A hybrid of 1-deoxynojirimycin and benzotriazole induces preferential inhibition of butyrylcholinesterase (BuChE) over acetylcholinesterase (AChE).

The synthesis of four heterodimers in which the copper(I)-catalysed azide-alkyne cycloaddition was employed to connect a 1-deoxynojirimycin moiety with a benzotriazole scaffold is reported. The heterodimers were investigated as inhibitors against acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE). The heterodimers displayed preferential inhibition (> 9) of BuChE over AChE in the micromolar concentration range (IC50 = 7-50 µM). For the most potent inhibitor of BuChE, Cornish-Bowden plots were used, which demonstrated that it behaves as a mixed inhibitor. Modelling studies of the same inhibitor demonstrated that the benzotriazole and 1-deoxynojirimycin moiety is accommodated in the peripheral anionic site and catalytic anionic site, respectively, of AChE. The binding mode to BuChE was different as the benzotriazole moiety is accommodated in the catalytic anionic site.

Introduction

Alzheimer’s disease (AD) is a neurodegenerative process that constitutes the most common type of dementia, which causes death 3–9 years after diagnosis. AD is a multifactorial disease in which all the factors involved in the progression of the disease have not been pinpointed; however, the two major pathogenic mechanisms are believed to include accumulation of amyloid-beta (Aβ) plaques between the neurons that causes neuronal loss and formation of neurofibrillary tangles (NFTs) within the neurons that disturbs the synaptic communication between the cells., The AD brain usually includes additional abnormalities such as inflammation, deficits of the neurotransmitter acetylcholine (ACh), oxidative stress, and metal ion dyshomeostasis. Currently, there is no fully established therapy available for AD, presumably because all factors involved in the progression of the disease have not yet been identified. In this context, it is worth mentioning that the Federal Drug Administration (FDA) used its accelerated approval pathway (an approval pathway of drugs against serious diseases that lack other medical options) when it gave green light for aducanumab as an AD drug in 2021. Aducanumab was approved due to its ability to reduce the level of senile plaque in patients with AD, and thereby being the first approved drug that addresses one of the main pathophysiological hallmarks of AD. However, no unambiguously improvement of cognition was observed in those patients involved in two separate phase III trials. Indeed, it has been found that significant levels of senile plaques can be present in the brain of elderly people without cognitive impairments. Before aducanumab was approved there were only four AD drugs available on the market, which are only able to slow down or delay the symptoms of AD by a few months. Three out of those palliative drugs, namely donepezil, galantamine, and rivastigmine, are cholinesterase (ChE) inhibitors (Figure 1(a)). Such treatment is in line with the cholinergic hypothesis in which the cognitive decline in AD patients is due to degeneration of neurons in the basal forebrain, which in turn causes loss of neurotransmission in regions of the brain that are essential for the cognitive functions. Therefore, the purpose of ChE inhibitor drugs is to boost the neurotransmission between neurons by inhibiting the rapid hydrolysis of the neurotransmitter acetylcholine (ACh) in the synaptic cleft by the two major ChEs, acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE).

Figure 1.

(a) FDA approved ChE inhibitors. (b) Examples of iminosugars.

Iminosugars, such as naturally occurring 1-deoxynojirimycin (1-DNJ) (4) (Figure 1(b)) are carbohydrate analogues in which the ring oxygen atom is replaced by a nitrogen atom. Many iminosugars can be partially protonated at physiological pH, in which the conjugate acid can be considered as a charged analogue of the transition state of glycosidase catalysed cleavage of glycosidic bonds. Therefore, it is not surprising that iminosugars are mostly famous for their properties as glycosidase inhibitors. The glycosidase inhibitory properties of iminosugars have made them attractive as lead compounds for treatment of diseases such as cancer, diabetes, viral infections, and lysosomal disorders in which carbohydrate processing enzymes are apparent pharmaceutical targets. The FDA has approved three iminosugars: miglitol (5), miglustat (6), and migalastat (7) for treatment of type 2 diabetes, Gaucher’s disease, and Fabry’s disease, respectively. In addition, in a cellular model of H4APPsw it has been found that miglustat (6) lowers the level of Aβ protein, which is the major component in senile plaque.

