devices, CA, USA) [15].

Estimation of IC50 values

The concentrations of the test compounds, which inhibited the hydrolysis of PNP-G by α-glucosidase by 50% (IC50), were determined by monitoring the effect of increasing the concentration of these compounds on the inhibition values. The IC50 values were then calculated by using EZ-Fit enzyme kinetics program (Perrella Scientific Inc., Amherst, MA, USA) [15].

Zone of inhibition assay

Test sample (3 mg) was taken and dissolved in 3 mL of DMSO (1 mg/mL). Molten nutrient agar (45 mL) was poured on the sterile petri plates and was allowed to solidify. Bacterial lawn was made on these nutrient agar plates by dispensing 7 mL sterile soft agar containing 100 mL of cultures of the test organisms. Wells were dugged with the help of 6 mm sterile metallic borer at appropriate distances, then 100 µL of sample was poured into each well and the plates were incubated at 37º C for 24 hours. The results in terms of zones of inhibition were recorded. Imiperium was used as a positive control, while DMSO was used as a negative control. All the chemicals used were of analytical grades (Sigma, USA) [20].

RESULTS AND DISCUSSION

Fermentation of dehydroabietic acid (1) for 12 days with Cunninghamella elegans TSY 0865, Rhizopus stolonifer ATCC-10404, Gibberella fujikuroi ATCC-10704 and Cephalosporium aphidicola IMI-68689 resulted three regio- and stereoselective hyroxyl products, 2-4 (Scheme 1). The HREI MS of metabolite 2 exhibited the molecular ion (M+) at m/z 316.1536, corresponding to the formula C20H28O3, which indicated that a new oxygen functionality was introduced during fermentation period. Metabolite 2 was found to be 1β-hydroxy derivative of 1, based on 1H and 13C NMR signals at δH 3.92/δC 76.8. Hydroxylation at C-1 position was further supported by COSY and HMBC interactions. The β-orientation of C-1 OH group was deduced on the basis of NOESY correlations between H-1 (δ 3.92) and H-5 (δ 2.20). The structure of known metabolite 2 (1β-hydroxydehydroabietic acid) was further deduced by comparison with the reported data (Gouiric et al., 2004). Metabolite 2 was previously obtained by the fermentation of 1 with Fusarium oxysporum, F. moniliforme and Aspergillus niger [25].

Metabolite 3 was obtained as a white powder (Scheme 1). Its molecular formula was determined as C20H28O3 according to the HREI MS data (m/z 316.1479: calcd for C20H28O3, 316.1492), indicated that one oxygen had been incorporated into the molecule, as compared to 1. Metabolite 3 was found to be 15-hydroxy derivative of 1, based on 13C NMR signals at δ 72.3. The position of the newly introduced hydroxyl at C-15 position was inferred from the HMBC coupling of C-16 and C-17 methyl protons with C-15 (δ 72.3). The structure of known metabolite 3 (15-hydroxydehydroabietic acid) was further deduced by comparison with the reported data [26].

Metabolite 4 was obtained as an amorphous material (Scheme 1). The HREI MS of metabolite 3 exhibited the molecular ion (M+) at m/z 316.1528, corresponding to the formula C20H28O3, indicating an introduction of a new oxygen in the molecule, probably as OH during fermentation period. Compound 4 was found to be C-16 hydroxy derivative of 1, based on NMR signals at δH 3.64/δC 68.7 and further confirm by comparison with the reported data [27]. The position of the newly introduced hydroxyl at C-16 position was inferred from the HMBC coupling of H-15 and C-17 methyl protons with C-16 (δ 68.7).

Dehydroabietic acid (1) and its transformed products 2-4 were subjected to α-glucosidase Inhibitory Activity. According to the results, the dehydroabietic acid (1) showed a promising inhibitory effect, which is 38 times more than the standard deoxynojirimycin. The activity of 2 was also found to be much better than the transformed products 2-4 (Table 1). This may be due to binding of substrate 2 with the enzyme binding site through hydrophobic interactions. Introduction of hydroxyl groups through transformation such as in metabolites 2-4, increase the hydrophilicity, which may cause formation of the hydrogen bonding with surrounding buffer system, thus the hydrophobic interactions with the binding site is distorted, thus a decrease in the overall α-glucosidase inhibitory activities was observed. Among the transformed products, compound 4 showing more inhibitory activity than the compound 2 probably due to hydroxylation at isopropyl side chain causing less steric hindrance, which help in the binding with the enzyme.

Table 1: α-Glucosidase Inhibitory Activity of Compounds 1-4

Compound IC50 (μM ± S.E.M)
1 11±01
2 130±15
3 99±43
4 81±90
Acarbose 780±20
Deoxynojirimycin 425.6±14

Dehydroabietic acid (1) and its transformed products 2-4 were tested for their antibacterial activity against two Gram-positive bacteria including Bacillus subtilis and Staphylococcus aureus, in addition to four Gram-negative bacteria (Escherichia coli, Shigella flexneri, Pseudomonas aeruginosa and Salmonella typhi) using previously reported zone of inhibition test method [19]. All metabolites 2-4 exhibited antibacterial activity but compound 4 demonstrated significant antibacterial activities against various strains maybe due to the presence of OH group at C-16 position (Table 2).

