Design and Synthesis of Backbone-Fused, Conformationally Constrained Morpholine-Proline Chimeras

Hocine, Sofiane; Berger, Gilles; Hanessian, Stephen

doi:10.1021/acs.joc.9b03413

Cited by 7 publications

(11 citation statements)

References 61 publications

(88 reference statements)

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“…As mTOR has a deeper pocket as compared to PI3K, the introduction of substituents on the morpholine ring, such as an ethylene bridge between positions 3 and 5 or a methyl group at position 3, have been studied in order to develop selective and highly brain penetrant mTOR kinase inhibitors . In particular, the introduction of the bridged morpholine moiety is often beneficial for CNS candidates, as they are effective in decreasing lipophilicity, partly because of an enhancement of the polar surface area resulting from conformational changes. , For example, PQR620, containing two 3,5-bridged morpholines, inhibits mTOR kinase potently and selectively, and showed antitumor effects in vitro and in vivo , with promising benefits in CNS indications due to its brain/plasma distribution ratio . Similarly, compound 27 , possessing two 3-methylmorpholines, is a potent, orally available, and specific ATP-competitive mTOR inhibitor with selectivity against all Class I PI3K isoforms and other kinases (Figure ).…”

Section: Biological Activity Of Morpholine Derivatives On Cns Tumorsmentioning

confidence: 99%

“…Also, it can be added to enhance the potency toward a target protein, as the oxygen atom can form hydrogen bonds, while the relatively electron-deficient ring can establish hydrophobic interactions . Finally, the flexible conformation resulting from the equilibrium between the chairlike and skew-boat topologies provides the optimal features for a suitable scaffold directing the appendages in the right position. , Morpholine has also an improved CYP3A4 profile, prolonged bioavailability, and optimal clearance, being oxidized easily into nontoxic derivatives. − A plethora of morpholine derivatives have already been present in the market for several decades (Figure ). Just to give some examples, doxapram (1976), phendimetrazine (1979), moclobemide (1992), reboxetine (1997), and aprepitant (2003) − are drugs with applications in several CNS diseases, mainly as anxiolytics and/or antidepressants.…”

Section: Introductionmentioning

confidence: 99%

“…23 Finally, the flexible conformation resulting from the equilibrium between the chairlike and skew-boat topologies provides the optimal features for a suitable scaffold directing the appendages in the right position. 24,25 Morpholine has also an improved CYP3A4 profile, prolonged bioavailability, and optimal clearance, being oxidized easily into nontoxic derivatives. 17−22 A plethora of morpholine derivatives have already been present in the market for several decades (Figure 1).…”

Section: ■ Introductionmentioning

confidence: 99%

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Occurrence of Morpholine in Central Nervous System Drug Discovery

Lenci

Calugi

Trabocchi

2021

ACS Chem. Neurosci.

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Developing drugs for the central nervous system (CNS) requires fine chemical modifications, as a strict balance between size and lipophilicity is necessary to improve the permeability through the blood-brain barrier (BBB). In this context, morpholine and its analogues represent valuable heterocycles, due to their conformational and physicochemical properties. In fact, the presence of a weak basic nitrogen atom and of an oxygen atom at the opposite position provides a peculiar pK a value and a flexible conformation to the ring, thus allowing it to take part in several lipophilic−hydrophilic interactions, and to improve blood solubility and brain permeability of the overall structure. In CNS-active compounds, morpholines are used (1) to enhance the potency through molecular interactions, (2) to act as a scaffold directing the appendages in the correct position, and (3) to modulate pharmacokinetic/ pharmacodynamic (PK/PD) properties. In this perspective, selected morpholinecontaining CNS drug candidates are discussed to reveal the active pharmacophores accountable for the (1) modulation of receptors involved in mood disorders and pain, (2) bioactivity toward enzymes and receptors responsible for neurodegenerative diseases, and (3) inhibition of enzymes involved in the pathology of CNS tumors. The medicinal chemistry/pharmacological activity of morpholine derivatives is discussed, in the effort to highlight the importance of morpholine ring interactions in the active site of different targets, particularly reporting binding features retrieved from PDB data, when available.

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Section: Biological Activity Of Morpholine Derivatives On Cns Tumorsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

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Occurrence of Morpholine in Central Nervous System Drug Discovery

Lenci

Calugi

Trabocchi

2021

ACS Chem. Neurosci.

