A Triazolopyrimidine-Based Dihydroorotate Dehydrogenase Inhibitor with Improved Drug-like Properties for Treatment and Prevention of Malaria

Phillips, Margaret A.; White, Karen L.; Kokkonda, Sreekanth; Deng, Xingming; White, John; Mazouni, Farah El; Marsh, Kennan C.; Tomchick, Diana R.; Manjalanagara, Krishne; Rudra, Kakali Rani; Wirjanata, Grennady; Noviyanti, Rintis; Price, Ric N.; Marfurt, Jutta; Shackleford, David M.; Chiu, Francis Chi Keung; Campbell, Michael G.; Jiménez-Dı́az, Marı́a Belén; Ferrer-Bazaga, Santiago; Angulo-Barturen, Íñigo; Martínez, María Santos; Lafuente-Monasterio, María José; Kaminsky, Werner; Silué, Kigbafori D.; Zeeman, Anne‐Marie; Kocken, Clemens H. M.; Leroy, Didier; Blasco, Benjamin; Rossignol, Emilie; Rueckle, Thomas; Dave, M. A.; Burrows, Jeremy N.; Waterson, David; Palmer, Michael; Rathod, Pradipsinh K.; Charman, Susan A.

doi:10.1021/acsinfecdis.6b00144

Cited by 79 publications

(77 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Another example is reducing the molecular weight of the DSM265 to DSM421 by replacing the SF 5 ‐aniline moiety with a series of CF 3 ‐pyridinyls. DSM421 now is a new antimalarial compound with better solubility and absorption properties than DSM265 …”

Section: Effect Of Chemical Structure On Physicochemical Properties Amentioning

confidence: 99%

“…Drug latentiation and pro‐drug formation is a classical approach to circumvent structure‐related problems via esterification, amidation, benzylation of carboxylic acid or hydroxy/amino functional groups as well as salt formation . Other chemical modification strategies include chemical substitutions to reduce molecular weight and conjugation to carrier molecule…”

Section: Chemical and Pharmaceutical Solutionsmentioning

confidence: 99%

See 1 more Smart Citation

Chemical structure modifications and nano‐technology applications for improving ADME‐Tox properties, a review

Farouk

Shamma

2019

Archiv der Pharmazie

View full text Add to dashboard Cite

The chemical structure of a drug molecule affects its physicochemical properties and subsequent biological activities. Many pharmacologically active molecules fail to reach the market or have an inconvenient route of administration due to their chemical structure. This is especially important with the recent tendency to develop drug candidates beyond the drug-likeness space for addressing difficult targets such as protein-protein interfaces. The objective of this review is to discuss chemical and pharmaceutical approaches for circumventing structure-related problems and achieving acceptable ADME-Tox properties. The chemical structure-associated limitations are critically discussed. Chemical modifications and pharmaceutical technology applications for improving drug-likeness are illustrated. Attention is paid to modern therapeutic candidates and targets. In conclusion, chemical modifications as well as nanotechnology applications can be used effectively to enhance absorption, permeability, and selective distribution to a body compartment, to improve drug specificity, to limit off-target toxicity as well as to enhance stability and to protect against metabolism. The nano-technology-based solutions are relatively easier to develop over a new molecular entity, but adopting the chemical approach is more established in terms of safety, quality control, and regulatory assessment methods. K E Y W O R D Sblood-brain barrier, cancer tissue delivery, drug delivery, drug targeting, protein-protein interaction

show abstract

Section: Effect Of Chemical Structure On Physicochemical Properties Amentioning

confidence: 99%

Section: Chemical and Pharmaceutical Solutionsmentioning

confidence: 99%

Chemical structure modifications and nano‐technology applications for improving ADME‐Tox properties, a review

Farouk

Shamma

2019

Archiv der Pharmazie

View full text Add to dashboard Cite

show abstract

“…The inhibition of pf DHODH has arisen as a therapeutic strategy to impede a broad range of invasive diseases, including malaria where the triazolopyrimidine‐based inhibitor, DSM265, has proceeded to clinical development . Recent studies have identified a potent derivative of DSM421, by substituting the SF 5 ‐aniline group of DSM265 with a series of CF 3 ‐pyridinyls, while retaining the main triazolopyrimidine scaffold towards inhibiting Plasmodium falciparum DHODH ( pf DHODH) . Experimental studies performed on the derivative compound DSM421 revealed improved solubility, a decrease in intrinsic clearance and a surge in plasma levels after oral dosing in comparison with DSM265.…”

Section: Introductionmentioning

confidence: 99%

“…Experimental studies performed on the derivative compound DSM421 revealed improved solubility, a decrease in intrinsic clearance and a surge in plasma levels after oral dosing in comparison with DSM265. DSM421 was also shown to maintain a long‐predicted half‐life in humans . The superiority of the substituted CF 3 ‐pyridinyl to the core triazolopyrimidine scaffold resulted in the improved physical and chemical properties of DSM421 while concurrently aiding in a more simplified synthetic route as opposed to DSM265 …”

Section: Introductionmentioning

confidence: 99%

“…A resolved 3D crystal structure of pf DHODH ( Figure ) in complex with DSM265 and DSM421 served as a first attempt to provide structural perspectives on the binding of these two inhibitors . However, since X‐ray crystal structures are representative static snapshots of the complexes, they do not provide a comprehensive insight on the structural dynamics and the corresponding conformations changes of associated with the differential binding of these two triazolopyrimidine‐based inhibitors, particularly the enhanced inhibitory prowess of DSM421.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

