Acetylcholinesterase: Treatment of Alzheimer's disease

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Alzheimer's disease (AD) is a disorder that attacks the central nervous system through progressive degeneration of its neurons. AD occurs in around 10% of the elderly and, as yet, there is no known cure. Patients with this disease develop dementia which becomes more severe as the disease progresses. It was suggested that symptoms of AD are caused by decrease of activity of cholinergic neocortical and hippocampal neurons. Treatment of AD by ACh precursors and cholinergic agonists was ineffective or caused severe side effects. ACh hydrolysis by AChE causes termination of cholinergic neurotransmission. Therefore, compounds which inhibit AChE might significantly increase the levels of ACh depleted in AD. Indeed, it was shown that AChE inhibitors improve the cognitive abilities of AD patients at early stages of the disease development.

1 The first generation of AD drugs - monovalent AChE inhibitors
2 The second generation of AD drugs - bivalent AChE inhibitors
- 2.1 Compound 3
- 2.2 Aricept (donepezil, E2020)
  - 2.2.1 See details of AChE-Aricept complex in various languages

The first generation of AD drugs - monovalent AChE inhibitors

The first generation of AD drugs were AChE inhibitors: alcaloids like (-)-Huperzine A (HupA) and (-)-galanthamine (GAL, Reminyl); synthetic compounds tacrine (Cognex) and rivastigmine (Exelon). See also AChE bivalent inhibitors

HupA

HupA, discovered by Chinese scientists from 1980s, has been proved to be a powerful, highly specific, and reversible inhibitor of AChE. The crystal structure of the complex of TcAChE with HupA at 2.5 Å resolution (1vot) was determined in 1997 and it shows an unexpected orientation for the inhibitor with surprisingly few strong direct interactions with protein residues to explain its high affinity. HupA binds to TcAChE at the active site, and its in comparison to ACh. The principal interactions of are including: a direct (colored orange) through a water molecule as a linker at the bottom of the gorge; cation-π interactions between the amino group of (colored green) with the distance between the nitrogen and the centroid of the aromatic rings of 4.8 and 4.7 Å, respectively; at the top of the gorge, hydrogen bonds through two water molecules as linkers formed between the amino group of (colored magenta). An unusually short (~3.0 Å) C-H→O HB has been seen between the ethylidene methyl group of (colored crimson) ^[1]^[1].

Galanthamine

. (red) is an alkaloid from the flower snowdrop (Galanthus nivalis). The X-ray crystal structure of the TcAChE/GAL complex (1dx6) was determined at 2.3 Å resolution. The inhibitor binds at the base of the active site gorge of TcAChE, interacting with both the choline-binding site (Trp84) and the acyl-binding pocket (Phe288, Phe290). The tertiary amine appears to make a non-conventional hydrogen bond, via its N-methyl group, to Asp72. The hydroxyl group of the inhibitor makes a strong hydrogen bond (2.7 Å) with Glu199 ^[2]. ACh (gray) is shown for comparison.

Tacrine

(Cognex). In the X-ray crystal structure of TcAChE/ complex which was determined at 2.8 Å resolution, the tacrine is seen (magenta) bound in the active site of TcAChE (1acj) ^[3]. ACh (gray) is shown for comparison.

See Tacrine.

Rivastigmine

(Exelon) is a carbamate inhibitor of AChE, and it is currenly used in therapy of Alzheimer's Disease. Rivastigmine (colored yellow) interacts with TcAChE (colored green) at the (1gqr). The carbamyl moiety of rivastigmine is to the active-site S200 Oγ. The second part of rivastigmine (the leaving group), NAP ((−)-S-3-[1-(dimethylamino)ethyl]phenol) is also held in the active-site gorge, but it is from the carbamyl moiety, hence, carbamylation took place. The of TcAChE/NAP (colored magenta) is known (1gqs). The TcAChE active-site residues which are interacting with NAP are colored violet. NAP is located in a similar region of TcAChE active site, but with different orientation than that of the NAP part (colored yellow) in the TcAChE/rivastigmine complex. Only H440 and F330 significantly change their side-chain conformations. of the TcAChE active sites in 4 different structures TcAChE/rivastigmine (1gqr), TcAChE/NAP (1gqs), native TcAChE (2ace), and TcAChE/VX (1vxr, TcAChE colored white and VX black) reveals that the conformation of H440 in the TcAChE/NAP structure is very similar its conformation in the native TcAChE (2ace), but the distance between H440 Nδ and E327 Oε is significantly longer in the TcAChE/rivastigmine and the TcAChE/VX complexes. This structural change disrupts the catalytic triad consisting of S200, E327, H440. This could explain the very slow kinetics of AChE reactivation after its inhibition by Rivastigmine ^[4].

