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Dopamine Receptor

Dopamine receptors are a class of G protein-coupled receptors that bind the neurotransmitter dopamine.
These receptors play crucial roles in regulating various physiological processes, including movement, cognition, emotion, and reward-motivated behavior.
Dopamine receptors are divided into two main families, D1-like and D2-like, based on their structural and functional characteristics.
Imbalances in dopamine receptor signaling have been implicated in numerous neurological and psychiatric disorders, such as Parkinson's disease, schizophrenia, and addiction.
Understanding the complex mechanisms underlying dopamine receptor function is essential for developing effective therapies targeting these receptors.
PubCompare.ai's AI-driven platform can enhance your dopamine receptor research by helping you locate optimal protocols from literature, pre-prints, and patents using intelligent comparisons, improving reproducibilty and accuracy with its cutting-edge tools.
Experience the future of dopamnie receptor optimization today.

Most cited protocols related to «Dopamine Receptor»

High-Throughput Molecular Docking Protocol

Cited 11 times

The AmpC campaign used the structure in PDB 1L2S, while the D₄ campaign used PDB 5WIU. In each, 45 matching spheres were calculated around and including the ligand atoms—a 26 μM thiophene carboxylate for AmpC and nemonapride for D₄ structures were prepared and AMBER united atom charges assigned^{14 (link)}. The magnitude of the partial atomic charges for five residues in AmpC were increased without changing the net residue charge⁵⁶. For both targets, the low protein dielectric was extended into the binding site using pseudo-atom positions representing possible ligand docking sites, the radius was 1.0 Å and 2.0 Å for D₄ and AmpC respectively^{14 (link),54 ,60}. For the D₄ dopamine receptor, the desolvation volume of the site was also increased by similar atom positions, using a radius of 0.3 Å. This improved ligand charge-balance in benchmarking calculations, reducing the number of high-ranking dications. Energy grids representing the AMBER van der Waals potential⁶¹, Poisson-Boltzmann electrostatic potentials using QNIFFT^{62 ,63}, and ligand desolvation from the occluded volume of the target for different ligand orientations⁵⁴ were calculated. Using DOCK3.7.2⁶⁴, over 99 million and over 138 million library molecules were docked against AmpC and the D₄ dopamine receptor, respectively. Each library molecule was sampled in about 4054 and 3300 orientations and, on average, 280 and 479 conformations for AmpC and D₄, respectively, and were rigid-body minimized with a simplex minimizer. The throughput averaged 1 second per library compound.

Lyu J., Wang S., Balius T.E., Singh I., Levit A., Moroz Y.S., O’Meara M.J., Che T., Algaa E., Tolmachova K., Tolmachev A.A., Shoichet B.K., Roth B.L, & Irwin J.J. (2019). Ultra-large library docking for discovering new chemotypes. Nature, 566(7743), 224-229.

Publication 2019

Amber Binding Sites cDNA Library Diet, Protein-Restricted Dopamine Receptor Electrostatics Human Body Ligands Mental Orientation Muscle Rigidity nemonapride Radius Thiophene

High-Throughput Molecular Docking Protocol

Cited 9 times

Publication 2019

Amber Binding Sites cDNA Library Diet, Protein-Restricted Dopamine Receptor Electrostatics Human Body Ligands Mental Orientation Muscle Rigidity nemonapride Radius Thiophene

Immunophenotyping Neuronal Subpopulations

Cited 8 times

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Publication 2011

alexa fluor 488 Antibodies Antibodies, Anti-Idiotypic Biological Factors Cells Centrifugation Chickens Common Cold DAPI Domestic Sheep Dopamine Dopamine D1 Receptor Dopamine Receptor Endothelial Cells Ethanol Flow Cytometry Immunoglobulins Inversion, Chromosome Mesencephalon Mus Novus Pellets, Drug Phosphates Phycoerythrin Rabbits Saline Solution Streptavidin Striatum, Corpus Technique, Dilution TFRC protein, human Tyrosine 3-Monooxygenase