X-ray analysis has demonstrated that the overall structure of AChE and BuChE is very similar and that both enzymes host a catalytic triad consisting of histidine, glutamate, and serine almost on the bottom of a ca. 20 Å deep active gorge., Both enzymes contain a tryptophan residue in the catalytic anionic binding site (CAS) nearby the catalytic triad, which establishes π–cation interactions with the cationic ACh substrate and thereby place its ester functional group in a favourable position for hydrolysis in the catalytic triad. At the mouth of the active site gorge of both enzymes there is an initial substrate binding site, the peripheral anionic binding site (PAS), which is structurally different between AChE and BuChE as the PAS of AChE is more rich in aromatic residues.

Because iminosugars can be protonated at physiological pH, and as such they were thought to establish cation–π interactions with the tryptophan residue in CAS of AChE in the same way as the quaternary ammonium groups of ACh and of the AChE inhibitors edrophonium and decamethonium. When a library of 23 iminosugars of different stereochemistry and with substituents in various positions were tested as AChE and BuChE inhibitors, some of them showed inhibition of especially BuChE in the micromolar concentration range. Dual binding site AChE inhibitors (i.e., such inhibitors that bind simultaneously to PAS and CAS of AChE) are attractive dual action AD drug candidates because they: (1) increase the concentration of the neurotransmitter ACh and (2) inhibit the AChE promoted formation of amyloid fibrils (a component in senile plaques) when the PAS interacts with Aβ-proteins. Following this line, 1-DNJ (4) has been employed as a binding unit in the development of dual binding site ChE inhibitors when it is connected to a second aryl-substituted selenourea (exemplified by 8), tacrine (exemplified by 9), or catechol binding unit (exemplified by 10) (Figure 2(a)). This type of compounds was found to behave as mixed inhibitors of AChE and/or BuChE. The results were interpreted in such a way that heterodimers including a 1-DNJ moiety can bind both to the catalytic site and PAS of BuChE and AChE. Modelling studies of 9 indicated that its 1-DNJ binding unit, in its acidic form, and tacrine binding unit are able to interact simultaneously with the Trp residues in PAS and CAS, respectively. Modelling studies of 10, on the other hand, in complex with AChE and BuChE demonstrated that its 1-DNJ binding unit, in its acidic form, and catechol binding unit bind to the catalytic active site and PAS, respectively.

Figure 2.

(a) Reported iminosugars ChE inhibitors. (b) Reported AD multifactorial agent candidate. (c) Iminosugar heterodimers evaluated in the current work.

Bedi and co-workers reported a series of coumarin-benzotriazole heterodimers (exemplified by 11 in Figure 2(b)) as multifactorial agents for AD treatment. The most promising candidate, viz. compound 11, exhibited inhibition potency against AChE and copper-promoted aggregation of Aβ protein. In addition, 11 displays chelation properties with biometal ions (Cu2+, Zn2+, and Fe2+) and is therefore potentially able to tackle metal homeostasis imbalance, which is thought to be involved in the progression of AD. Dimer 11 displayed mixed AChE inhibition, which was consistent with docking studies in which the coumarin and benzotriazole moiety binds to PAS and CAS, respectively. When the benzotriazole ring was connected to a naphthoquinone and anthraquinone system interesting multitarget agents for AD were obtained as they inhibit both ChEs and monoamine oxidase (MAO) B.

