This paper investigates two possible treatment targets for neuroblastoma (NB) stage 4 (NBS4), c-Src kinase (Csk) and retinoic acid (RA) signalling pathways as potential candidates for a multi-target drug. Research has demonstrated that many cancer cells overexpress and/or hyperactivate c-Src, a tyrosine that is a member of the Src-family kinases. In the case of NBS4, there are indications that successful inhibition of c-Src could inhibit disease progression. Research into the altered signalling of RA, which preserves the differentiated state of adult neurons, neural stem cells, and NB cells (SH-SY5Y), is also investigated as a potential multi-target drug.
Methods:
Using computer-aided technology, including OpenEye Scientific suite, Molegro Virtual docking, Samson suite, and Discovery Studio Visualiser, the results revealed that the receptors for both targets, Csk and RA, share similar amino acid sequencing that ranges from 80–100%, offering the possibility of further testing for multi-target drug use. Work was done to explore possible synthesis routes for each of the four compounds using the retrosynthesis program Spaya. Predictive toxicology was done using the Toxicity Estimation Software Tool (T.E.S.T.).
Results:
Four compounds (inhibitors) targeting the Csk tyrosine kinase and RA pathways were identified as potential inhibitors.
Conclusions:
Currently, no effective therapeutic agents for NBS4 exist. Immunotherapy which has proven effective in treating various cancers, is currently used to treat NBS4 and has a 40% to 50% survival rate. This paper investigates two possible treatment targets for NBS4, Csk and RA signalling pathways as possible candidates for a multi-target drug. Four potential inhibitors have been identified.
There are five stages in the clinical neuroblastoma (NB) staging system: 1, 2A, 2B, 3, 4S, and 4 [1]. For those diagnosed with NB stage 4 (NBS4) the treatment options are limited with a survival rate of between 40% to 50% [1]. In a review of drug therapies aimed at treating NBS4, Gerges and Canning [2] (2024) examined the potential for creating multi-targeted drugs to treat high-risk NBS4 using computational methods available to medicinal chemistry. Finding novel therapeutic drug targets by this approach usually involves computational techniques like molecular docking, homology modelling, molecular dynamics, and quantitative structure-activity relationships (QSAR) [3]. The work reported here follows on from that review and investigates two different types of inhibitors for the signalling pathways c-Src kinase (Csk) and retinoic acid (RA) signalling pathways[2]. Six targets were originally identified and investigated by the authors [2] and the results of the Protein Aligner revealed that the receptors for four of the six targets shared similar amino acid sequencing that ranged from 80–100%. The four targets that share similar sequencing included histone deacetylase (HDAC), bromodomain (BRD), hedgehog (HH), and tropomyosin receptor kinase (TRK) and are the focus of a separate paper. The remaining two targets of the original six, Csk and RA signalling pathways showed similarity across their receptors of 80–100% are the focus of this paper. Their potential for multi-targeted drug use was investigated further with four compounds (inhibitors) targeting the Csk and RA pathways identified.
Current treatment for NBS4
With therapeutic agents finding little success in the treatment of NBS4, immunotherapy which has been effective in treating a number of cancers is currently used. This treatment uses monoclonal antibodies and has increased the 5-year survival rate of NBS4 to 40% to 50% [4–6]. Dinutuximab (UNITUXIN), a monoclonal antibody, is an example of cancer immunotherapy and for patients with NBS4, it is used in conjunction with other therapeutic agents. It was approved by the FDA in 2015 for use in the United States [6].
c-Src kinase inhibitors
Proliferation, differentiation, migration, and membrane trafficking are just a few of the cellular functions that are critical to the Src family kinases (SFKs) of non-receptor tyrosine kinases (TK) [7]. TK deregulation has been linked to cancer, with pharmaceutical companies and academic institutions now targeting small molecule TK inhibitors (TKIs) as one of the largest drug families for the treatment of cancer (Figure 1) [8]. TKIs may be associated with fewer harmful side effects during anti-tumor treatments because they target particular molecular targets [8]. As a result, numerous TKIs have undergone testing for their anti-proliferative and anti-cancer properties in vitro and in vivo, with some approved for clinical trials and others currently used in cancer treatment [9]. One subclass of non-receptor TKs targeted in the treatment of human cancers is the SFKs. Of these, c-Src promotes angiogenesis, invasion, migration, and cell proliferation (Figure 1) [10]. c-Src hyperactivation results in abnormal cell activity, which aids in cancer development. High expression levels of c-Src, which have been found in several cancers, are typically associated with a poor overall survival prognosis [11]. More than one study has shown that c-Src inhibitors play an important role in antiproliferative activity in SH-SY5Y cells (NBS4 cell line) [12–23].
