Candice Soares de Melo1, Vinayak Singh2,3, Alissa Myrick2, Sandile B Simelane1, Dale Taylor4, Christel Brunschwig4, Nina Lawrence4, Dirk Schnappinger5, Curtis A Engelhart5, Anuradha Kumar6, Tanya Parish6, Qin Su7, Timothy G Myers7, Helena I M Boshoff8, Clifton E Barry8, Frederick A Sirgel9, Paul D van Helden9, Kirsteen I Buchanan10, Tracy Bayliss10, Simon R Green10, Peter C Ray10, Paul G Wyatt10, Gregory S Basarab1,4, Charles J Eyermann1, Kelly Chibale1,3, Sandeep R Ghorpade1. 1. Drug Discovery and Development Centre (H3D), Department of Chemistry, University of Cape Town, Rondebosch 7701, South Africa. 2. Drug Discovery and Development Centre (H3D), University of Cape Town, Rondebosch 7701, South Africa. 3. South African Medical Research Council Drug Discovery and Development Research Unit, Department of Chemistry and Institute of Infectious Disease and Molecular Medicine, University of Cape Town, Rondebosch 7701, South Africa. 4. Drug Discovery and Development Centre (H3D), Division of Clinical Pharmacology, Department of Medicine, University of Cape Town, Observatory 7925, South Africa. 5. Department of Microbiology and Immunology, Weill Cornell Medical College, New York, New York 10065, United States. 6. Infectious Disease Research Institute, 1616 Eastlake Ave E, Suite 400, Seattle, Washington 98102, United States. 7. Genomic Technologies Section, Research Technologies Branch, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, Maryland 20892, United States. 8. Tuberculosis Research Section, Laboratory of Clinical Infectious Diseases, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, Maryland 20892, United States. 9. South African Medical Research Council Centre for Tuberculosis Research/DST/NRF Centre of Excellence for Biomedical Tuberculosis Research, Division of Molecular Biology and Human Genetics, Faculty of Medicine and Health Science, Stellenbosch University, Tygerberg 7505, South Africa. 10. Drug Discovery Unit, School of Life Sciences, University of Dundee, Dundee DD1 5EH, U.K.
Abstract
Phenotypic screening of a Medicines for Malaria Venture compound library against Mycobacterium tuberculosis (Mtb) identified a cluster of pan-active 2-pyrazolylpyrimidinones. The biology triage of these actives using various tool strains of Mtb suggested a novel mechanism of action. The compounds were bactericidal against replicating Mtb and retained potency against clinical isolates of Mtb. Although selected MmpL3 mutant strains of Mtb showed resistance to these compounds, there was no shift in the minimum inhibitory concentration (MIC) against a mmpL3 hypomorph, suggesting mutations in MmpL3 as a possible resistance mechanism for the compounds but not necessarily as the target. RNA transcriptional profiling and the checkerboard board 2D-MIC assay in the presence of varying concentrations of ferrous salt indicated perturbation of the Fe-homeostasis by the compounds. Structure-activity relationship studies identified potent compounds with good physicochemical properties and in vitro microsomal metabolic stability with moderate selectivity over cytotoxicity against mammalian cell lines.
Phenotypic screening of a Medicines for Malaria Venture compound library against Mycobacterium tuberculosis (Mtb) identified a cluster of pan-active 2-pyrazolylpyrimidinones. The biology triage of these actives using various tool strains of Mtb suggested a novel mechanism of action. The compounds were bactericidal against replicating Mtb and retained potency against clinical isolates of Mtb. Although selected MmpL3 mutant strains of Mtb showed resistance to these compounds, there was no shift in the minimum inhibitory concentration (MIC) against a mmpL3 hypomorph, suggesting mutations in MmpL3 as a possible resistance mechanism for the compounds but not necessarily as the target. RNA transcriptional profiling and the checkerboard board 2D-MIC assay in the presence of varying concentrations of ferrous salt indicated perturbation of the Fe-homeostasis by the compounds. Structure-activity relationship studies identified potent compounds with good physicochemical properties and in vitro microsomal metabolic stability with moderate selectivity over cytotoxicity against mammalian cell lines.
Tuberculosis
(TB) caused by Mycobacterium tuberculosis (Mtb) continues to be one of the leading causes
of death and morbidity globally, claiming 1.2 million lives in 2018.[1] The emergence and spread of multi drug-resistant
(MDR) and extensively drug-resistant (XDR) strains of Mtb that are resistant to the first- and second-line drugs have further
exacerbated the situation.[2] The rise in
anti-microbial resistance warrants the search for new drugs with unique
modes of action that can bypass existing modes of resistance or can
be used as adjunctive therapy to compensate for those that are vulnerable
to promoting resistance. While considerable progress has been made
toward establishing a TB drug pipeline, the high attrition rate in
clinical development reinforces the need to continually replenish
the pipeline with high-quality leads that act through the inhibition
of novel targets.[3]In light of the
above, we have been engaged in early TB drug discovery
to identify and progress new chemical series with potentially novel
modes of action lacking cross-resistance with existing drugs.[4,5] One approach to identify compounds with a novel mode of action is
to phenotypically screen compound libraries against Mtb growing under different media conditions with different carbon sources
followed by a biology triage process to weed out actives hitting frequently
encountered targets such as the respiratory system (e.g., QcrB) and
cell–wall synthesis (e.g., MmpL3 and DprE1), as well as DNA
damaging agents. Herein, we describe structure–activity relationship
(SAR) and target identification studies of one novel chemical series,
2-pyrazolylpyrimidinones—represented in Figure . This series was identified through high-throughput
screening of a Medicines for Malaria Venture (MMV) compound library.
Figure 1
Generic
structure of pyrazolylpyrimidones.
Generic
structure of pyrazolylpyrimidones.
Results
and Discussion
Phenotypic Hits with a Novel Mode of Action
A high-throughput
screen of a ∼530,000 diverse set of compounds from MMV compound
library against Mtb was conducted at the National
Institute of Allergy and Infectious Diseases of the National Institutes
of Health (NIAID/NIH, U.S.). Reconfirmed hits were followed up for
determination of minimum inhibitory concentration (MIC) on multiple
media that identified a cluster of pan-active pyrazolylpyrimidinones
represented by compounds 1 and 2 (Table ). The biology triage
of these actives (described in the target identification section),
suggestive of a unique mechanism of action (MoA), generated further
interest in the exploration of these hits. We recognized that pyrazolylpyrimidinones
potentially possess iron-chelating properties by virtue of their two
sp2 heteroatoms in a 1,4-relationship on adjacent rings, which might
play a crucial role in the SAR and mode of action.[6] During these studies, we came across the related pyrazolopyrimidinone
(PZP, Figure a) compound
reported as an intracellular iron chelator in Mtb.[7] PZP is reported to chelate iron through
the pyrimidinone carbonyl and 2-position pyrazole nitrogen. Similarly,
bidentate iron chelation by the pyrazolylpyrimidinones from the pyrimidinone
nitrogen and pyrazole nitrogen as depicted in Figure b may be hypothesized. A single-crystal X-ray
structure of the pyrazolylpyridines–Fe complex is reported
in the literature which supports this hypothesis.[8,9] This
aspect of metal chelation by the compounds was considered while planning
further SAR exploration and target identification studies with the
series.
Table 1
Properties of the
Hits from the MMV
Library Screena
Properties
1
2
MIC 7H9/ADC/Tw (μM)
0.6
2
MIC GAST-Fe (μM)
0.02
0.02
MIC 7H9/Glu/BSA/Tx (μM)
1.5
2
MIC 7H9/Glu/Cas/Tx
(μM)
0.3
0.4
MIC 7H9/DPCC/Cas/Tx (μM)
0.4
0.2
MIC 7H9/DPCC/Chol/BSA/Tx (μM)
1.5
6
Vero IC50 (μM)
8
1.2
HepG2 IC50 (Glu/Gal μM)
4/4
ND
SolubilitypH7.4 (μM)
10
<5
LogDpH7.4
2.5
2.2
Molecular
Weight
266.304
295.346
Microsomal stability H/R/Mo %remaining
98/69/22
73/76/78
MIC—minimum inhibitory concentration
against Mtb H37Rv; 7H9—Middlebrook 7H9; ADC—albumin–dextrose–catalase
supplement; Tw—Tween 80; GAST-Fe—glycerol-alanine-salts
with Tween and iron salts; Glu—glucose; BSA—bovine serum
albumin; Tx—Tyloxapol; Cas—Casitone; DPCC—dipalmitoylphosphatidylcholine
and cholesterol; Chol—cholesterol; H/R/Mo—human/rat/mouse;
IC50—50% inhibitory concentrations; solubilitypH7.4—aqueous solubility at pH 7.4.
Figure 2
(a) Structure of PZP; and (b) depiction of metal chelation by pyrazolylpyrimidinone 1.
(a) Structure of PZP; and (b) depiction of metal chelation by pyrazolylpyrimidinone 1.MIC—minimum inhibitory concentration
against Mtb H37Rv; 7H9—Middlebrook 7H9; ADC—albumin–dextrose–catalase
supplement; Tw—Tween 80; GAST-Fe—glycerol-alanine-salts
with Tween and iron salts; Glu—glucose; BSA—bovine serum
albumin; Tx—Tyloxapol; Cas—Casitone; DPCC—dipalmitoylphosphatidylcholine
and cholesterol; Chol—cholesterol; H/R/Mo—human/rat/mouse;
IC50—50% inhibitory concentrations; solubilitypH7.4—aqueous solubility at pH 7.4.
Synthesis
In order to explore the
SAR profiles of the
series, various routes were explored toward the synthesis of diverse
range of analogues as represented by compounds 3–54 in Tables –5. To facilitate
exploration of a broad array of substituents off the pyrazole ring
and pyrimidinone core, a concise and scalable synthesis leading to
an advanced intermediate was desired. As summarized in Scheme , this was achieved by the
ring formation reaction of 6-substituted-2-thiomethyl-pyrimidin-4-one 55 via condensation of the appropriate β-keto-ester
and thiourea, and subsequent methylation of the thiol.[10] Intermediates 55a–g were
reacted with hydrazine hydrate in refluxing ethanol to give the versatile
2-hydrazinylpyrimidin-4(1H)-ones 56a–g, which gave access to analogues for SAR exploration on the pyrazole
ring and the R1 substituent on the pyrimidinone core. Similarly, substitution
of a phenyl group at the R2 position was achieved through bromination
at C5 of 6-methyl-2-thiomethyl-pyrimidin-4-one (55, R1
= CH3) followed by a Suzuki cross-coupling reaction with
phenyl boronic acid to provide 55h, which was then treated
with hydrazine to form 56h.
Table 2
Pharmacophore Evaluation
of Pyrazolylpyrimidinonesa
MIC were measured
in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility measured at pH
7.4; CHO—an epithelial cell-line derived from the ovary of
the Chinese hamster; and V—Vero cell-line; SI—selectivity
index between CHO IC50 and Mtb MIC.
Table 5
SAR at the Pyrazole R3 Positiona
MIC—were measured in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility at pH 7.4; CHO—an
epithelial cell-line derived from the ovary of the Chinese hamster;
and SI—selectivity index between CHO IC50 and Mtb MIC.
Scheme 1
Synthetic Route to
Explore R1 and R2 on the Pyrimidinone and Polar
Modifications at R5 on the Pyrazole
Synthetic Route to
Explore R1 and R2 on the Pyrimidinone and Polar
Modifications at R5 on the Pyrazole
Reagents and conditions:
(i)
(a) thiourea, KOH, EtOH, reflux (b) iodomethane, NaOH, H2O/EtOH; (ii) NH2NH2·H2O, EtOH,
reflux; (iii) Br2, AcOH, 60 °C; (iv) phenylboronic
acid, Pd(PPh3)2Cl2, 1,4-dioxane,
K2CO3; (v) acetylacetone, EtOH, AcOH, reflux;
(vi) 3-aminocrotonitrile, EtOH, reflux; (vii) acetyl chloride, pyridine,
CH2Cl2; and (viii) ethyl acetoacetate, EtOH,
AcOH, reflux.MIC were measured
in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility measured at pH
7.4; CHO—an epithelial cell-line derived from the ovary of
the Chinese hamster; and V—Vero cell-line; SI—selectivity
index between CHO IC50 and Mtb MIC.MIC—were
measured in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility measured at pH
7.4; CHO—an epithelial cell-line derived from the ovary of
the Chinese hamster; and SI—selectivity index between CHO IC50 and Mtb MIC.MIC—were measured in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility measured at pH
7.4; CHO—an epithelial cell-line derived from the ovary of
the Chinese hamster; and SI—selectivity index between CHO IC50 and Mtb MIC.MIC—were measured in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility at pH 7.4; CHO—an
epithelial cell-line derived from the ovary of the Chinese hamster;
and SI—selectivity index between CHO IC50 and Mtb MIC.The Knorr
reaction was used to incorporate the 3,5-dimethylpyrazole
via an acid-catalyzed condensation of hydrazine precursors 56a–h and acetylacetone. This led to hit compound 1 and related
analogues exploring the R1 (11, 12, 19, 20, and 21) and R2 (8–9) positions of the pyrimidinone core as well as quinazolin-4(3H)-one analogue (10). In addition, 2-hydrazinylpyrimidin-4(1H)-one 56a and 56d were reacted
with (Z)-3-aminocrotonitrile to afford 5-aminopyrazolylpyrimidinone
analogues 14 and 33,[11] which allowed for several transformations to be carried
out to expand SAR exploration on the pyrazole ring later described
in Scheme . To explore
polar modifications off the pyrazole ring, a mixture of 2-(5-amino-3-methyl-1H-pyrazol-1-yl)-6-phenylpyrimidin-4(3H)-one 14 and pyridine in dichloromethane was treated with acetyl
chloride to provide N-acetyl amide 15.[2] In addition, hydrazine 56a was heated with ethyl acetoacetate in acidic ethanol to yield pyrazolone 13.