As above mentioned, thus far, four papers have been published, which describe the use of iminosugars as ChE inhibitors., Herein, in the fifth paper, we present the synthesis of four heterodimers 12a–12d (Figure 2(c)), which contain 1-DNJ and benzotriazole binding units connected via a linker of variable length. The thought behind including two binding units within the same molecule is to establish simultaneously interaction with the catalytic active site and PAS of ChEs. The inhibitory testing demonstrated that 12a–12d exhibit preferential inhibition of BuChE over AChE. To get a better picture of the selectivity, our study also includes modelling studies for the binding of 12b to AChE and BuChE.

Materials and methods

General procedures

DMF, CH3CN and CH2Cl2 were dried over 4 Å molecular sieves (oven dried). The reactions were carried out under an argon atmosphere, unless otherwise specified. Microwave reactions were performed in a CEM Discover-SP, max power 300 W. TLC analyses were performed on Merck silica gel 60 F254 plates using UV light for detection. Silica gel NORMASIL 60® 40–63 µm pore size was used for flash column chromatography. NMR spectra were recorded on a Bruker Avance NMR spectrometer; 1H NMR spectra were recorded at 400.13 MHz, 13 C NMR spectra were recorded at 100.61 MHz, in CDCl3 or CD3OD. Chemical shifts are reported in ppm relative to an internal standard of residual chloroform (δ = 7.26 for 1H NMR; δ = 77.16 for 13 C NMR) and residual methanol (δ = 3.31 for 1H NMR; δ = 49.00 for 13 C NMR). High-resolution mass spectra (HRMS) were recorded on a Qexactive spectrometer in positive electrospray ionisation (ESI) mode.

Synthetic protocols

General procedure for the preparation of compounds 18a–d

To a solution of iminosugar 17 (0.30 mmol, 1 equiv.) in dry acetonitrile (15 ml) were added the corresponding alkyl dibromide (12 equiv.) and potassium carbonate (1.3 equiv.). The resulting mixture was heated under microwave irradiation at 100 °C for 1 h. The reaction mixture was then cooled to room temperature and the solvent was evaporated under reduced pressure, followed by addition of 10 ml of water and extraction with EtOAc (2 × 20 ml). The combined organic layers were dried (MgSO4), filtered and concentrated under reduced pressure. The residue was purified by silica gel flash column chromatography (See Supplementary Material).

General procedure for the synthesis of compounds 19a–d

To a solution of the alkyl bromide 18a, 18 b, 18c, or 18d (0.22 mmol, 1 equiv.) in DMF (2 ml) was added NaN3 (4 equiv.). The reaction mixture was heated overnight at 45 °C under Ar-atmosphere. The mixture was then cooled to room temperature and the solvent was evaporated under reduced pressure; 10 ml of water was then added, and the aqueous phase was extracted with CH2Cl2 (2 × 20 ml). The combined organic layers were dried (MgSO4), filtered and concentrated under reduced pressure without the need for further purification (See Supplementary Material).

General procedure for the synthesis of compounds 21a–d

To a mixture of alkyne 20 (0.2 mmol, 1 equiv.), azide 19a, 19b, 19c, or 19d (0.2 mmol, 1 equiv.), and copper (II) sulphate pentahydrate (0.4 equiv.) in DMF (4 ml) in a foil covered round bottom flask was added sodium ascorbate (0.8 equiv.). The mixture was kept stirring at room temperature under Ar-atmosphere overnight. The solvent was then removed under reduced pressure, and the concentrate was suspended in water (10 ml) and EtOAc (20 ml). The layers were separated, and the organic extract was dried (MgSO4), filtered, and concentrated under reduced pressure. The residue was purified by silica gel flash column chromatography (See Supplementary Material).

General procedure for the synthesis of compounds 12a–d

A solution of compound 21a, 21b, 21c, or 21d (0.12 mmol, 1 equiv.) in anhydrous CH2Cl2 (10 ml) under an Ar-atmosphere at −78 °C was slowly added BCl3 (1 M in heptane, 33 equiv.). After addition, the mixture was kept stirring at −78 °C for 2 h and then at 0 °C overnight. The volatiles were then removed under reduced pressure and the concentrate underwent purification by silica gel column chromatography (See Supplementary Material).

