Enzymes in Organic Media

Enzymes in Organic Media Tahir Rana University of Ottawa September 25th 2008 1

Outline • Structure and Function • Applications of Enzymes • Limitations of Enzymes in Aqueous Media • Concerns • Applications of Enzymes in Organic Media • Total Synthesis of Fredericamycin A 2

Structure And Function What are Enzymes ? • Enzymes are proteins • Enzymes catalyze reactions 3

Structure And Function Enzyme Structure • Primary Structure – order of amino acids • Secondary Structure - α-helix, β-sheet • Tertiary Structure - arrangement in 3D • Quaternary Structure- interaction of subunits 4 Sakuraba, H. et al. J. Biol. Chem. 2003, 361, 278, 10799-10806.

Structure And Function Catalytic Scheme 5

Structure And Function Factors Involved in Enzymatic Catalysis • Increase in local concentration • Positioning and enhancement of active site functional groups • Specificity • Introduction of strain into substrate 6

Applications of Enzymes Examples: Asymmetric Aldol DERA – Deoxyribose Aldolase 7 Wong, C,H.; Gilsen, H. J. Am. Chem Soc. 1994, 164, 8422-8423. Wong, C.H. Liu, J. J. Angewantde Chemie. 2001, 114, 1462-1465.

Applications of Enzymes Industrial Examples 8 Anderson, B. et al. J. Am. Chem. Soc. 1995, 117, 12358-12359. Liese, A.; Seelbach, K.; Wandrey, C. Industrial Biotransformations. Wiley-VCH, 2005, 117-121.

Applications of Enzymes Industrial Examples 9 Ricks, E.; Estrada-Valdes, M; Iacobucci, G. Biotech. Prog. 1992. 8, 197-203. Liese, A.; Seelbach, K.; Wandrey, C. Industrial Biotransformations, Wiley-VCH. 2005.

Applications of Enzymes Amide Hydrolysis 10

Limitations of Aqueous Enzymology • Solubility of non-polar substrates • Polymerization of phenols 11 Bruno, F.; Ayyagari, S.; Akkara, J. Trends in Biotechnology. 1999, 17, 67-73. Reihmann, M.; Ritter, H. Syn. Of Pol. Using Peroxidases. Adv. Poly. Sci. Springer-Verlag. 2006, 194, 1-49.

Limitations Thermal Inactivation in Aqueous Media • Irreversible: • Molecular Aggregation • Deamidation • Reversible: • Changes in higher order structure 12 Klibanov, A.; Ahern, T. Methods of Biochemical Analysis, 1988, 33, 91-128.

Limitations Domination of Hydrolysis • Water is in excess • Cannot use other nucleophiles 13

Overcoming Limitations The Solution – Organic Solvents • Increased solubility of non-polar substrates 14 Bruno, F.; Ayyagari, S.; Akkara, J. Trends in Biotechnology. 1999, 17, 67-73. Reihmann, M.; Ritter, H. Syn. Of Pol. Using Peroxidases. Adv. Poly. Sci. Springer-Verlag. 2006, 194, 1-49.

Overcoming Limitations Suppression of Thermal Inactivation in Organic Sol. % Activity of Lipase at 100 °C 15 Klibanov, A.; Zaks, A. Science. 1984, 224, 1249-1251.

Overcoming Limitations Opportunity for Synthesis 16

Overcoming Limitations Recap - Advantages of Organic Solvents • Increased solubility of non-polar substrates • Suppression of Thermal Inactivation • Opportunity for synthesis 17

Outline • Structure and Function • Applications of Enzymes • Limitations of Aqueous Enzymology • Concerns Regarding Enzymes in Organic Solvents • Applications of Enzymes in Organic Media • Total Synthesis of Fredericamycin A 18

Concerns • Structural Integrity • Mechanistic Integrity • Diminished Activity 19

Concerns Addressed % Alpha Helix Content of Subtilisin Structural Integrity 20 Klibanov, A.; Griebenow, K. J. Am. Chem. Soc. 1996, 118, 11965-119700.

Heavy lines = MeCN Light lines = water Concerns Addressed Structure of Subtilisin in Water and Acetonitrile Ca Backbone Trace Active Site (Asp-32,His-64,Ser-221) 21 Klibanov, A. et al. Proc. Nat. Acad. Sciences. 1993, 90, 8653-8657.

Concerns Addressed Mechanism of Transesterification 22 Chaterjee, S.; Russell, A. Enzyme Microb. Technol. 1993, 15, 1022-1029.

Concerns Addressed Mechanism of Transesterification 23 Chaterjee, S.; Russell, A. Enzyme Microb. Technol. 1993, 15, 1022-1029.

