Process development of transaminase catalyzed reactions for large scale

industrial use

Matthew D. Truppo

Chiral Amines

• Useful building blocks in stereoselective synthesis• Present in a wide range of pharmaceutical intermediates (>70%)

FF

FN

OH NH2

NN

N

CF3

H3PO4 H2O

Merck’s Januvia for type 2 Diabetes$2B/yr projected sales

Chemical Methods to Produce Chiral Amines

1. Crystallization with chiral carboxylic acids (resolution of racemic amine)

½ of material wasted

R1

NH2

R2 R3

R4

O

OHR1

NH3+

R2 R3

R4

O

O-R1

NH3+

R2 R3

R4

O

O-

crystalline in solution

2. Reductive Amination

difficulties = making starting material and cleaving X

multiple step synthesis

R1

N

R2

X

R1

HN

R2

Xreduction

R1

NH2

R2

R1 R2

O

R1 R2

OH

R1 R2

OMs

R1 R2

N3

R1 R2

NH2Reduction ActivationAzide

Displacement Reduction

TRANSAMINASE

Transaminase Reactions: Challenges and Goals

R1

O

R2 R1

NH2

R2

Transaminase

N

O

HOOPO3

N

H2N

HOOPO3

NH2

O

OH

O

O

OHTransaminase

R1

O

R2 R1

NH2

R2

Transaminase

N

O

HOOPO3

N

H2N

HOOPO3

NH2

O

OH

O

O

OHTransaminase

Equilibrium

O

O

OHInhibition

Goals:

1. Evaluate transamination equilibrium and inhibition issues

2. Develop general methods for driving reactions to completion

• Novel rapid transaminase screening system

• Process development activities at 50mL scale

R1 R2

NH2

Inhibition

Use transaminases for the practical and economic industrial synthesis of chiral amines

Why Use Acetophenone as Model Substrate?

O NH2

• Representative building block for chemical synthesis

• One of the most difficult transformations:

• acetophenone substrate solubility issues

• product methylbenzylamine inhibition/deactivation issues

• substrate to product equilibrium issues

• If we can run this reaction in the synthesis direction, we should be able to run almost any substrate

Transamination Equilibrium

Driving Acetophenone Transamination Equilibrium

0

10

20

30

40

50

60

70

0 5 10 15 20 25

time (hours)

% c

onve

rsio

n 50mM alanine (1X eq.)

500mM alanine (10X eq.)

LDH, GDH system (10X eq.) • Transaminase still active

• Equilibrium strongly favors starting ketone and amine donor

• Excess amine donor isn’t enough for high productivity process

50mM acetophenone

O NH2Transaminase

NH2

O

OHO

O

OH

Equilibrium

Transaminase Inhibition

O NH2Transaminase

NH2

O

OHO

O

OH

Inhibition by Pyruvate

0

10

20

30

40

50

60

70

0 20 40 60 80 100 120

pyruvate (mM)

% in

hibi

tion

Inhibition by Methylbenzylamine

0

10

20

30

40

50

60

70

80

90

0 50 100 150MBA concentration (mM)

% in

hibi

tion

Driving Transamination ReactionsLactate Dehydrogenase System

• Pyruvate consumption drives equilibrium and eliminates pyruvate inhibition• GDH / NADH cofactor recycle = proven efficient, cost effective system• Acid formation enables reaction tracking

R1

O

R2 R1

NH2

R2

Transaminase

NH2

O

OH

O

O

OH

NAD

GlucoseDehydrogenase

GlucoseGluconolactoneGluconic Acid

NADH

Lactate DehydrogenaseOH

O

OH

Driving Transamination Reaction Using LDH System

Driving Acetophenone Transamination Equilibrium

0

10

20

30

40

50

60

70

0 5 10 15 20 25

time (hours)

% c

onve

rsio

n 50mM alanine (1X eq.)

500mM alanine (10X eq.)