Scheme 7
Synthetic Routes
Used to Explore the Pyrazole R5 Position
Reagents and conditions:
(i)
diketone, EtOH, AcOH, reflux; (ii) 3-aminocrotonitrile, EtOH, reflux;
(iii) acetaldehyde, DMF, AcOH, NaCNBH4, MeOH, 25 °C;
(iv) N-(2-methoxyethyl)-3-oxobutanamide, Lawesson’s
reagent, THF, 25 °C; and (v) Cs2CO3, Pd2(dba)3, XantPhos, 1,4-dioxane, aryl halide, 120
°C
Syntheses of compounds 3–7 (Table ) with changes in
the central
core ring are summarized in Scheme . Compounds masking the pyrimidinone amide were synthesized
from compound 1 via a Mitsunobu reaction to form methyl
ether 3 and N-methylation of 1 with iodomethane
using potassium carbonate in N,N-dimethylformamide (DMF) to afford N-methyl pyrimidinone 4. The nucleophilic aromatic substitution reaction of 2,6-dichloro-4-iodopyridine
with sodium methoxide gave intermediates 57 and 58 in a 2:1 ratio, which upon separation allowed for the synthesis
of compounds 5 and 6, respectively. Briefly,
the three-step synthesis from 57 and 58 involved
a Suzuki cross-coupling reaction with phenylboronic acid to afford
intermediates 59 and 60, respectively, followed
by a Buchwald Hartwig amination to introduce the pyrazole (intermediates 61 and 62, respectively), and finally O-demethylation
with boron tribromide to afford compounds 5 and 6, respectively.
Scheme 2
Synthetic Routes to Access Core Modifications
Reagents and conditions: (i)
MeOH, PPh3, DIAD, THF, 25 °C; (ii) MeI, K2CO3, DMF, 100 °C; (iii) NaOCH3, MeOH,
80 °C; (iv) phenylboronic acid, Pd(PPh3)2Cl2, K2CO3, 1,4-dioxane, reflux;
(v) 3,5-dimethylpyrazole, xanphos, Pd(OAc)2, Cs2CO3, 1,4-dioxane, 130 °C; (vi) BBr3, MeOH;
(vii) BBr3, CH2Cl2; (viii) urea,
1,4-dioxane, 140 °C, microwave; (ix) POCl3, DMF; (x)
3,5-dimethylpyrazole, Cs2CO3, 1,4-dioxane, 80
°C, microwave; and (xi) 20% aq NaOH, 80 °C.
Synthetic Routes to Access Core Modifications
Reagents and conditions: (i)
MeOH, PPh3, DIAD, THF, 25 °C; (ii) MeI, K2CO3, DMF, 100 °C; (iii) NaOCH3, MeOH,
80 °C; (iv) phenylboronic acid, Pd(PPh3)2Cl2, K2CO3, 1,4-dioxane, reflux;
(v) 3,5-dimethylpyrazole, xanphos, Pd(OAc)2, Cs2CO3, 1,4-dioxane, 130 °C; (vi) BBr3, MeOH;
(vii) BBr3, CH2Cl2; (viii) urea,
1,4-dioxane, 140 °C, microwave; (ix) POCl3, DMF; (x)
3,5-dimethylpyrazole, Cs2CO3, 1,4-dioxane, 80
°C, microwave; and (xi) 20% aq NaOH, 80 °C.Pyrimidin-2(1H)-one 7 was
synthesized
by the cyclization of ethyl benzoylacetate with urea to provide uracil 63, which was then reacted with phosphorus oxychloride in
the presence of a catalytic amount of DMF to give 2,4-dichloropyrimidine 64 (Scheme ).[12] The activated 2,4-dichloropyrimidine
readily undergoes nucleophilic substitution with the pyrazole at the
4-chloro position by heating in the microwave at 80 °C (intermediate 65) and subsequent hydrolysis of 2-Cl afforded compound 7, with the carbonyl functionality between the ring nitrogens.Compounds 16 and 17 (Table ), in which the pyrazole ring
was replaced with other 5-membered heterocycles, were synthesized
in a similar manner from 2,4-dichloro-6-phenylpyrimidine 64 (Scheme ). The alkaline
hydrolysis of intermediate 64 with 20% aqueous sodium
hydroxide occurred primarily at the 4-Cl position to provide advanced
intermediate 66 (isomer ratio 70:30),[13] which was reacted with the corresponding 5-membered heterocycle
to displace 2-Cl using cesium carbonate under microwave heating at
80 °C (Scheme ). Compound 18 with an N-methylimidazole
was synthesized by condensing 1-methyl-1H-imidazole-2-carboximidamide
with ethyl benzoylacetate in low yields.
Scheme 3
Synthetic Route for
Pyrazole Replacements
Reagents and conditions: (i)
urea, 1,4-dioxane, 140 °C, microwave; (ii) POCl3,
DMF; (iii) 20% aq NaOH, 80 °C (iv) 5-membered heterocycle, Cs2CO3, 1,4-dioxane, 80 °C, microwave; and (v)
EtOH, reflux, 1 h.
Synthetic Route for
Pyrazole Replacements
Reagents and conditions: (i)
urea, 1,4-dioxane, 140 °C, microwave; (ii) POCl3,
DMF; (iii) 20% aq NaOH, 80 °C (iv) 5-membered heterocycle, Cs2CO3, 1,4-dioxane, 80 °C, microwave; and (v)
EtOH, reflux, 1 h.In order to introduce groups
with polar functionalities at the
R1 and R2 positions on the pyrimidinone core, 2,4,6-trichloropyrimidine
was a useful and accessible starting material when the appropriate
β-keto-ester was not readily available to pursue synthetic routes,
as shown in Schemes and 3. Treatment of 2,4,6-trichloropyrimidine
in aqueous 1,4-dioxane, brought to the alkaline reaction with NaOH,
led to hydrolysis at room temperature with the formation of 4,6-dichloro-2-hydroxypyrimidine 67 and 2,6-dichloropyrimidin-4(3H)-one 68, with the former precipitating out as the sodium salt (Scheme ).[14] The filtrate was concentrated to approximately half the
volume and cooled to afford a precipitate which was filtered off and
acidified to pH 2 using 5 N HCl to give the required regioisomer 68, in approximately 40% yield. The reactivity of each position
of the pyrimidine halides follows the general order C6(4) > C2
≫
C5.[15] A strong preference for the C6 position
has been observed in Suzuki cross-coupling reactions.[16−20] Coupled with the use of a lower temperature for the Suzuki coupling,
this allowed for the sequential introduction of different substituents.
Scheme 4
Synthetic Route to Polar Substitutions on R1 of the Pyrimidinone
Reagents and conditions: (i)
aqueous NaOH, dioxane; (ii) boronic acid, Cs2CO3, Pd(OAc)2, dppf, 1,4-dioxane, 70 °C or K2CO3, PdCl2(dppf)2, 1,4-dioxane,
70 °C; and (iii) 3,5-dimethylpyrazole, Cs2CO3, 1,4-dioxane, 130 °C, microwave.
Synthetic Route to Polar Substitutions on R1 of the Pyrimidinone
Reagents and conditions: (i)
aqueous NaOH, dioxane; (ii) boronic acid, Cs2CO3, Pd(OAc)2, dppf, 1,4-dioxane, 70 °C or K2CO3, PdCl2(dppf)2, 1,4-dioxane,
70 °C; and (iii) 3,5-dimethylpyrazole, Cs2CO3, 1,4-dioxane, 130 °C, microwave.Thus,
2,6-dichloropyrimidin-4(3H)-one 68 underwent
a Suzuki cross-coupling with the appropriate boronic acid,
using Pd(OAc)2/dppf or PdCl2(dppf)2 as the catalyst to afford compounds 69a–d. Coupling
of intermediates 69a–d with 3,5-dimethylpyrazole
was achieved by heating to 130 °C under microwave irradiation
using 15 mol % Pd2(dba)3, xanphos, and Cs2CO3 in 1,4-dioxane to afford the desired compounds 22–25 (Table ). A slightly modified procedure, as shown in Scheme , was used to prepare amide 26. Methyl 2,6-dichloropyrimidine-4-carboxylate was treated
with sodium methoxide at 0 °C to obtain intermediate 70. Intermediate 70 was then reacted with 3,5-dimethylpyrazole
under microwave heating using Cs2CO3 as a base
to give acid 71, which was followed by subsequent in
situ hydrolysis of the methyl ester. Acid 71 was coupled
with 4-fluoroaniline using 1-[bis(dimethylamino)methylene]-1H-1,2,3-triazolo[4,5-b]pyridinium 3-oxid
hexafluorophosphate (HATU) to give amide intermediate 72, which was demethylated using boron tribromide in dichloromethane
to give compound 26.
Table 3
Polar Substitutions
on Pyrimidinonea
MIC—were
measured in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility measured at pH
7.4; CHO—an epithelial cell-line derived from the ovary of
the Chinese hamster; and SI—selectivity index between CHO IC50 and Mtb MIC.
Scheme 5
Synthetic Route to Amide 26
Reagents and conditions: (i)
CH3ONa, THF, 0 °C; (ii) 3,5-dimethylpyrazole, Cs2CO3, 1,4-dioxane, 110 °C, microwave; (iii)
4-fluoroaniline, HATU, Et3N, DMF; and (iv) BBr3, CH2Cl2.
Synthetic Route to Amide 26
Reagents and conditions: (i)
CH3ONa, THF, 0 °C; (ii) 3,5-dimethylpyrazole, Cs2CO3, 1,4-dioxane, 110 °C, microwave; (iii)
4-fluoroaniline, HATU, Et3N, DMF; and (iv) BBr3, CH2Cl2.To determine
if polarity at the R2 position on the pyrimidinone
core was tolerated, compounds 27–29 (Table ) were synthesized
using the route, as shown in Scheme . 4-Fluorobenzaldehyde was condensed with thiourea
and ethyl cyanoacetate using potassium hydroxide in refluxing ethanol
to give 2-mecapto-5-cyanopyrimidinone intermediate 73.[21] The thiol of intermediate 73 was methylated using methyl iodide in the presence of sodium hydroxide
followed by displacement with hydrazine in refluxing ethanol to give
2-hydrazinyl-5-cyanopyrimidinone intermediate 74. This
intermediate was then condensed with acetylacetone by heating in acetic
acid-ethanol at 85 °C to obtain compound 27, which
was hydrolyzed to amide 28 by heating in concentrated
sulfuric acid at 85 °C.[22] The conversion
of amide 28 to acid 29 was achieved via
nitrosation by heating with tert-butyl nitrite in
acetic acid at 85 °C followed by hydrolysis.[23]
Scheme 6
Synthetic Route to Polar Substitutions on R2 of the
Pyrimidinone
Reagents and conditions: (i)
ethyl 2-cyanoacetate, KOH, ethanol, reflux; (ii) (a) MeI, NaOH, H2O (b) NH2NH2·H2O, EtOH,
reflux; (iii) acetylacetone, AcOH, EtOH, 85 °C; (iv) H2SO4, 80 °C; and (v) tert-butyl nitrite,
AcOH, 75 °C.
Synthetic Route to Polar Substitutions on R2 of the
Pyrimidinone
Reagents and conditions: (i)
ethyl 2-cyanoacetate, KOH, ethanol, reflux; (ii) (a) MeI, NaOH, H2O (b) NH2NH2·H2O, EtOH,
reflux; (iii) acetylacetone, AcOH, EtOH, 85 °C; (iv) H2SO4, 80 °C; and (v) tert-butyl nitrite,
AcOH, 75 °C.Compounds 30–47 (Table ) were synthesized
to explore the SAR around
the R5 position of the pyrazole ring, keeping the C6-position on the
pyrimidinone core fixed as trifluoromethyl. Using the same methodology,
as shown Scheme ,
the condensation of 56d with the corresponding 1,3-dicarbonyl
compound afforded compounds 30–32 exclusively
as one regioisomer as confirmed by NOESY NMR (Scheme ). In addition, 56d provided access to compound 33, which served as a versatile intermediate and allowed for
several transformations to form N-substituted pyrazole derivatives.