The second generation of AD drugs - bivalent AChE inhibitors

The active site of consists of . First of them is the "catalytic anionic site" (CAS), which involves mentioned above catalytic triad (colored orange) and the conserved residues and also participating in ligands recognition. Another conserved residue (colored cyan) is situated at the second binding subsite, termed the "peripheral anionic site" (PAS), ~14 Å from CAS. Therefore, the ligands that will be able to interact with both these subsites, will be more potent AChE inhibitors in comparison to compounds interacting only with CAS (mentioned in the previous section "The first generation of AD drugs - monovalent AChE inhibitors"). One of the ways to produce such ligands is to introduce two active substances into one compound. If it is spatially necessary these subunits could be divided by alkyl linker with suitable length. For example, according to the strategy of the use of a bivalent ligand, the (RS)-(±)-tacrine-(10)-hupyridone ((R)-3 or (S)-3) was designed and synthesized. It consists of mentioned above (colored magenta), 10-carbon (yellow), and (red). The tacrine moiety of this inhibitor binds at the CAS, the linker spans the gorge, and the hupyridone moiety binds at the PAS (1zgb) ^[5]. There are also only PAS-binding AChE inhibitors, (magenta) is a good example of them. of the crystal structure of the edrophonium/TcAChE (CAS-binding inhibitor) (2ack) on the thioflavin T/TcAChE complex structure (2j3q) shows that these ligands' positions do not overlap. Of note is that Phe330, which is part of the CAS, is the single residue interacting with thioflavin T. This residue is the only one which significantly to avoid clashes in comparison to other CAS residues of the edrophonium/TcAChE complex ^[6] ^[7].

Compound 3

Described above, (abbreviated as ; colored red) is a CAS-binding inhibitor and it is currently used in therapy of Alzheimer's Disease under the trade name Razadyne. Conjugate of GAL through the (8 carbons, yellow) with a (blueviolet) called compound 3 has a larger affinity for AChE than that of GAL alone. This is similar to previously described cases of bivalent ligands (e.g. (RS)-(±)-tacrine-(10)-hupyridone). A comparison between /TcAChE (1w4l) and structure (1dx6) shows an identical binding mode of the GAL-moiety (transparent red) of compound 3 to that of GAL alone (blue) at the CAS. A PEG molecule (gray) is located at the active site of the galanthamine/TcAChE structure. The alkyl linker spans the active-site gorge and the phthalimido moiety of compound 3 is situated near Trp279 at the PAS. Compound 3 has higher affinity to TcAChE than GAL. This can be explained by the higher number of interactions between compound 3 (which interacts not only with residues within CAS but also within PAS) and TcAChE relative to GAL ^[8].

Aricept (donepezil, E2020)

(Donepezil) is one of the most interesting drugs that have been designed as AChE bivalent inhibitors. It was developed, synthesized and evaluated by the Eisai Company in Japan. These inhibitors were designed on the basis of QSAR studies prior to elucidation of the 3D structure of Torpedo californica AChE (TcAChE) (1ea5). It significantly enhances performance in animal models of cholinergic hypofunction and has a high affinity for AChE, binding to both electric eel and mouse AChE in the nanomolar range. The X-ray structure of the E2020-TcAChE complex (1eve) shows that E2020 has a along the active-site gorge, extending from the anionic subsite () of the active site, at the bottom, to the peripheral anionic site (), at the top, via aromatic stacking interactions with conserved aromatic acid residues. E2020 does not, however, interact directly with either the catalytic triad or the 'oxyanion hole' but only . The X-ray structure shows, a posteriori, that the design of E2020 took advantage of several important features of the active-site gorge of AChE, to produce a drug with both high affinity for AChE and a high degree of selectivity for AChE versus butyrylcholinesterase (BChE). It also delineates voids within the gorge that are not occupied by E2020 and could provide sites for potential modification of E2020 to produce drugs with improved pharmacological profiles ^[9].