c-Src in cancer. VEGF: vascular endothelial growth factor; VEGFR2: VEGF receptor 2; LATS: large tumor suppressor; YAP: Yes-associated protein; TAZ: transcriptional co-activator with PDZ-binding motif; TEAD: transcriptional enhanced associate domain; GAPs: GTPase-activating proteins. Created in BioRender. Gerges, A. (2024) https://BioRender.com/t65n288
Retinoic acid inhibitors
The small lipophilic molecule RA, derived from vitamin A, is essential for axonal growth, neuronal differentiation, neuronal patterning, and embryonic development (Figure 2) [24]. Research on the effect of RA on neuronal development has improved our knowledge of neurodegenerative diseases [25]. It has been noted that the symptoms of neurodegenerative diseases are caused by RA altered signalling, which maintains the differentiated state of adult neurons, neural stem cells, and NB cells in particular (cell line SH-SY5Y) [26–36].
Retinoic Acid receptors and their actions. The three retinoic acid receptor subtypes (RARα, RARβ and RARγ) act as ligand-inducible transcription factors binding to DNA regulatory elements in the promoter regions of target genes by forming heterodimers with the retinoid X receptors (RXRα, RXRβ and RXRγ). RDH: retinol dehydrogenase; PALDH: retinaldehyde dehydrogenase; CRABP: cellular retinoic acid-binding protein; FABP5: fatty acid binding protein 5; PPARβ/δ: peroxisome proliferator-activated receptor beta/delta; ERα: estrogen receptor alpha; ERE: estrogen response elements; E2: estradiol; RARα: retinoic acid receptor-alpha; RXR: retinoid X receptor; PDK-1: phosphoinositide-dependent kinase-1; RA: retinoic acid; RARE: RA responsive element. Created in BioRender. Gerges, A. (2025) https://BioRender.com/v19a099
Medicinal chemistry approach to drug development
In the search for a multi-target drug for NBS4 using advanced medicinal chemistry software, the approach is to assesses the possibility of different targets (Figures 1 and 2) by assessing receptor similarities and selecting two lead compounds for each target (four compounds in total), see Figure 3 [8] and Figure 4 [29], that have demonstrated an inhibitory effect on NBS4 cells to form the basis of a search for a multi-targeted drug [29].
Chemical structure of the lead c-Src inhibitors, compounds 18 and 29
Chemical structure of the lead RA pathway inhibitors, compounds 8A and 8E
For the two targets (Csk and RA) two receptors from each target were selected (Table 1) and their amino acid sequence similarity tested using Protein Aligner [37] (see Figure 5), which reported 80–100% similarity. Protein Aligner checks for amino acid sequence similarity between receptors with high similarity indicating their suitability for use in cross-docking. For the purposes of this work docking involves docking a compound to a receptor known for that target (i.e. Csk 4O2P [8] and 5D10 [38]) whereas cross-docking involves docking a compound to a receptor that belongs to a different target (i.e. RA 1CBQ and 1CBS [39]) and vice versa. The aim of cross-docking is to explore the suitability of selected compounds belonging to different targets to determine their suitability for use as a multi-target drug. This is a process that involves selecting known lead compounds to produce hitlists of compounds, and was done using BROOD [40] as part of the OpenEye suite.
Drug targets and their selected receptors
Drug target (n = 2)
Proteins selected from PDB (n = 4)
c-Src kinase (Csk)
4O2P [8] and 5D10 [38]
Retinoic acid (RA)
1CBQ and 1CBS [39]
PDB: Protein Data Bank
Several BROOD rounds (Figure 6) were completed on the two lead compounds for each target to produce hitlists using “Shape and Color” and “Shape and Electrostatics”. On completion, BROOD ranked each of the hitlists according to BROOD hitlist parameters (see list below) and the top 25 of each hitlist was selected to run on OEDocking, using FRED (Figure 7) [41], ROCS (Figure 8) [42], AFITT (Figure 9) [43], and VIDA [44]. In addition, the Samson docking suite, including AutoDock Vina Extended (Figures 10 and 11) [45, 46] and Fitted (Molecular Forecaster) [47], with another docking program, Molegro [48], acted as confirmation for both the docking and cross-docking procedures. From this process, eight compounds for the Csk target were identified and six from the RA target, making a total of 14 compounds. All 14 compounds showed improved parameters compared to the original lead compounds (see Table 2). The compounds for each individual target were then cross-docked with the receptors identified for the other targets [43]. From the 14 compounds run, four showed potential suitability for multi-target use (two from each list) see Table 2.
