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Article

Bacopa monnieri and Their Bioactive Compounds Inferred Multi-Target Treatment Strategy for Neurological Diseases: A Cheminformatics and System Pharmacology Approach

by
Rajendran Jeyasri
1,†,
Pandiyan Muthuramalingam
1,†,
Vellaichami Suba
1,
Manikandan Ramesh
1,* and
Jen-Tsung Chen
2
1
Department of Biotechnology, Science Campus, Alagappa University, Karaikudi 630 003, India
2
Department of Life Sciences, National University of Kaohsiung, Kaohsiung 811, Taiwan
*
Author to whom correspondence should be addressed.
Author’s contributed equally to this article.
Biomolecules 2020, 10(4), 536; https://doi.org/10.3390/biom10040536
Submission received: 14 February 2020 / Revised: 28 March 2020 / Accepted: 31 March 2020 / Published: 2 April 2020
(This article belongs to the Special Issue Phytochemical Omics in Medicinal Plants)

Abstract

:
Neurological diseases (NDs), especially Alzheimer’s and Spinocerebellar ataxia (SCA), can severely cause biochemical abnormalities in the brain, spinal cord and other nerves of human beings. Their ever-increasing prevalence has led to a demand for new drug development. Indian traditional and Ayurvedic medicine used to combat the complex diseases from a holistic and integrative point of view has shown efficiency and effectiveness in the treatment of NDs. Bacopa monnieri is a potent Indian medicinal herb used for multiple ailments, but is significantly known as a nootropic or brain tonic and memory enhancer. This annual herb has various active compounds and acts as an alternative and complementary medicine in various countries. However, system-level insights of the molecular mechanism of a multiscale treatment strategy for NDs is still a bottleneck. Considering its prominence, we used cheminformatics and system pharmacological approaches, with the aim to unravel the various molecular mechanisms represented by Bacopa-derived compounds in identifying the active human targets when treating NDs. First, using cheminformatics analysis combined with the drug target mining process, 52 active compounds and their corresponding 780 direct receptors were retrieved and computationally validated. Based on the molecular properties, bioactive scores and comparative analysis with commercially available drugs, novel and active compounds such as asiatic acid (ASTA) and loliolide (LLD) to treat the Alzheimer’s and SCA were identified. According to the interactions among the active compounds, the targets and diseases were further analyzed to decipher the deeper pharmacological actions of the drug. NDs consist of complex regulatory modules that are integrated to dissect the therapeutic effects of compounds derived from Bacopa in various pathological features and their encoding biological processes. All these revealed that Bacopa compounds have several curative activities in regulating the various biological processes of NDs and also pave the way for the treatment of various diseases in modern medicine.

