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Article

Three-Dimensional Common-Feature Hypotheses for Octopamine Agonist 1-Arylimidazolidine-2-Thiones

1
Department of Applied Genetics and Pest Management, Faculty of Agriculture, Graduate School, Kyushu University, 6-10-1 Hakozaki, Fukuoka 812-8581, Japan
2
Graduate School of Bioresource and Bioenvironmental Sciences, Kyushu University, 6-10-1 Hakozaki, Fukuoka 812-8581, Japan
3
School of Agriculture, Kyushu Tokai University, Kumamoto 869-1404, Japan
4
Kyushu Women’s University, 1-1 Jiyugaoka, Yahatanishi-ku, Kita-Kyushu, Fukuoka 807-8586, Japan
*
Author to whom correspondence should be addressed.
Int. J. Mol. Sci. 2002, 3(2), 56-68; https://doi.org/10.3390/i3020056
Submission received: 4 October 2001 / Accepted: 22 January 2002 / Published: 28 February 2002

Abstract

:
Three-dimensional pharmacophore hypotheses were built from a set of 10 octopamine (OA) agonist 1-arylimidazole-2(3H)-thiones (AIHTs) and 1-arylimidazolidine-2-thiones (AITs). Among the ten common-featured models generated by program Catalyst/HipHop, a hypothesis including a hydrophobic aromatic (HpAr), three hydrophobic aliphatic (HpAl) and a hydrogen-bond acceptor lipid (HBAl) features was considered to be important in evaluating the OA-agonist activity. Active OA agonist 2,6-Et2 AIT mapped well onto all the HpAr, HpAl and HBAl features of the hypothesis. On the other hand, inactive compound 2,6-Et2 AIHT was shown to be difficult to achieve the energetically favorable conformation which is found in the active molecules in order to fit the 3D common-feature pharmacophore models. The present studies on OA agonists demonstrate that an HpAr, three HpAls and an HBAl sites located on the molecule seem to be essential for OA-agonist activity.

1. Introduction

Quantitative structure-activity relationship (QSAR) modeling is an area of research pioneered by Hansch and Fujita [1,2]. The QSAR study assumes that the difference of the molecules in the structural properties experimentally measured accounts for the difference in their observed biological or chemical properties [1,2,3]. The result of QSAR usually reflects as a predictive formula and attempts to model the activity of a series of compounds using measured or computed properties of the compounds. More recently, QSAR has been extended by including the three-dimensional information. In drug discovery, it is common to have measured activity data for a set of compounds acting upon a particular protein but not to have knowledge of the three-dimensional structure of the active site. In the absence of such three-dimensional information, one may attempt to build a hypothetical model of the active site that can provide insight on the nature of the active site. Such a model is known as a Hypo. Catalyst/Hypo is useful in building 3D pharmacophore models from the activity data and conformational structure. It can be used as an alternative for QSAR methods because of easy visualization and high prediction.
In a previous application, we described the use of Catalyst/Hypo to derive a 4- and 5-feature hypothesis from a set of 17 octopamine (OA) antagonists [4] and 43 agonists [5], respectively. Three-dimensional pharmacophore hypotheses were built from a set of 9 OA agonists responsible for the inhibition of sex-pheromone production in Helicoverpa armigera [6]. These sets included a variety of types of molecules, covering 5 orders of magnitude in activity. For these type of training sets, the use of the hypothesis-generation tool was appropriate. This tool builds hypotheses (overlays of chemical features) for which the fit of individual molecules to a hypothesis can be correlated with the molecule's affinity. However, the high structural homology among the derivatives used in the current study combined with their smaller activity range makes this "quantitative" hypothesis generation method inappropriate. For this type of training set, the common-feature hypothesis generation, also called HipHop [7], is more suitable. HipHop generates hypotheses consisting only of identification and overlay of common features (without the use of activity data). The aim of this work is to derive feature-based 3D models from a small set of 10 OA agonists using HipHop.