Scheme 1: Fermentation of dehydroabietic acid (1) by Cunninghamella elegans, Rhizopus stolonifer, Gibberella fujikuroi, and Cephalosporium aphidicola.

Table 2: Antibacterial Activities of Compounds 1-4

Compound Escherichiacoli Bacillussubtilis Shigella flexnari Staphylococcusaureus Pseudomonasaeruginosa Salmonellatyphi
1 15 17 15 15 Inactive 17
2 Inactive 11 11 Inactive 14 Inactive
3 Inactive 10 10 Inactive 12 Inactive
4 19 20 12 Inactive 16 20
Imipenem 30 33 27 33 24 25

CONCLUSIONS

In summary, the present research on the biotransformation of dehydroabietic acid (1) by Cunninghamella elegans, Rhizopus stolonifer, Gibberella fujikuroi, and Cephalosporium aphidicola have been conducted for the first time. Fermenation of 1 for 12 days with fungal strains yielded three hydroxylated transformed products 2-4. Structures of all new metabolites were elucidated by using spectroscopic techniques. All compounds 1-4 were then subjected to α-glucosidase Inhibitory Activity and antibacterial activities. Compound 1 showed promising inhibitory effect against α-glucosidase, which is 38 times more than the standard deoxynojirimycin. All metabolites 2-4 exhibited antibacterial activity but compound 4 demonstrated significant antibacterial activities against various strains maybe due to the presence of OH group at C-16 position.

CONFLICT OF INTERESTS

Declared None

ACKNOWLEDGMENTS

Syed Adnan Ali Shah would like to acknowledge the Ministry of Higher Education (MOHE) for financial support under the Fundamental Research Grant Scheme (FRGS) with reference numbers 600-RMI/FRGS 5/3 (12/2012), and also Universiti Teknologi MARA (UiTM) for the financial support under the Principal Investigator Support Initiative (PSI) Grant Scheme with reference number UiTM 600-RMI/DANA 5/3/PSI (251/2013) and Cumulative Impact Factor Initiative (CIFI) Grant Scheme with reference number UiTM 600-RMI/DANA 5/3/CIFI (117/2013).