Docking results from AFITT with the top clusters from the hitlists (n = 14)
Target
Clusters
AFFIT
FRED
AutoDock Vina Extended
Molegro
Fitted
RA (n = 6)
Clusters
1CBS
1CBS
1CBS
1CBS
1CBS
1
Cluster 18, 1 of 1
0.6619
–6.652
–8.355
106.873
–25.3637
2
Cluster 3, 1 of 30
0.6612
–7.42
–9.364
32.95
–28.3973
3
Cluster 23, 1 of 25
0.6207
–7.27
–9.222
113.34
–22.8749
4
Cluster 20, 1 of 7
0.5474
–9.061
–9.472
14.94
–23.4724
5
Cluster 21, 1 of 5
0.5448
–4.6477
–8.952
76.28
–20.8754
6
Cluster 22, 1 of 4
0.5448
–4.67
–8.843
–10.53
–25.0819
7
8E (lead compound)
0.4543
–4.156
–8.589
–94.37
–23.6039
c-Src (n = 8)
Clusters
402P
402P
402P
402P
402P
1
Cluster 16, 1 of 1
0.7654
–6.03
–8.384
–58.58
–25.413
2
Cluster 20, 1 of 5
0.7471
–6.51
–8.361
–45.59
–26.526
3
Cluster 7, 1 of 1
0.5397
–6.43
–8.856
–60
–28.785
4
Cluster 19, 1 of 5
0.5065
–5.7
–8.386
–58.99
–22.472
5
Cluster 1, 1 of 43
0.503
–6.34
–8.931
–58.72
–24.192
6
Cluster 17, 1 of 3
0.489
–5.65
–8.823
–39.86
–26.285
7
Cluster 4, 1 of 1
0.3898
–6.88
–8.392
58.04
–28.788
8
Cluster 3, 1 of 1
0.3717
–3.63
–8.655
–44.07
–27.369
9
Compound 18 (lead compound)
0.7432
–6.34
–8.108
–45.94
–24.476
Selected compounds in bold. RA: retinoic acid
To check and compare the compounds (clusters) for toxicity and mutagenicity, the Toxicity Estimation Software Tool (T.E.S.T.) was used to provide the prediction mechanisms of the toxic action of the clusters [49]. The results from T.E.S.T. showed some similarity with the original lead compounds (Table 3), which also confirmed their suitability for use. Further work was done to explore possible synthesis routes for each of the four compounds using the retrosynthesis program Spaya [50].
Results from the T.E.S.T. compared to the lead compounds
Clusters
Bioconcentration factor1
Ames mutagenicity2
Oral rat LD503 [–Log10(moL/kg)]
48-hour T. pyriformis IGC504 (mg/L)
18, 1 of 1
19.08
Negative
373.49
N/A
23, 1 of 25
18.78
Negative
833.23
N/A
19, 1 of 5
39.65
N/A
839.23
N/A
4, 1 of 1
21.54
N/A
1,714.20
N/A
Compound 8A
12.25
Negative
881.07
N/A
Compound 8E
15.68
Negative
1,193.20
N/A
Compound 18
15.64
Positive
1,010.18
N/A
Compound 29
28.91
Positive
457.49
N/A
1 Bioconcentration factor: ratio of the chemical concentration in fish as a result of absorption via the respiratory surface to that in water at a steady state; 2 Ames mutagenicity: a compound is positive for mutagenicity if it induces revertant colony growth in any strain of Salmonella typhimurium; 3 Oral rat LD50: amount of chemical (mg/kg body weight) that causes 50% of rats to die after oral ingestion; 4 48-hour T. pyriformis IGC50: Concentration of the test chemical in water (mg/L) that causes 50% growth inhibition to Tetrahymena pyriformis after 48 hours. N/A: not applicable
Materials and methodsMaterials
Computer programs:
OpenEye Scientific programs, which include various applications. The suite comprises BROOD, VIDA, MakeReceptor, FRED, and AFITT;
Molegro Virtual Docker;
The Samson suite includes Protein Aligner, AutoDock Vina Extended, and the Fitted suite by Molecular Forecaster;
T.E.S.T.;
BIOVIA Discovery Studio Visualizer [51];
Spaya-retrosynthesis software.