The reductive amination of acetaldehyde with 33 in the
presence of sodium cyanoborohydride in methanol gave ethylaminopyrazole 34. Attempts to synthesize the N,N-dialkyl derivative from compound 34 failed
as the corresponding derivatives decomposed on standing. Compound 47 was synthesized in the same manner by reductive amination
of acetaldehyde with 2-hydrazineyl-6-(3-pyridinyl)pyrimidinone 56g. The synthesis of 5-(aryl-amino)pyrazoles 40–46 was achieved via a Buchwald Hartwig amination of 33 and the corresponding aryl halide.
Table 4
SAR at the Pyrazole R5 Positiona
MIC—were measured in Middlebrook
7H9/Glu/BSA/Tyloxapol media at day 7; IC50—50% inhibitory
concentrations; solubility—aqueous solubility measured at pH
7.4; CHO—an epithelial cell-line derived from the ovary of
the Chinese hamster; and SI—selectivity index between CHO IC50 and Mtb MIC.
Synthetic Routes
Used to Explore the Pyrazole R5 Position
Reagents and conditions:
(i)
diketone, EtOH, AcOH, reflux; (ii) 3-aminocrotonitrile, EtOH, reflux;
(iii) acetaldehyde, DMF, AcOH, NaCNBH4, MeOH, 25 °C;
(iv) N-(2-methoxyethyl)-3-oxobutanamide, Lawesson’s
reagent, THF, 25 °C; and (v) Cs2CO3, Pd2(dba)3, XantPhos, 1,4-dioxane, aryl halide, 120
°CCompound 38 was synthesized
from hydrazine 56d and N-(2-methoxyethyl)-3-oxobutanamide
with Lawesson’s
reagent, which allows for the efficient installation of substituted-5-amino
groups on the pyrazole core in a single step.[24] However, this methodology failed in the case of the synthesis of
compounds 36, 37, and 39, with
2-(5-hydroxy-3-methyl-1H-pyrazol-1-yl)-6-(trifluoromethyl)pyrimidin-4(3H)-one being obtained as the major product. An alternate
highly regioselective route to 5-(substituted-amino)pyrazoles 36, 37, and 39 was achieved following
a modified literature procedure.[25]As shown in Scheme , the displacement of one methylthio group of the α-oxoketene
dithioacetal 75(26,27) by the appropriate
amine in the presence of acetic acid in ethanol afforded the N,S-acetals 76a-c, which were useful three-carbon 1,3-electrophiles.[28] Cyclocondensation with hydrazine 56d in refluxing
ethanol, gave access to 5-(substituted-amino)pyrazoles 36, 37, and 39. The regioisomeric products
with 3-(substituted-amino)pyrazoles could be isolated in minor quantities
and showed much less potent activity against Mtb (data
not shown).
Scheme 8
Synthetic Route to Compounds 36–39
Reagents and conditions: (i)
NH2-R, EtOH, reflux; (ii) 33, AcOH, EtOH,
100 °C.
Synthetic Route to Compounds 36–39
Reagents and conditions: (i)
NH2-R, EtOH, reflux; (ii) 33, AcOH, EtOH,
100 °C.Compound 35, with
an O-ethyl group
at R5, was synthesized, as shown in Scheme . The condensation of ethyl acetoacetate
and hydrazine delivered pyrazolone 77, which on subsequent O-ethylation with ethyl iodide gave 78. Intermediate 78 was coupled with 79, synthesized by the oxidation
of thiomethyl-pyrimidin-4-one 55d with mCPBA to yield 35.
Scheme 9
Synthesis of Compound 35
Reagents and conditions: (i)
(a) thiourea, KOH, EtOH and (b) MeI, NaOH, H2O; (ii) mCPBA, CH2Cl2, 25 °C; (iii) N2H2. H2O, EtOH; (iv) EtI, K2CO3, DMF, 70 °C; and (v) Cs2CO3, 1,4-Dioxane, 130 °C.
Synthesis of Compound 35
Reagents and conditions: (i)
(a) thiourea, KOH, EtOH and (b) MeI, NaOH, H2O; (ii) mCPBA, CH2Cl2, 25 °C; (iii) N2H2. H2O, EtOH; (iv) EtI, K2CO3, DMF, 70 °C; and (v) Cs2CO3, 1,4-Dioxane, 130 °C.Compounds 48–50 with substitutions on the pyrazole
C4 position were synthesized, as shown in Scheme . The bromination of compound 12 gave compound 48, which on Suzuki cross-coupling with
pyridine-3-boronic acid gave compound 49. Attempts to
displace C4-Br of 48 with morpholine to synthesize compound 50 were unsuccessful. In an alternative route, the morpholine
ring was preinstalled on acetylacetone via bromination with N-bromosuccinimide (intermediate 80) followed
by the reaction with morpholine in the presence of triethylamine to
give intermediate 81. This intermediate was then condensed
with hydrazine 56d by refluxing in ethanol-acetic acid
to give compound 50.
Scheme 10
Synthesis of Compounds with Pyrazole
C4 Substitutions
Reagents and conditions: (i)
Br2, AcOH, 100 °C, 2h; (ii) pyridine-3-boronic acid,
K2CO3, Pd(dppf)Cl2, THF/water (10:1),
70 °C, 16h; (iii) N-bromosuccinamide, p-toluene sulphonic acid, CH2Cl2;
0 °C; (iv) morpholine, Et3N, CH2Cl2; and (v) EtOH/AcOH reflux, 16 h.
Synthesis of Compounds with Pyrazole
C4 Substitutions
Reagents and conditions: (i)
Br2, AcOH, 100 °C, 2h; (ii) pyridine-3-boronic acid,
K2CO3, Pd(dppf)Cl2, THF/water (10:1),
70 °C, 16h; (iii) N-bromosuccinamide, p-toluene sulphonic acid, CH2Cl2;
0 °C; (iv) morpholine, Et3N, CH2Cl2; and (v) EtOH/AcOH reflux, 16 h.Compound 51 was synthesized in a similar fashion to
compound 33, by condensing hydrazine 56d with 3-cyclopropyl-3-oxopropanenitrile (82) (Scheme ). The synthesis
of compounds 52–54 was accomplished from 83, as shown in Scheme . The reaction of 83 with 85 under microwave heating gave acid 53. This compound
was then coupled with dimethylamine using HATU to give compound 54. Pyrazole ester 83 was converted to the corresponding
dimethylaminomethyl derivative 84 via a standard two-step
protocol involving the reduction of the ester to the aldehyde followed
by reductive amination with dimethylamine. Intermediate 84 was reacted with 2-methylsulphonylpyrimidinone 79 under
microwave heating to obtain compound 52.
Scheme 11
Synthesis
of Compounds with Pyrazole C3 Modifications
Reagents
and conditions. (i)
DMF, 130 °C, 2 h; (ii) Cs2CO3, 1,4-dioxane,
130 °C, microwave; (iii) N,N-dimethylamine, HATU, Et3N, DMF; (iv) (a) DIBALH, CH2Cl2, −78 °C; (b) N,N-dimethylamine, NaCNBH3, THF, RT, 24
h; and (v) Cs2CO3, 1,4-dioxane, 130 °C,
microwave.
Synthesis
of Compounds with Pyrazole C3 Modifications
Reagents
and conditions. (i)
DMF, 130 °C, 2 h; (ii) Cs2CO3, 1,4-dioxane,
130 °C, microwave; (iii) N,N-dimethylamine, HATU, Et3N, DMF; (iv) (a) DIBALH, CH2Cl2, −78 °C; (b) N,N-dimethylamine, NaCNBH3, THF, RT, 24
h; and (v) Cs2CO3, 1,4-dioxane, 130 °C,
microwave.
Formal Hit Assessment to Determine the Pharmacophore
Critical
for Antitubercular Activity
Although the initial hits, 1 and 2 (Table ), showed reasonably potent antitubercular activity
(MIC < 2 μM), they suffered from unfavorable physicochemical
properties including low solubility, low to moderate microsomal metabolic
stability (MS), and a low selectivity index (SI) between Mtb MIC and mammalian cell toxicity as determined by measuring 50% inhibitory
concentrations (IC50) determined against a CHO cell-line
(an epithelial cell-line derived from the Chinese-hamster ovary).
A formal hit assessment study was undertaken to determine the minimum
pharmacophoric features critical for antitubercular potency and to
understand the SAR features needed to improve the SI. Initially, compounds
with single point modifications on the pyrimidinone and pyrazole portions
of the molecule were synthesized and profiled in a first wave of assays
comprising Mtb MIC, CHO IC50, and aqueous
solubility. The substituents on the pyrimidinone and pyrazole rings
were labeled R1-R5, as shown Figure (see Table ). Masking of the pyrimidinone amide as −OCH3 (3) or N-CH3 (4) abolished the Mtb activity, indicating the essentiality
of the NH, which might be involved in the critical hydrogen bond (HB)
donor–acceptor interactions with the target. Each of the nitrogens
of the pyrimidinone ring were found to be essential for maintaining Mtb activity (5 and 6). Interestingly,
compound 7 with the carbonyl functionality between the
ring nitrogens pyrimidin-2(1H)-one vs pyrimidin-4(3H)-one as in 1 maintained similar Mtb activity. The additional SAR explorations in this work were limited
to the pyrimidin-4(3H)-one core as in compound 1, considering the ease of synthesis.Compound 8 with a methyl group added at the pyrimidinone C5 (R2) position,
while keeping a phenyl substituent at C6 (R1), retained a good MIC
value (2 μM) while improving aqueous solubility (120 μM)
and the SI (12.5) for cytotoxicity. However, isomeric compound 9 with C5-phenyl (R2) and C6-methyl (R1) showed a poor MIC
value (9 μM) with a lower SI of 1, whereas the fusion of the
phenyl ring with the pyrimidinone ring to form the corresponding quinazolinone
(compound 10) retained potency but with a low SI of only
2. A phenyl substituent at the R1 (pyrimidinone C6) position was necessary
to maintain Mtb activity. Compounds 11 and 12 with CH3 and CF3 groups,
respectively, at R1 instead of the phenyl substituent showed a 10–15-fold
loss in activity. As compound 12 with the CF3 group at R1 showed higher solubility and SI relative to 1, this modification was included in further explorations for potency
and selectivity. Overall, these SAR observations suggested the requirement
for hydrophobic substitutions on the pyrimidinone ring for the retention
of potent in vitro activity against Mtb.A few polar modifications on the pyrazole ring were attempted
in
order to evaluate the scope of reducing lipophilicity and improving
drug-like properties. Changing the C5′-methyl (R5) on the pyrazole
to oxygen abolished the activity as observed for compound 13, whereas an amino group at the C5′-position as in compound 14 resulted in the retention of activity comparable to compound 1 (3 μM) and significantly improved solubility (180
μM). Unfortunately, this polar modification did not improve
the SI. N-acetyl amide derivative 15 retained the activity and SI profile similar to parent amine 14. Compound 16, with an unsubstituted pyrazole,
lost potency considerably (MIC 50 μM). A similar loss in potency
was observed when the pyrazole ring was replaced with other 5-membered
rings like triazole or imidazole, as in compounds 17 and 18, respectively. This suggests the critical nature of an
appropriately substituted pyrazole moiety for maintaining antitubercular
activity.The SAR observations regarding the critical pharmacophoric
features
required for maintaining and/or improving antitubercular activity
along with the scope for further SAR studies are summarized in Figure . In summary, the
pyrimidin-4(3H)-one ring was retained for further
SAR studies considering the critical nature of the cyclic amide as
well as the ring nitrogens for maintaining the antitubercular activity.
The SAR observations suggest the important role of hydrophobic substituents
at the R1 and R2 positions for potency. We explored the scope of polar
interactions further away from the main scaffold by extending polar
groups from the aryl ring at the R1 position. In addition, we also
explored a few polar groups at the R2 position instead of a methyl
group, which could influence HB-donor acceptor interactions of the
pyrimidinone ring amide. The 3,5-disubstituted pyrazole ring was critical
for maintaining activity, but there was a clear scope to extend substituents
from the R5 position to improve potency and physicochemical properties.
The scope of substitution at the R4-postion remained to be explored.
Figure 3
Essential
pharmacophoric features and scope for further SAR studies.
Essential
pharmacophoric features and scope for further SAR studies.