LDH, GDH system (10X eq.) • Equilibrium strongly favors starting materials

• LDH system drives equilibrium and eliminates pyruvate inhibition

• reaction proceeds >20X further

NH2

Transaminase

NH2

O

OHO

O

OH

O

GlucoseDehydrogenase

Glucose Gluconolactone

NADHNAD+

LactateDehydrogenase

OH

O

OH

Colorimetric Screen of Acetophenone Transamination

0

5

10

15

20

25

30

35

40

45

50

101 103 105 107 109 111 113 115 117

transaminase (ATA#)

rate

(uM

/min

)

pH Indicator Colorimetric Assay

HPLC Assay

• Very precise quantification of transaminase activity• Directly scale this screening system up to first delivery scale

O NH2Transaminase

NH2

O

OH

O

O

OH

NAD

GlucoseDehydrogenase

GlucoseGluconolactoneGluconic Acid

NADH

Lactate DehydrogenaseOH

O

OH

pH indicator

Why not track NADH consumption?

pH Based Colorimetric Transaminase Activity Assay

Transaminase Screening System

0

10

20

30

40

50

60

70

80

0 10 20 30

time (hours)

% c

onve

rsio

n

HPLCpH indicator

Transaminase Screening System

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

0 10 20 30

time (hours)

abs

560n

m

pH indicator

Running Transamination with pH Indicator

• we have a precise colorimetric assay for enzyme activity and quantitative determination of product formation

• tuning buffer strength = track entire reaction profile

Microscale Process Development Using pH Indicator Assay

Transaminase Rate vs. pH (20C)

6.0

8.0

10.0

12.0

14.0

16.0

18.0

6.5 7 7.5 8 8.5 9

pH

rate

(uM

/min

)

• 100uL scale reactions run in plate spec for process development• Temperature activity/stability and pH activity profiles obtained• Inhibition studies, substrate and enzyme loading can be analyzed

• Note these profiles are for the complete ATA/LDH/GDH reaction system not just a single enzyme (great for direct scaling of process)

Transaminase Rate vs. Temperature

0

10

20

30

40

50

60

70

80

90

100

10 20 30 40 50

temperature (C)

rate

(uM

/min

)

0

1

2

3

4

5

6

7

1/2

life

(hou

rs)HPLC assay

colorimetric

stabiltyactivity

Transamination Scale-Up Directly from Screening Conditions to Reactor

• conversion tracked by automated pH control (NaOH addition) –red points show HPLC conversion

• >95% conversion of 50mM acetophenone (6g/L) with 1M alanine• Both S- and R-methylbenzylamine can be made with >99% ee

20mL Transamination of 50mM Acetophenone

0.0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

0.0 2.0 4.0 6.0 8.0 10.0

time (hours)

2M N

aOH

(mL)

0

10

20

30

40

50

60

70

80

90

100

conv

ersi

on (%

)

Methylbenzylamine Aqueous Conc. with Resins

0

50

100

150

200

250

300

350

400

450

0 10 25 50 100 200 400

resin (g/L)

Aqu

eous

MBA

con

c. (m

M)

ion exchange resinadsorbent resin

50% inhibition

80% inhibition

In-situ Product Extraction Using Resins

• Amberlite Ion Exchange Resin (IRP-69) and Polymeric Adsorbent Resin

• Ion exchange resin at 200g/L reduces a 420mM (50g/L) MBA chargeaqueous concentration to ~25mM (below the 50% inhibition barrier)

30mL Scale Resin/LDH Transamination System

• reactions run with automated pH control in Multimax reactors

• 50g/L (420mM) acetophenone reactions proceeded to >95% conversion with 200g/L resin

• isolation of product MBA requires simple dilute NaOH wash of ion exchange resin

NH2

Transaminase

NH2

O

OHO

O

OH

GlucoseDehydrogenase

Glucose Gluconolactone

NADHNAD+

O

LactateDehydrogenase

OH

O

OH

50g/L Transamination of Acetophenone

0

10

20

30

40

50

60

70

80

90

100

0 20 40 60

time (hours)

% c

onve

rsio

nno resin100g/L resin200g/L resin

Ion-exchangeresin

Driving Transamination ReactionsAmino Acid Dehydrogenase System

• Catalytic alanine system• amino donor generated in situ• Eliminates pyruvate inhibition• Cheap ammonia is amine donor