See Treatments:AChE Inhibitor References.

See details of AChE-Aricept complex in various languages

1eve (German)
1eve (Hebrew)
1eve (Arabic)
1eve (Spanish)
1eve (Italian)
1eve (Chinese)
1eve (Turkish)
1eve (Russian)
1eve (French)

References

↑ ^1.0 ^1.1 Raves ML, Harel M, Pang YP, Silman I, Kozikowski AP, Sussman JL. Structure of acetylcholinesterase complexed with the nootropic alkaloid, (-)-huperzine A. Nat Struct Biol. 1997 Jan;4(1):57-63. PMID:8989325
↑ Greenblatt HM, Kryger G, Lewis T, Silman I, Sussman JL. Structure of acetylcholinesterase complexed with (-)-galanthamine at 2.3 A resolution. FEBS Lett. 1999 Dec 17;463(3):321-6. PMID:10606746
↑ Harel M, Schalk I, Ehret-Sabatier L, Bouet F, Goeldner M, Hirth C, Axelsen PH, Silman I, Sussman JL. Quaternary ligand binding to aromatic residues in the active-site gorge of acetylcholinesterase. Proc Natl Acad Sci U S A. 1993 Oct 1;90(19):9031-5. PMID:8415649
↑ Bar-On P, Millard CB, Harel M, Dvir H, Enz A, Sussman JL, Silman I. Kinetic and structural studies on the interaction of cholinesterases with the anti-Alzheimer drug rivastigmine. Biochemistry. 2002 Mar 19;41(11):3555-64. PMID:11888271
↑ Haviv H, Wong DM, Greenblatt HM, Carlier PR, Pang YP, Silman I, Sussman JL. Crystal packing mediates enantioselective ligand recognition at the peripheral site of acetylcholinesterase. J Am Chem Soc. 2005 Aug 10;127(31):11029-36. PMID:16076210 doi:http://dx.doi.org/10.1021/ja051765f
↑ Ravelli RB, Raves ML, Ren Z, Bourgeois D, Roth M, Kroon J, Silman I, Sussman JL. Static Laue diffraction studies on acetylcholinesterase. Acta Crystallogr D Biol Crystallogr. 1998 Nov 1;54(Pt 6 Pt 2):1359-66. PMID:10089512
↑ Harel M, Sonoda LK, Silman I, Sussman JL, Rosenberry TL. Crystal structure of thioflavin T bound to the peripheral site of Torpedo californica acetylcholinesterase reveals how thioflavin T acts as a sensitive fluorescent reporter of ligand binding to the acylation site. J Am Chem Soc. 2008 Jun 25;130(25):7856-61. Epub 2008 May 31. PMID:18512913 doi:http://dx.doi.org/10.1021/ja7109822
↑ Greenblatt HM, Guillou C, Guenard D, Argaman A, Botti S, Badet B, Thal C, Silman I, Sussman JL. The complex of a bivalent derivative of galanthamine with torpedo acetylcholinesterase displays drastic deformation of the active-site gorge: implications for structure-based drug design. J Am Chem Soc. 2004 Dec 1;126(47):15405-11. PMID:15563167 doi:http://dx.doi.org/10.1021/ja0466154
↑ Kryger G, Silman I, Sussman JL. Structure of acetylcholinesterase complexed with E2020 (Aricept): implications for the design of new anti-Alzheimer drugs. Structure. 1999 Mar 15;7(3):297-307. PMID:10368299

Proteopedia Page Contributors and Editors (what is this?)