SAR of Polar Groups at R1 and R2 Positions of the Pyrimidinone
Core
Several polar R1 and R2 substituents on the pyrimidinone
ring were incorporated in order to expand the scope relative to activity
(Table ) and increase
solubility and SI. Compound 19 with a 4-fluorophenyl
group at the R1 position retained activity and cytotoxicity similar
to compound 1. The replacement of the phenyl ring with
pyridine rings considerably improved solubility, as observed for compounds 20 and 21, although with some loss in Mtb activity. Compound 20, with a 4-pyridyl
ring, was more potent (MIC 9 μM) than compound 21 with a 3-pyridyl ring (MIC 50 μM) leading to the speculation
of the role of HB-interactions through the 4-pyridine nitrogen. Hence,
compounds 22 to 25 with various polar substitutions
at the para-position of the phenyl ring at the R1 position were prepared.
Unfortunately, all these compounds lost activity. Next, we considered
the option of inserting a polar linker between the pyrimidinone and
phenyl rings. Among the various groups attempted, only compound 26 with a 4-flurophenyl group extended by a carboxamide linker
at the R1 position, retained weak activity (25 μM).Based
on the encouraging data for compound 8 with a C5-methyl
group on the pyrimidinone, we explored adding a few polar groups such
as CN, CONH2, and CO2H at this position, but
unfortunately this led to the loss of activity (compounds 27, 28, and 29). Overall, these observations
indicated very limited scope for adding polar substitutions on the
pyrimidinone ring. Hence, we turned our attention to exploring possible
interactions from the pyrazole ring.
SAR of the Pyrazole Ring
Further exploration on the
pyrazole ring was planned, maintaining the CF3 as the R1
substituent on the pyrimidinone, as it increased the solubility and
SI exemplified for compound 12. In addition, the smaller
CF3 group kept the molecular weight and lipophilicity on
the low side compared to the phenyl. The addition of bulkier alkyls
like ethyl and cyclopropyl (compounds 30 and 31) at the R5 position on the pyrazole were tolerated for Mtb activity relative to 12 but with a deterioration of
the SI, whereas a slight loss in activity was observed for compound 32 with the phenyl group at the R5 position. Isomers of these
compounds with bulkier groups at the R3 position could not be synthesized
because of the selectivity observed in the condensation reaction of
hydrazine with requisite diketones favoring the placement of bulkier
groups at the R5 position. Compound 33 with a NH2 at the R5 position maintained a profile similar to compound 12, whereas compound 34 with an aminoethyl at
the R5 position showed increased toxicity against CHO cell lines without
a significant improvement in activity. Compound 35 with
an O-ethyl group at the R5 position had a potency
and selectivity profile similar to compound 12. The extension
of polar groups like −NH2 or −OH via a short
ethylamino linker from the R5 position as in compounds 36 and 37, respectively, was detrimental to activity against Mtb. Compounds 38 and 39, with
the neutral ether substituents like methoxyethylamino and pyranamino,
respectively, at the R5 position, showed more potent activity (MIC
1.5–2 μM) as compared to 12 while the SI
was about the same. Based on these observations, it is speculated
that the R5 position lies in a more hydrophobic region of the compound
binding site within the target in Mtb. Hence, we
decided to examine aryl groups, some with polarity, at R5 toward maintaining
activity while improving solubility with polar substituents placed
distant from the main scaffold.Compound 40 with
a 4-F-aniline at the R5 position showed Mtb potency
and a SI profile similar to 39, with an aminopyran at
position R5, but had lower aqueous solubility (15 μM) as expected
because of the overall increase in lipophilicity with an additional
aryl ring. Compound 41 with a 2,4-difluoroanilino group
at the R5 position was the most potent compound (MIC 0.2 μM)
obtained so far in these studies but was poorly soluble (<5 μM)
in aqueous media. The addition of polar groups like CN and dimethylcarboxamide
(42 and 43) at the para-position of the
R5-anilino groups decreased activity (MIC 9 and >50 μM, respectively).
Similarly, compound 44 with a 4-pyridylamino at the R5
position was inactive against Mtb up to the highest
concentration tested (MIC > 50 μM). Interestingly, compound 45 with a 2-pyridylamino group at the same R5 position was
quite potent with a MIC of ≤1 μM. The compound had moderate
aqueous solubility (25 μM) with a modest SI of 25 for CHO cell-line
toxicity, thus making it a valuable compound for MoA studies (see
below). A few compounds with polar substituents para to the amino
group on the 2-pyridyl ring were synthesized and screened with a view
to improving physicochemical properties. For example, compound 46 with a 4-morpholino-2-pyridylamino group at the R5 position
retained good activity (MIC = 2 μM) with improved solubility
(180 μM) but was significantly more cytotoxic (SI 0.6).Compound 47, with a 3-pyridyl at the R1 position and
an ethylamino group at the R5 position, showed modest activity with
an MIC of 6.25 μM and CHO IC50 of >50 μM.A limited SAR exploration at the R4 position on the pyrazole was
conducted to evaluate the scope for further improvement in potency
and selectivity. Compound 48 with 4-bromopyrazole showed
only moderate activity (MIC 25 μM, CHO IC50 >
50
μM) and was used as an intermediate for further synthesis. Replacing
the bromine with a 3-pyridyl ring (49) abolished Mtb activity (MIC >50 μM), whereas the morpholine
ring at this position (50) was well tolerated with an
MIC = 6.25 μM and a cleaner cytotoxicity profile (CHO IC50 > 50 μM). In comparison, the R3 position on the
pyrazole
showed a very limited scope for further modifications. In general,
a cyclopropyl group as in compound 51 was well tolerated
for Mtb potency but larger groups in general gave
weakly active compounds. Polar groups like dimethylaminomethyl, carboxylic
acid, and amide as in compounds 52, 53,
and 54, respectively, led to considerable loss of activity
against Mtb (MICs > 50 μM).In summary,
various modification on the pyrimidinone and pyrazole
portions of the scaffold showed potential for improvement in potency
against Mtb in vitro and MICs as low as 200 nM could
be achieved. However, in general there was a narrow scope to improve
the SI against mammalian cell-line toxicity. The potential impact
of both these activities in vivo remains to be determined.
Physicochemical,
DMPK, and Safety Profiles
Presented
in Table are physicochemical
and in vitro DMPK properties of representative compounds,
including solubility, microsomal MS, and human plasma protein binding
(PPB). Compounds showed moderate to high aqueous solubility with excellent in vitro microsomal stability, with the exception of compound 8 that was only moderately stable in microsomes. A small number
of compounds that were tested for the inhibition of liver cytochrome
P450 enzymes did not show significant inhibition up to 20 μM
(data not shown), indicating minimal possibility of metabolism-based
drug–drug interactions of these compounds, which is a desirable
attribute of a TB drug.[29,30] The compounds tested
in the series were highly bound to the human plasma most likely due
to the albumin binding of acidic pyrimidinone.[31] The safety profiles of compounds 1 and 12 were evaluated across a panel of 21 liability targets (39
functional assays), which included cell-based GPCRs and ion channels
in both agonist and antagonist readout, and biochemical functional
assays for nuclear hormone receptors and phosphodiesterases.[32] Both compounds showed no significant inhibition
or activation of the enzyme/receptors at 10 μM test concentration.
Both compounds showed hERG IC50 > 30 μM. In summary,
the in vitro safety profile of the compounds indicated
no obvious safety liability even though the reason for mammalian cytotoxicity
observed was not clear.
Table 6
In Vitro ADME Properties
of Selected Compoundsd
compound
8
12
39
40
45
47
50
clog Pa
1.82
1.36
1.30
2.52
1.46
0.66
1.54
clog Da
1.82
1.36
1.09
2.52
1.46
1.09
1.40
solubility
(μM)b
120
200
50
15
25
90
160
MSc H/R/Mo % remaining after 30 min
65/54/45
>99/92/>99
>99/>99/93
98/98/96
>99/96/>99
80/95/94
ND
PPBd human fu
ND
0.006
0.014
0.013
ND
0.009
0.03
Calculated log P/log D (StarDrop).
Kinetic solubility measured
at pH
7.4.
Microsomal stability
H: human, R:
rat Mo: mouse.
PPB; fu—fraction
unbound.
Calculated log P/log D (StarDrop).Kinetic solubility measured
at pH
7.4.Microsomal stability
H: human, R:
rat Mo: mouse.PPB; fu—fraction
unbound.The pharmacokinetic
parameters of representative compounds, 12, 47, and 40 were measured from
mouse blood at intravenous doses of 2 mg/kg and oral doses of 20 mg/kg
in the mouse (Table ). The compounds were well tolerated following either route of administration,
with no obvious effects noted in the animals over the course of the
exposure. Compounds 12 and 40 showed a low
volume of distribution and low rate of clearance with moderate oral
bioavailability of approximately 40%. Compound 47 showed
rapid blood clearance and high volume of distribution with an oral
bioavailability of 33%. Further analysis of mouse blood samples from
the PK studies of 47 showed the glucuronide as the major
metabolite. However, further optimization of physicochemical properties
to improve pharmacokinetic properties, along with improved SI, is
warranted in order to identify a compound suitable for in
vivo efficacy studies in TB animal models.
Table 7
Pharmacokinetic Parameters in Male
C57/BL6 Mouse Blooda
route of
administration
i.v.
oral
i.v.
oral
i.v.
oral
12
47
40
dose (mg/kg)
2
20
2
20
2
20
apparent t1/2 (h)
3.1
4
5.6
4.4
4.0
6.1
CLtotal (mL/min/kg)
2.7
80.9
0.4
CLint (mL/min/kg)
476
>4000
34
Vd (L/kg)
0.7
37.4
0.1
Cmax (μM)
29.1
65.6
2.4
2.9
33.1
104.5
Tmax (h)
0.5
0.5
1.0
AUC0–∞ (min·μM)
2928
12004
91
313
15373
65417
oral bioavailability F (%)
41
33
44
i.v.: intravenous; t1/2: elimination
half-life; CLtotal: total
blood clearance; CLint: intrinsic clearance; Vd: volume of distribution during elimination phase; Cmax, maximum (peak) plasma concentration following
oral administration; and AUC: area under the curve.
i.v.: intravenous; t1/2: elimination
half-life; CLtotal: total
blood clearance; CLint: intrinsic clearance; Vd: volume of distribution during elimination phase; Cmax, maximum (peak) plasma concentration following
oral administration; and AUC: area under the curve.
Bactericidality and Activity
against Clinical Isolates
The compounds were found to be
bactericidal against replicating Mtb showing 2 log
CFU reduction at 1–2× MIC
over the time period of 7 days (Fig. S1). Importantly, we also evaluated the activity of 1, 12, 15, and 20 against a panel of
clinical isolates (Table S1). All the tested
compounds retained MICs against clinical isolates within the 4-fold
range of MICs against the drug-sensitive Mtb H37Rv
strain.
Target Deconvolution Studies
Biology Triaging
In order to explore the MoA, potent
compounds were initially screened against various tool strains to
rule out the involvement of known mechanisms and/or targets. The tested
compounds retained activity against a QcrB mutant (A396T) and did
not show hypersensitivity against a cytochrome-bd oxidase knockout
mutant strain (cydKO),[33] thereby eliminating them as potential targets. The compounds did
not show a positive signal in two standard bioluminescence reporter
assays: PiniB-LUX[34]—detects modulation
in the iniB expression, if a compound targets Mtb cell–wall biosynthesis, and PrecA-LUX[34]—detects modulation in the recA expression, an indicator of genotoxic compounds. A strain carrying
a mutation in DprE1 (C387S), which confers resistance to other DprE1
inhibitors, was not resistant, suggesting DprE1 is not the target.
However, strains carrying mutations in MmpL3 were cross-resistant
to compounds (Table ).[35] The compounds showed an increase
of 8–100-fold in MIC values against the strains with either
MmpL3F255L or MmpL3V681I or MmpL3G596R, whereas, there was no change in activity against the MmpL3F644L mutant. Most of these mutations lie within the region
required for proton translocation.[36] Variability
in the MICs against these mutant strains is suggestive of the fact
that the compounds may bind differently to the protein depending on
the mutation. To investigate whether or not compounds 1, 2, 12, 15, 47, 40, and 38 retain target selectivity
for MmpL3 in Mtb cells, we asked whether or not conditional
depletion of MmpL3 in a mmpL3 hypomorph (Grover et
al., manuscript under review) would
sensitize Mtb to the growth inhibitory effects of
the compounds. However, transcriptional silencing of mmpL3 resulted in no significant change in the MICs of the compounds,
confirming that MmpL3 is not the direct target of this series (Table S2). We hypothesize that MmpL3 acts as
a transporter of these compounds across the cell membrane as the compounds
can form heme-like iron-complexes, and MmpL3 is known to act as a
heme transporter.[37,38] Hence, MmpL3 is likely to be
responsible for building resistance toward compounds through the impairment
of transport of compounds across the cell membrane rather than being
a direct target. It is to be noted that the compounds were PiniB-LUX
negative—indicating a non-cell wall MoA.
