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Highly Stereoselective Biocatalytic Synthesis of Key Cyclopropane Intermediate to Ticagrelor Kari E. Hernandez, Hans Renata, Russell D. Lewis, S. B. Jennifer Kan, Chen Zhang, Jared Forte, David Rozzell, John A. McIntosh, and Frances H. Arnold ACS Catal., Just Accepted Manuscript • DOI: 10.1021/acscatal.6b02550 • Publication Date (Web): 17 Oct 2016 Downloaded from http://pubs.acs.org on October 17, 2016

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Highly Stereoselective Biocatalytic Synthesis of Key

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Cyclopropane Intermediate to Ticagrelor

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AUTHOR NAMES

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Kari E. Hernandez†, Hans Renata†,§, Russell D. Lewis‡, S. B. Jennifer Kan†, Chen Zhang¶, Jared

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Forte¶, David Rozzell¶, John A. McIntosh†,♯, and Frances H. Arnold†,‡,*

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AUTHOR ADDRESSES

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†

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California Institute of Technology, Pasadena, CA, 91125, United States

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§

Division of Chemistry and Chemical Engineering and ‡Biology and Biological Engineering,

Current address: Department of Chemistry, Scripps Research Institute, Jupiter, FL, 33458,

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United States

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¶

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♯

Provivi, Inc., Santa Monica, CA, 90404, United States Current address: Merck, Kenilworth, NJ, 07033, United States

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KEYWORDS

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biocatalysis, directed evolution, ticagrelor, cyclopropanation, Bacillus subtilis, truncated globin

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ABSTRACT

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Extending the scope of biocatalysis to important non-natural reactions such as olefin

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cyclopropanation will open new opportunities for replacing multi-step chemical syntheses of

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pharmaceutical intermediates with efficient, clean, and highly selective enzyme-catalyzed

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processes. In this work, we engineered the truncated globin of Bacillus subtilis for the synthesis

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of a cyclopropane precursor to the antithrombotic agent ticagrelor. The engineered enzyme

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catalyzes the cyclopropanation of 3,4-difluorostyrene with ethyl diazoacetate on a preparative

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scale to give ethyl-(1R, 2R)-2-(3,4-difluorophenyl)-cyclopropanecarboxylate in 79% yield, with

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very high diastereoselectivity (>99% dr) and enantioselectivity (98% ee), enabling a single-step

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biocatalytic route to this pharmaceutical intermediate.

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TEXT Ticagrelor (1) is a P2Y12 antagonist developed by AstraZeneca under the trade name

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Brilinta® (Figure 1). It was approved by the FDA in 2011 for the prevention of platelet

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aggregation after the occurrence of a thrombotic event.1 Sales in 2015 were $619 million and are

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projected to go as high as $3.5 billion by 2023.2-3 Most of the patented syntheses of ticagrelor

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use a key chiral cyclopropane intermediate, (1R,2S)-2-(3,4-difluorophenyl)cyclopropan-1-amine

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(2). The various methods reported for the preparation of this building block are lengthy,

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requiring resolutions, chiral auxiliaries or expensive catalysts to obtain the desired enantiomer.4-

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pharmaceutical production ‘greener’.19-20 A notable example of success in the development of

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biocatalytic alternatives can be found in Merck’s production of sitagliptin, used to treat Type 2

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diabetes. Directed evolution was used to engineer a transaminase to synthesize the drug under

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industrial process conditions; the result was a biocatalytic process with 10-13% higher product

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yield, a 19% reduction in overall waste, and elimination of all heavy metals.21 Similarly,

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biocatalysis can potentially offer very high selectivity and environmentally friendly process

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conditions for the synthesis of ticagrelor. Turner and coworkers recently examined three

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complementary biocatalytic routes for the preparation of cyclopropylamine 2.22 They

Recently, there has been a push to use biocatalysts in order to decrease toxic wastes and make

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demonstrated that a ketoreductase could convert 1-(3,4-difluorophenyl)-3-nitropropan-1-one to

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the corresponding enantiopure alcohol, a building block that could lead to cyclopropylamine 2 in

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two to three steps; alternatively, a lipase or amidase could be used for kinetic resolution of a

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racemic mixture of cyclopropyl ester or amide to yield chiral precursors suitable for the

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preparation of 2.