2. Materials and Methods

Chemicals. OA [2-amino-1-(4-hydroxyphenyl)ethanol], theophylline (1,3-dimethylxanthine), and ethylene glycol bis(β-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA) were purchased from Nacalai Tesque (Kyoto, Japan); GTP was from Sigma Chemical Co. (St. Louis, U.S.A.); ATP disodium salt was from Kohjin Co. (Tokyo, Japan); lithium aluminum hydride (LAH) was from Chemetall GmbH (Frankfurt, Germany).
Radiochemical. The cAMP radioimmunoassay (RIA) kit (cord RPA 509) was purchased from Amersham International (Buckinghamshire, England).
Synthesis of test compounds. All compounds were prepared using published methods. 1-Arylimidazole-2(3H)-thiones (AIHTs) were prepared by the condensation of the corresponding arylisothiocyanates with aminoacetaldehyde dimethyl acetal followed by acid-catalized cyclization of the intermediate N-arylthioureas [8]. 1-Arylimidazolidine-2-thiones (AITs) were synthesized by the cyclization of monoethanolamine hydrogen sulfate with arylisothiocyanates in the presence of sodium hydroxide as described in the previous report [9]. The structures of the compounds were confirmed by 1H and 13C NMR measured with a JEOL JNM-EX400 spectrometer at 400 MHz, tetramethyl silane (TMS) being used as an internal standard for 1H NMR, and elemental analysis.
Insects. Males and females of Periplaneta americana were used indiscriminately, as their nervous systems exhibited no gross structural or neurochemical differences. The insects were reared under crowded conditions in this laboratory at 28oC with a photoperiod of 12 h light:12 h dark and at a relative humidity of 65-70% for more than 7 years; they were provided with an artificial mouse diet (Oriental Yeast Co., Chiba, Japan) and water ad libitum.
Adenylate-cyclase assay. The adenylate-cyclase assay was conducted on adult American cockroaches (P. americana L) as shown in previous report [9,10,11,12]. Thoracic nerve cords of P. americana were homogenized (15 mg/ml) in a 6 mM Tris-maleate buffer (pH 7.4) by using a chilled microtube homogenizer (S-203, Ikeda Sci., Tokyo, Japan) as shown in previous report. The homogenate was diluted (1 mg/ml) in 6 mM Tris-maleate, and then centrifuged at 120,000 x g and 4oC for 20 min. The supernatant was discarded, the pellet being resuspended by homogenizing (1 mg/ml) in the buffer, and again centrifuged at 120,000 x g and 4oC for 20 min. The resulting pellet (P2) resuspended in the buffer was equivalent to the starting amount (15 mg/ml). The adenylate-cyclase activity was measured according to Nathanson's procedure under optimal conditions [9,10,11,12,13] in a test tube containing 200 μl of 120 mM Tris-maleate (pH 7.4, including 15 mM theophylline, 12 mM MgCl2 and 0.75 mM EGTA), 60 μl of the P2 fraction and 30 μl of each synthesized compound solution in polyethylene glycol. An appropriate solvent control was run in parallel. The enzyme reaction (5 min at 30oC) was initiated by adding 10 μl of a mixture of 3 mM GTP and 60 mM ATP, stopped by heating at 90oC for 2 min and then centrifuged at 1000 x g for 15 min to remove the insoluble material. The cAMP level in the supernatant was measured by RIA [9,10,11,12]. Protein concentration was determined by the Lowry method [14], using bovine serum albumin (Sigma, St. Louis, U.S.A.) as the standard. Enzyme activity in each assay was corrected using OA as a reference. The maximal stimulatory activity (mostly at 0.1 mM) was calculated relative to OA (100%) and control (0%).
Hypothesis generation. All experiments were conducted on a Silicon Graphics O2, running under the IRIX 6.5 operating system. Hypotheses generation was applied against previously described data sets and their functionality is available as part of Molecular Simulations Incorporated's Catalyst/Hiphop (version 4.0) modeling environment (Burlington, U.S.A.). Molecules were edited using the Catalyst 2D/3D visualizer. Catalyst automatically generated conformational models for each compound using the Poling Algorithm [15,16,17]. The number of conformations needed to produce a good representation of a compound's conformational space depends on the molecule. Conformation-generating algorithms were adjusted to produce a diverse set of conformations, avoiding repetitious groups of conformations all representing local minima. The conformations generated were used to align common molecular features and generate pharmacophoric hypotheses. HipHop used conformations generated to align chemically important functional groups common to the molecules in the study set. A pharmacophoric hypothesis then was generated from these aligned structures. 
The models emphasized a conformational diversity under the constraint of 20 kcal/mol energy threshold above the estimated global minimum based on use of the CHARMm force field [15,16,17,18]. Molecular flexibility was taken into account by considering each compound as a collection of conformers representing a different area of conformational space accessible to the molecule within a given energy range. Catalyst provides two types of conformational analysis: fast and best quality. Best option was used, specifying 250 as the maximum number of conformers. The molecules associated with their conformational models was submitted to Catalyst hypothesis generation. Hypotheses approximating the pharmacophore were described as a set of features distributed within a 3D space. This process only considered surface accessible functions such as hydrogen-bond acceptor (HBA), hydrogen-bond acceptor lipid (HBAl), hydrogen-bond donor (HBD), hydrophobic (Hp), hydrophobic aromatic (HpAr), hydrophobic aliphatic (HpAl), negative ionizable (NI) and positive ionizable (PI).
HipHop provides feature-based alignment of a collection of compounds without considering activity. It matches the chemical features of a molecule, against drug candidate molecules. HipHop takes a collection of conformational models of molecules and a selection of chemical features, and produces a series of molecular alignments in a variety of standard file formats. HipHop begins by identifying configurations of features common to a set of molecules. A configuration consists of a set of relative locations in 3D space and associated feature types. A molecule matches the configurations if it possesses conformations and structural features that can be superimposed within a certain tolerance from the corresponding ideal locations. HipHop also maps partial features of molecules in the alignment set. This provision gives the option to use partial mapping during the alignment. Partial mapping allows to identify larger, more diverse, more significant hypotheses and alignment models without the risk of missing compounds that do not map to all of the pharmacophore features. Misses, the number of molecules which do not have to map to all features in generated hypotheses, FeatureMisses, the the number of maximal molecules which do not have to map to each feature in generated hypotheses and CompleteMisses, the number of molecules which do not have to map to any feature in a given hypothesis, were set as 3, 2 and 2, respectively.