Polypharmacology Profiling Using Bayesian Models

Cited 7 times

Predictive polypharmacology profiling was undertaken using Bayesian activity models, based on our previously published approach⁹. The Bayesian method for polypharmacology profiling was chosen as it provided both good performance on noisy datasets and a high speed of calculation^{51 (link)}. High confidence models were built using ChEMBL (release 1). Activity data were filtered to keep only activity endpoint points that had either IC₅₀, k_i or EC₅₀ values and where the ChEMBL confidence score was at least 7 (protein assignment was direct or homologue). A compound was considered active when the mean activity value was below 10μM. All inactive compounds were assigned to the target ‘none’. Following this procedure 133,061 compounds remained with 215,967 activity endpoints, which were used for model building. Multiple category Laplacian-modified naïve Bayesian models were built with ECFP6 representations⁵² for 784 targets. For each model the data were split in two for the validation step: compounds were clustered and assigned a cluster number. Clusters with an odd number were assigned to the test set, and the clusters with even number were assigned to the training set. Models were built with the training set, and the test set was scored. The training set was scored using its own model as comparison. Finally a model was built with all data and scored against itself, the training set and whole set should provide similar validation statistics. Statistics on the performance of the models are described in Supplementary Table 12. The results for the model containing all 785 targets the results were very similar to the models for the receptor subsets. Two analyses were used to assess the performance of the different models. The first analysis provides an overall score and does not need to specify a cut-off for distinguishing active from inactive compounds. The area under the Receiver Operating Characteristic (ROC) Curve (AUC) provides an indication of the ability of the model to prioritize active compounds over inactive compounds. The ROC curve is the plot of true positive rate versus false positive rate. However it did not provide information on early enrichment, which was important in studies such as the present one where only the top ranking compounds were considered. Therefore the Boltzmann-Enhanced Discrimination of ROC (BEDROC)⁵³ was used, which solves the early enrichment issue by adding a weight to compounds recognized early. BEDROC was derived from the Robust Initial Enhancement (RIE), and the Sum of log of ranks test (SLR)^{54 (link)} which provided a statistical test to assess which method performs better than random. The percent of active compound retrieved in the top 5% is also calculated (Recall =5%). The second analysis required a cut-off to make the distinction between active and inactive as they varied with the rank of the compounds. For each model, the specificity (true negative rate), sensitivity (true positive rate), false positive rate, false negative rate, precision, F-measure and Matthews Correlation Coefficient (MCC) were calculated at different cut-off values. The cut-off providing the best MCC score was used, as it was shown to provide better performance^{55 (link)} (Supplementary Fig. 12). The quality of the models was assessed using an internal leave-one-out validation: one compound was part of the test set, and was scored using the remaining data as the training set. Then the area under the ROC curve was calculated (Supplementary Fig. 13). A cut-off score to minimize the sum of the percent misclassified for category members and for category non-members was calculated and used to classify compounds in the contingency table.
An All Data Model for dopamine receptors only was built using data from pre release of ChEMBL (StARLite version 31), with similar numbers of compounds and endpoints. The model was built without considering the confidence level of target assignment to gather as much data as possible. This model was used for initial calculation on the evolution of the isoindole series and the 2,3-dihydro-indol-1-yl series. The quality of the models was assessed using the same procedures as described above. The results from the All Data Models and the High Confidence Models were very similar (e.g. D2 model R₂=0.998, D4 models R₂=0.984).

Besnard J., Ruda G.F., Setola V., Abecassis K., Rodriguiz R.M., Huang X.P., Norval S., Sassano M.F., Shin A.I., Webster L.A., Simeons F.R., Stojanovski L., Prat A., Seidah N.G., Constam D.B., Bickerton G.R., Read K.D., Wetsel W.C., Gilbert I.H., Roth B.L, & Hopkins A.L. (2012). Automated design of ligands to polypharmacological profiles. Nature, 492(7428), 10.1038/nature11691.