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Recent reports from our laboratory23-24 and others25-26 have shown that heme proteins can

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catalyze the cyclopropanation of various olefins using diazo compounds. Cyclopropyl motifs are

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present in many bioactive and synthetic compounds and serve as versatile intermediates in

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organic synthesis.27-28 The proteins reported to catalyze olefin cyclopropanation have proven to

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be amenable to directed evolution for increased activity and to obtain the desired product with

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high diastereo- and enantioselectivity in a single step: for example, Wang et al. engineered a

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cytochrome P450 to produce the chiral cyclopropane core of levomilnacipran.24

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Here we report an enantioselective synthesis of the chiral cyclopropane core of ticagrelor

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(Figure 1C) using a whole-cell biocatalyst expressing an engineered heme protein derived from

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Bacillus subtilis group II truncated hemoglobin (UniProt ID: O31607).29 This engineered enzyme

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catalyzes the cyclopropanation of commercially available 3,4-difluorostyrene (DFS, 3) using

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ethyl diazoacetate (EDA, 4) to provide one-step access to ethyl-(1R,2R)-2-(3,4-difluorophenyl)-

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cyclopropanecarboxylate (R,R)-5, an ester precursor of the ticagrelor cyclopropylamine 2, with

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excellent selectivity for the desired stereoisomer.

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We began by screening various heme proteins for their ability to catalyze the reaction of

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DFS (3) with EDA (4) to produce the ticagrelor cyclopropyl ester (R,R)-5. Most of the proteins

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tested, such as the H64V V68A variant of sperm whale myoglobin,25 gave primarily the opposite

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enantiomer of the desired precursor. Three proteins gave an enantio-enriched product with the

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desired (R,R)-configuration: B. subtilis group II truncated globin, Hydrogenobacter thermophilus

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cytochrome c M59A Q62A, and Bacillus megaterium P450-BM3 T268A C400H, which gave

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product in 34, 44, and 8 % ee, respectively. Mutagenesis was performed on all three proteins, but

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substantial improvement in enantioselectivity was only observed with variants of the B. subtilis

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group II truncated globin. The directed evolution strategy we used to optimize the performance

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of this protein is outlined below.

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B. subtilis group II truncated globin is a small (132 residues, 15 kDa) monomeric protein

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with very high oxygen affinity and a published crystal structure (PDB ID: 1UX8).29 We

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hypothesized that iron-carbenoid formation occurred in the distal region of the heme and that

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mutation of amino acid residues in this nascent “active site” could improve its catalytic

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performance. Bordeaux et al. showed that mutations at H64 and V68 in sperm whale myoglobin

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could tune the stereoselectivity of the cyclopropanation reaction between ethyl diazoacetate and

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styrene.25 We chose the analogous residues in B. subtilis truncated globin (T45 and Q49, based

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on a sequence alignment, see Supplemental Information) and targeted those two sites for

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mutagenesis (Figure 2). The two residues were mutated simultaneously to one of three residues

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(leucine, phenylalanine, and alanine) in an attempt to find variants that would improve the yield

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and enantioselectivity of the reaction. The T45A Q49A double mutant stood out as highly

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selective, yielding the desired product in 95% ee with a yield of 57%. Modeling with a Dunbrack

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rotamer library30 suggests that the amount of space in the nascent active site is increased when

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the polar and larger threonine and glutamine are mutated to smaller, non-polar alanine.

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Truncated globins natively bind oxygen and do not have an active site for catalysis; we

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attribute the observed improvement in selectivity to the formation of a binding pocket on the

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distal side of the heme, which presumably binds the substrates in an orientation that favors

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formation of the desired product. To further improve enantioselectivity, site-saturation

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mutagenesis was performed at position A45, and the distal heme ligand Y25. While mutations at

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A45 failed to improve enantioselectivity, screening of the Y25 library led to the discovery of

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variant Y25L T45A Q49A, which maintained the yield of the parent protein while affording

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>99% dr and 97% ee at 20 mM DFS and 40 mM EDA.

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To further increase product yield, the Y25L T45A Q49A variant was expressed in two E.

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coli BL21 derivative cell lines C41(DE3) and C43(DE3), which have been optimized to

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overexpress mildly toxic proteins.31 Both C41(DE3) and C43(DE3) cells expressing the Y25L

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T45A Q49A variant showed increases in enantio- and diastereoselectivity through improved

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expression of the recombinant protein. The engineered protein now effectively outcompetes the

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small amount of background reaction from the cells (which produces racemic product).32 The

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C43(DE3) line displayed the highest diastereo- and enantioselectivity (>99% dr and ee) at 20

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mM DFS/40 mM EDA and was selected for use in preparative-scale reactions.

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Preparative scale (0.4 mmol, 20 mL) reactions were performed anaerobically23-24 using

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whole-cell catalyst (OD600=80) and 20 mM DFS/40 mM EDA (Figure 3). Initially these

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reactions were done with simultaneous addition of the bacterial catalyst and reagents, which gave

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high selectivity for the desired product, but only ~50% yield. After testing a range of reaction

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conditions, we found that slow addition of the whole-cell catalyst and EDA (4) solutions to DFS

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(3) over the course of 3 hours gave the ticagrelor cyclopropyl ester (R,R)-5 as virtually a single

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isomer (>99% dr, 98% ee) in 79% yield (see Supporting Information). It is likely that slow

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addition slows down the formation of EDA dimer and reduces catalyst inactivation by carbene