1. Introduction

Medicinal plants are a pivotal reservoir of plenty of pharmacologically active compounds, and have been used as a therapeutic medicine for several diseases since the ancient period. Medicinal plants are the essential backbone of traditional medicine; around 3.3 billion people in the least-developed countries are still utilizing them on a regular basis [1]. Medicinal plants offer rich resources of pharmacological ingredients that can be used in drug development. Above and beyond that, these plants play a significant role in the development of human cultures around the globe. According to the International Union for Conservation of Nature (IUCN) report, worldwide, almost 80,000 flowering plant species are used for pharmaceutical purposes.
Bacopa monnieri (L.) is an important medicinal plant in Indian traditional Ayurvedic medicines. It is a small perennial herbaceous plant commonly known as ‘Brahmi’, belonging to the family Scrophulariaceae. It is a renowned Indian medicinal plant that has been used as a memory booster in the Ayurvedic medicinal system for more than 3000 years [2,3]. It is used in traditional medicine to treat various nervous disorders, digestive aid, improve learning, memory, and concentration and to provide relief to patients with anxiety, and skin disorders; specific uses include the treatment of asthma, insanity and epilepsy [4,5,6]. The Bacopa herb, also called nootropic herb, helps in the repair of damaged neurons, neuronal synthesis, and the restoration of synaptic activity, and improves brain function. B. monnieri contains alkaloid brahmine, nicotinine, herpestine, bacosides A and B, saponins A, B and C, triterpenoid saponins, stigmastanol, β-sitosterol, betulinic acid, D-mannitol, stigmasterol, α-alanine, aspartic acid, glutamic acid, and serine and pseudojujubogenin glycoside [7]. The plant possesses a wide variety of pharmacologically active principles including memory enhancing, tranquillizing, sedative, antidepressant, antioxidant, cognitive, anticancer, antianxiety, adaptogenic, antiepileptic, gastrointestinal effects, endocrine, gastrointestinal, smooth muscle relaxant effects, cardiovascular, analgesic, antipyretic, antidiabetic, antiarthritic, anticancer, antihypertensive, antimicrobial, antilipidemia, anti-inflammatory, neuroprotective, and hepatoprotective activities [8,9,10].
It has a very important role in Ayurvedic therapies for the treatment of cognitive disorders of aging [8,11]. Diverse mechanisms of action for its cognitive effects have been proposed, including acetylcholinesterase (AChE) inhibition, antioxidant neuroprotection, β-amyloid reduction, neurotransmitter modulation (acetylcholine [ACh], 5-hydroxytryptamine [5-HT], dopamine [DA]), choline acetyltransferase activation, and increased cerebral blood flow [12]. Theoretically, paring B. monnieri with a stimulant would ward off malaise, but this combination has not been tested [10]. Metabolites or active compounds from B. monnieri interact with the dopamine and serotonergic systems, but its main molecular mechanism concerns promoting neuron communication. It does this by increasing the growth of nerve endings, also called dendrites. Characteristics of saponins called “bacosides”, particularly bacoside A, have been considered to be the major bioactive constituents responsible for the cognitive effects of B. monnieri [13,14,15]. In addition, herbal medicine contains a plethora of active chemical compounds/molecules evolved through a long-term evolutionary process for safeguarding B. monnieri from various environmental stresses such as physio-chemical changes, the attack of pathogens, climatic changes, etc. The drug activity of herbal medicine may be due to the individual and synergistic action of phytomolecules. To the best of our knowledge, the molecular mechanism of such actions and the identification of the novel lead molecules against neurological diseases (NDs) are more difficult to study.
In light of this, and despite the significance of traditional Indian medicine, how the metabolites/compounds work and what their active human targets are are still vague. The present study aimed to explore the holistic molecular mechanism and the biological properties/pharmacological activity of phytomolecules derived from B. monnieri against NDs. The following issues need to be solved immediately: (i) Which active phytomolecules are involved in the regulatory processes for the treatment NDs? (ii) Which human targets are linked and modulated by the phytochemicals to achieve the biological activity and the purpose of curing NDs? With the emerging prosperity of pharmacological systems and powerful analytical tools such as cheminformatics, network pharmacology investigation allows us to understand the holistic mechanisms of Indian traditional medicine in treating complex NDs. The current study reveals deeper insights into the molecular mechanisms of active phytomolecules in treating NDs. The cheminformatics analysis was used to filter out the active and novel phytomolecules with potent pharmacological activity; also, the reliability of compound/drug–human target interactions was evaluated. The obtained potential human targets were then inputted into specific repositories to figure out their encoding NDs, pathways and holistic mechanisms of active phytomolecules. We hope that with the help of systems pharmacology and the exploration of molecular cross-talks of Indian traditional medicine, we will positively promote the development of new therapies for a mixture of neurological and other diseases in the near future.

2. Materials and Methods

An integrated cheminformatics and system pharmacology approach has been applied for the first time, to unveil the curative effects of Bacopa-derived, pharmacologically active compounds—consisting of: (1) target fishing and functional analysis to identify the compounds—direct target network; (2) network construction and analysis to illustrate the molecular mechanisms of Bacopa-derived compounds in treating NDs, particularly Alzheimer’s and SCA; (3) gene ontology enrichment for targets will pave the way for pathway integration analysis to reveal the regulatory mode of target players in multiple functional nodes from a signaling pathway level.

2.1. Collection of Phytomolecules

Detailed information on 52 phytochemicals from B. monnieri was collected from the literature and other web sources [16]. A list of biologically phytomolecules is depicted in Table 1.

2.2. Phytochemical Information Retrieval

In total, 52 biologically active plant-derived molecules from B. monnieri were procured from the PubChem database [17]. The 3D structures and Canonical SMILIES were collected from Molinspiration tool [18] and the PubChem database [17].