3. Results and discussion

Assessment of 3D hypothesis for OA-agonist activity. OA-agonist activities of test compounds at several concentrations were examined using the adenylate-cyclase assay which was conducted on adult American cockroaches (P. americana L). AIT 70 with 2,6-Et2-Ph substituent showed the highest OA-agonist activity, followed by AIT 73 with 2,6-iPr2-Ph substituent. The activity as OA agonist was structure specific. AIT 70 was the only full agonist in this study and all other AITs and AIHTs were partial agonists. A slight modification of structure of 70 decreased the OA-agonist activity dramatically: substituents at 2,6 positions of the phenyl, the introduction of a substituent to the imidazolidine ring at position 4 and the introduction of a double bond to the imidazolidine ring at position 4 and 5, leading to an imidazole ring. Hypotheses were generated to explain the specificity of the OA agonists. A set of 10 molecules, including 70 and its derivatives, was selected randomly as the target training set. Their experimental biological activities are listed in Table 1 and Table 2. Among the 10 molecules of the training set, 70 and 73 were chosen as reference compounds, which were allowed to map all features, and other 8 molecules were allowed to map partially on the hypotheses (Table 3). Except for this classification, the activities of the molecules were not used in the analysis. This tool builds hypotheses (overlays of common features) for which the fit of individual molecules to a hypothesis can be correlated with the molecule’s activity. 
The 3D-hypothesis study was performed with the Catalyst (version 4.0) package. The geometry of each compound was built with a visualizer and optimized by using the generalized CHARMm-like force field implemented in the program. A preparative test was performed with HBA, HBAl, HBD, Hp, HpAr, HpAl, NI and PI [19]. NI and PI were used rather than negative charge and positive charge in order to broaden the search for deprotonated and protonated atoms or groups at physiological pH. Using conformatinal poling [15], a representative family of conformers was generated, within a 20 kcal/mol range of the computed minimum, for each molecule. Potential hypothesis models were produced with the minimum permitted interfeature spacing of 2.00 Å generating alignments of common features [7], which included the projected point of HBA and Hp [15].
It was found that hypotheses contain good correlation with HBA and/or Hp. The characteristics of ten hypotheses are listed in Table 4. All the hypotheses contain 5 features with the ranking scores ranging from 95.812 to 102.317. Hypotheses 1 and 2 consist of the same common-feature functions of an HpAr, three HpAls and an HBAl. The second group composes of hypotheses 3, 4, 9 and 10 which are characterized by an HpAr, two HpAls, an Hp and an HBAl features. Other hypotheses 5 and 6 are characterized by an HpAr, three HpAls and an HBA features. Hypotheses 7 and 8 consist of an HpAr, two HpAls, an Hp and an HBA. The rank score range over the 10 generated hypotheses is 6.505. The small rank score range observed here may be due to two factors, namely molecules in the training set are fairly rigid and have a high degree of structural homology. Due to the relatively small range and owing, moreover, to the placement of the identified hypotheses within this range, special care was taken to test for chance correlation. The higher the ranking score, the less likely it is that the molecules in the training set fit the hypothesis by a chance correlation.
Table 1. OA agonist AIHTs used in this study. Ijms 03 00056 i001
Table 1. OA agonist AIHTs used in this study. Ijms 03 00056 i001
CompoundaRmp (oC)Adenylate-cyclase activity (relative to OA, %)b
1H186-1873.0±2.9
22-Br280-2812.5±2.2
32-Cl240-2417.7±1.9
42-Me249-2503.7±5.1
52-MeO238-2393.5±1.3