Methods
Identifying drug targets;
Selection of two proteins (receptors) for each target;
Download the Protein Data Bank (PDB) files and their electron density map from the PDB database;
Comparing the similarities of the receptors. Run protein similarity on Samson (Protein Aligner) to determine suitability;
Selection of two lead compounds for each type;
Run the lead compounds on BROOD (from the OpenEye suite) and produce hitlists using Shape and Colour and Shape and Electrostatics;
Receptor preparations using MakeReceptor from the OpenEye suite;
Docking the hit compounds with OpenEye suite (FRED), Molegro, and Samson suite (AutoDockVina and Fitted);
Run cross-docking: each hitlist clusters from one target to the other target (using their protein/receptor);
Run hits with AFITT to rank the compounds according to their fitting probabilities;
Run selected clusters on ROCS;
Run selected clusters on T.E.S.T.;
Run clusters on Spaya to find the best synthesis route.
Results
Figure 5 shows the Protein alignment [37] (similarities) between the selected proteins ranging from 80% to 100%.
Protein alignment of the selected receptors from two targets. The similarity (in grey) was obtained using Protein Alignment by Samson. Zero indicates 100% similarity, and 100% means no similarity
Figure 6 below shows some of the hitlist from BROOD [40].
Print screen of BROOD (Shape and Color) outcome when using compound 18 as a lead compound, only showing the first 11 clusters
BROOD Hitlist parameters (Figure 6) include:
AroRingCt: number of aromatic rings in the molecule;
ClusterID/IdeaGroup: cluster ID of the molecule;
Colour: the replacement fragment's colour Tanimoto score in comparison to the query fragment;
Combo: Tanimoto combo score for the replacement fragment's shape and colour in comparison to the query fragment;
Egan: the Boolean indicates if the molecule satisfies the Egan bioavailability model;
Fragment: SMILES string of the replacement fragment;
Freq: the replacement fragment’s frequency;
fsp3C: the molecule’s fraction of sp3 hybridized carbon atoms;
HvyAtoms: number of heavy atoms in the molecule;
LipinskiDon: number of Lipinski donors in the molecule;
LipinskiAcc: number of Lipinski acceptors in the molecule;
LipinskiFail: Boolean specifying whether the molecule fails Lipinski’s rule of five;
Local strain: calculated local strain of the molecule;
Molecular TanimotoCombo: shape + colour Tanimoto combo score of the molecule against the query molecule;
MolWt: molecular weight of the molecule;
p(active): belief score of the molecule;
RingCt: number of ring atoms;
RingRatio: ratio of the number of ring atoms to the total number of heavy atoms;
Rotors: number of rotatable bonds in the molecule;
Shape: compare the replacement fragment’s Shape Tanimoto score to that of the query fragment;
Source Mols: SMILES strings of the molecules the replacement fragment is part of;
Source Mol Labels: labels of the molecules the replacement fragment is part of;
tPSA: calculated topological polar surface area of the molecule;
Veber: Boolean specifying whether the molecule passes the Veber bioavailability model;
XlogP: calculated LogP of the molecule [52].
The next stage was to dock the hitlists with their relevant receptors: Figure 7 shows one of the docking outcomes using FRED (OpenEye suite).
FRED docking result: 4O2P with some of the selected clusters
The chosen compounds were also subjected to ROCS, a program that scores and aligns a database of molecules with a query. The score assigns a number to molecules according to their likelihood of having biological characteristics in common with the query molecule (see Figure 8).
An example from ROCS outcome
AFITT is another crystallographic tool from the OpenEye suite (Figure 9). By combining the shape and MMFF technologies of OpenEye, AFITT creates a new combined forcefield that fits small molecules into crystallographic density while preserving superior chemistry. It also offers an interface to external refinement programs, such as real space correlation coefficient (RSCC) calculation and interactive Ramachandran plots to verify the refinement [43].
Docking receptor 5D10 with all clusters from c-Src, and RA with AFITT
AutoDock Vina Extended (Figures 10 and 11) showing the docking of clusters to receptors 402P and 1CBS.
Docking receptor 4O2P with all the clusters from c-Src and RA, including the lead compounds, using AutoDock Vina Extended from Samson suite
Docking receptor 1CBS with all clusters from c-Src, and RA, including the lead compounds, using AutoDock Vina Extended
Retrosynthesis results using Spaya
Synthesis of cluster 4, 1 of 1, c-Src inhibitor (Figure 12).