2.3. Human Target Imputations

The identified compounds with their canonical SMILIES were searched against human in Swiss TargetPrediction tool to retrieve the compounds in combating human targets (www.swisstargetprediction.ch/).

2.4. Mining of Human Targets and Its Features

Identified potential human targets were subjected onto the Expression Atlas database for retrieving human targets and their features, such as corresponding genomic transcripts, chromosome numbers, the start and end positions of the targets, and UniProt IDs [19].

2.5. Gene Ontology (GO) Analysis

Identified targets and their corresponding official gene symbols were subjected to the GOnet database (https://tools.dice-database.org/GOnet/) [20], to obtain GO against humans with a significant q-value threshold level of <0.05. Targets were also categorized as per GO molecular function, cellular component, and biological process according to the GOnet functional enrichment classification.

2.6. Network Construction

2.6.1. Compound–Target-Network (C-T-N)

A C-T-N was constructed to combat NDs by expounding the multi-target therapeutic feature of the pharmacologically active compounds. In this interaction, a possible target protein and a candidate compound were linked if the protein was targeted by the phyto-compound.

2.6.2. Target-Disease-Network (T-D-N)

The specific targets correlated with NDs were sorted out to explore a detailed interrelationship between potential targets and diseases, and those corresponding diseases with their potential targets were obtained from Expression Atlas database. Finally, T-D-N were built by linking all the target proteins with their relevant diseases using the previously obtained target associated disease information.
Visualization of all networks was accomplished by Cytoscape 3.7.2 [21]. In the obtained result network, nodes represent compounds, diseases and targets, whereas edges indicate the interactions between them.

2.6.3. Identification of Properties of Active Compounds

Phytochemicals with their corresponding canonical SMILIES were uploaded on to the Molinspiration tool to extract the significant calculation on phytomolecules with their molecular properties, and also to predict a bioactive score for the vital targets such as GPCR ligand activity (GPCR), Kinase inhibitor activity (Ki), protease inhibitor activity (Pi), enzymes and nuclear receptors (Ncr), and the number of violations (nvio) (http://www.molinspiration.com) [18].

2.6.4. Compound Comparison

Identified potential compounds with their significant molecular and bioactive properties were compared with commercially available drugs which are responsible for two different neurological diseases. The comparison revealed the pharmacologically active compounds with the help of GPCR, nvio, Ki, Pi, Ei, and Ncr properties.

3. Results

3.1. Compound Information Retrieval

Fifty-two numbers of phytomolecules were used as a query in the PubChem database and the Molinspiration tool to retrieve the Canonical SMILIES (Table S1) and 3D structure of the compounds (Figure 1). This collected information was used for further analyses.

3.2. Identification Compounds Combating Human Targets

Phytomolecules targeting human receptors were identified using the Swiss TargetPrediction tool. The study identified 52 phytomolecules targeting 780 human direct receptors. A list of compound and human target information was given in Table S2. These human receptors/targets involved in various functions, especially on the signal transducer and activator, neuronal acetylcholine receptor, apoptosis regulator Bcl–2, transcription factor activities, controling the microtubule associated protein functions, and so forth. In addition, a functional description of the target proteins is given in Table S3.

3.3. Properties of Human Targets

Fifty-two numbers of potential compounds and 52 active human targets with their corresponding information of UniProt ID, chromosome number, start and end position and ortholog information were retrieved, and are given in Table 2. These attributes will pave the way for deciphering their detailed molecular function.

3.4. GO Annotation

Human targets with their characteristic features were analyzed by official gene symbols using the GOnet database, and showed a significant involvement of these proteins in diverse molecular functions, cellular components and biological processes. The target gene-encoding proteins were predicted to be involved in biological regulation, including in synaptic regulation, immune system processes, cell–cell signaling, responses to stimuli, and developmental growth (Figure 2). In cellular components, targets were present in the synapse, organelle, membrane, and protein-containing complex (Figure 3). The inherent molecular functions of these proteins corresponded to different types of catalytic activity, binding activity and transcription regulator activity (Figure 4). The activation effect of these compounds on their encoding human targets would definitely reduce the risk of NDs and their associated diseases. For example, these active compounds serve as an inhibitor of Aβ – peptide accumulation in the brain in the development of Alzheimer’s disease.