Publication 2012

11-dehydrocorticosterone Biological Evolution Discrimination, Psychology Dopamine Receptor Hypersensitivity Isoindoles Mental Recall Proteins

Generating DRD2-Active Molecules via ML

Cited 6 times

In one of our studies the objective of the Agent is to generate molecules that are predicted to be active against a biological target. The dopamine type 2 receptor DRD2 was chosen as the target, and corresponding bioactivity data was extracted from ExCAPE-DB [33 (link)]. In this dataset there are 7218 actives (pIC50 > 5) and 343204 inactives (pIC50 < 5). A subset of 100,000 inactive compounds was randomly selected. In order to decrease the nearest neighbour similarity between the training and testing structures [34 (link)–36 (link)], the actives were grouped in clusters based on their molecular similarity. The Jaccard [37 ] index, for binary vectors also known as the Tanimoto similarity, based on the RDKit implementation of binary Extended Connectivity Molecular Fingerprints with a diameter of 6 (ECFP6 [38 (link)]) was used as a similarity measure and the actives were clustered using the Butina clustering algorithm [39 (link)] in RDKit with a clustering cutoff of 0.4. In this algorithm, centroid molecules will be selected, and everything with a similarity higher than 0.4 to these centroids will be assigned to the same cluster. The centroids are chosen such as to maximize the number of molecules that are assigned to any cluster. The clusters were sorted by size and iteratively assigned to the test, validation, and training sets (assigned 4 clusters each iteration) to give a distribution of

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of the clusters respectively. The inactive compounds, of which less than 0.5% were found to belong to any of the clusters formed by the actives, were split randomly into the three sets using the same ratios.
A support vector machine (SVM) classifier with a Gaussian kernel was built in Scikit-learn [40 ] on the training set as a predictive model for DRD2 activity. The optimal C and Gamma values utilized in the final model were obtained from a grid search for the highest ROC-AUC performance on the validation set.

Olivecrona M., Blaschke T., Engkvist O, & Chen H. (2017). Molecular de-novo design through deep reinforcement learning. Journal of Cheminformatics, 9, 48.

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Publication 2017

11-dehydrocorticosterone Biopharmaceuticals Cloning Vectors Dopamine Receptor DRD2 protein, human Gamma Rays

Most recents protocols related to «Dopamine Receptor»

Quantifying Dopamine Receptor Expression

The sections were washed three times in PBS and incubated for 4 days at 4°C on a shaker, in the presence of an anti-GS antibody and one of the anti-dopamine receptor antibodies, in a solution of 0.1 M PBS containing 2% normal donkey serum. Subsequently, the sections were washed in PBS. The sections were then incubated in a mixture of secondary antibodies (Alexa 555-conjugated goat anti-rat IgG (1:400, A21434, Thermo Fisher Scientific, Waltham, MA, USA) for D1R detection, Alexa 555-conjugated donkey anti-rabbit IgG (1:400, A31572, Thermo Fisher Scientific) for D2R and D4R detection, Alexa 555-conjugated donkey anti-goat IgG (1:400, A21432, Thermo Fisher Scientific) for D5R detection, Alexa 488-conjugated donkey anti-mouse IgG (1:400, A21202, Thermo Fisher Scientific) for GS detection, diluted with 0.1 M PBS containing Hoechst 33342 (2 μg/ml; H21492; Thermo Fisher Scientific) for nuclear labeling and 2% normal donkey serum for 4 h at room temperature. The sections were washed in PBS, then briefly washed in distilled water, and mounted on slides with ProLong Diamond (P36970; Thermo Fisher Scientific). The cerebral cortex was observed using an LSM-880 confocal laser scanning microscope (Carl Zeiss, Oberkochen, Germany) equipped with a blue diode laser of 405 nm, an argon laser of 488 nm, and a DPSS laser of 561 nm. Images were obtained using the 63× (N.A., 1.4) and 100× (N.A., 1.4) oil immersion objective lenses, and 20X objective lens (N.A., 0.8). To obtain an image with each objective, the pinhole size was adjusted so that the airy unit of Alexa 555 was 1. The optical slice thicknesses were 0.9, 0.9, and 2.0 μm for 63× , 100× , and 20× lenses, respectively. The brightness and contrast of the images were adjusted using image browser software (ZEN2; Carl Zeiss). Images were exported in TIFF format.