Synthesis of cluster 4, 1 of 1, c-Src inhibitor
Synthesis of cluster 19, 1 of 5, c-Src inhibitor (Figure 13).
Synthesis of cluster 19, 1 of 5, c-Src inhibitor
Synthesis of clusters 18, 1 of 1, RA pathway inhibitor (Figure 14).
Synthesis of clusters 18, 1 of 1, RA pathway inhibitor
Synthesis of cluster 23, 1 of 25, RA pathway inhibitor (Figure 15).
Synthesis of cluster 23, 1 of 25, RA pathway inhibitor
Discussion
The process of developing a multi-target drug is described as taking “a well-established primary target for a particular disease [and adding], secondary activities […] to enhance efficacy and reduce the effect” [53]. Creating such a drug involves taking the inhibitory effects of two or more drugs and combining them into a single molecule [54]. Previous methods used for drug development include “Pharmacophore” and “Screening”. This article employs a computer-aided virtual screening (VS) strategy with some modifications in the pursuit of multi-target drug discovery. Having identified two targets, two receptors from each target were selected (see Table 1) and a Protein Aligner tool from Samson was used to check for their suitability. Protein Aligner checks for amino acid sequence similarity between receptors with high similarity indicating their suitability for use in cross-docking. The aim of cross-docking is to explore the selected compounds for use as a multi-target drug. This is a process that involves selecting known lead compounds to produce hitlists of compounds and was done using BROOD [40] as part of the OpenEye suite.
As part of the OpenEye suite, several rounds from BROOD were completed on the two lead compounds for each target to produce hitlists using “Shape and Color” and “Shape and Electrostatics” with the top 25 of each hitlist selected to run on OEDocking [41], ROCS [42], AFITT [43], and VIDA [44]. The hitlists of compounds (clusters) were docked, and the selected compounds cross-docked. The clusters were docked with more than one docking program as a means to validating the result. The final ranking of the selected clusters was done on AFITT as the receptor preparation with the tool MakeReceptor, giving the user more control over the receptor-creating process. AFITT also has the advantage of real-space fitting of ligands in density, integrated with REFMAC, PHENIX, BUSTER, CNX, and COOT and fragment and cocktail fitting [43]. In AFFIT, it is possible to select more than one ligand to fit generation of high-quality refinement dictionaries for use. This can be done during reciprocal space refinement that includes the use of forcefield (MMFF); semi-empirical (AM1, PM3) methods during reciprocal space refinement for BUSTER and Phenix; real space fitting of protein residues; proper handling of covalently bonded ligands, and proper handling of multiple occupancy ligands.
The ranking is based not only on the best results but also on the ability of the identified compounds to cross-dock on the receptors of other targets, and it was this process that led to the selection of the four compounds. Using the tool ROCS provided cluster validation, which is based on a large database search [42]. The toxicity and mutagenicity of the four compounds were tested using T.E.S.T. to provide the prediction mechanisms of the toxic action of the clusters [49]. The results from T.E.S.T. showed some similarity with the original lead compounds (Table 3), which also provided data on their suitability for use. Further work was done to explore possible synthesis routes for each of the four compounds using the retrosynthesis program Spaya [50].
In conclusion using a computer-aided modified VS approach, four compounds were identified demonstrating the possibility of inhibiting two targets simultaneously: the Csk and the RA signalling pathways. Going forward, future research will concentrate on preparing and evaluating the identified compounds both in vitro and in vivo [55].
AbbreviationsCsk
c-Src kinase
NB
neuroblastoma
NBS4
neuroblastoma stage 4
PDB
Protein Data Bank
RA
retinoic acid
SFKs
Src family kinases
T.E.S.T
Toxicity Estimation Software Tool
TK
tyrosine kinase
TKIs
tyrosine kinase inhibitors
VS
virtual screening
DeclarationsAcknowledgements
Thanks to Dr. Corinne Kay for her advice and support over the years and to Mr. Colin Gaudion for testing some of the programs used for this work.
Author contributions
AG: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Resources, Validation, Writing—original draft. UC: Writing—review & editing. Both authors read and approved the submitted version.
Conflicts of interest
The authors’ daughter, Isabella, was diagnosed with NBS4 in January 2003. Isabella relapsed in March 2005 and died in July 2005, a week after her seventh birthday.
