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Acetyl-CoA Carboxylase Inhibition by ND-630 Inhibits Fatty Acid Synthesis and Stimulates Fatty Acid Oxidation in Cultured Cells and in Experimental Animals
Geraldine Harriman, Jeremy Greenwood*, Sathesh Bhat*, Liang Tong#, Ruiying Wang#, Debamita Paul#, Rosana Kapeller and H. James Harwood Jr.Nimbus Discovery, Inc., Cambridge, MA, USA; *Schrödinger, Inc., New York, NY, USA; #Columbia University, New York, NY, USA
NO
N
O
N
O
O O
O
CH3O
OCH3
OHOH
OCH3
0 12
5,000
Months
Ideas
Milestone Achieved
Confirm binding mode (x-ray)
175 Total
synthesized compound
8,000 nM <10 nM Potency
ACC1, ACC2
1.3MM
In vivo target engagement
16
10,000
225
<1 nM
Rat DIO Studiesin progress
mg
TGs
per
g Li
ver T
issu
e
0
2
4
3 10 30Vehicle ND-630 (mg/kg)
Lean DIO
0
100
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300
0.39 1.56 6.25 25 100Inhibitor (μM)
mA
50 Probe + cpd + ACC2Probe + cpd + buffer
-787
-387
-187
13
213
1013
30 40 50 60 70 80Temperature (°C)
Fluo
resc
ence
(dR
)
413
613
-587
813
5 μM hBC5 μM hBC + 50 μM Cp 5 μM hBC + 20 μM Soraphen5 μM hBC + 100 μM Ligand5 μM hBC + 50 μM Ligand5 μM hBC + 20 μM Ligand
0.001
0.010
0.100
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0 4 8 12 16 20 24Time (hrs)
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cent
ratio
n (μ
M)
IV PO_A
0.001 0.01 0.1 1 100
10000
20000
30000
40000
cpm
ND-630CP640186(3 μM)
Inhibitor (μM)
ED50= 0.14 mg/kg PO
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Vehicl
e 0.3 1mg/kg
3 10 30
DP
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Tiss
ue
MED = 3 mg/kg PO
0.7
0.75
0.8
0.85
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1
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1.1
1.15
-60 0 60 120 180 240
RQ
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EM
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Vehicle 3mpk 10mpk 30mpk
Time (min)
Mito
chon
drion
Acetyl -CoA
ACC Inhibitor
ACC1
Malonyl-CoA
Malonyl-CoA
Fatty acid synthesis Fatty acid oxidation
ACC2
Hepatic Lipid Lowering
Liver Targeted
Liver Disease
Inhibitor Mediated Effects Potential For Disease Modification
Improvement in Insulin Sensitivity with
Weight Neutrality Type 2 Diabetes
Plasma Lipid Lowering Dyslipidemia
ABSTRACT Inhibition of acetyl-CoA carboxylase (ACC) reduces fatty acid synthesis and stimulates fatty acid oxidation and has the potential to favorably affect the morbidity and mortality asso-ciated with obesity, diabetes, and fatty liver diseases. ACC exists as two tissue-specific isozymes; ACC1 present in li-pogenic tissues and ACC2 present in oxidative tissues. To achieve maximal effectiveness an ACC inhibitor should inhibit both isozymes. Most efforts to discover ACC inhibitors have focused on in-teractions within the carboxyltransferase (CT) domain of the enzyme active center. By contrast, our efforts have focused on the allosteric subunit dimerization site on the biotin car-boxylase (BC) domain where Soraphen interacts. This is also the same site where the phospho-containing motif of phos-pho-ACC binds to prevent dimerization and subsequent acti-vation of the enzyme. Using state-of-the-art structure-based drug design tech-niques together with crystal structures of the BC domain of human ACC2, we identified a unique series of small mole-cule allosteric inhibitors that bind to the Soraphen binding site and inhibit enzymatic activity. Development of this series has yielded deep structure-activity relationships, sub-nanomolar enzyme inhibition, functional activity in HepG2 and C2C12 cells and favorable drug-like properties leading to in vivo proof of concept. For example, the series representative ND-630 inhibits both human ACC1 and ACC2 (IC50 = 2.0 nM), inhibits HepG2 cell fatty acid synthesis (EC50 = 66 nM), stimulates C2C12 cell fat-ty acid oxidation (2-fold at 200 nM), inhibits rat hepatic fatty acid synthesis (ED50 = 0.14 mg/kg) and stimulates rat whole body fatty acid oxidation (minimum effective dose 3 mg/kg). Together these observations suggest that allosteric ACC inhibition has the potential to favorably impact diabetes, obe-sity, fatty liver and lipid disorders.