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“…Nevertheless, gem-diamines are widely used in medicinal products, because the existence of a lone pair on the nitrogen atom will increase and improve the lipophilicity and the solubility of the pharmaceutical targets [14][15][16]. Given to the prevalence of diamines, there is a need for doing structure elucidation and also studying their chemical insights [17]. The symmetric as well as asymmetric catalysis, in particular in pharmaceutical industry, are continually seeking for rapid synthetic routes to novel heterocyclic structures for earlystage drug discovery, as well as safe, robust and environmentally friendly routes for large scale production.…”

Section: Introductionmentioning

confidence: 99%

X-ray Crystal Structure and Hirshfeld Analysis of Gem-Aminals-Based Morpholine, Pyrrolidine, and Piperidine Moieties

et al. 2020

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The gem-aminals of 1,2-dimorpholinoethane (1) and 1-morpholino-3-morpholinium bromide propane (2) were synthesized by reaction of two molar ratio of morpholine with the halogenating agents in the presence of basic condition (K2CO3) in acetone at room temperature (RT) overnight. The structures of the centro-symmetric compound 1 and the morpholinium salt derivative 2 were assigned unambiguous by single crystal X-ray diffraction analysis and compared with the 1,2-di(pyrrolidin-1-yl)ethane 3 and 1,2-di(piperidin-1-yl)ethane 4. The 1,2-dimorpholinoethane molecule has a center of symmetry at the midpoint of the C-C bond of the ethyl moiety leading to two equivalent halves. It crystallized in monoclinic crystal system and P21/n space group, while the unit cell parameters are determined to be a = 6.0430(3), b = 8.0805(3), c = 11.1700(4) Å, and β = 97.475(2)° with unit cell volume of 540.80(4) Å3 and Z = 2 at 170(2) K. The less symmetric analogue 2 crystallized in the lower space group P21 with unit cell parameters of a = 6.37450(10), b = 11.1378(2), c = 9.6549(2) Å, and β = 93.358(2)°, while the unit cell volume is 684.30(2)Å3 at 120(2) K. Using Hirshfeld analysis, the molecules of 1 are mainly packed by weak N…H (4.2%), O…H (16.8%), and H…H (79.0%) interactions. In contrast, the molecules of 2 are packed by significantly short O…H (14.4%) and Br…H (11.6%) interactions in addition to the relatively long H…H (73.3%) interactions. DFT calculations predicted the molecular geometry of the studied compounds showing a good agreement with the experimental X-ray structures. Due to symmetry considerations, compounds 1, 3, and 4 are nonpolar with zero dipole moment, while the less symmetric molecule 2 has a dipole moment of 6.914 Debye. Their electronic aspects, such as natural population charges, HOMO, and LUMO energies as well as the corresponding reactivity descriptors, were also calculated and discussed.

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“…Currently, strategies to synthesize diverse bridged amines are limited. State-of-the-art methodologies typically target the related classes of spirocyclic or fused aza-cycles , or target specific ring types in the context of natural product synthesis. , As a consequence, bridged aza-cycles remain underrepresented in medicinal chemistry optimization campaigns, not because of a lack of interest but because of the barrier to synthesizing these structures.…”

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confidence: 99%

Synthesis of Bridged Bicyclic Amines by Intramolecular Amination of Remote C–H Bonds: Synergistic Activation by Light and Heat

et al. 2020

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The construction of complex aza-cycles is of interest to drug discovery due to the prevalence of nitrogen-containing heterocycles in pharmaceutical agents. Herein we report an intramolecular C−H amination approach to afford value-added and complexity-enriched bridged bicyclic amines. Guided by density functional theory and nuclear magnetic resonance investigations, we determined the unique roles of light and heat activation in the bicyclization mechanism. We applied both light and heat activation in a synergistic fashion, achieving gram-scale bridged aza-cycle synthesis.

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Design and Synthesis of Backbone-Fused, Conformationally Constrained Morpholine-Proline Chimeras

Cited by 7 publications

References 61 publications

Occurrence of Morpholine in Central Nervous System Drug Discovery

Occurrence of Morpholine in Central Nervous System Drug Discovery

X-ray Crystal Structure and Hirshfeld Analysis of Gem-Aminals-Based Morpholine, Pyrrolidine, and Piperidine Moieties

Synthesis of Bridged Bicyclic Amines by Intramolecular Amination of Remote C–H Bonds: Synergistic Activation by Light and Heat

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