REFERENCES

  1. Pertino MW, Verdugo V, Theoduloz C, Schmeda-Hirschmann G. Synthesis and antiproliferative activity of some novel triazole derivatives from dehydroabietic acid. J Molecules (Basel, Switzerland) 2014;19(2):2523-35.
  2. Tamaki H. Antiulcer activity of dehydroabietic acid derivatives. J Chem Pharm Bull 1985;33:1472-87.
  3. Sepúlveda B, Astudillo L, Rodríguez JA, Yáñez T, Theoduloz C, Schmeda-Hirschmann G. Gastroprotective and cytotoxic effect of dehydroabietic acid derivatives. J of the Italian Pharmacological Society Res 2005;52(5):429-37.
  4. Gigante B, Silva AM, Marcelo-Curto MJ, Feio SS, Roseiro J, Reis LV. Structural effects on the bioactivity of dehydroabietic acid derivatives. J Planta Med 2002;68(8):680-4.
  5. Tanaka R, Tokuda H, Ezaki Y. Cancer chemopreventive activity of "rosin" constituents of Pinus spez. and their derivatives in two-stage mouse skin carcinogenesis test. Int J Phytomedicine of phytotherapy 2008;15(11):985-92.
  6. Huang X-C, Wang M, Pan Y-M, Yao G-Y, Wang H-S, Tian X-Y, et al. Synthesis and antitumor activities of novel thiourea α-aminophosphonates from dehydroabietic acid. Eur J Med Chem 2013;69:508-20.
  7. Bhatti HN, Khera RA. Biological transformations of steroidal compounds:a review. J Steroids 2012;77(12):1267-90.
  8. Shah SAA, Tan HL, Sultan S, Faridz MABM, Shah MABM, Nurfazilah S, et al. Microbial-catalyzed biotransformation of multifunctional triterpenoids derived from phytonutrients. Int J of Molecular Sci 2014;15(7):12027-60.
  9. Shah SAA, Sultan S, Hassan NB, Muhammad FKB, Faridz MABM, Hussain FBM, et al. Biotransformation of 17α-ethynyl substituted steroidal drugs with microbial and plant cell cultures:a review. J Steroids 2013;78(14):1312-24.
  10. Shah SAA, Sultan S, Zaimi M. Biotransformation of tissue-specific hormone tibolone with fungal culture Trichothecium roseum. J of Molecular Structure 2013;1042:118-22.
  11. Shah SAA, Sultan S, Adnan HS. A whole-cell biocatalysis application of steroidal drugs. Orient J Chem 2013;29(2):389-403.
  12. Sultan S, Ghani NA, Shah SAA, Ismail NH, Noor MZ, Naz H, et al. Microbial transformation of anthraquinones-Biosci Biotechnol Res Asia. J Bioorg Med Chem 2013;10(2):577-82.
  13. Azam SS, Shah SAA. Reaz Uddin, Zaheer-ul-Haq. Molecular docking studies of potent inhibitors of tyrosinase and α-glucosidase. J Bioorg Med Chem Res 2012;21:1677-83.
  14. Shah SAA, Sultan S, Adnan HS, J. Solid Phase Microbial Transformation of Cortexolone and Prolyl endopeptidase Inhibitory Activity of the Transformed Products. Int J Pharm Sci Suppl 1. 2011;3:1-6.
  15. Choudhary MI, Shah SAA, Atta ur R, Khan S-N, Khan MTH. Alpha-glucosidase and tyrosinase inhibitors from fungal hydroxylation of tibolone and hydroxytibolones. J Steroids 2010;75(12):956-66.
  16. Choudhary SAA, I. M. Atta-ur-Rahman. Microbial Transformation of Anabolic Steriods. J Nat Prod Res 2008;22:1289-96.
  17. Choudhary MI, Batool I, Shah SAA, Khan SN, Atta-ur-Rahman. Microbial Hydroxylation of oleonilic acid. J Nat Prod Res 2008;22:489-94.
  18. Choudhary MI, Basha FZ, Abbas G, Khan SN, Shah SAA. Atta-ur-Rahman, Science at the interface of chemistry and biology:Discoveries of α-glucosidase inhibitors and antiglycation agents. J Pure Appl Chem 2007;79:2263-7.
  19. Choudhary MI, Yousuf S, Samreen, Shah SAA, Ahmed S, Atta ur R. Biotransformation of physalin H and leishmanicidal activity of its transformed products. J Chem Pharm Bull (Tokyo) 2006;54(7):927-30.
  20. Choudhary MI, Shah SAA, Sami A, Ajaz A, Shaheen F, Atta ur R. Fungal metabolites of (E)-guggulsterone and their antibacterial and radical-scavenging activities. J Chem Biodivers 2005;2(4):516-24.
  21. Choudhary MI, Batool I, Shah SAA, Nawaz SA, Atta ur R. Microbial hydroxylation of pregnenolone derivatives. J Chem Pharm Bull (Tokyo) 2005;53(11):1455-9.
  22. Sultan S, Choudhary MI, Khan SN, Fatima U, Atif M, Ali RA, Eur J Med Chem 2013;62:764-70.
  23. Choudhary MI, Shah SAA, Musharraf SG, Shaheen F, Atta Ur R. Microbial transformation of dehydroepiandrosterone. J Natural product Res 2003;17(3):215-20.
  24. Parshikov IA, Netrusov AI, Sutherland JB. Microbial transformation of antimalarial terpenoids. J Biotechnology Adv 2012;30(6):1516-23.
  25. Gouiric SC, Feresin GE, Tapia AA, Rossomando PC, Schmeda-Hirschmann G, Bustos DA. 1,7-Dihydroxydehydroabietic acid, a new biotransformation product of dehydroabietic acid by Aspergillus niger. World J of Microbiology Biotechnology 2004;20:281-4.
  26. Janocha S, Zapp J, Hutter M, Kleser M, Bohlmann J, Bernhardt R. Resin acid conversion with CYP105A1:an enzyme with potential for the production of pharmaceutically relevant diterpenoids. European J of Chemical Biology 2013;14(4):467-73.
  27. Haekkinen ST, Lackman P, Nygren H, Oksman-Caldentey K, Maaheimo H, Rischer H. Differential patterns of dehydroabietic acid biotransformation by Nicotiana tabacum and Catharanthus roseus cells. J Biotechnol 2012;157:287-94.
  28. Choudhary MI, Sultan S, Jalil S, Anjum S, Rahman AA, Fun H-K, et al. Microbial transformation of mesterolone. J Chem Biodivers 2005;2(3):392-400.
  29. Choudhary MI, Sultan S, Yaqoob M, Musharraf SG, Yasin A, Shaheen F, et al. Microbial transformation of cortisol and prolyl endopeptidase inhibitory activity of its transformed products. J Natural product Res 2003;17(6):389-95.
  30. Casañola-Martín GM, Marrero-Ponce Y, Khan MTH, Ather A, Sultan S, Torrens F, et al. TOMOCOMD-CARDD descriptors-based virtual screening of tyrosinase inhibitors:evaluation of different classification model combinations using bond-based linear indices. J Bioorg Med Chem 2007;15(3):1483-503.
  31. Choudhary MI, Sultan S, Khan MTH, Rahman A-U. Microbial transformation of 17alpha-ethynyl-and 17alpha-ethylsteroids, and tyrosinase inhibitory activity of transformed products. J Steroids 2005;70(12):798-802.
  32. Choudhary MI, Sultan S, Khan MTH, Yasin A, Shaheen F, Atta ur R. Biotransformation of (+)-androst-4-ene-3,17-dione. J Natural Product Res 2004;18(6):529-35.
  33. Musharraf SG, Atta Ur R, Choudhary MI, Sultan S. Microbial transformation of (+)-adrenosterone. J Natural Product Letters 2002;16(5):345-9.