Concerns Addressed Mechanistic Integrity Transesterification in Organic Solvents Ester Hydrolysis in Water Ping Pong Mechanism Conclusion: Mechanism is the same • Chaterjee, S.; Russell, A. Enzyme Microb. Technol. 1993, 15, 1022-1029. • Klibanov, A. Trends Biochem. Sci. 1989, 14, 141-144. 24

Concerns Addressed Diminished Activity • Enzymes have reduced activity in dry organic solvents Due to lack of: • a) conformational mobility • b) transition state stabilization • c) entropy 25 Klibanov, A. Trends In Biotech. 1997. 15, 97-101.

Concerns Addressed Effect of Water on Activity Enzyme Activity as a Function of Water Content • Activity can be recovered 26 Klibanov, A. J. Biol. Chem. 1987. 263, 8017-8021.

Concerns Addressed • Structurally intact • Act by the same mechanism • Activity can be recovered 27

Applications in Org. Media Applications Problem: Max Conversion = 50 % 28 • Wong, C-H.; Koeller, K. Nature. 2001. 409, 232-241 • Klibanov, A.; Kirchner, G.; Scollar, P. J. Am. Chem. Soc. 1985. 107, 2072-2076.

Resolution: Meso Diols Applications in Org. Media 29 Kim, M.J.; Lee, S. Synlett. 1993. 767-768.

Applications in Org. Media 60 % Overall Yield 30 Kim, M.J.; Lee, S. Synlett. 1993. 767-768.

Applications in Org. Media Applications: Desymmetrization • Loss of one or more symmetry elements • Potential for 100 % conversion 31 Gotor, V. et al. Organic Letters. 2007. 9, 4203-4206.

Applications in Org. Media Applications: Total Synthesis of Epoxyquinols A and B

Applications in Org. Media Retrosynthesis Mehta, G.; Islam, K. Tett. Lett. 2004. 45, 3611-3615.

Applications in Org. Media Desymmetrization Step Mehta, G.; Islam, K. Tett. Lett. 2004. 45, 3611-3615.

Outline • Structure and Function • Applications of Enzymes • Limitations of Aqueous Enzymology • Concerns • Applications of Enzymes in Organic Media • Total Synthesis of Fredericamycin A 35

Total Synthesis of Fredericamycin A • Isolated from Streptomyceus griseus • Antitumor activity • 7 Total Syntheses; 5 Racemic, 2 Asymmetric 36

Total Synthesis of Fredericamycin A Retrosynthesis of 1st Asymmetric Synthesis 37 Kita. Y. et al. J. Am. Chem. Soc. 2001. 123, 3214-3222.

Total Synthesis of Fredericamycin A Installation of Spiro Center F E D Fredericamycin A 33 Steps 0.075 % Overall Yield 38 Kita. Y. et al. J. Am. Chem. Soc. 2001. 123, 3214-3222.

Total Synthesis of Fredericamycin A Retrosynthesis of 2nd Asymmetric Synthesis A B C F E D 39 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Synthesis of DEF Ring System 40 Clive, D. J. of Heterocyclic Chemistry. 1987, 9, 804-807.

Total Synthesis of Fredericamycin A Synthesis of DEF Ring System 41 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Synthesis of DEF Ring System • Difficult separation of acyl hydrazone • 4.5 % overall yield (from pyridone) • Approach abandoned 42 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Synthesis of DEF Ring System- 2 R=CO2Me R=CO2Me 43 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Solution ? • Use the synthetic ability of enzymes in organic solvents 44

Total Synthesis of Fredericamycin A Synthesis of DEF Ring System - 2 R=CO2Me 45 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Total Synthesis – Fredericamycin A • 30 % Yield (from pyridone) 46 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Total Synthesis – Fredericamycin A A B C F E D 47 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Total Synthesis – Fredericamycin A 28 Linear Steps 0.75 % Overall Yield 48 Kita, Y. et al. European J. of Chem. 2005. 11, 6286-6297.

Total Synthesis of Fredericamycin A Comparison of Syntheses • Lewis Acid: 4 steps to establish chirality at spiro center • Enzymatic: 1 step to establish chirality at spiro center • Enzymatic: 28 yield steps, 0.75 % yield, Lewis Acid: 33 steps, 0.075 % 49

Summary • Enzymes are valuable tools for organic synthesis • Enzymes can be used in organic solvents • There are clear advantages to using enzymes in organic media • Application to the total synthesis of Fredericamycin A 50

Enzymes in Organic Media

Enzymes in Organic Media

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