NH2

O

OH

O

O

OH

NAD

GlucoseDehydrogenase

Glucose Gluconolactone Gluconic Acid

NADH

Amino Acid DehydrogenaseH2O Ammonia

R1

O

R2 R1

NH2

R2

Transaminase

Transamination Using Catalytic Alanine SystemAcetophenone Transamination (Catalytic Alanine

- LAADH System)

0

10

20

30

40

50

60

70

80

90

100

0 10 20 30 40 50

time (hours)

conv

ersi

on (%

)

• 50mM acetophenone (6g/L) with 25mM pyruvate reaction proceeded to complete conversion

• Slower rate than LDH system, but uses a 40X reduction in alanine

Actually used no amine donor that’s accepted by transaminase!

NH2 O

R1

O

R2 R1

NH2

R2

Transaminase

Driving Transamination ReactionsIsopropylamine System

• Single enzyme system with very cheap amino donor• Equilibrium can be driven via acetone removal• Limited to transaminases that accept isopropylamine (IPM)• Transaminases must also be stable in high IPM concentrations

Transamination of Acetophenone using Isopropylamine Amino Donor

0

10

20

30

40

50

60

70

80

90

100

0 10 20 30 40time (hours)

conv

ersi

on (%

)

ATA-113ATA-117

Isopropylamine Transamination System

• Both S-methylbenzylamine (using ATA-113) and R-methylbenzylamine (using ATA-117) can be produced with >99% ee

• 50mM (6g/L) acetophenone with 1M IPM proceeds to >95% conversion

Driving Transaminations via Spontaneous Secondary Intramolecular Product Reactions

Transaminase

NH2 O

OEt

O O

OEt

NH2 O

NH

O

• transamination of ethyl 4-acetylbutyrate

• spontaneous cyclization of amine product to 6-methyl-2-piperidone product

Transaminase

NH2 O

OEtO

OEtNH2

O O

NH

O

• transamination of ethyl levulinate

• spontaneous cyclization of amine product to 5-methyl-2-2-pyrrolidinone

50g/L Ethyl 4-Acetylbutyrate Transamination

0

10

20

30

40

50

60

70

80

90

100

0 5 10 15time (hours)

% c

onve

rsio

n

Ethyl 4-acetylbutyrate Demo at 50 mL Scale and 50 g/L

• ATA-113 and ATA-117 produce >99% ee S or R product with >95% conversion

Summary

• 3 process methods for driving transamination reactions demonstrated in 50mL scale reactors• Can produce both R- and S-amines using Codexis’transaminase library with:

>99% ee and >90% yield

(Method 2, AADH/GDH)

(Method 3, isopropylamine)

(Method 1, LDH/GDH)

NH2

Transaminase

NH2

O

OHO

O

OH

GlucoseDehydrogenase

Glucose Gluconolactone

NADH

Amino Acid DehydrogenaseNH4

+H2O

NAD+

O

LactateDehydrogenase

OH

O

OH

GlucoseDehydrogenase

Glucose Gluconolactone

NADHNAD+

NH2 OO NH2Transaminase

NH2

O

OH

O

O

OH

NAD

GlucoseDehydrogenase

GlucoseGluconolactoneGluconic Acid

NADH

Lactate DehydrogenaseOH

O

OH

• rapid high-throughput pH based colorimetric assay for transaminase activity• microscale process development that can be scaled up directly for material delivery

Screening hit = first material delivery

Rapid Screen/Micro-scale Development Process Development

(Isopropylamine System)

(LDH/GDH System)

R1

NH2

R2

Transaminase

NH2

O

OHO

O

OH

GlucoseDehydrogenase

Glucose Gluconolactone

NADHNAD+

R1

O

R2

LactateDehydrogenase

OH

O

OH

NH2

O

ion-exchangeresin

R1

N

Summary – Transamination Manufacturing Processes (> 50 g/L substrate)

• demonstrated transamination reactions at >50 g/L substrate loading• in situ product removal with an ion exchange resin to selectively bind amine product• spontaneous intramolecular secondary reaction of amine product• demonstrated on the production of >40 amines with >99% ee

Acknowledgements

Prof. Nick Turner