62-Et204-2058.5±2.2
72-iPr245-2465.7±2.5
83-Cl163-1644.5±3.6
93-NO2225-2265.4±2.0
103-MeO157-1582.3±1.6
114-Cl222-2232.6±0.5
124-I259-2606.5±0.7
134-Me219-2205.9±2.6
144-CF3199-2003.7±2.4
154-CN269-2703.9±1.5
164-MeS196-1974.0±4.3
174-MeO228-2293.2±1.8
184-Et170-1702.4±2.0
194-EtO209-2102.9±1.6
204-Ac192-1933.3±1.8
214-Et2N228-2293.5±4.9
224-iPr171-1722.5±3.5
234-EtOCO173-1742.7±0.4
244-BzO256-2573.0±4.2
252,3-Cl2260-2616.2+1.8
262-Cl,4-Br243-2442.4±0.2
272-Br,4-Me234-2356.9±2.9
282-Me,4-Cl237-2383.2±3.1
292-NO2,4-Me229-2305.8±2.5
302-NO2,4-MeO242-2432.7±0.8
312-MeO,4-NO2254-2551.5±5.0
322,4-Me2202-2034.1±5.6
332,4-(MeO)2248-2494.1±4.1
342,5-Cl2277-2781.7±1.3
352-Me,5-Cl250-2512.1±1.3
362-MeO,5-Cl261-2620.9±0.1
372-Cl,5-CF3209-2106.1±2.7
382-MeO,5-Me211-2129.5±7.8
392,5-(MeO)2206-2071.6±1.1
402,6-Cl2300-3011.8±1.8
412-Cl,6-Me300-3014.3±5.3
422,6-Me2290-2914.1±5.5
432,6-Et2204-2053.4±3.3
442-Et,6-iPr225-2262.9±3.0
453,4-Cl2247-2486.1±0.2
463-NO2,4-Cl239-2405.5±0.7
473,4-(MeO)2243-2443.0±2.8
483,5-Cl2237-2386.4±3.7
493,5-Me2202-2032.4±2.0
503,5-(CF3)2163-1644.1±1.3
513,5-(MeO)2158-1594.5±3.4
522,3,4-Cl3266-2676.9±1.3
532,6-Me,4-Br300-30111.8±1.8
542,4,6-Me3277-2782.7±0.2
552,3,4,5-Cl4262-2637.5±2.2
aAll AIHTs were prepared by the condensation of the corresponding arylisothiocyanates with aminoacetaldehyde dimethyl acetal followed by acid-catalized cyclization of the intermediate N-arylthioureas [8].bThe adenylate-cyclase assay of test compounds was conducted at several concentrations on adult American cockroaches as shown in previous report [9,10,11,12,13]. The basal (control) and maximal adenylate-cyclase activities stimulated by OA (0.1 mM) were 26.2±5.6 and 612.2±127.5 pmol cAMP/min/mg of protein, respectively. The maximal stimulatory activities (mostly at 0.1 mM) of test compounds were calculated relative to OA (100%) and control (0%).
Table 2. OA agonist AITs used in this study. Ijms 03 00056 i002
Table 2. OA agonist AITs used in this study. Ijms 03 00056 i002
CompoundaRaRbmp (oC)Adenylate-cyclase activity (relative to OA, %)b
56HH118-1190.6±0.8
572-MeH122-1244.5±3.3
583-ClH111-1137.6±1.1
593-CF3H119-1211.6±0.7
604-AcH123-1253.0±0.8
614-iPrH154-1563.2±0.6
622-Cl,4-NO2H113-1152.8±0.3
632-MeO,4-NO2H137-1395.7±1.4
642,6-Cl2H121-1222.4±0.1
652,6-F2H161-1623.6±0.4
662-Cl,6-MeH195-1968.9±0.8
672,6-Me2H210-2113.9±0.1
682-Me,6-EtH106-1082.6±1.1
692-Me,6-iPrH145-1471.3±0.1
702,6-Et2H71-72104.0±1.6
712,6-Et2Me136-13716.1±1.3
722-Et,6-iPrH162-1633.6±0.1
732,6-iPr2H115-11623.8±0.3
aThe AIT compounds were synthesized by the cyclization of monoethanolamine hydrogen sulfate with arylisothiocyanates in the presence of sodium hydroxide as described in the previous report. [9]bThe adenylate-cyclase assay of test compounds was conducted at several concentrations on adult American cockroaches as shown in previous report. [9,10,11,12,13] The basal (control) and maximal adenylate-cyclase activities stimulated by OA (0.1 mM) were 26.2±5.6 and 612.2±127.5 pmol cAMP/min/mg of protein, respectively. The maximal stimulatory activity (mostly at 0.1 mM) of test compound was calculated relative to OA (100%) and control (0%).
Table 3. Characteristics for the common feature hypothesis run.
Table 3. Characteristics for the common feature hypothesis run.
CompoundConfsaFeatures/ConfsaPrincipalbMaxOmitFeatc
699.7811
432112.0011
54212.5011
64112.0011
66212.0011
67111.0011
702811.7920
718513.3911
722412.0011
731112.0020
aAbbreviations: Confs, number of conformers; Features/Confs, total number of features divided by the number of conformers (summed over the entire family of conformers).bPrincipal=1 means that this molecule must map onto the hypotheses generated by the search procedure. Partial mapping is allowed. Principal=2 means that this is a reference compound. The chemical feature space of the conformers of such a compound is used to define the initial set of potential hypotheses.cMaxOmitFeat=1 means a feature of a compound may not be mapped to a hypothesis model. MaxOmitFeat=0 means all features of a compound are mapped to a hypothesis model.