Ethical approval
Not applicable.
Consent to participate
Not applicable.
Consent to publication
Not applicable.
Availability of data and materials
The datasets [generated/analyzed] for this study can be found in the [Zenodo database] [https://zenodo.org/records/14620395?preview=1&token=eyJhbGciOiJIUzUxMiJ9.eyJpZCI6IjQ0OGE0YzVkLWU2N2EtNDgwMy04YzJjLTg2MmQ2YWY4ZGE1MiIsImRhdGEiOnt9LCJyYW5kb20iOiI2YTM2Y2RhYzhhOTM5NzI4MzVmZmYyNTZiNmExYTBiZSJ9.wD-fegFi-zj4iOVk6_c0rL8eRIZYsivt9I1zL5gTWy81pUNAp_EjI1XIWawvfZP83Y7ym8Scu4_q2g9F73KFdg].
Open Exploration maintains a neutral stance on jurisdictional claims in published institutional affiliations and maps. All opinions expressed in this article are the personal views of the author(s) and do not represent the stance of the editorial team or the publisher.
ParaboschiIPriviteraLKramer-MarekGAndersonJGiulianiSNovel Treatments and Technologies Applied to the Cure of NeuroblastomaChildren (Basel)2021848210.3390/children806048234200194PMC8226870GergesACanningUNeuroblastoma and its Target Therapies: A Medicinal Chemistry ReviewChemMedChem202419e20230053510.1002/cmdc.20230053538340043KumaloHMBhakatSSolimanMESTheory and applications of covalent docking in drug discovery: merits and pitfallsMolecules2015201984200010.3390/molecules2002198425633330PMC6272664MoraJDinutuximab for the treatment of pediatric patients with high-risk neuroblastomaExpert Rev Clin Pharmacol201696475310.1586/17512433.2016.116077526934530BhoopathiPMannangattiPEmdadLDasSKFisherPBThe quest to develop an effective therapy for neuroblastomaJ Cell Physiol202123677759110.1002/jcp.3038433834508PenningtonBRenSBartonSBacelarMEdwardsSJDinutuximab Beta for Treating Neuroblastoma: An Evidence Review Group and Decision Support Unit Perspective of a NICE Single Technology AppraisalPharmacoeconomics2019379859310.1007/s40273-018-0744-030465228RoskoskiR JrSrc protein-tyrosine kinase structure, mechanism, and small molecule inhibitorsPharmacol Res20159492510.1016/j.phrs.2015.01.00325662515TintoriCFallacaraALRadiMZamperiniCDreassiECrespanEet al.Combining X-ray crystallography and molecular modeling toward the optimization of pyrazolo[3,4-d]pyrimidines as potent c-Src inhibitors active in vivo against neuroblastomaJ Med Chem2015583476110.1021/jm501315925469771PytelDSliwinskiTPoplawskiTFerriolaDMajsterekITyrosine kinase blockers: new hope for successful cancer therapyAnticancer Agents Med Chem20099667610.2174/18715200978704775219149483BruntonVGFrameMCSrc and focal adhesion kinase as therapeutic targets in cancerCurr Opin Pharmacol200884273210.1016/j.coph.2008.06.01218625340GrantSDentPKinase inhibitors and cytotoxic drug resistanceClin Cancer Res2004102205710.1158/1078-0432.ccr-0001-415073093RadiMBrulloCCrespanETintoriCMusumeciFBiavaMet al.Identification of potent c-Src inhibitors strongly affecting the proliferation of human neuroblastoma cellsBioorg Med Chem Lett20112159283310.1016/j.bmcl.2011.07.07921856155SchenoneSZanoliSBrulloCCrespanEMagaGCurrent Advances in the Development of Anticancer Drugs Targeting Tyrosine Kinases of the Src FamilyCurrent Drug Therapy200831587610.2174/157488508785747862VitaliRManciniCCesiVTannoBPiscitelliMMancusoMet al.Activity of tyrosine kinase inhibitor Dasatinib in neuroblastoma cells in vitro and in orthotopic mouse modelInt J Cancer200912525475510.1002/ijc.2460619623650PMC7184229WheelerDLIidaMDunnEFThe role of Src in solid tumorsOncologist2009146677810.1634/theoncologist.2009-000919581523PMC3303596KruewelTSchenoneSRadiMMagaGRohrbeckABottaMet al.Molecular characterization of c-Abl/c-Src kinase inhibitors targeted against murine tumour