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transfer to the protein (heme cofactor and nucleophilic side chains) rather than the DFS, an

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inactivation mechanism we recently analyzed in detail in another cyclopropanation enzyme.33

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This work has generated an efficient, stereoselective, and potentially low-cost bacterial

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biocatalyst for producing the cyclopropane precursor to the antithrombotic agent ticagrelor. The

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ester product of the biocatalytic reaction (R,R)-5, can be converted easily to the amine ticagrelor

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precursor 2 via ammonolysis followed by Hofmann rearrangement16 of the corresponding amide

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or a Curtius rearrangement9 on the corresponding acyl azide. This work has also demonstrated

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how directed evolution can rapidly optimize a newly discovered enzyme activity, olefin

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cyclopropanation, to achieve desired product selectivity and yield. With careful process

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optimization, processes based on biological catalysts such as reported here can continue to

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replace far less environmentally friendly methods for producing pharmaceutical intermediates.

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FIGURES (A) N

N

N N HO

F

HN

N

(B)

F

F

EtO 2C

S

F

F

OH O

(R,R)-5

1

2

OH

(C) F +

EtO 2C

B. subtilis truncated globin

N2

F

EtO 2C

+

3

F

EtO 2C

F

F

2

F

H 2N

(R,R)-5

4

F (S,S)-5

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Figure 1. (A) Structure of ticagrelor 1. (B) The cyclopropyl ester precursor 5 can be converted to

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the cyclopropylamine precursor 2 by making the acyl azide and performing a Curtius

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rearrangement9 or via ammonolysis followed by Hofmann rearrangement16 of the corresponding

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amide. (C) Cyclopropanation of 3,4-difluorostyrene (3) with ethyl diazoacetate (4) catalyzed by

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engineered heme protein makes the cyclopropyl ester 5.

Y25

Q49

T45

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Figure 2. Positions of the Y25, T45, and Q49 residues near the heme iron in the B. subtilis wildtype protein (PDB ID: 1UX8).

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A)

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100 75

% ee 50 (trans) 25 0

wild-type

T45A Q49A Y25L T45A Q49A

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B) 98 % ee (trans) 96

94

BL21

1

C41

C43

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Figure 3. (A) Enantioselectivity of the cyclopropanation reaction catalyzed by various B. subtilis

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variants. Reaction conditions: OD600=60, 20 mM DFS/40 mM EDA. (B) Enantioselectivity of

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the cyclopropanation reaction catalyzed by B. subtilis T45A Q49A Y25L expressed in various E.

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coli strains. Reaction conditions: OD600=60, 20 mM DFS/40 mM EDA. The error bars represent

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standard deviation of % ee (trans) for the reactions run in triplicate.

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ASSOCIATED CONTENT

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Supporting information available: experimental procedures, standard curves, and characterization

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of ticagrelor cyclopropyl ester (R,R)-5. This material is available free of charge via the Internet at

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http://pubs.acs.org.

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AUTHOR INFORMATION

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Corresponding author

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*E-mail: [email protected] (Frances H. Arnold)

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Funding sources

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This work was supported in part by the National Science Foundation, Office of Chemical,

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Bioengineering, Environmental and Transport Systems SusChEM Initiative (grant CBET-

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1403077) and the Defense Advanced Research Projects Agency Biological Robustness in

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Complex Settings Contract HR0011-15-C-0093. Funding for this work to Provivi, Inc. from the

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National Science Foundation under Phase 1 STTR Grant 1549855 is also gratefully

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acknowledged. R.D.L. is supported by NIH/NRSA training grant (5 T32 GM07616). Any

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opinions, findings, and conclusions or recommendations expressed in this material are those of

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the author(s) and do not necessarily reflect the views of the funding organizations.

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Notes

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Caltech and FHA have a financial ownership interest in Provivi, Inc., the company sponsoring

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this research through the National Science Foundation STTR Program. FHA and Caltech may

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benefit financially from this interest if the company is successful in making product(s) that is/are

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related to this research. The terms of this arrangement have been reviewed and approved by

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Caltech in accordance with its conflict of interest policies.

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ACKNOWLEDGMENTS

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We thank Dr. S. Virgil and the Center for Catalysis and Chemical Synthesis (3CS) at Caltech for

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assistance with the SFC.

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ABBREVIATIONS

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EDA, ethyl diazoacetate; DFS, 3,4-difluorostyrene

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Facilitates Engineering of Improved Enzymes, J. Am. Chem. Soc. 2016, 138, 12527-12533.

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Renata, H.; Lewis, R. D.; Sweredoski, J.; Moradian, A.; Hess, S.; Wang, Z. J.; Arnold, F.

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ACS Catalysis

TOC graphic

F

HN N F F

EtO 2C

EtO 2C

N2

B. subtilis truncated globin Y25L T45A Q49A

F

N

N

F

N HO

N

F S

OH O

OH

ticagrelor

2

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