Table 4. Results of the common feature hypothesis run.
Table 4. Results of the common feature hypothesis run.
HypothesesFeatureaRank ScoreDirect HitbPartial Hitb
1HpArHpAlHpAlHpAlHBAl102.31711110101110000101000
2HpArHpAlHpAlHpAlHBAl102.21211110101110000101000
3HpArHpAlHpAlHpHBAl100.84811111101110000001000
4HpArHpAlHpAlHpHBAl100.84811111101110000001000
5HpArHpAlHpAlHpAlHBA100.31711110101110000101000
6HpArHpAlHpAlHpAlHBA100.21211110101110000101000
7HpArHpAlHpAlHpHBA98.84811111101110000001000
8HpArHpAlHpAlHpHBA98.84811111101110000001000
9HpArHpAlHpAlHpHBAl95.91711110101110000101000
10HpArHpAlHpAlHpHBAl95.81211110101110000101000
aAbbreviations: HpAr, hydrophobic aromatic; HpAl, hydrophobic aliphatic; Hp, hydrophobic; HBAl, hydrogen-bond acceptor lipid; HBA, hydrogen-bond acceptor.bDirect Hit, all the features of the hypothesis are mapped. Direct Hit=1 means yes; Partial Hit, partial mapping of the hypothesis. Partial Hit=0 means no. Each number refers to a molecule in Table 3 (same order).
OA agonists-receptor interaction. Comparison of the procedure and regression studies shows that hypotheses 1, 3, 5 and 7 are the best models among the four groups and are selected for further evaluation. Figure 1 and Figure 2 depict the most active compound AIT 70 and its AIHT analog 43, which has a low OA-agonist activity, mapped to hypothesis 1, respectively. The molecule 70 maps well to the five features of hypothesis 1, whereas an HpAl is supposed to map to double bond in 43. The partition coefficients measured using octanol-water solvent system and substituted benzen solutes for ethyl and ethlenyl are 1.02 and 0.82 [20], respectively. Thus, the double bond in 43 is less hydrophobic than a saturated bond in 70 and 43 does not suit to the hypothesis 1. Besides, the introduction of a methyl group at position 4 of the imidazolidine ring of 70 lowered the activity dramatically, leading to 71 (Fig. 3). The methyl group sticks out of an HpAl. Taken together, 2,6-Et2-Ph and the imidazolidine ring without any substituents are important for OA-agonist activity. An imidazole ring and the introduction of substituents to the imidazolidine ring are not favorable. Generally, more active molecules map well to all the features of the hypothesis (Fig. 1) and compounds that have low activity map poorly to the hypothesis (Fig. 2 and Fig. 3). Other compounds in Table 1 with low activity also do not fit to these features.
Figure 1. Mapping of 70 to hypothesis 1, which contains an HpAr (blue), three HpAls (blue) and an HBAl (green).
Figure 1. Mapping of 70 to hypothesis 1, which contains an HpAr (blue), three HpAls (blue) and an HBAl (green).
Ijms 03 00056 g001
Figure 2. Mapping of 43 to hypothesis 1, which contains an HpAr (blue), three HpAls (blue) and an HBAl (green).
Figure 2. Mapping of 43 to hypothesis 1, which contains an HpAr (blue), three HpAls (blue) and an HBAl (green).
Ijms 03 00056 g002
Figure 3. Mapping of 71 with (S)-configuration to hypothesis 1, which contains an HpAr (blue), three HpAls (blue) and an HBAl (green).
Figure 3. Mapping of 71 with (S)-configuration to hypothesis 1, which contains an HpAr (blue), three HpAls (blue) and an HBAl (green).
Ijms 03 00056 g003
An HpAl of hypothesis 3 is replaced by an Hp, leading to hypothesis 1 and an HBAl of hypothesis 3 is replaced by an HBA, leading to hypothesis 5. An HpAl of hypothesis 5 is replaced by an Hp, leading to hypothesis 7. The small range of rank score suggests that these hypotheses were homogenous. Roughly speaking, hypotheses 1, 3, 5 and 7 have the good similarity in 3D spatial shape and therefore these hypotheses are considered to be equivalent.