CF₃‐Pyridinyl Substitution on Antimalarial Therapeutics: Probing Differential Ligand Binding and Dynamical Inhibitory Effects of a Novel Triazolopyrimidine‐Based Inhibitor on Plasmodium falciparum Dihydroorotate Dehydrogenase

Agoni

Salifu

2019

Chemistry & Biodiversity

View full text Add to dashboard Cite

The quest for reliable dihydroorotate dehydrogenase (DHODH) inhibitors has engendered the discovery of potential therapeutic compounds at different stages of clinical trials. Although promising, high attrition rates and unfavorable bioactivities have limited their drug developmental progress. A recent structural modification of DSM265, a triazolopyrimidine-based inhibitor, yielded DSM421, derived by the substitution of the SF 5 -aniline group on DSM265 with a CF 3 -pyridinyl moiety. Consequently, DSM421 exhibited improved pharmacological and pharmacokinetics attributes relative to DSM265. The improved bioactivity mediated by the CF 3 -pyridinyl group leaves us with a curiosity to investigate underlying ligand-binding mechanisms and dynamics using computational methods. Presented in this study are insights that clearly explain the effects of structural SF 5 -aniline!CF 3pyridinyl modifications on pfDHODH inhibition. Findings showed that the CF 3 -pyridinyl group induced an optimal and stabilized positioning of DSM421 within the binding pocket, allowing for steady and strong intermolecular interactions which favored its stronger binding affinity as estimated and correlated with bioactivity data. These interactions consequently induced a pronounced stabilization of the structural conformation of pfDHODH by restricting residue motions, which possibly underpinned its enhanced inhibitory activity relative to DSM265. Active site interactions of the CF 3 -pyrinidyl group with residues Ser236, Ile237, and Phe188 characterized by strong π -π stacking and halogen interactions also stabilized its positioning which altogether accounted for its enhanced inhibitory prowess towards pfDHODH. On the contrary, fewer and weaker interactions characterized DSM265 binding which could explain its relatively lower binding affinity. Findings will facilitate the design of novel pfDHODH inhibitors with enhanced properties.

show abstract

Study on Significance of Receptor Targeting in Killing of Intracellular Bacteria with Membrane‐Impermeable Antibiotics

Catania

Mastrotto

Moore

et al. 2021

Advanced Therapeutics

View full text Add to dashboard Cite

Water‐soluble antibiotics are largely excluded from therapy of intracellular infections, such as Shigella spp., Listeria spp., or Salmonella spp., due to their inability to permeate mammalian cell membrane. Here, the authors study if targeting offers an advantage to deliver killing doses of membrane‐impermeable antibiotics intracellularly to infected cells. Mannose‐decorated liposomes, loaded with gentamicin, are fabricated to target mannose receptor, a recognition system of (infected) macrophages. Designing a family of liposomes with varying surface presentation of mannose ligand, the authors show a clear dependence of cellular internalization on the ligand surface presentation. Significantly for the killing of intracellular bacteria, the study demonstrates internalization of mannosylated liposomes by the entire population of macrophages, both Salmonella‐infected and non‐infected, resulting in an efficient treatment of intracellular infection. This contrasts with non‐targeted liposomes, where internalization does not occur by a substantial subpopulation of infected cells. The study points to the significance of targeted delivery of antibiotics for treatment of intracellular infections.

show abstract

A Triazolopyrimidine-Based Dihydroorotate Dehydrogenase Inhibitor with Improved Drug-like Properties for Treatment and Prevention of Malaria

Cited by 79 publications

References 43 publications

Chemical structure modifications and nano‐technology applications for improving ADME‐Tox properties, a review

Chemical structure modifications and nano‐technology applications for improving ADME‐Tox properties, a review

CF₃‐Pyridinyl Substitution on Antimalarial Therapeutics: Probing Differential Ligand Binding and Dynamical Inhibitory Effects of a Novel Triazolopyrimidine‐Based Inhibitor on Plasmodium falciparum Dihydroorotate Dehydrogenase

Study on Significance of Receptor Targeting in Killing of Intracellular Bacteria with Membrane‐Impermeable Antibiotics

Contact Info

Product

Resources

About

A Triazolopyrimidine-Based Dihydroorotate Dehydrogenase Inhibitor with Improved Drug-like Properties for Treatment and Prevention of Malaria

Cited by 79 publications

References 43 publications

Chemical structure modifications and nano‐technology applications for improving ADME‐Tox properties, a review

Chemical structure modifications and nano‐technology applications for improving ADME‐Tox properties, a review

CF3‐Pyridinyl Substitution on Antimalarial Therapeutics: Probing Differential Ligand Binding and Dynamical Inhibitory Effects of a Novel Triazolopyrimidine‐Based Inhibitor on Plasmodium falciparum Dihydroorotate Dehydrogenase

Study on Significance of Receptor Targeting in Killing of Intracellular Bacteria with Membrane‐Impermeable Antibiotics

Contact Info

Product

Resources

About

CF₃‐Pyridinyl Substitution on Antimalarial Therapeutics: Probing Differential Ligand Binding and Dynamical Inhibitory Effects of a Novel Triazolopyrimidine‐Based Inhibitor on Plasmodium falciparum Dihydroorotate Dehydrogenase