Table 8
Cross-Screening against mmpL3 Mutantsa
strain
1
2
12
15
47
40
38
H37Rv WT MIC (μM)
1.7
4.8
15
27
5.8
1.2
1.2
MmpL3 F255L
MIC (μM)
18
55
170
>200
41
>200
39
MmpL3 F644L MIC (μM)
1.9
5.4
17
24
5.5
1
1.9
MmpL3
V681 MIC (μM)
16
45
>200
MmpL3 G596R MIC (μM)
40
110
>200
WT: wild-type.
WT: wild-type.Based on the structural similarity
of the compounds with the published
thymidylate kinase inhibitors,[39,40] we asked whether this
compound series can inhibit Mtb thymidylate kinase,
which is an essential target encoded by Rv3247c. To investigate this,
we tested the activity of the compounds 1, 2, and 12 against the Rv3247c hypomorph. However, we
did not observe any MIC modulation of the compounds upon silencing
of Rv3247c, suggesting that the tested compounds are not the thymidylate
kinase inhibitors.
Treatment with 45 and 12 Affects Genes
Involved in Fe Homeostasis
In continuation of our efforts
to explore MoA, the effects of 45 (at 1 μM and
10 μM) and 12 (at 20 μM) treatment on the
gene expression of Mtb was investigated. Mtb cultures were treated with the compound for 6 h, harvested,
and the RNA extracted for transcriptional profiling by microarray
analysis. The data obtained from the transcriptional profiling of Mtb exposed to 45 and 12 were
similar (Table S3). We performed in-depth
analysis of the data obtained from samples treated with 45, which was tested at two concentrations. The 50 most upregulated
(>4-fold) genes were selected in order to understand their potential
contribution in the cellular response based on the MoA of 45 (Table S4). This indicated a transcriptional
signature related to iron-sequestration. The upregulated genes included rv2377c-78c-79c-80c-81c-82c-83c-84-85-2386c (mbtA-H)—all of which are associated with mycobactin biosynthesis
or regulation,[41] which are known to be
upregulated in response to iron deprivation.Another upregulated
gene-set rv1342-43-44-45-46-47-48-49 is also associated
with the mycobactin biosynthesis or regulation or with iron transport
where rv1348 and rv1349 were annotated
as iron-regulated transporters, both being essential for growth in vitro.[42−44] The esx-3 gene cluster is composed
of 11 genes stretching from rv0282 to rv0292. All of these were upregulated 2–5-fold in response to the
stress caused by the compound. rv0287 and rv0288 are predicted to be essential for growth in vitro. Interestingly, ESX-3 is known to be required for
the mycobactin-mediated siderophore iron uptake pathway,[45−48] and it is essential in Mtb but not in Mycobacterium smegmatis, a species which, in addition
to mycobactins, produces exochelin that functions independently of
ESX-3. However, ESX-3 is still required for mycobactin-mediated iron
uptake in the latter species.[45,46,48] The nonessential nature of ESX-3 in M. smegmatis has previously proven to be of a great advantage when resolving
mechanisms related to ESX-3 and mycobactin iron metabolism.[48] Some of the top upregulated genes are involved
in lipid metabolism, for example, rv3249-51-52 potentially
a transcriptional response to correct damage to fatty acids. Fe has
been reported to affect lipid metabolism, specifically because of
Fe-catalyzed lipid oxidation. In line with this, we observed that
genes, including rv3741-42, (oxidoreductase) were
upregulated. The observed upregulation of the rv3269-70 operon encoding a stress response protein and a metal cation transporter,
respectively, further supports the notion that the cellular response
to 45 is one of the disruption of iron homeostasis. Rv0285—PE5 which was upregulated in our study, is
downregulated in the presence of iron.[49] Importantly, most of the upregulated genes of our data set were
found to be downregulated when Mtb was exposed to
an excess of iron.[49] Our data set also
complements the recently published work by Kurthkoti et al.,[50] where authors performed transcriptomics in iron-starved
cultures and identified similar upregulated clusters of genes. This
strongly suggests that the disruption of Fe homeostasis is an important
component of the MoA of 45.In summary, our data
suggest that upon exposure to 2-pyrazolylpyrimidinones, Mtb goes into an iron-starvation state. As expected, it
upregulates genes involved in the mycobactin (siderophore) synthesis
pathway and its regulation. Siderophores are small, high-affinity
iron-chelating compounds secreted by microorganisms such as bacteria
and fungi. In the process of cellular uptake, the Fe3+-siderophore
complex is subsequently reduced to Fe2+ to release the
iron.
Iron Plays a Significant Role in the MoA
To confirm
the role of iron in the MoA of this series, an Fe rescue experiment
was performed by supplementing standard Middlebrook 7H9/Glu/CAS/Tx
media with 200 μM ferric ammonium citrate. The supplementation
of Fe3+ resulted in a 4-fold increase in the MIC (Table S5). Under physiological conditions, iron
can exist in either the reduced ferrous (Fe2+) form or
the oxidized ferric (Fe3+) form. The redox potential of
Fe2+/Fe3+ makes iron extremely versatile when
it is incorporated into proteins as a catalytic center or as an electron
carrier. Thus, iron is important for numerous biological processes,
which include the tricarboxylic acid cycle, gene regulation, DNA biosynthesis,
and so forth. Although iron is abundant in nature, it does not normally
occur in its biologically relevant but aerobically unstable ferrous
form. To evaluate this, we supplemented the Mtb culture
with 200 μM ferrous sulfate, resulting in an 8-fold increase
in the MIC for 45 (Table S5). Next, we confirmed the ability of Fe2+ to rescue the Mtb from 45 toxicity in a checkerboard (2D)
assay using GAST (glycerol-alanine-salts-Tween 80) media which is
devoid of Fe unlike Middlebrook 7H9/Glu/CAS/Tx (Figure A). The inhibition of Mtb growth by 45 in GAST medium supplemented with 12.5
μM Fe+2 (MIC 0.12 μM) decreased in a dose-dependent
manner with increasing concentration of Fe2+ and resulted
in a ≥32-fold increase in MIC at 100/200 μM Fe2+. To determine that 45 forms a complex with Fe2+, we performed UV–vis scanning of 45 with increasing
amounts of Fe2+ (Figure B). The band intensity at 270, which was observed for 45 alone, decreased after the addition of Fe2+,
whereas the absorbance around 285 is shifted to 300 with the increase
in intensity, indicating the formation of the 45-Fe2+ complex.
Figure 4
Fe2+ plays a critical role in the MoA of 45. (A) Fe2+ rescue of Mtb from
growth
inhibition mediated by 45. (B) Spectroscopic titration
of 45 with Fe2+. The data are representative
of two biological replicates performed in duplicate.
Fe2+ plays a critical role in the MoA of 45. (A) Fe2+ rescue of Mtb from
growth
inhibition mediated by 45. (B) Spectroscopic titration
of 45 with Fe2+. The data are representative
of two biological replicates performed in duplicate.In line with the observation of better rescue with ferrous
than
ferric iron and a preference of heme for the former, there is a strong
possibility that the compound binds iron to form a heme-like complex
that enters Mtb via MmpL3. This also supports the
reason for resistance with some of the MmpL3 mutants as described
previously—heme prefers ferrous over ferric. Involvement of
a heme-like structure could also explain the associated cytotoxicity
of the series, as described earlier. This is because of the toxic
nature of heme to eukaryotic cells, which require specific heme-binding
proteins to maintain a nontoxic homeostasis.
Conclusions
Whole-cell phenotypic screening of MMV compound library led to
the identification of 2-pyrazolylpyrimidinones with potent antitubercular
activity and a novel mode of action. Detailed SAR studies identified
several compounds with potent activity against Mtb with moderate to high aqueous solubility and excellent in
vitro microsomal stability. The compounds were bactericidal
against replicating Mtb and retained potency against
clinical isolates. Transcriptional profiling suggested that upon exposure
to 2-pyrazolylpyrimidinones, Mtb goes into an iron-starvation
state that may account for lethality. Iron supplementation using a
high concentration of ferrous salts showed shifts in MICs of the compounds,
further confirming that 2-pyrazolylpyrimidinones perturbs the Fe-homeostasis
in Mtb. Further optimization of pharmacokinetic properties,
along with improved SI between MIC and mammalian cytotoxicity, is
needed to identify a compound suitable for in vivo efficacy studies in mouse TB models and eventual development as
a viable drug useful for the treatment of TB in humans.
Experimental Section
MIC Testing and Triage Assays
Unless
otherwise indicated,
an Alamar Blue fluorescence-based broth microdilution assay was used
to assess MIC of compounds against Mtb strains, as
described previously.[51,52] Rifampicin was included as a
control. Biology triage assays were carried out as described by Naran
et al.[34]
MICs against Mutant Strains
MICs were determined after
5 days of growth in Middlebrook 7H9 medium plus OADC supplement and
0.05% w/v Tween 80 as described previously.[53] Growth was monitored by OD. Data were fit using the Levenberg–Marquardt
least-squares plot. MIC was defined as the concentration required
to inhibit growth by 90%.
RNA Extraction and Transcriptional Profiling
Total
RNA was extracted from Mtb H37Rv that had been treated
for 6 h with 1× and 10× MIC of the compound or vehicle control
as previously described.[54] RNA quality
was confirmed by UV spectral analysis and Agilent 2100 Bioanalyzer
returning a RNA integrity number of 8 or higher. Fluorescent-tagged
cDNA was prepared via a direct random-primed labeling method as follows.
To 4.0 μg of RNA, 4.5 μg of a random hexamer (Invitrogen#
48190-011) was added, a final volume of 14.5 μL, heat denatured
at 70 °C for 5 min then immediately cooled to 0 °C on ice.
cDNA synthesis and fluorophore (Cy3 or Cy5) incorporation were carried
out using the following reverse transcription reaction components
5 μL of 5× First-Strand buffer, 1.25 μL of 0.1 M
DTT, 2.5 μL of dNTP mix (made by 5 mM each of dATP, dGTP), dTTP,
0.5 mM dCTP, plus 1 μL of 200 U/μL SuperScriptIII (Invitrogen#
18080-044), 1 μL of 40 U/μL RNAseOut, and 1 μL of
Cy3 or Cy5-dCTP (GE# PA55321) were added for incubation at 25 °C
for 5 min and at 48 °C for 90 min. Template RNA was chemically
hydrolyzed by 5 μL of 1 M NaOH and heated at 70 °C for
15 min. The hydrolysis reaction was neutralized with 5 μL of
1 M HCl. The labeled cDNA was purified on an Amicon Ultra-0.5 column
(Millipor# C82301) following the manufacturer’s recommendations
for PCR purification. cDNA yields and dye incorporation were measured
with a Nanodrop ND-1000. A mixture of equal amounts (0.7 μg)
of Cy3- and Cy5-labeled cDNA was loaded into hybridization chambers
for incubation with an Agilent SurePrint G3 4x44K custom oligonuclotide
microarray (design number 021966, 021362).Microarrays were
hybridized robotically using a TECAN HS Pro 4800 hybridization station,
Agilent 2× gene expression hybridization HI-RPM buffer, and 10×
blocking reagent at 65 °C for 17 h and washed with Agilent Gene
Expression Wash Buffer 1 at room temperature and Gene Expression Wash
Buffer 2 at 37 °C. Then, slides were dried under a nitrogen gas
for 3 min at 30 °C. The slides were imaged using an Agilent high-resolution
DNA microarray scanner (model G2505C) at 5 μm resolution and
100/10% PMT dual scanning for XDR extended dynamic range. Agilent
Feature Extraction software was used for image analysis.
DMPK
All protocols for in vitro DMPK
studies and mouse PK studies are available in the supplementary document.
Animal studies were conducted following guidelines and policies as
stipulated in the UCT Research Ethics Code for Use of Animals in Research
and Teaching, after review and approval of the experimental protocol
by the UCT Senate Animal Ethics Committee (protocol FHS-AEC 013/032).
Chemistry
All commercial reagents were purchased from
Sigma-Aldrich, Combi-Blocks, Enamine, or Fluorochem and were used
without further purification. Solvents were used as received unless
otherwise stated. Analytical thin-layer chromatography was performed
on SiO2 plates on aluminum backing. Visualization was accomplished
by UV irradiation at 254 and 220 nm. Flash column chromatography was
performed using a Teledyne ISCO flash purification system with SiO2 60 (particle size 0.040–0.055 mm, 230–400 mesh).