3.5. C-T-N Analysis

The C-T-N result was displayed in Figure 5, consisting of 52 compounds and 780 human targets. Network interaction between the compounds and targets revealed the multi-target properties of elements, which is the essence of the plausible action mode of herbal drugs. As for the human targets, 52 compounds (Table 2) had a high probability, which showed the potential therapeutic effect of each compound present in Bacopa for combatting NDs, particularly Alzheimer’s and SCAby—modulating, inhibiting and or transducing the signals of these possible proteins.

3.6. T-D-N Analysis

T-D-N analysis illustrated the particular mechanisms of the potential drug case by case, which were most relevant to NDs (especially Alzheimer’s and SCA) and their associated targets, and were constructed into T–D interaction (Figure 6). The results showed that the treatment of NDs has the multi-target therapeutic efficacy present in Bacopa-derived compounds. These compounds may alter the targets (yet to be characterized), and their disease-associated pathways deserve more attention in continuous therapy.

3.7. Features of Active Molecules and Novel Compounds

The significant calculated properties of GPCR, Ki, Pi, Ei, Ncr, and nVio were retrieved and are given in Table 3. Based on the number of violations, enzyme inhibitor activity feature scores above 0.5 were considered to be of a significant level. According to this, commercially available drugs (responsible for Alzheimer’s and SCA) and compounds were compared, and novel compounds were identified and are listed in Table 4.

4. Discussion

The prevalence of NDs and the ineffectiveness of allopathic medicine in dealing with multiple trait disorders mean it is crucial that we research and develop successful curative systems. The significant efficacy of Indian traditional medicine has been well established over 1000 years of practice. Though the pharmaceutical components of drugs have been extracted and purified for new drug development, this method always ends in failure due to the violation of functional drug regulation. Traditional Indian medicine treating multiple complex diseases can be also seen as a complexity fronting another complexity, which primarily speculates through the equilibrium of the entire human body system by controlling the molecular interactions between all the elements within the species. Nevertheless, the exact mode of action on the target protein and pathway stage of traditional or herbal drug mechanisms remains a roadblock to us. Therefore, in the present study, we applied a cheminformatics and integrated pharmacology approach to human systems to unravel the pharmacological role of Bacopa-derived phytomolecules in the treatment of NDs at a molecular system level. This finding also described the novel compounds for treating Alzheimer’s and SCA by inhibiting AChE, β-amyloid accumulation in the brain and degenerative changes in the cerebellum and spinal cord, respectively.
In this study, with the help of cheminformatics and the PubChem database, 52 active compounds [16] were identified. All 52 compounds strongly interact with 780 direct human targets by drug targeting. Interestingly, it was predicted to be involved in diverse biological activities against NDs (Table S3) that have not been previously reported, demonstrating the reliability of the Swiss TargetPrediction, UniProtKB and GOnet evaluation methods. A Cytoscape v3.7.2 was then executed to get the molecular interaction straight to C-T-N. The analytical results revealed the various biological processes and modes of action used by drug compounds to achieve their curative effects. Finally, in further analyses to decipher their therapeutic potential of Bacopa, a T-D-N and an NDs-associated pathway (especially for Alzheimer’s and SCA/long-term depression) were constructed (Figures S1 and S2).
Previous reports have detailed that even though the “unique/single target” compounds utilize their utmost suppressive effects on their direct human targets, they may not always produce appropriate results [22]. To the best of our knowledge, various compounds acting on multiple or the same targets hit by the same compounds gain more efficacy on binding opportunities with each other and gain more chances of affecting the entire interaction equilibrium, making the Indian traditional medicine therapy more efficacious and fruitful to society. The C-T-N analytical results showed that there are multi-target functional modules in a single active compound. Of the 52 compounds with corresponding human targets, all of them were able to act on more than 15 active targets. For example, CHRNB1 (acetylcholine ion-channel activation receptor), indicated for the activation of the cholinergic receptor nicotinic β1 subunit, has shown that myasthenic syndrome is usually the result of the prolonged activation of CHRNB1, which is mechanistically correlated with the development of NDs. Accordingly, active compounds can exert their various biological effects in this complex human system with numerous compound–target–disease interactions by controlling the associated goals and pathways and achieving curative outcomes for NDs.
NDs are not caused by a single factor, affecting different types of NDs and aggravating one another. Some stressors involved in the development of NDs are complex, but at the same time drugs have not yet emerged specifically for those conditions. Therefore, the multi-level curative effects of Bacopa phytomolecules include controlling various physiological functional regulation, transcriptional reprogramming—particularly on cerebral blood flow, and their important effectiveness in the battle against NDs from a panoramic perspective. Since modern medicine is incapable of making a breakthrough so far in the treatment of NDs, why should we not transfer our focus to Indian traditional medicine, which is well documented as confronting complex NDs?