Oda S, & Funato H. (2023). D1- and D2-type dopamine receptors are immunolocalized in pial and layer I astrocytes in the rat cerebral cortex. Frontiers in Neuroanatomy, 17, 1111008.

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Publication 2023

Anti-Antibodies anti-IgG Antibodies Antibodies, Anti-Idiotypic Argon Ion Lasers Cortex, Cerebral Diamond Dopamine Receptor Equus asinus GART protein, human Goat HOE 33342 Lasers, Semiconductor Lens, Crystalline Mice, House Microscopy, Confocal Rabbits Serum Submersion Vision

Dopamine Modulation of Basal Ganglia Synapses

The activation of D2‐like dopamine receptors, presumably on presynaptic terminals, decreases the probability of the release of neurotransmitters in inhibitory GPe‐STN synapses (Baufreton & Bevan, 2008 (link)) and excitatory STN‐GPe synapses (Hernández et al., 2006 (link)). However, no significant change was observed in GPe–GPe synapses (Miguelez et al., 2012 (link)). Additionally, activation of D1‐like dopamine receptors has been found to increase neurotransmitter release (Tecuapetla et al., 2007 (link)). Therefore, under normal conditions, we decreased the release probability (U) of GPe‐STN, STN‐GPe, and Str(iSPN)‐PGPe synapses by 50% and increased that of Str(dSPN)‐AGPe by 50%.

, & Kitano K. (2023). The network configuration in Parkinsonian state compensates network activity change caused by loss of dopamine. Physiological Reports, 11(4), e15612.

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Publication 2023

Dopamine Receptor Neurotransmitters Presynaptic Terminals Psychological Inhibition Synapses

Plasma Dopamine Excursion and Metabolic Outcomes

Assessment of plasma dopamine excursion upon nutrient feeding through time one-way repeated measures ANOVA with Dunn’s post-hoc corrections for multiple comparisons were performed, while between groups a comparison one-way ANOVA with Tukey’s post-hoc corrections for multiple comparisons was performed. To assess sleeve surgery effect on plasma dopamine excursion, one-way repeated measures ANOVA with Dunn’s post-hoc corrections for multiple comparisons were performed to assess differences in plasma dopamine concentration throughout time after a mixed meal feeding. Comparison between groups was assessed by one-way ANOVA with Tukey’s post-hoc corrections for multiple comparisons. A one way-ANOVA test with Tukey’s post-hoc corrections for multiple comparisons was performed to analyze all protein levels in sleeve gastrectomy surgery, bromocriptine, and liraglutide-treated animal models in all tissues. TH level on ilium and explants data were analyzed using the non-parametric Kruskal-Wallis with multiple comparisons test with Dunn’s post-hoc corrections. Data from adipose tissue ex vivo incubations were analyzed by one-way ANOVA with no corrections for multiple comparisons (Fisher’s LSD test). Results were presented as mean ± SEM. Regarding human data analysis, non-parametric tests were performed (sample size < 30/group), and results were presented as median and interquartile range. The Kruskal-Wallis test was applied to compare GLP-1R gene expression between groups. The Spearman correlation test was performed to assess the correlation between GLP-1 and dopamine receptors gene expression. Differences were considered significant at p < 0.05, and all computation analysis was performed using Graphpad Prism (6.0 version, GraphPad Software, Inc., San Diego, CA, USA).

Tavares G., Rosendo-Silva D., Simões F., Eickhoff H., Marques D., Sacramento J.F., Capucho A.M., Seiça R., Conde S.V, & Matafome P. (2023). Circulating Dopamine Is Regulated by Dietary Glucose and Controls Glucagon-like 1 Peptide Action in White Adipose Tissue. International Journal of Molecular Sciences, 24(3), 2464.