Purity of all final derivatives for biological testing was confirmed
to be >95% as determined using an Agilent 1260 Infinity binary
pump,
Agilent 1260 Infinity diode array detector (DAD), Agilent 1290 Infinity
column compartment, Agilent 1260 Infinity standard autosampler, and
Agilent 6120 quadrupole (single) mass spectrometer, equipped with
APCI and ESI multimode ionization sources. Using a Kinetex Core C18
2.6 μm column (50 mm × 3 mm); mobile phase B of 0.4% acetic
acid, 10 mM ammonium acetate in a 9:1 ratio of HPLC grade methanol
and type 1 water, mobile phase A of 0.4% acetic acid in 10 mM ammonium
acetate in HPLC grade (type 1) water, with a flow rate of 0.9 mL/min,
DAD; or an Agilent UPLC–MS was used: Agilent Technologies 6150
quadrupole, ES ionization, coupled with an Agilent Technologies 1290
Infinity II series UPLC system Agilent 1290 series HPLC at two wavelengths
254 and 290 nm using the following conditions: Kinetex 1.7 μm
Evo C18 100A, LC column 50 mm × 2.1 mm, solvent A of 0.1% (formic
acid) water, and solvent B of 0.1% (formic acid) acetonitrile. The
structures of the intermediates and end products were confirmed by 1H NMR and mass spectrometry. Proton magnetic resonance spectra
were determined in an appropriate deuterated solvent on a Varian Mercury
spectrometer at 300 MHz or a Varian Unity spectrometer at 400 MHz.
A mixture of 2-hydrazinyl-6-phenylpyrimidin-4(3H)-one (56a 0.2 g, 0.989 mmol) and pentane-2,4-dione
(0.121 mL, 1.187 mmol) was heated in a mixture of ethanol (0.5 mL)
and acetic acid (1.5 ml) at 100 °C for 16 h. After cooling to
room temperature, the reaction mixture was poured into ice cooled
water and stirred for 30 min. Solids formed were filtered, washed
with water, and dried to yield 1 as a white solid (200
mg, 0.744 mmol, 75% yield). HPLC purity: >99%. LC–MS APCI:
calcd for C15H14N4O, 266.304; observed m/z [M + H]+, 267.1. 1H NMR (300 MHz, CDCl3): δ 8.01–7.97 (m, 2H),
7.53–7.50 (m, 3H), 6.73 (s, 1H), 6.12 (s, 1H), 2.55 (s, 3H),
2.32 (s, 3H).
DIAD (0.110 mL, 0.563 mmol) was added dropwise
to a solution of 2-(3,5-dimethyl-1H-pyrazol-1-yl)-6-phenylpyrimidin-4(3H)-one (1) (100 mg, 0.376 mmol), triphenylphosphine
(148 mg, 0.563 mmol) in methanol (12.03 mg, 0.376 mmol), and tetrahydrofuran
(100 mL), and the reaction mixture was stirred at room temperature
for 4 h. The mixture was concentrated under reduced pressure, the
residue partitioned between dichloromethane and water, and the layers
separated. The aqueous phase was extracted with dichloromethane, the
combined organic solutions washed consecutively with water, 2 N aqueous
sodium hydroxide, water, and finally brine. The solution was then
dried over sodium sulfate and evaporated under reduced pressure. The
crude product was purified on an ISCO system using a 4 g silicycle
column and eluting with a gradient 0 to 70% ethyl acetate in hexane
over 20 min to yield 3 as a white solid (27 mg, 0.09
mmol, 24% yield). HPLC purity: 95%. LC–MS APCI: calcd for C16H16N4O, 280.33; observed m/z [M + H]+, 281.1. 1H NMR
(300 MHz, CDCl3): δ 7.99–7.96 (m, 2H), 7.49–7.47
(m, 3H), 6.92 (s, 1H), 6.31 (br s, 1H), 6.08 (s, 1H), 3.56 (s, 3H),
2.50 (s, 3H), 2.33 (s, 3H).
To a stirred solution of
2-(3,5-dimethyl-1H-pyrazol-1-yl)-6-phenylpyrimidin-4(3H)-one (1) (50 mg, 0.188 mmol) in DMF (2 mL)
was added potassium carbonate (52 mg, 0.563 mmol). The reaction mixture
was stirred for 5 min and iodomethane (35 μL, 0.563 mmol) was
added. The reaction mixture was stirred at 100 °C overnight.
The reaction mixture was extracted with ethyl acetate (3 × 10
mL). The combined organic layer was washed with LiCl solution (1 ×
10 mL) and dried over sodium sulfate, and the solvent was evaporated.
The obtained residue was purified by flash chromatography by using
15% ethyl acetate in hexane obtained 4 as a white solid
(39 mg, 0.141 mmol, 75% yield). HPLC Purity: 96%. LC–MS APCI:
calcd for C16H16N4O, 280.33; observed m/z [M + H]+, 281.1. 1H NMR (300 MHz, CDCl3): δ 8.01–7.97 (m, 2H),
7.53–7.50 (m, 3H), 6.73 (s, 1H), 6.18 (s, 1H), 3.52 (s, 3H),
2.55 (s, 3H), 2.32 (s, 3H).
To a cooled solution of
crude 61 (0.40 g, 1.43 mmol) in methanol (7 mL) was added
boron tribromide (1 M solution in dichloromethane) (4.2 mL, 4.29 mmol)
and stirred for 16 h at room temperature. Water was added to the reaction
mixture and extracted with dichloromethane. The combined organic phase
was dried over sodium sulfate, concentrated under vacuum, and purified
by preparative HPLC to give 5 as a white solid (0.08
g, 21%). HPLC purity: 98.6%. LC–MS APCI: calcd for C16H15N3O, 265.122; observed m/z [M + H]+, 266.2. 1H NMR
(400 MHz, CDCl3): δ 9.38 (br s, 1H), 7.64–7.62
(m, 2H), 7.51–7.47 (m, 3H), 6.76 (s, 1H), 6.70 (s, 1H), 6.07
(s, 1H), 2.58 (s, 3H), 2.3 (s, 3H).
To the solution of 2-chloro-4-(3,5-dimethyl-1H-pyrazol-1-yl)-6-phenylpyrimidine (intermediate 65, 0.16 g, 0.56 mmol) in THF (2 mL) was added 2 M aqueous NaOH solution
(2 mL) at room temperature, and the mixture was heated at 80 °C
for 4 h. The reaction mixture was then cooled in ice-bath and acidified
with glacial acetic acid. The precipitated solid was filtered under
vacuum, washed with chilled water, and dried to get 6-(3,5-dimethyl-1H-pyrazol-1-yl)-4-phenylpyrimidin-2(1H)-one
(7, 0.12 g, 80% yield) as a white crystalline powder.
HPLC purity: 99.2%. LC–MS APCI: calcd for C15H14N4O, 266.117; observed m/z [M + H]+, 267.2. 1H NMR (400 MHz,
DMSO-d6): δ 8.11 (m, 2H), 7.53 (m,
3H), 6.92 (s, 1H), 6.26 (s, 1H), 2.71 (s, 3H), 2.23 (s, 3H).
A mixture of 2-hydrazineyl-6-phenylpyrimidin-4(1H)-one (56a, 150 mg, 0.742 mmol) and ethyl
acetoacetate (0.114 mL, 0.890 mmol) was heated in a mixture of ethanol:
acetic acid, 1:3, under reflux for 5 h. The solid product obtained
after cooling and pouring onto ice-cold water was filtered off, washed
with water, and crystallized from ethanol to give 13 as
a white solid (39 mg, 0.148 mmol, 20% yield). HPLC purity 93%. LC–MS
APCI: calcd for C14H12N4O2, 268.27; observed m/z [M + H]+, 269.1. 1H NMR (400 MHz, DMSO-d6): δ 8.22–8.20 (m, 2H), 7.54–7.51
(m, 2H), 6.74 (s, 1H), 5.31 (s, 1H), 2.29 (s, 3H).
A mixture
of 2-(5-amino-3-methyl-1H-pyrazol-1-yl)-6-phenylpyrimidin-4(1H)-one (14, 100 mg, 0.374 mmol) and pyridine
(0.04 mL, 0.442 mmol) in dichloromethane (2 mL) was treated with a
solution of acetyl chloride (0.04 mL, 0.0448 mmol) in dichloromethane
(1 mL). The reaction mixture was stirred at room temperature for 24
h before it was diluted with dichloromethane (5 mL). The mixture was
washed with 2 N HCl (10 mL), 5% aqueous solution of NaHCO3, and brine. The organic phase was dried over sodium sulfate, filtered,
and concentrated in vacuo to give 15 as a white solid (45 mg, 0.145 mmol, 39% yield). HPLC purity: 98%.
LC–MS APCI: calcd for C16H15N5O2, 309.33; observed m/z [M + H]+, 310.1. 1H NMR (300 MHz, DMSO-d6): δ 11.55 (s, 1H), 8.13–8.03
(m, 2H), 7.63–7.52 (m, 3H), 6.95 (s, 1H), 6.64 (s, 1H), 2.22
(d, J = 15.1 Hz, 6H).
In a 10 mL microwave vial,
2-chloro-6-phenylpyrimidin-4(3H)-one (66, 0.1 g, 0.484 mmol), 1H-pyrazole (0.066 g, 0.968
mmol), and cesium carbonate (0.473 g, 1.452 mmol) were mixed in 1,4-dioxane
(1 mL). The vial was capped and microwaved at 100 °C for 1 h.
LCMS indicated two products of the same mass (isomers from 70:30 ratio
of the starting material). The reaction mixture was concentrated and
purified by preparative HPLC to afford 16 as a white
solid (29 mg, 0.121 mmol, 25% yield). HPLC purity: 96%. LC–MS
APCI: calcd for C13H10N4O, 238.25;
observed m/z [M + H]+, 239.1. 1H NMR (300 MHz, DMSO-d6): δ 8.78 (d, 1H, J = 3 Hz), 8.24–8.20
(m, 2H), 7.89 (d, 1H, J = 1.2 Hz), 7.56–7.53
(m, 3H), 7.07 (s, 1H), 6.65 (dd, 1H, J = 3 and 1.8
Hz).
1-methyl-1H-imidazole-2-carboximidamide (0.075 g, 0.61 mmol) and ethyl benzoylacetate
(0.12 g, 0.61 mmol) were refluxed in EtOH for 2 h. The reaction was
cooled, solvent was evaporated under vacuo, and the residue was purified
on preparative HPLC to give 2-(1-methyl-1H-imidazol-2-yl)-6-phenylpyrimidin-4(1H)-one (18, 15 mg, Yield 10%) as a brown solid.
HPLC purity: 94.2%. LC–MS APCI: calcd for C14H12N4O, 252.101; observed m/z [M + H]+, 253.4, 1H NMR (400 MHz,
DMSO-d6): δ 7.99 (t, J = 3.6 Hz, 2H), 7.52–7.49 (m, 3H), 7.21 (s, 1H), 7.14 (s,
1H), 6.83 (s, 1H), 4.29 (s, 3H).
In 1,4-dioxane (2 mL)
solution of N-(4-(2-chloro-6-oxo-1,6-dihydropyrimidin-4-yl)phenyl)methanesulfonamide
(69a 0.09 g, 0.300 mmol), under a nitrogen atmosphere,
cesium carbonate (0.147 g, 0.450 mmol), 3,5-Dimethylpyrazole (0.035
g, 0.360 mmol), XantPhos (0.052 g, 0.090 mmol), and Tris(dibenzylideneacetone)dipalladium(0)
(0.041 g, 0.045 mmol) were added, and the mixture was heated at 130
°C for 18 h in a sealed tube. The reaction mixture was cooled
to room temperature, concentrated in vacuo, filtered, and washed with
DCM/MeOH, (80:20) and the filtrate concentrated to yield the crude
product. The crude product was dissolved in 1 mL of water and acidified
with 1 M HCl, then concentrated and purified by preparative HPLC to
afford 22 as an off-white solid (3 mg, 8.01 μmol,
3% yield). HPLC purity: 96%. LC–MS APCI: calcd for C16H17N5O3S, 359.40; observed m/z [M + H]+, 360.1. 1H NMR (300 MHz, DMSO-d6): δ 8.00
(d, J = 8.4 Hz, 2H), 7.27 (d, J =
8.3 Hz, 2H), 6.57 (s, 1H), 6.14 (s, 1H), 3.03 (s, 3H), 2.65 (s, 3H),
2.21 (s, 3H).
2-(3,5-dimethyl-1H-pyrazol-1-yl)-N-(4-fluorophenyl)-6-methoxypyrimidine-4-carboxamide 72 (40 mg, 0.117 mmol) was dissolved in dichloromethane (2
mL) under N2 and BBr3, 1 M in dichloromethane
(0.352 mL, 0.352 mmol) was added and stirred under N2 at
room temperature for 48 h. The reaction was quenched with dilute HCl
and diluted with dichloromethane. The dichloromethane layer was separated,
and the aqueous layer was again extracted with dichloromethane. Organic
layers were combined, washed with brine, and concentrated under vacuum.