5. Conclusions

B. monnieri showed various potential actions in the amelioration of cognitive disorders and cognitive enhancement in healthy people. Biomedical research on B. monnieri is still at a roadblock. Notably, our results on novel compounds—with their encoding properties, active targets, biological processes, and interactions—have opened the research floodgates with the integration of Ayurveda to the modern medicine era. This study also hypothesizes that Bacopa compounds and their combination with other substances—as is recommended by the Ayurvedic and modern medicine system—may result in synergistic effects and need to be studied further. The ethical implications of drugs which enhance cognition are vital, but should be appropriately mitigated with social and ethical considerations as field researchers enter the brave, advancing world of neural enhancement.

Supplementary Materials

The following are available online at https://www.mdpi.com/2218-273X/10/4/536/s1, Figure S1: title, Table S1: title, Video S1: title.

Author Contributions

M.R. and P.M. conceived and designed the experiments. R.J., P.M. and V.S. performed the experiments. R.J., P.M., V.S. and J.-T.C. analyzed the results. R.J., P.M. wrote the manuscript. M.R. and. J.-T.C. revised the manuscript. M.R. approved the final version of the manuscript. All authors have read and approved the final manuscript.

Funding

This research received no extrenal funding.

Acknowledgments

The authors thank RUSA 2.0 [F. 24-51/2014-U, Policy (TN Multi-Gen), Dept of Edn, GoI]. RJ and PM sincerely acknowledge the computational and bioinformatics facility provided by the Alagappa University Bioinformatics Infrastructure Facility (funded by DBT, GOI; File No. BT/BI/25/012/2012,BIF). The authors also thankfully acknowledge DST-FIST (Grant No. SR/FST/LSI-639/2015(C)), UGC-SAP (Grant No.F.5-1/2018/DRS-II (SAP-II)) and DST-PURSE (Grant No. SR/PURSE Phase 2/38 (G)) for providing instrumentation facilities.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Phytomolecules and their 3D structures.
Figure 1. Phytomolecules and their 3D structures.
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Figure 2. Classification human targets with their biological processes. Orange color encodes human targets; green color represents biological processes.
Figure 2. Classification human targets with their biological processes. Orange color encodes human targets; green color represents biological processes.
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Figure 3. Classification human targets with corresponding cellular component. Orange color encodes human targets; green color represents cellular components.
Figure 3. Classification human targets with corresponding cellular component. Orange color encodes human targets; green color represents cellular components.
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Figure 4. Classification human targets with encoding molecular functions. Orange color encodes human targets; green color represents various molecular functions.
Figure 4. Classification human targets with encoding molecular functions. Orange color encodes human targets; green color represents various molecular functions.
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Figure 5. Compound target network (C-T-N). The red color represents compounds and the green color indicates targets.
Figure 5. Compound target network (C-T-N). The red color represents compounds and the green color indicates targets.
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Figure 6. Target disease network (T-D-N). The dark color represents targets and the light color indicates diseases.