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Publication 2023

Animal Model Bromocriptine Dopamine Dopamine Effect Dopamine Receptor Gastrectomy Gene Expression Glucagon-Like Peptide 1 Homo sapiens Ilium Liraglutide neuro-oncological ventral antigen 2, human Nutrients Operative Surgical Procedures Plasma prisma Proteins Tissue, Adipose Tissues

Multiplex ELISA for Antibody Cross-Reactivity

Cross-reactivity of serum IgG, at fixed dilution of 1:400, against antigens p*17 and K4S2 were assessed by ELISA. Briefly, antigens p*17, K4S2 (5 µg/mL) or rM5 (1 μg/mL) were coated onto Nunc Maxisorp plates (ThermoFisher Scientific, Australia). After overnight blocking with 5% skim milk in 0.05% PBS Tween-20, test sera were applied at a fixed dilution of 1:400 diluted in 0.5% skim milk in 0.05% PBS Tween-20. After washing, goat anti-rat HRP (5204-2504, Bio-Rad, USA) secondary antibody was applied at 1:10,000 dilution. Plates were developed with o-Phenylenediamine dihydrochloride) tablets (OPD) (Sigma, Australia) and OD measured at 450 nm. Cross-reactivity of serum IgG against host proteins cardiac myosin, laminin, tropomyosin, dopamine receptors 1 and 2, lysoganglioside and tubulin and antigen rM5 were assessed by ELISA^{14 (link)}. Briefly, antigens were coated onto Nunc Maxisorp plates (ThermoFisher Scientific, Australia) at the concentration 1 μg/mL of rM5 and 10 μg/mL of cardiac myosin, laminin, tropomyosin (Sigma, Australia), dopamine receptor 1 and 2 (Aviva Systems Biology, USA), lysoganglioside (Sigma, Australia) and tubulin (MP Biomedicals, USA). After blocking with 1% bovine serum albumin, individual rat sera were added at the concentration of 1:400. The secondary antibody goat anti-rat IgG-HRP (112-035-003, Jackson ImmunoResearch, USA) was added at 1:5000 dilution. Plates were developed with, 2-2′-azino-di(3-ethylbenzthiazoline)-6-sulphonate (ABTS) (Sigma, Australia) and OD measured at 415 nm.

Reynolds S., Rafeek R.A., Hamlin A., Lepletier A., Pandey M., Ketheesan N, & Good M.F. (2023). Streptococcus pyogenes vaccine candidates do not induce autoimmune responses in a rheumatic heart disease model. NPJ Vaccines, 8, 9.

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Publication 2023

1,2-diaminobenzene 2,2'-azino-di-(3-ethylbenzothiazoline)-6-sulfonic acid Alkanesulfonates anti-IgG Antigens Cardiac Myosins Dopamine Receptor Enzyme-Linked Immunosorbent Assay Goat Immunoglobulins Laminin Milk, Cow's Proteins Serum Serum Albumin, Bovine Serum Sickness Technique, Dilution Tropomyosin Tubulin Tween 20

Confocal Imaging and Microscopy Analysis

Samples were imaged using Olympus Inverted Confocal FV3000 with a 10× objective except for samples using dopamine receptor antibodies which were imaged using the Zeiss Lightsheet Z.1. Image Z-stacks were then reconstructed and visualized using Imaris microscopy image analysis software.

Zwang T.J., Bennett R.E., Lysandrou M., Woost B., Zhang A., Lieber C.M., Richardson D.S, & Hyman B.T. (2023). Tissue libraries enable rapid determination of conditions that preserve antibody labeling in cleared mouse and human tissue. eLife, 12, e84112.

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Publication 2023

Antibodies Dopamine Receptor Microscopy

Top products related to «Dopamine Receptor»

Sch23390 by Merck Group

Sourced in United States, United Kingdom

SCH23390 is a laboratory reagent used for scientific research. It is a specific antagonist of the D1 dopamine receptor, and is commonly used as a tool compound in neuroscience and biochemistry studies. The core function of SCH23390 is to selectively bind to and block the activity of the D1 dopamine receptor in in vitro and in vivo experimental settings.

Qscript cdna supermix by Quanta Biosciences

Sourced in United States, Germany, Canada, Belgium, United Kingdom, Moldova, Republic of

QScript cDNA SuperMix is a ready-to-use solution for reverse transcription of RNA into cDNA. It contains all the necessary components for efficient conversion of RNA to cDNA, including a thermostable reverse transcriptase enzyme and RNase inhibitor.