• A structure-based virtual screen and drug design approach utilizing WaterMap was used to identify allosteric inhibitors of ACC that bind to the BC domain.
• Inhibitors were successfully optimized for excellent potency and drug-like properties in 12 months.
• ND-630 demonstrated in vivo proof of concept in pharmaco-logically relevant models of target engagement (rat FASyn ED50 = 0.14 mpk, PO & rat RQ MED = 3 mpk, PO).
FIGURE 1: Acetyl CoA Carboxylase (ACC): Master Regulator of Fatty Acid Synthesis & Oxidation
SUMMARY
NEXT STEPS• Using this approach, a portfolio of nanomolar inhibitors with diverse functional-group driven bio-distribution patterns have been identified and are being utilized for a breadth of ACC-aligned indications.
• Nimbus will report on the detailed pharmacology of ND-630 and other molecules in metabolic disease models, diabe-tes models and oncology models (cancer metabolism) in the future.
• Beneficial effects on lipids, blood glucose, weight, potentially diabetes and CV risk.
• Nimbus: FIRST small molecule allosteric inhibitor successfully targeting BC domain.
FIGURE 2: Nimbus Allosteric Inhibitors Show Promise for Both Metabolic Disease & Fatty Liver Disease
FIGURE 3: Previous Approaches Identified Inhibitors of the ACC CT Domain (ex. CP-640186)
FIGURE 4: Nimbus’ Unique Approach Identified Potent ACC BC Domain Inhibitors Targeting Soraphen Binding Site
FIGURE 5: Nimbus Approach has Delivered ACC Inhibitors with Demonstrated in vivo PoC in 12 Months
• Most CT-domain inhibitor series identified exhibited poor drug-like properties.
• Nimbus took an orthogonal approach and designed inhibitors that bound to the Soraphen binding site in the BC domain of the ACC complex.
• A structure-based virtual screen of 1.3M lead-like molecules was performed utiliz-ing Schrodinger’s computational tools including WaterMap and Glide. This led to the identification of a high quality family of hit molecules with micromolar inhibitory effects against the enzyme. Co-crystal structures of members of this series in the human BC domain confirmed the model and our approach.
• In an iterative design fashion over the next 12 month period, the potency of this fam-ily of hits were improved 1000x utilizing the computational model focusing on the re-placement or stabilization of high energy hydration sites within the Soraphen binding site.
• Simultaneous to the potency improvements, drug-like properties were optimized to deliver Development Candidate quality molecules that are currently being profiled in chronic models of metabolic syndrome and diabetes.
FIGURE 6: In vitro Assays Confirm Binding of Early Hits to BC Domain Prior to Obtaining Co-crystal Structures
• Early in the program we utilized the Soraphen-TAMRA binding assay and BC domain thermal shift assays to provide us confidence that our inhibitors in fact were binding in the Soraphen binding site.
• These tools were utilized until the first Nimbus inhibitor was co-crystalized in the hu-man BC domain. This co-crystal structure taught us our computational model was highly predictive and also provided additional information for WaterMap calculations.
FIGURE 7: ND-630 Displays Excellent Drug-like Properties
FIGURE 8: ND-630 in vivo Proof of Concept: Target Engagement in the Liver and Muscle
TARGET POTENCY• ACC1 IC50 = 2 nM• ACC2 IC50 = 2 nM• HepG2 EC50 = 66 nM• C2C12 FAOxn stim. 2x @ 200 nM
ADMET• Low multispecies intrinsic clearance (human,
mouse, rat, dog, monkey)• High solubility (>300 mM)• P450 inhib >50 mM, hERG >30 mM• Protein binding (98%)• DrugMatrixPanel 0/120 hits; 1000x window
RAT PK (10 mg/kg, PO)• 37%F, Cmax 6 mM, Cl 33 mL/min/kg, AUC 3.4 mM.hr, T1/2 = 4.5h, Vss 2 L/kg
• Liver exposure: 81 mM• Muscle exposure: 0.45 mM
PHARMACOLOGY• Rat RQ MED = 3 mpk PO• Rat FASyn ED50 = 0.14 mpk, PO
Soraphen-TAMRA Assay(Hit displaces soraphen)
Thermal Shift Assay(Hit binds to the BC domain)
Plasma PK Profile SD Rats IV (3 mpk, n=3, solution dose)PO_A (10 mpk, n=3, suspension dose)
Hep-G2 cell FAsyn Inhibition [14C]acetate incorporation into FA)
Target Engagement in Liver(Fatty acid synthesis inhibition)
Target Engagement in Muscle(Respiratory quotient)
Confirmatory Co-crystal Structures
Soraphen A
CP-640186