progenitor cells that express stem cell markersPLoS One20105e1414310.1371/journal.pone.001414321152443PMC2994747LoveraSSuttoLBoubevaRScapozzaLDölkerNGervasioFLThe different flexibility of c-Src and c-Abl kinases regulates the accessibility of a druggable inactive conformationJ Am Chem Soc20121342496910.1021/ja210751t22280319LinYRouxBComputational analysis of the binding specificity of Gleevec to Abl, c-Kit, Lck, and c-Src tyrosine kinasesJ Am Chem Soc2013135147415310.1021/ja405939x24001034PMC4026022LinYMengYHuangLRouxBComputational study of Gleevec and G6G reveals molecular determinants of kinase inhibitor selectivityJ Am Chem Soc2014136147536210.1021/ja504146x25243930PMC4210138MengYLinYRouxBComputational study of the "DFG-flip" conformational transition in c-Abl and c-Src tyrosine kinasesJ Phys Chem B201511914435610.1021/jp511792a25548962PMC4315421RedavideERole of an N2-Src-COPII pathway in neuroblastoma differentiation [dissertation]University of York; 2018.MolinariAFallacaraALMariaSDZamperiniCPoggialiniFMusumeciFet al.Efficient optimization of pyrazolo[3,4-d]pyrimidines derivatives as c-Src kinase inhibitors in neuroblastoma treatmentBioorg Med Chem Lett2018283454710.1016/j.bmcl.2018.09.02430262428JhaVMacchiaMTuccinardiTPoliGThree-Dimensional Interactions Analysis of the Anticancer Target c-Src Kinase with Its InhibitorsCancers (Basel)202012232710.3390/cancers1208232732824733PMC7466017le MaireAGermainPBourguetWProtein-protein interactions in the regulation of RAR-RXR heterodimers transcriptional activityMethods Enzymol202063717520710.1016/bs.mie.2020.02.00732359645YinLShenHDiaz-RuizOBäckmanCMBaeEYuSet al.Early post-treatment with 9-cis retinoic acid reduces neurodegeneration of dopaminergic neurons in a rat model of Parkinson's diseaseBMC Neurosci20121312010.1186/1471-2202-13-12023040108PMC3523975MandiliGMariniCCartaFZaniniCPratoMKhadjaviAet al.Identification of phosphoproteins as possible differentiation markers in all-trans-retinoic acid-treated neuroblastoma cellsPLoS One20116e1825410.1371/journal.pone.001825421573212PMC3088664ChenMHsuSLinHYangTRetinoic acid and cancer treatmentBiomedicine (Taipei)201442210.7603/s40681-014-0022-125520935PMC4265016JanesickAWuSCBlumbergBRetinoic acid signaling and neuronal differentiationCell Mol Life Sci20157215597610.1007/s00018-014-1815-925558812PMC11113123LoneAMDarNJHamidAShahWAAhmadMBhatBAPromise of Retinoic Acid-Triazolyl Derivatives in Promoting Differentiation of Neuroblastoma CellsACS Chem Neurosci2016782910.1021/acschemneuro.5b0026726551203LascioSDSabaEBelperioDRaimondiALucchettiHFornasariDet al.PHOX2A and PHOX2B are differentially regulated during retinoic acid-driven differentiation of SK-N-BE(2)C neuroblastoma cell lineExp Cell Res2016342627110.1016/j.yexcr.2016.02.01426902400PMC4819706ZagePENovel Therapies for Relapsed and Refractory NeuroblastomaChildren (Basel)2018514810.3390/children511014830384486PMC6262328Oral Liquid 13-cis-retinoic Acid (13-CRA) (My-CRA) [Internet][Cited 2023 Jul 12]. Available from: https://clinicaltrials.gov/study/NCT03291080CuiSWangYWangYTangXRenXZhangLet al.Design, synthesis and biological evaluation of 3-(imidazo[1,2-a]pyrazin-3-ylethynyl)-2-methylbenzamides as potent and selective pan-tropomyosin receptor kinase (TRK) inhibitorsEur J Med Chem20191794708210.1016/j.ejmech.2019.06.06431271959MagalingamKBRadhakrishnanAKSomanathSDMdSHaleagraharaNInfluence of serum concentration in retinoic acid and phorbol ester induced differentiation of SH-SY5Y human neuroblastoma cell lineMol Biol Rep20204787758810.1007/s11033-020-05925-233098048BayevaNCollEPiskarevaODifferentiating