Figure 6. Target disease network (T-D-N). The dark color represents targets and the light color indicates diseases.
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Table 1. List of Phytomolecuels.
Table 1. List of Phytomolecuels.
S. NoCompoundsAbbreviations/Acronyms
1NicotineNt
2D-MannitolD-Mn
3Bacoside ABCS A
4Bacopasaponin ABCSN A
5Bacopasaponin BBCSN B
6Bacopasaponin CBCSN C
7Bacopasaponin DBCSN D
8Bacopasaponin EBCSN E
9Bacopasaponin FBCSN F
10Bacopasaponin GBCSN G
11Bacopaside IBPS I
12Bacopaside IIBPS II
13Bacopaside IIIBPS III
14Bacopaside IVBPS IV
15Bacopaside VBPS V
16Bacopaside VIIIBPS VIII
17Bacopaside XIIBPS XII
18Plantainoside BPTS B
19Betulinic acidBTA
20Cucurbitacin ACCB A
21Cucurbitacin BCCB B
22Cucurbitacin CCCB C
23Cucurbitacin DCCB D
24Cucurbitacin ECCB E
25Stearic acidSTRA
26RosavinRSV
273,4Dimethoxycinnamic acid3,4DMCA
28Ascorbic acidASBA
29Asiatic acidASTA
30Brahmic acidBMA
31WogoninWG
32OroxindinOX
33LoliolideLLD
34StigmasterolSGMS
35β-sitosterolβ-SS
36Ebelin lactoneEBL
37StigmastanolSGMSL
38BacosterolBCSt
39BacosineBCSn
40HeptacosaneHCS
41OctacosaneOCS
42NonacosaneNCS
43TriacontaneTC
44HentriacontaneHTA
45DotriacontaneDOT
46ApigeninAG
47QuercetinQR
48Ursolic acidUSA
49LuteolinLT
50AsiaticosideASTS
51Bacopaside VIBPS VI
52Bacopaside VIIBPS VII
Table 2. Features of human active targets.
Table 2. Features of human active targets.
Compound NameTargetUniprot IDChr. NoStartEndOrthologs
NtCHRNB1P112301774450617457707Chrnb1 (Mus musculus)
D-MnTDP1Q9NUW8148995493990044768Tdp1 (Mus musculus)
BCS ASTAT3P40763174231332442388568Stat3 (Mus musculus)
BCSN AMBNL1Q9NR563152243828152465780Mbnl1 (Mus musculus)
BCSN BSTAT3P40763174231332442388568Stat3 (Mus musculus)
BCSN CPTPN2P17706181278547812929643Ptpn2 (Mus musculus)
BCSN DPTPN1P18031205051032150585241Ptpn1 (Mus musculus)
BCSN EMBNL1Q9NR563152243828152465780Mbnl1 (Mus musculus)
BCSN FMBNL1Q9NR563152243828152465780Mbnl1 (Mus musculus)
BCSN GMAPTP10636174589438246028334Mapt (Mus musculus)
BPS IFGF1P052305142592178142698070Fgf1 (Mus musculus)
BPS IIPTPN1P18031205051032150585241Ptpn1 (Mus musculus)
BPS IIIFGF1P052305142592178142698070Fgf1 (Mus musculus)
BPS IVMBNL1Q9NR563152243828152465780Mbnl1 (Mus musculus)
BPS VSTAT3P40763174231332442388568Stat3 (Mus musculus)
BPS VIIIMBNL1Q9NR563152243828152465780Mbnl1 (Mus musculus)
BPS XIISTAT3P40763174231332442388568Stat3 (Mus musculus)
PTS BPRKCGP05129195387919053907652Prkcg (Mus musculus),
BTAAKR1B10O602187134527592134541408Akr1b10 (Mus musculus)
CCB AITGALP20701163047265830523185Itgal (Mus musculus)
CCB BITGALP20701163047265830523185Itgal (Mus musculus)
CCB CITGALP20701163047265830523185Itgal (Mus musculus)
CCB DITGALP20701163047265830523185Itgal (Mus musculus)
CCB EITGALP20701163047265830523185Itgal (Mus musculus)
STRAFABP3P0541313136562531376850Fabp3 (Mus musculus)
RSVMMP1P0395611102789920102798160Mmp1a (Mus musculus)
3,4DMCACA1P0091588532760885379014Car1 (Mus musculus)
ASBATDP1Q9NUW8148995493990044768Tdp1 (Mus musculus)
ASTAAKR1B10AKR1B107134527592134541408Akr1b10 (Mus musculus)
BMAAKR1B10O602187134527592134541408Akr1b10 (Mus musculus)
WGPTGS1P232199122370530122395703Ptgs1 (Mus musculus)
OXADORA1P305421203090654203167405Adora1 (Mus musculus)
LLDTDP1Q9NUW8148995493990044768Tdp1 (Mus musculus)
SGMSARP10275106754403267730619Ar (Mus musculus)
β-SSTDP1Q9NUW8148995493990044768Tdp1 (Mus musculus)
EBLDRD2DRD211113409615113475691Drd2 (Mus musculus)
SGMSLARP10275106754403267730619Ar (Mus musculus)
BCStTDP1Q9NUW8148995493990044768Tdp1 (Mus musculus)
BCSnPOLBP0674684233845442371808Polb (Mus musculus)
HCSCES2O00748166693444466945096Ces2c (Mus musculus)
OCSCES2O00748166693444466945096Ces2c (Mus musculus)
NCSCDC25AP3030434815714648188402Cdc25a (Mus musculus)