The residue was purified by column chromatography using 0–20%
methanol in dichloromethane to give 26 as an off-white
solid (12 mg, 0.035 mmol, 30% yield). HPLC purity: 96.5% LC–MS
ESI: calcd for C16H14FN5O2, 327.113; observed m/z [M + H]+, 328.10. 1H NMR (300 MHz, DMSO-d6): δ 12.80 (br s, 1H), 10.15 (br s, 1H), 7.81–7.86
(m, 2H), 7.24 (t, J = 9 Hz, 2H), 6.94 (s, 1H), 6.28
(s, 1H), 2.72 (s, 3H), (s, 3H).
A mixture of 4-(4-fluorophenyl)-2-hydrazinyl-6-oxo-1,6-dihydropyrimidine-5-carbonitrile 74 (50 mg, 0.204 mmol) and pentane-2,4-dione (0.025 mL, 0.245
mmol) was heated in a mixture of ethanol (0.5 mL) and acetic acid
(1.5 mL) at 85 °C for 3 h. The reaction was cooled, and a yellow
crystalline precipitate formed was filtered under vacuum, triturated
with a small amount of ethanol, and dried to afford 27 as a light-yellow solid (37 mg, 0.120 mmol, 59% yield). HPLC purity:
95.8%. LC–MS ESI: calcd for C16H12FN5O, 309.103; observed m/z [M – H]+, 308.10. 1H NMR (300 MHz,
DMSO-d6): δ 8.05–8.10 (m,
2H), 7.46 (t, J = 9 Hz, 2H), 6.35 (s, 1H), 2.65 (s,
3H), 2.27 (s, 3H).
2-(3,5-Dimethyl-1H-pyrazol-1-yl)-4-(4-fluorophenyl)-6-oxo-1,6-dihydropyrimidine-5-carbonitrile 27 (50 mg, 0.162 mmol) was heated with H2SO4 (0.5 mL, 9.38 mmol) for 2 h at 80 °C. The reaction mixture
was then poured slowly on ice with vigorous stirring. A white precipitate
was formed which was filtered, washed with cold water and cold ethanol,
and dried to give 28 as a light-yellow solid (32 mg,
0.098 mmol, 60% yield). HPLC purity: >98% LC–MS ESI: calcd
for C16H14FN5O2, 327.113;
observed m/z [M – H]+, 326.10. 1H NMR (300 MHz, DMSO-d6): δ 7.87–7.92 (m, 2H), 7.83 (br s, 1H),
7.50 (br s, 1H), 7.32 (t, J = 9 Hz, 2H), 6.25 (s,
1H), 2.62 (s, 3H), 2.24 (s, 3H).
In a 7 mL reaction vial, 2-(3,5-dimethyl-1H-pyrazol-1-yl)-4-(4-fluorophenyl)-6-oxo-1,6-dihydropyrimidine-5-carboxamide 28 (20 mg, 0.061 mmol) and tert-butyl nitrite
(0.022 mL, 0.183 mmol) were stirred in acetic acid (0.5 mL) a 75 °C
for 3 h. A white precipitate was formed. It was centrifuged out, washed
with cold ethanol, and dried in an oven to give 29 as
a white solid (12 mg, 0.037 mmol, 60% yield). HPLC purity: >99%
LC–MS
ESI: calcd for C16H13FN4O3, 328.097; observed m/z [M –
H]+, 327.10. 1H NMR (300 MHz, DMSO-d6): δ 7.77–7.81 (m, 2H), 7.35 (t, J = 9 Hz, 2H), 6.27 (s, 1H), 2.62 (s, 3H), 2.24 (s, 3H).
To a solution of 56d (0.70 g, 1.28 mmol) in DMF was added 3-aminocrotonitrile
(0.70 g, 8.43 mmol) and heated to 100 °C for 16 h. Water was
added, extracted with ethyl acetate, and the combined organic layer
was washed with saturated sodium bicarbonate solution, water, and
brine solution, dried over sodium sulfate, and concentrated under
vacuum. The crude product was purified by preparative HPLC to yield 33 as a white solid (0.076 g, 23%). HPLC purity: 95.5%. LC–MS
APCI: calcd for C9H8F3N5O, 259.068; observed m/z [M + H]+, 259.8. 1H NMR (400 MHz, DMSO-d6): δ 7.15 (s, 2H), 6.30 (s, 1H), 5.23 (s, 1H),
2.08 (s, 3H). 13C NMR (100 MHz, DMSO-d6): δ 14.34, 88.68, 105.72, 120.24, 122.97, 151.14,
151.32, 151.55, 151.88, 156.03, 168.05.
To a solution of 33 (0.20 g, 0.77 mmol), acetic acid (0.14 g, 2.30 mmol) in
DMF (5 mL) and acetaldehyde (0.10 g, 2.31 mmol) were added and the
reaction was allowed to stir at room temperature for 16 h. Sodium
cyanoborohydride (0.24 g, 3.86 mmol) in methanol (2 mL) was added
and stirred at room temperature overnight. The reaction mixture was
concentrated, water was added, and extracted with ethyl acetate. The
organic layer was concentrated and purified by preparative HPLC to
give 34 as a white solid (0.07 g, 32%). HPLC purity:
95.2%; LC–MS APCI: calcd for C11H12F3N5O, 287.099; observed m/z [M + H]+, 288.0. 1H NMR (400 MHz,
CDCl3): δ 7.14 (s, 1H), 6.48 (s, 1H), 5.19 (s, 1H),
3.23 (q, J = 6.40 Hz, 2H), 2.19 (s, 3H), 1.32 (t, J = 7.20 Hz, 3H); 13C NMR (100 MHz, CD3OD): δ 12.56, 13.40, 39.09, 104.82, 119.62, 122.34, 152.30,
152.51, 152.85, 153.14, 155.01.
To solution of sulphonyl
intermediate 79 (0.50 g, 2.06 mmol) and cesium carbonate
(1.6 g, 5.16 mmol) in 1,4-dioxane was added 78 (0.52
g, 4.12 mmol) in sealed tube and heated to 100 °C for 16 h. Solids
were filtered through Celite and the filtrate concentrated under vacuum.
The crude product was purified by preparative HPLC to afford 35 as a white solid (0.07 g, 12%). HPLC purity: 95%; LC–MS
APCI: calcd for C11H11F3N4O2, 288.083; observed m/z [M + H]+, 288.8. 1H NMR (400 MHz, CDCl3): δ 10.43 (s, 1H), 6.53 (s, 1H), 5.80 (s, 1H), 4.28
(q, J = 7.20 Hz, 2H), 2.67 (s, 3H), 1.43 (t, J = 7.20 Hz, 3H).
Step 1: To a −5 °C cooled solution of 4-methyleneoxetan-2-one
(1.0 g, 11.90 mmol) in tetrahydrofuran (10 mL) was added 2-methoxyethylamine
(0.90 g, 11.30 mmol) and stirred for 30 min. The solvent was evaporated
under vacuum. The crude product was purified by column chromatography
using 3–5% methanol in dichloromethane to afford N-(2-methoxyethyl)-3-oxobutanamide (1.2 g, 7.50 mmol, 63%). LC–MS
APCI: calcd for C7H13NO3, 159.19;
observed m/z [M + H]+, 160.2. 1H NMR (300 MHz, DMSO-d6): δ 8.13 (s, 1H), 3.29–3.36 (m, 4H), 3.20–3.27
(m, 5H), 2.13 (s, 3H). Step 2: To a solution of N-(2-methoxyethyl)-3-oxobutanamide (0.50 g, 3.14 mmol) in
tetrahydrofuran (10 mL) was added Lawesson’s reagent (1.40
g, 3.45 mmol) and stirred for 30 min at room temperature under a nitrogen
atmosphere. Hydrazine 33 (0.61 g, 3.45 mmol) was added
to the reaction mixture and stirred at room temperature for 24 h.
The reaction was quenched with saturated sodium bicarbonate solution
and extracted with ethyl acetate. The combined organic phase was washed
with water and brine, dried over sodium sulfate, and concentrated
under vacuum. The crude product was purified by preparative HPLC to
yield 38 as a white solid (0.065 g, 0.22 mmol. 7% yield).
HPLC purity: 98.9%. LC–MS APCI: calcd for C12H14F3N5O2, 317.110; observed m/z [M + H]+, 318.0. 1H NMR (400 MHz, DMSO-d6): δ 7.71
(s, 1H), 6.45 (s, 1H), 5.37 (s, 1H), 3.52 (t, J =
5.20 Hz, 2H), 3.27–3.33 (m, 5H), 2.13 (s, 3H). 13C NMR (100 MHz, DMSO-d6): δ 14.44,
44.66, 58.52, 70.51, 87.07, 106.26, 120.03, 122.75, 151.28, 152.24,
154.78, 166.47.
In a sealed tube 33 (0.25 g, 0.96 mmol), 1-bromo-4-fluoro benzene (0.33 g,
1.92 mmol) and cesium carbonate (0.93 g, 2.88 mmol) were taken in
dioxane (10 mL). The mixture was purged with nitrogen gas for 20 min.
To this tris(dibenzylideneacetone)dipalladium(0) (0.079 g, 0.08 mmol)
and XantPhos (0.07 g, 0.13 mmol) was added and sealed. The reaction
mixture was stirred at 120 °C for 4 h. The reaction mixture filtered
through Celite and filtrate was concentrated under vacuum. The crude
product was purified by preparative HPLC to obtain 40 as a white solid (0.09 g, 0.51 mmol, 26% yield). HPLC purity: 95.4%;
LC–MS APCI: calcd for C15H11F4N5O, 353.090; observed m/z [M + H]+, 354.0. 1H NMR (400 MHz, CD3OD): δ 7.22–7.34 (m, 2H), 6.97–7.09 (m, 2H),
6.40 (s, 1H), 5.87 (s, 1H), 2.24 (s, 3H). 13C NMR (400
MHz, CD3OD): δ 14.00, 90.34, 105.40, 118.74, 121.42,
122.71, 124.14, 130.36, 138.72, 148.73, 152.72, 158.26, 160.06, 160.64,
176.68.
To a solution of 2-(5-amino-3-methyl-1H-pyrazol-1-yl)-6-(pyridin-3-yl)pyrimidin-4(3H)-one (0.10 g, 0.37 mmol), acetic acid (0.07 g, 1.11 mmol) in DMF
(5 mL) and acetaldehyde (0.05 g, 1.11 mmol) were added, and reaction
mixture stirred at room temperature for 16 h. Sodium cyanoborohydride
(0.11 g, 1.86 mmol) in methanol (2 mL) was added, and the reaction
mixture stirred at room temperature overnight. The reaction mixture
was concentrated, water was added, and extracted with ethyl acetate.
The organic layer was concentrated and purified by preparative HPLC
to give 47 as a white solid (0.03 g, 0.299 mmol, 27%).
HPLC purity 97.53%; LC–MS APCI: calcd for C15H16N6O, 296.139; observed m/z [M + H]+, 297.2. 1H NMR (400 MHz,
CD3OD): δ 9.42 (s, 1H), 8.77–8.82 (m, 2H),
7.82 (q, J = 5.20 Hz, 1H), 7.15 (s, 1H), 3.42 (q, J = 7.20 Hz, 2H), 2.40 (s, 3H), 1.39 (t, J = 7.20 Hz, 3H).
To a solution of 12 (1.0 g, 3.87 mmol) in acetic acid (20 mL) was added bromine
(0.24 mL, 4.65 mmol) at 20 °C and stirred at room temperature
for 3 days. Water was added to the reaction mixture. Solids formed
were filtered, washed with water, and dried. The crude product was
purified by preparative HPLC to yield 48 as a white solid
(0.3 g, 1.07 mmol, 23.0%). HPLC purity: 99.3%; LC–MS APCI:
calcd for C10H8BrF3N4O,
335.983; observed m/z [M –
H]+, 337.0; 1H NMR (400 MHz, DMSO-d6): δ 13.58 (s, 1H), 6.93 (s, 1H), 2.58 (s, 3H), 2.24
(s, 3H).
A solution of 48 (0.50 g, 1.48 mmol), pyridine-3-boronic acid (0.22 g, 1.78 mmol)
and potassium carbonate (0.41 g, 2.96 mmol) in tetrahydrofuran/water
(20/2 mL) was repeatedly purged with nitrogen. Pd(dppf)Cl2 (0.18 g, 0.22 mmol) was added and heated at 70 °C for 16 h.
The reaction mixture was cooled, water was added, and extracted with
ethyl acetate. Combined organic layers were washed with water and
brine solution, dried over sodium sulfate, and concentrated under
vacuum. The crude product was purified by preparative HPLC to yield 49 as a white solid (0.10 g, 0.36 mmol, 20% yield). HPLC purity:
99.8%; LC–MS APCI: calcd for C15H12F3N5O, 335.099; observed m/z [M – H]+, 336.1. 1H NMR (400
MHz, CDCl3): δ 400 MHz, CDCl3: δ
8.68 (d, J = 4.88 Hz, 1H), 8.58 (s, 1H), 7.66 (d, J = 7.60 Hz, 1H), 7.48 (t, J = 7.28 Hz,
1H), 6.64 (s, 1H), 2.68 (s, 3H), 2.29 (s, 3H).