Ab5084p by Merck Group

Sourced in United States

The AB5084P is a high-precision laboratory instrument designed for accurate and reliable measurements. Its core function is to provide consistent and repeatable data collection for research and scientific applications. The product specifications and technical details are available upon request.

Trizol by Thermo Fisher Scientific

Sourced in United States, Germany, China, Japan, United Kingdom, Canada, France, Italy, Australia, Spain, Switzerland, Belgium, Denmark, Netherlands, India, Ireland, Lithuania, Singapore, Sweden, Norway, Austria, Brazil, Argentina, Hungary, Sao Tome and Principe, New Zealand, Hong Kong, Cameroon, Philippines

TRIzol is a monophasic solution of phenol and guanidine isothiocyanate that is used for the isolation of total RNA from various biological samples. It is a reagent designed to facilitate the disruption of cells and the subsequent isolation of RNA.

Rneasy plus mini kit by Qiagen

Sourced in Germany, United States, United Kingdom, Netherlands, Canada, Japan, France, Spain, China, Australia, Italy, Switzerland, Belgium, Denmark, Sweden, Norway, Singapore, Jamaica, Hong Kong

The RNeasy Plus Mini Kit is a product from Qiagen designed for the purification of total RNA from a variety of sample types. It utilizes a silica-membrane-based technology to effectively capture and purify RNA molecules.

Sulpiride by Bio-Techne

Sourced in United Kingdom, United States

Sulpiride is a laboratory reagent used for analytical and research purposes. It is a selective dopamine D2 receptor antagonist. Sulpiride is commonly used in various research applications, including neuroscience and pharmacology studies.

Quinpirole by Bio-Techne

Sourced in United Kingdom, United States

Quinpirole is a synthetic chemical compound that is commonly used as a laboratory tool in scientific research. It functions as a selective agonist for the D2 and D3 dopamine receptors, which are important in the study of the dopaminergic system and its role in various biological processes and neurological disorders.

Rneasy kit by Qiagen

Sourced in Germany, United States, United Kingdom, Spain, Netherlands, Canada, France, Japan, China, Italy, Switzerland, Australia, Sweden, India, Singapore, Denmark, Belgium

The RNeasy kit is a laboratory equipment product that is designed for the extraction and purification of ribonucleic acid (RNA) from various biological samples. It utilizes a silica-membrane-based technology to efficiently capture and isolate RNA molecules.

More about "Dopamine Receptor"

Dopamine receptors are a class of G protein-coupled receptors that bind the neurotransmitter dopamine.
These receptors, also known as D receptors, play pivotal roles in regulating various physiological processes, including motor control, cognition, emotion, and reward-motivated behavior.
The dopamine receptor family is divided into two main subtypes: D1-like (D1 and D5) and D2-like (D2, D3, and D4) receptors, based on their structural and functional characteristics.
Imbalances in dopamine receptor signaling have been implicated in numerous neurological and psychiatric disorders, such as Parkinson's disease, schizophrenia, and addiction.
For example, the D1 receptor antagonist SCH23390 and the D2 receptor antagonist sulpiride have been extensively studied for their potential therapeutic applications in these conditions.
Understanding the complex mechanisms underlying dopamine receptor function is crucial for developing effective therapies targeting these receptors.
Researchers can leverage advanced tools like the QScript cDNA SuperMix and the RNeasy Plus Mini Kit to study dopamine receptor expression and signaling pathways.
Additionally, the AB5084P antibody can be used to detect and quantify dopamine receptor proteins, while the TRIzol reagent can be employed for efficient RNA extraction and subsequent gene expression analysis.
Compounds like the D2 receptor agonist quinpirole have also been utilized to investigate the role of dopamine receptors in various physiological and behavioral processes.
By employing these experimental tools and techniques, scientists can gain deeper insights into the regulation and function of dopamine receptors, ultimately paving the way for the development of novel and more effective therapies targeting dopamine-related disorders.
PubCompare.ai's AI-driven platform can enhance your dopamine receptor research by helping you locate optimal protocols from literature, pre-prints, and patents using intelligent comparisons.
This can improve the reproducibility and accuracy of your experiments, allowing you to experience the future of dopamine receptor optimization today.