Joel L. Sussman, Michal Harel

Retrieved from "http://52.214.119.220/wiki/index.php/Acetylcholinesterase:_Treatment_of_Alzheimer%27s_disease"

@@ Line 8: / Line 8: @@
 ===HupA===
-'''HupA''', discovered by Chinese scientists from 1980s, has been proved to be a powerful, highly specific, and [http://en.wikipedia.org/wiki/Enzyme_inhibitor#Reversible_inhibitors reversible inhibitor] of AChE. The [http://en.wikipedia.org/wiki/X-ray_crystallography crystal structure] of the complex of ''Tc''AChE with HupA at 2.5 Å resolution ([[1vot]]) was determined in 1997 and it shows an unexpected orientation for the inhibitor with surprisingly few strong direct interactions with protein residues to explain its high affinity. <font color='blueviolet'><b>HupA</b></font> binds to ''Tc''AChE at the active site, and its <scene name='1vot/Active_site/8'>observed orientation is almost orthogonal</scene> in comparison to <font color='gray'><b>ACh</b></font>. The principal interactions of <scene name='1vot/1vot_ache_interactions/2'>HupA with TcAChE</scene> are including: a direct <scene name='1vot/1vot_199_130_117/2'>hydrogen bond with Tyr130 and HBs with Glu199 and Gly117 </scene> <span style="color:orange;background-color:black;font-weight:bold;">(colored orange)</span> through a water molecule as a linker at the bottom of the gorge; [http://en.wikipedia.org/wiki/Cation-pi_interaction cation-π] interactions between the amino group of <scene name='1vot/1vot_84_330/2'>HupA and Trp84 and Phe330</scene> <span style="color:lime;background-color:black;font-weight:bold;">(colored green)</span> with the distance between the nitrogen and the centroid of the aromatic rings of 4.8 and 4.7 Å, respectively; at the top of the gorge, [http://en.wikipedia.org/wiki/Hydrogen_bond hydrogen bonds] through two water molecules as linkers formed between the amino group of <scene name='1vot/1vot_70_72_81_85_121/3'>HupA and Tyr70, Asp72, Ser81, Asn85 and Tyr121</scene> <font color='magenta'><b>(colored magenta)</b></font>. An unusually short (~3.0 Å) C-H→O HB has been seen between the ethylidene methyl group of <scene name='1vot/1vot_440/2'>HupA and the main chain oxygen of His440</scene> <font color='crimson'><b>(colored crimson)</b></font> <ref name="Raves"/>.
+'''HupA''', discovered by Chinese scientists from 1980s, has been proved to be a powerful, highly specific, and [http://en.wikipedia.org/wiki/Enzyme_inhibitor#Reversible_inhibitors reversible inhibitor] of AChE. The [http://en.wikipedia.org/wiki/X-ray_crystallography crystal structure] of the complex of ''Tc''AChE with HupA at 2.5 Å resolution ([[1vot]]) was determined in 1997 and it shows an unexpected orientation for the inhibitor with surprisingly few strong direct interactions with protein residues to explain its high affinity. <font color='blueviolet'><b>HupA</b></font> binds to ''Tc''AChE at the active site, and its <scene name='1vot/Active_site/8'>observed orientation is almost orthogonal</scene> in comparison to <font color='gray'><b>ACh</b></font>. The principal interactions of <scene name='1vot/1vot_ache_interactions/2'>HupA with TcAChE</scene> are including: a direct <scene name='1vot/1vot_199_130_117/2'>hydrogen bond with Tyr130 and HBs with Glu199 and Gly117 </scene> <span style="color:orange;background-color:black;font-weight:bold;">(colored orange)</span> through a water molecule as a linker at the bottom of the gorge; [http://en.wikipedia.org/wiki/Cation-pi_interaction cation-π] interactions between the amino group of <scene name='1vot/1vot_84_330/2'>HupA and Trp84 and Phe330</scene> <span style="color:lime;background-color:black;font-weight:bold;">(colored green)</span> with the distance between the nitrogen and the centroid of the aromatic rings of 4.8 and 4.7 Å, respectively; at the top of the gorge, [http://en.wikipedia.org/wiki/Hydrogen_bond hydrogen bonds] through two water molecules as linkers formed between the amino group of <scene name='1vot/1vot_70_72_81_85_121/3'>HupA and Tyr70, Asp72, Ser81, Asn85 and Tyr121</scene> <font color='magenta'><b>(colored magenta)</b></font>. An unusually short (~3.0 Å) C-H→O HB has been seen between the ethylidene methyl group of <scene name='1vot/1vot_440/2'>HupA and the main chain oxygen of His440</scene> <font color='crimson'><b>(colored crimson)</b></font>
+<ref name="Raves">PMID:8989325</ref><ref name="Raves"/>.
 ===Galanthamine===