Inhibition assays

The inhibitory activity of 12a–12d against AChE and BuChE was carried out following minor modifications of the Ellman assay, as reported previously using Thermo ScientificTM VarioskanTM LUX microplate reader and Greiner F-bottom 96-well plates.

General method for docking simulations

Structures for all proteins (AChE: PDBid 4EY7; BuChE: PDBid 6QAA) were retrieved from the Protein DataBank. Crystal structures were optimised using the QuickPrep protocol from MOE (Chemical Computing Group). All ligands were drawn, hydrogens added, and the geometry was optimised with MOE. For the docking calculations, performed with MOE, in the placement stage, we used the Triangle Matcher algorithm with the London dG scoring scheme. In the refinement stage, the receptor was kept rigid, and the GBVI/WSA dG scoring scheme was used.

Synthesis

The synthesis of 1-DNJ-benzotriazole heterodimers 12a–12d commenced from commercially available methyl α-D-glucopyranoside (13) (Scheme ), which was converted into tetra-O-benzylated 1-DNJ 17 by following a five-step sequence reported by Wennekes et al. including: (1) per-O-benzylation, (2) acidic cleavage of glycosidic bond, (3) reduction of pyranose 15, (4) double Swern oxidation of diol 16, and (5) double reductive amination to obtain 17. N-alkylation of 17 via a nucleophilic substitution reaction is challenging when carried out under conventional heating, presumably due to the steric hindrance on the NH-group exerted by the 6-O-benzyl group. One solution for the N-alkylation challenge of 17 is to use microwave irradiation. Thus, bromoalkyl derivatives 18a–18d of 1-DNJ were obtain in 44–77% when 17 was treated with an excess of dibromoalkanes in acetonitrile in the presence of K2CO3 under microwave irradiation. Treatment of 18a–18d with sodium azide provided the azide cycloaddition partners 19a–19d in excellent yield with no need for purification before they underwent copper(I)-catalysed azide-alkyne cycloaddition (CuAAC) with N-propargyl benzotriazole 20 to afford heterodimers 21a–21d in 71–84% yield. BCl3 promoted de-O-benzylation of 21a–21d provided the target compounds 12a–12d.

Scheme 1.

Synthesis of target compounds 12a–12d.

Cholinesterase inhibition studies

The inhibition potencies of 1-DNJ-benzotriazole heterodimers 12a–12d were tested against eeAChE (AChE from Electrophorus electricus) and eqBuChE (BuChE from equine serum) by using minor modification of the Ellman assay. The minimum inhibitory concentrations required to achieve 50% inhibition (IC50) of the ChE enzymes are tabulated in Table 1. The test series includes galantamine (2) as a positive reference and parent 1-DNJ (4) to assess the impact of the benzotriazole binding group on the inhibitory properties of 12a–12d.

Table 1.

IC50 values for the inhibition of eeAChE and eqBuChE by heterodimers 12a–12d.

Compound		IC50(μM)a			BuChE selectivityd
		n	eeAChEb	eqBuChEc
1-DNJ (4)	4		>100[26]	10 ± 0	>10
Galantamine (2)	2		1.29 ± 0.14	5.47 ± 0.40	0.24
	12a	2	>500	50 ± 3	>10
	12b	5	65 ± 2	6.7 ± 0.7	9.7
	12c	7	>500	26 ± 0.7	>19
	12d	9	>500	17 ± 0.7	>19

Mean ± SD.

[S] = 121 µM.

[S] = 112 µM.

BuChE selectivity = IC50(AChE)/IC50(BuChE).