4. Conclusion

In rational drug design process, it is common that the biological-activity data of a set of compounds acting upon a particular protein is known, while information of the three-dimensional structure of the protein active site is absent. A three-dimensional pharmacophore hypothesis that is consistent with known data should be useful and predictive in evaluating new compounds and directing further synthesis. A pharmacophore model postulates that there is an essential three-dimensional arrangement of functional groups that a molecule must possess to be recognized by the active site. It collects common features distributed in 3D space that is intended to represent groups in a molecule that participates in important interactions between drugs and their active sites. Hence, a pharmacophore model provides crucial information about how well the common features of a subject molecule overlap with the hypothesis model. It also informs the ability of molecules to adjust their conformations in order to fit an active site with energetically reasonable conformations. Such characterized 3D models convey important information in an intuitive manner.
The present work shows how a set of activities of various OA agonists may be treated statisticaly to uncover the molecular characteristics which are essential for high activity. These characteristics are expressed as common features disposed in three-dimensional space and are collectively termed a hypothesis. Hypotheses were obtained and applied to map the active or inactive compounds. Important features such as an HpAr, three HpAls and an HBAl of the surface-assessable models were found for OA agonists. They are the minimum components of a hypothesis for effective OA agonists. Graphical examination of the ten hypotheses shows that there are four major families of models depending mainly on the location and the orientation of the projected point of the HBA and Hp. It was found that more active OA agonists map well to all the features of the hypotheses. For some inactive compounds, their lack of affinity is primarily due to their inability to achieve an energetically favorable conformation shared by the active compounds. Taken together, an HpAr, three HpAls and an HBAl located on the molecule seem to be essential for OA-agonist activity. The hypotheses obtained here correspond those published previously against OA receptor 3 of locust nervous system using binding assay [5].

Acknowledgement

This work was supported in part by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science and Culture of Japan.

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Hirashima, A.; Morimoto, M.; Ohta, H.; Kuwano, E.; Taniguchi, E.; Eto, M. Three-Dimensional Common-Feature Hypotheses for Octopamine Agonist 1-Arylimidazolidine-2-Thiones. Int. J. Mol. Sci. 2002, 3, 56-68. https://doi.org/10.3390/i3020056

AMA Style

Hirashima A, Morimoto M, Ohta H, Kuwano E, Taniguchi E, Eto M. Three-Dimensional Common-Feature Hypotheses for Octopamine Agonist 1-Arylimidazolidine-2-Thiones. International Journal of Molecular Sciences. 2002; 3(2):56-68. https://doi.org/10.3390/i3020056

Chicago/Turabian Style

Hirashima, Akinori, Masako Morimoto, Hiroto Ohta, Eiichi Kuwano, Eiji Taniguchi, and Morifusa Eto. 2002. "Three-Dimensional Common-Feature Hypotheses for Octopamine Agonist 1-Arylimidazolidine-2-Thiones" International Journal of Molecular Sciences 3, no. 2: 56-68. https://doi.org/10.3390/i3020056

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