Step 1: 3-Bromopentane-2,4-dione
()—To
a solution of acetylacetone (1.0 g, 10.0 mmol) in acetic acid (15
mL) was added bromine (1.9 g, 12.0 mmol) at 0 °C. The reaction
was heated at 60 °C for 3 h. Saturated sodium bicarbonate solution
was added, and the layer was separated. The combined organic layer
was washed with water, dried over sodium sulfate, and concentrated
under vacuum to yield 80 as a light-yellow solid (1.2
g, 67.0%). This was taken as such to the next step without further
analysis. Step 2: 3-Morpholinopentane-2,4-dione ()—To a solution
of morpholine (0.58 g, 6.70 mmol) and triethylamine (1.1 g, 11.17
mmol) in dichloromethane (10 mL) was added 80 (1.0 g,
5.58 mmol) dissolved in dichloromethane (10 mL) at 0 °C. The
reaction was stirred at room temperature for 2 h. Water was added,
and the layers separated. The combined organic layers were washed
with water, dried over sodium sulfate, and concentrated under vacuum
to yield 81 (0.80 g, 78%) as viscous brown oil. LC–MS
APCI: calcd for C9H15NO3, 185.22;
observed m/z [M + H]+, 186.2. 1H NMR (400 MHz, DMSO-d6): δ 4.31 (s, 1H), 3.57–3.62 (m, 4H), 2.84 (d, J = 4.40 Hz, 2H), 2.60 (d, J = 4.80 Hz,
2H), 2.18 (s, 6H). Step 3: 2-(3,5-Dimethyl-4-morpholino-1H-pyrazol-1-yl)-6-trifluoromethylpyrimidin-4(3H)-one
()—A
solution of 81 (0.30 g, 1.62 mmol) and 56d (0.31 g, 1.62 mmol) in ethanol/acetic acid mixture (15/5 mL) was
refluxed for 16 h. The solvent was evaporated under vacuum. Crude
product was purified by preparative HPLC to yield 50 (0.07
g, 13%). HPLC purity: 99.9%; LC–MS APCI: calcd for C14H16F3N5O2, 343.126; observed m/z [M + H]+, 344.1.1H NMR (400 MHz, DMSO-d6): δ 13.10
(s, 1H), 6.79 (s, 1H), 3.69 (d, J = 2.80 Hz, 4H),
2.96 (d, J = 3.60 Hz, 4H), 2.51 (s, 3H), 2.30 (s,
3H).
To a solution of 2-hydrazinyl-6-(trifluoromethyl)pyrimidin-4(3H)-one (56d, 0.25, 1.28 mmol) in DMF (5 mL)
was added 3-cyclopropyl-3-oxopropanenitrile (0.15 g, 1.41 mmol) and
heated at 130 °C in a microwave for 1 h. The reaction mixture
was poured into water and extracted with ethyl acetate. The organic
layer washed with plenty of water and brine solution, dried over sodium
sulfate, and concentrated in vacuo. The crude mass was purified by
prep HPLC to give 2-(5-amino-3-cyclopropyl-1H-pyrazol-1-yl)-6-(trifluoromethyl)pyrimidin-4(3H)-one 51 as a white solid (51 mg, 0.179 mmol,
14% yield). HPLC purity: 96%; LC–MS APCI: calcd for C11H10F3N5O, 285.084; observed m/z [M + H]+, 286.0. 1H NMR (400 MHz, CDCl3): δ 6.54 (s, 1H), 5.79 (br
s, 2H), 5.25 (s, 1H), 1.82 (t, J = 4.40 Hz, 1H),
1.00 (d, J = 8.00 Hz, 2H), 0.82 (d, J = 2.00 Hz, 2H).
Step 1: ethyl
2,4-dioxopentanoate—To a solution of sodium metal
(0.86 g, 37.67 mmol) dissolved in ethanol (15 mL) was added a mixture
of diethyl oxalate (5.0 g, 34.24 mmol) and acetone (2.0 g, 34.24 mmol)
and heated at 60 °C for 16 h. The reaction mass was concentrated
under vacuum, diluted with water, and the product was extracted with
ethyl acetate. The organic phase was washed with water and brine,
dried over sodium sulfate, and concentrated. The crude product was
then purified by column chromatography using silica gel (230–400
mesh) with 10–20% ethyl acetate in petroleum ether as an eluent
to yield ethyl 2,4-dioxopentanoate as yellow oil (2.1 g, 13.93 mmol,
37%). 1H NMR (300 MHz, CDCl3): δ 14.40
(s, 1H), 6.39 (s, 1H), 4.37 (q, J = 7.20 Hz, 2H),
2.28 (s, 3H), 1.40 (t, J = 7.20 Hz, 3H). Step 2: Ethyl 5-methyl-1H-pyrazole-3-carboxylate ()—To a solution
of ethyl 2,4-dioxopentanoate (2.0 g, 12.65 mmol) in ethanol (10 mL)
and acetic acid (20 mL) was added hydrazine hydrate (0.75 g, 15.18
mmol). The reaction mixture was heated at the reflux for 16 h. Solvents
were evaporated under vacuum. Water was added, and the product was
extracted with ethyl acetate. The organic layer washed with saturated
sodium bicarbonate solution, water, and brine, dried over sodium sulfate,
and concentrated under vacuum to afford 83 an off-white
solid (1.3 g, 8.6 mmol, 68%). LC–MS APCI: calcd for C7H10N2O2, 154.17; observed m/z [M + H]+, 154.8. 1H NMR (400 MHz, DMSO-d6): δ 13.15
(s, 1H), 6.46 (s, 1H), 4.25 (q, J = 7.20 Hz, 2H),
2.26 (s, 3H), 1.27 (t, J = 6.80 Hz, 3H). Step 3: 5-methyl-1H-pyrazole-3-carbaldehyde—To a
solution of 83 (4.0 g, 25.97 mmol) in dichloromethane
(50 mL) at −78 °C was added di-isobutylaluminiumhydride
(1 M in dichloromethane, 52.0 mL, 51.94 mmol) dropwise under a nitrogen
atmosphere. The reaction mixture was stirred at −78 °C
for 2 h. It was then quenched with methanol at −78 °C,
warmed to room temperature, and washed with water. The organic phase
was dried over sodium sulfate and concentrated under vacuum to yield
5-methyl-1H-pyrazole-3-carbaldehyde. This material
was taken as such for the next step without purification. Step 4: N,N-Dimethyl-1-(5-methyl-1H-pyrazol-3-yl)methanamine ()—To a solution
of 5-methyl-1H-pyrazole-3-carbaldehyde (1.0 g, 9.09
mmol) in methanol was added N,N-dimethyl
amine (2a M in tetrahydrofuran, 23 mL, 45.45 mmol) and stirred for
24 h at room temperature. Sodium cyanoborohydride (1.7 g, 27.27 mmol)
was added to the reaction and stirred at room temperature for another
4 h. The reaction mixture was concentrated, the crude material diluted
with water, and the product was extracted with ethyl acetate. The
organic layer washed with water and brine solution, dried over sodium
sulfate, and concentrated under vacuum to afford 84 as
a white solid (0.60 g, 4.31 mmol, 48%). LC–MS APCI: calcd for
C7H13N3, 139.20; observed m/z [M + H]+, 139.8. Step 5: 2-(3-((Dimethylamino)methyl)-5-methyl-1H-pyrazol-1-yl)-6-(trifluoromethyl)
pyrimidin-4(3H)-one ()—A solution of 84 (0.60 g, 4.31 mmol),
sulfonyl intermediate 79 (0.48 g, 2.15 mmol) and cesium
carbonate (2.0 g, 6.37 mmol) in 1,4-dioxane was heated in sealed tube
at 130 °C for 16 h. The reaction mixture was filtered through
Celite and the filtrate was concentrated under vacuum. The crude product
was then purified by preparative HPLC to yield the free base as a
gum. It was dissolved in dichloromethane and stirred with hydrogen
chloride in 1,4-dioxane (in excess) for 2 h. Solvents were evaporated
under vacuum, formed solids were washed with diethyl ether, and dried
under vacuum to afford 52 (0.06 g, 9.38%) as a white
hydrochloride salt. HPLC purity: 99.8%. LC–MS APCI: calcd for
C12H14F3N5O, 301.115;
observed m/z [M + H]+, 302.2. 1H NMR (400 MHz, CD3OD): δ 6.83
(s, 1H), 6.59 (s, 1H), 4.43 (s, 2H), 2.98 (s, 6H), 2.75 (s, 3H).
To solution of 6-(4-fluorophenyl)-2-(methylsulfonyl)pyrimidin-4(3H)-one (0.3 g, 1.118 mmol) 85 (Synthesized
according to protocol for compound 79) and cesium carbonate
(0.911 g, 2.80 mmol) in DMF was added 83 (0.172 g, 1.118
mmol) in a sealed tube and heated to 130 °C in a microwave for
2 h. The reaction mixture was concentrated under vacuum and then was
purified by preparative HPLC to yield 53 as an off-white
solid (60 mg, 0.179 mmol, 16% yield). HPLC purity: 94%. LC–MS
APCI: calcd for C15H11FN5O3, 314.27; observed m/z [M + H]+, 315.1. 1H NMR (300 MHz, Methanol-d4): δ 8.19–8.08 (m, 2H), 7.26 (t, J = 8.8 Hz, 2H), 6.77 (s, 1H), 6.66 (d, J = 1.1 Hz, 1H), 2.93–2.82 (m, 3H).
Authors: Zhiyuan Zhang; Michael B Wallace; Jun Feng; Jeffrey A Stafford; Robert J Skene; Lihong Shi; Bumsup Lee; Kathleen Aertgeerts; Andy Jennings; Rongda Xu; Daniel B Kassel; Stephen W Kaldor; Marc Navre; David R Webb; Stephen L Gwaltney Journal: J Med Chem Date: 2010-12-27 Impact factor: 7.446
Authors: James J Lynch; Terry R Van Vleet; Scott W Mittelstadt; Eric A G Blomme Journal: J Pharmacol Toxicol Methods Date: 2017-02-16 Impact factor: 1.950
Authors: Candice Soares de Melo; Soares de Melo Candice; Tzu-Shean Feng; Renier van der Westhuyzen; Richard K Gessner; Leslie J Street; Garreth L Morgans; Digby F Warner; Atica Moosa; Krupa Naran; Nina Lawrence; Helena I M Boshoff; Clifton E Barry; C John Harris; Richard Gordon; Kelly Chibale Journal: Bioorg Med Chem Date: 2015-10-22 Impact factor: 3.641
Authors: S T Cole; R Brosch; J Parkhill; T Garnier; C Churcher; D Harris; S V Gordon; K Eiglmeier; S Gas; C E Barry; F Tekaia; K Badcock; D Basham; D Brown; T Chillingworth; R Connor; R Davies; K Devlin; T Feltwell; S Gentles; N Hamlin; S Holroyd; T Hornsby; K Jagels; A Krogh; J McLean; S Moule; L Murphy; K Oliver; J Osborne; M A Quail; M A Rajandream; J Rogers; S Rutter; K Seeger; J Skelton; R Squares; S Squares; J E Sulston; K Taylor; S Whitehead; B G Barrell Journal: Nature Date: 1998-06-11 Impact factor: 49.962
Authors: Huaqing Cui; Juana Carrero-Lérida; Ana P G Silva; Jean L Whittingham; James A Brannigan; Luis M Ruiz-Pérez; Kevin D Read; Keith S Wilson; Dolores González-Pacanowska; Ian H Gilbert Journal: J Med Chem Date: 2012-12-14 Impact factor: 7.446
Authors: M Sloan Siegrist; Magnus Steigedal; Rushdy Ahmad; Alka Mehra; Marte S Dragset; Brian M Schuster; Jennifer A Philips; Steven A Carr; Eric J Rubin Journal: MBio Date: 2014-05-06 Impact factor: 7.867
Authors: Evgeny V Shchegolkov; Yanina V Burgart; Daria A Matsneva; Sophia S Borisevich; Renata A Kadyrova; Iana R Orshanskaya; Vladimir V Zarubaev; Victor I Saloutin Journal: RSC Adv Date: 2021-10-31 Impact factor: 4.036
Figure 1
Figure 2
Scheme 1
Scheme 7
Scheme 2
Scheme 3
Scheme 4
Scheme 5
Scheme 6
Scheme 8
Scheme 9
Scheme 10
Scheme 11
Figure 3
Figure 4