TCCES2O00748166693444466945096Ces2c (Mus musculus)
HTACES2O00748166693444466945096Ces2c (Mus musculus)
DOTCES2O00748166693444466945096Ces2c (Mus musculus)
AGAKR1B10O602187134527592134541408Akr1b10 (Mus musculus)
QRCA12O43570156332137863382161Car12 (Mus musculus)
USAPOLBP0674684233845442371808Polb (Mus musculus)
LTMMP1P0395611102789920102798160Mmp1a (Mus musculus)
ASTSSTAT3P40763174231332442388568Stat3 (Mus musculus)
BPS VIFGF1P052305142592178142698070Fgf1 (Mus musculus)
BPS VIIMAPTP10636174589438246028334Mapt (Mus musculus)
Table 3. Active Compounds and its Features.
Table 3. Active Compounds and its Features.
CompoundGPCR lgKiNcrPiEiNvio
Nt−0.32−0.79−1.57−0.8−0.310
D-Mn−0.64−0.88−0.88−0.72−0.011
BCS A−1.05−2−1.64−0.74−1.143
BCSN A−0.77−1.61−1.13−0.48−0.683
BCSN B−0.57−1.51−1.21−0.36−0.583
BCSN C−2.69−3.53−3.34−2.21−2.673
BCSN D−0.89−1.87−1.54−0.59−0.973
BCSN E−3.6−3.79−3.73−3.53−3.513
BCSN F−3.65−3.82−3.77−3.6−3.573
BCSN G−0.62−1.61−1.24−0.46−0.523
BPS I−3.13−3.68−3.61−2.75−2.93
BPS II−2.99−3.6−3.48−2.6−2.953
BPS III−1.65−2.85−2.47−1.05−1.73
BPS IV−1.04−1.99−1.52−0.76−1.043
BPS V−1.04−1.99−1.52−0.76−1.043
BPS VIII−3.65−3.82−3.77−3.6−3.573
BPS XII−3.65−3.8−3.77−3.58−3.593
PTS B0.21−0.040.10.130.362
BTA0.31−0.50.930.140.551
CCB A0.45−0.420.790.10.521
CCB B0.52−0.40.880.10.561
CCB C0.42−0.360.80.120.611
CCB D0.54−0.330.910.060.651
CCB E0.47−0.380.690.040.471
STRA0.11−0.20.170.060.21
RSV0.14−0.08−0.080.020.341
3,4DMCA−0.42−0.66−0.15−0.68−0.130
ASBA−0.53−1.09−0.01−0.810.20
ASTA0.2−0.460.910.280.660
BMA0.25−0.450.930.290.751
WG−0.140.120.13−0.310.230
OX0.02−0.060.24−0.060.391
LLD−0.45−0.91−0.04−0.330.560
SGMS0.12−0.480.74−0.020.531
β-SS0.14−0.510.730.070.511
EBL0.33−0.120.920.130.681
SGMSL0.21−0.350.650.240.481
BCSt0.21−0.370.560.150.471
BCSn0.29−0.490.910.190.561
HCS0.04−0.040.040.040.031
OCS0.04−0.040.040.040.031
NCS0.04−0.040.040.030.021
TC0.04−0.040.040.030.021
HTA0.03−0.030.040.030.021
DOT0.03−0.030.030.030.021
AG−0.070.180.34−0.250.260
QR−0.060.280.36−0.250.280
USA0.28−0.50.890.230.691
LT−0.020.260.39−0.220.280
ASTS−3.38−3.7−3.55−2.96−3.263
BPS VI−1.65−2.85−2.47−1.05−1.73
BPS VII−2.73−3.56−3.37−2.28−2.623
Table 4. Comparison of Drug and Novel Compounds.
Table 4. Comparison of Drug and Novel Compounds.
DrugGPCR lgKiNcrPiEiNvio
Alzheimer’s Disease
Tacrine−0.11−0.37−0.93−0.590.430
Edrophonium−0.64−1.59−1.42−0.870.690
Neostigmine−0.22−0.82−0.35−0.07−0.660
Donepezil0.22−0.160.030.030.250
Pyriostigmine−0.19−0.86−2.19−0.460.590
CompoundGPCR lgKiNcrPiEinvio
WG−0.140.120.13−0.310.230
ASTA0.2−0.460.910.280.660
AG−0.070.180.34−0.250.260
QR−0.060.280.36−0.250.280
LLD−0.45−0.91-0.04−0.330.560
CCB A0.45−0.420.790.10.521
CCB B0.52−0.40.880.10.561
CCB C0.42−0.360.80.120.611
BMA0.25−0.450.930.290.751
OX0.02−0.060.24−0.060.391
USA0.28−0.50.890.230.691
BCSn0.29−0.490.910.190.561
BTA0.31−0.50.930.140.551
Spinocerebellar Ataxia
DrugGPCR lgKiNcrPiEinvio
Phenytoin0.07−0.47−0.320.01−0.020
Primidone−0.06−0.58−0.64−0.38−0.060
Valporic Acid−0.83−1.55−0.78−0.74−0.390
Trimethadione−0.59−1.44−1.53−0.54−0.60
Mephenytoin−0.65−1.25−1.68−0.76−0.510
Lamotrigine−0.160.36−1.12−0.840.080
Ethosuximide−0.76−2.1−1.7−1.1−0.380
Ethotoin−0.22−0.98−1.32−0.43−0.160
Oxcarbazepine−0.020.1−0.35−0.26−0.20
CompoundGPCR lgKiNcrPiEinvio
ASTA0.2−0.460.910.280.660
WG−0.140.120.13−0.310.230
LLD−0.45−0.91−0.04−0.330.560
OX0.02−0.060.24−0.060.391
BCSn0.29−0.490.910.190.561
BTA0.31−0.50.930.140.551
D-Mn−0.64−0.88−0.88−0.72−0.011
SGMS0.12−0.480.74−0.020.531
β-SS0.14−0.510.730.070.511
BCSt0.21−0.370.560.150.471
HCS0.04−0.040.040.040.031
OCS0.04−0.040.040.040.031
NCS0.04−0.040.040.030.021
TC0.04−0.040.040.030.021
HTA0.03−0.030.040.030.021
DOT0.03−0.030.030.030.021