Neuroblastoma: A Systematic Review of the Retinoic Acid, Its Derivatives, and Synergistic InteractionsJ Pers Med20211121110.3390/jpm1103021133809565PMC7999600HunsuVOFaceyCOBFieldsJZBomanBMRetinoids as Chemo-Preventive and Molecular-Targeted Anti-Cancer TherapiesInt J Mol Sci202122773110.3390/ijms2214773134299349PMC8304138Protein Aligner [Internet]OneAngstrom; [cited 2024 Jul 4]. Available from: https://www.samson-connect.net/extensions/0bee42d5-181b-b366-39a5-36607f0b5731EngelJRichtersAGetlikMTomassiSKeulMTermatheMet al.Targeting Drug Resistance in EGFR with Covalent Inhibitors: A Structure-Based Design ApproachJ Med Chem20155868446310.1021/acs.jmedchem.5b0108226275028KleywegtGJBergforsTSennHMottePLGsellBShudoKet al.Crystal structures of cellular retinoic acid binding proteins I and II in complex with all-trans-retinoic acid and a synthetic retinoidStructure1994212415810.1016/s0969-2126(94)00125-17704533Wang L-h, Evers A, Monecke P, Naumann T. Ligand based lead generation - considering chemical accessibility in rescaffolding approaches via BROODJ Cheminf20124O2010.1186/1758-2946-4-S1-O20PMC3341233McGannMFRED and HYBRID docking performance on standardized datasetsJ Comput Aided Mol Des20122689790610.1007/s10822-012-9584-822669221López-RamosMPerruccioFHPPD: ligand- and target-based virtual screening on a herbicide targetJ Chem Inf Model2010508011410.1021/ci900498n20359237JanowskiPAMoriartyNWKelleyBPCaseDAYorkDMAdamsPDet al.Improved ligand geometries in crystallographic refinement using AFITT in PHENIXActa Crystallogr D Struct Biol20167210627210.1107/S205979831601222527599738PMC5013598VIDA v4.4.0 released [Internet]OpenEye, Cadence Molecular Sciences; c2025 [cited 2023 Jun 6]. Available from: https://www.eyesopen.com/news/vidav4.4.0-releasedEberhardtJSantos-MartinsDTillackAFForliSAutoDock Vina 1.2.0: New Docking Methods, Expanded Force Field, and Python BindingsJ Chem Inf Model2021613891810.1021/acs.jcim.1c0020334278794PMC10683950TrottOOlsonAJAutoDock Vina: improving the speed and accuracy of docking with a new scoring function, efficient optimization, and multithreadingJ Comput Chem2010314556110.1002/jcc.2133419499576PMC3041641MoitessierNPottelJTherrienEEnglebiennePLiuZTombergAet al.Medicinal Chemistry Projects Requiring Imaginative Structure-Based Drug Design MethodsAcc Chem Res20164916465710.1021/acs.accounts.6b0018527529781ThomsenRChristensenMHMolDock: a new technique for high-accuracy molecular dockingJ Med Chem20064933152110.1021/jm051197e16722650Toxicity Estimation Software Tool (TEST) [Internet][Cited 2024 Sep 9]. Available from: https://www.epa.gov/comptox-tools/toxicity-estimation-software-tool-testParrotMTajmouatiHSilvaVBRdAtwoodBRFourcadeRGaston-MathéYet al.Integrating synthetic accessibility with AI-based generative drug designJ Cheminform2023158310.1186/s13321-023-00742-837726842PMC10507964BIOVIA Discovery Studio Visualizer [Internet]Dassault Systèmes; c2002-2025 [cited 2023 May 4]. Available from: https://discover.3ds.com/discovery-studio-visualizer-downloadBROOD [Internet]OpenEye, Cadence Molecular Sciences; c2025 [cited 2023 Apr 10]. Available from: https://www.eyesopen.com/BROODMorphyRKayCRankovicZFrom magic bullets to designed multiple ligandsDrug Discov Today200496415110.1016/S1359-6446(04)03163-015279847LiXLiXLiuFLiSShiDRational Multitargeted Drug Design Strategy from the Perspective of a Medicinal ChemistJ Med Chem2021641058160510.1021/acs.jmedchem.1c0068334313432KlebeGFrom In Vitro to In Vivo: Optimization of ADME and Toxicology PropertiesKlebeGDrug DesignSpringer, BerlinHeidelberg2024pp. 291–308.10.1007/978-3-642-17907-5_19