As shown in Table 1, 1-DNJ together with heterodimers 12a, 12c, and 12d exhibited very poor inhibition potency against AChE. Heterodimer 12b was an outlier from this triplet of heterodimers as it displayed inhibition in the micromolar concentration range, which shows that the arming of 1-DNJ with a benzotriazole group can strengthen its AChE inhibition potency when the number of CH2-groups in the linker is optimised.

When testing for activity towards BuChE that includes an active site gorge with a larger volume compared to AChE and different combination of residues, which affect the inhibitor selectivity of such enzymes, all heterodimers, 12a–12d, became inhibitors in the micromolar concentration range (IC50 = 7–50 μM) with a clear preference for BuChE over AChE (BuChE selectivity ≥ 9.7). From Table 1, it is obvious that arming 1-DNJ with a benzotriazole binding group can both attenuate and increase its BuChE inhibitory potency. In fact, 12b is a 1.5-fold more potent BuChE inhibitor than 1-DNJ. Heterodimers 12a, 12c, and 12d, on the other hand, are 1.7 up to 5 times less potent BuChE inhibitors than 1-DNJ.

Even though IC50-values provide useful information about inhibition potency they do not provide any information about the type of inhibition and affinity for inhibitors to their enzymes. Therefore, two plots (1/V vs. [I] and [S]/V vs. [I]) were created for the inhibition of BuChE by 12b (Figure 3). Since an intersection point is present in both plots, it was concluded that 12b behaves as a mixed inhibitor against BuChE. The mixed inhibition type was interpreted as 12b has the capacity to bind both to PAS and the active site of BuChE. However, because the competitive inhibition constant (Ki = 4.9 ± 0.40 μM) is smaller than the uncompetitive inhibition constant (αKi = 12 ± 1 μM), it is reasonable to expect that 12b possesses a greater affinity for the active site than for PAS.

Figure 3.

Cornish-Bowden plots for analysing the mode of inhibition of 12b.

Docking studies

The preferred binding pose of 12b in recombinant human acetylcholinesterase (rhAChE) is shown in Figure 4, in which the benzotriazole and iminosugar moiety is accommodated in PAS and CAS, respectively. The most striking result, given that 12b binds in its acidic form, is that no cation–π interactions are observed between the positively charged nitrogen atom of 12b and any of the aromatic residues in the active gorge. However, because increased polarity of a X-H bond increases the strength of a X − H···π interaction, it is possible that the positively charged nitrogen atom of 12b further polarise the C–H bonds of the neighbouring endocyclic CH2-group and thereby strengthen its CH–π interaction with Tyr341. In addition, the CH2-group between the benzotriazole and triazole moiety was observed to participate in a CH–π interaction with Trp286 in PAS.

Figure 4.

Most energetically favoured binding pose of 12b to rhAChE.

The most stable binding pose of 12b to the active gorge of human BuChE (hBuChE) is presented in Figure 5. The binding mode of 12b to AChE and BuChE is very different as the benzotriazole moiety of 12b is accommodated in the CAS of BuChE in which it participates in π–π interactions with the Trp82 moiety.

Figure 5.

Preferred binding pose of 12b to hBuChE.

Conclusions

Heterodimers 12a–12d are stronger inhibitors for BuChE than for AChE. The inhibition of BuChE by 12a–12d is susceptible to the number of CH2-groups between the 1-DNJ and benzotriazole binding groups as 12b is a more potent BuChE inhibitor than 1-DNJ whereas 12a, 12c, and 12d are less potent than 1-DNJ. Modelling studies suggest that the 1-DNJ binding group is placed in the PAS of BuChE and the benzotriazole binding group in the CAS. This suggested dual binding site inhibition is supported by Cornish-Bowden plots, which demonstrate that 12b exhibit mixed type of inhibition against BuChE. The hydroxyl groups of heterodimers 12a–12d open the gate to prepare derivatives, which include additional pharmacophores and thereby target more of the factors that are involved in the progression of AD. Indeed, such studies are currently in progress in our laboratories.

Click here for additional data file.