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Jeyasri, R.; Muthuramalingam, P.; Suba, V.; Ramesh, M.; Chen, J.-T. Bacopa monnieri and Their Bioactive Compounds Inferred Multi-Target Treatment Strategy for Neurological Diseases: A Cheminformatics and System Pharmacology Approach. Biomolecules 2020, 10, 536. https://doi.org/10.3390/biom10040536

AMA Style

Jeyasri R, Muthuramalingam P, Suba V, Ramesh M, Chen J-T. Bacopa monnieri and Their Bioactive Compounds Inferred Multi-Target Treatment Strategy for Neurological Diseases: A Cheminformatics and System Pharmacology Approach. Biomolecules. 2020; 10(4):536. https://doi.org/10.3390/biom10040536

Chicago/Turabian Style

Jeyasri, Rajendran, Pandiyan Muthuramalingam, Vellaichami Suba, Manikandan Ramesh, and Jen-Tsung Chen. 2020. "Bacopa monnieri and Their Bioactive Compounds Inferred Multi-Target Treatment Strategy for Neurological Diseases: A Cheminformatics and System Pharmacology Approach" Biomolecules 10, no. 4: 536. https://doi.org/10.3390/biom10040536

APA Style

Jeyasri, R., Muthuramalingam, P., Suba, V., Ramesh, M., & Chen, J. -T. (2020). Bacopa monnieri and Their Bioactive Compounds Inferred Multi-Target Treatment Strategy for Neurological Diseases: A Cheminformatics and System Pharmacology Approach. Biomolecules, 10(4), 536. https://doi.org/10.3390/biom10040536

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