Compound Screening Guide!
High-Throughput Screening Accelerates Drug Discovery
Drug discovery is a long-term and high-cost process, which is roughly divided into several parts such as early drug development, preclinical research stage, clinical research stage, and approval for listing. Early drug development is a key process in the development of new drugs, including the study of disease mechanism, target discovery and confirmation, and the discovery of lead compounds[1].
High-Throughput Screening (HTS) is one of the commonly used techniques in drug discovery, which is used to find out potential lead compounds for pharmacochemical optimization from compound libraries, greatly speeding up the process of high-volume compound screening.
Using automated rapid testing of thousands to millions of samples, HTS can verify biological activity at the model organism, cell, or molecular level, screening for small molecular compounds, chemical mixtures, natural products, oligonucleotides, and antibodies with known structures[2][3].
How to Choose a Suitable Library?
If there is a clear target, pathway or disease, it is recommended to select the corresponding compound library. If there are specific protein names and structures associated with clear pathways, virtual screening can be used for preliminary screening, and then purchase corresponding physical compounds based on the results of virtual screening.
In addition, MCE can also help customers to screen and match the compounds that according to specific experiments.
How to Use Compound Library for Screening Experiments?
Screening based on compound library mainly includes experimental design, drug screening, data analysis, lead compound confirmation and other processes.
Type of Screening Experiments
As shown in Figure 3, there are many methods for HTS experimental screening, including cell-based experiments, biochemical experiments, and experiments on simple organisms in vivo (zebrafish, etc.).
More commonly used is cell-based screening, which can provide data that cannot be obtained from biochemical assays, such as whether a compound has pharmacological activity at a specific receptor or intracellular target. Cell-based screening therefore holds particular promise as an important tool for studying cell growth and differentiation, examining the effects of small molecules and cell growth conditions on cell function and physiology, and understanding mammalian cell signaling pathways[3].
Screening Procedures of Cell-Based Screening Experiments
1)?Preliminary Screening
Cell viability/proliferation assay is one of the commonly used experiments, and it is recommended to screen with a single concentration. 10 μM is commonly used for screening (If the cells can tolerate higher DMSO content, the primary screening concentration can also be increased to 30/50 μM). Compare the inhibition/activation rate or screen out positive compounds based on the activity data and number of compounds screened (The lower the concentration of compounds used in the initial screening, the fewer compounds screened and the higher the relative activity).
2)?Re-Screening
The positive compounds obtained from the preliminary screening were re-screened with different concentrations. It is recommended to set 6-7 concentrations, and the dilution range should be higher than four orders of magnitude. The maximum concentration can be set by referring to the DMSO tolerance test data, generally no more than 100 μM, and at least 3 replicates should be set for each concentration.
The best active compound is selected by screening results, which excluded false positive compounds and no concentration dependent compounds.
3)?Validation of Lead/Hit Compounds
Because each detection method has certain limitations, for the lead compounds obtained from the preliminary screening or re-screening, further verification analysis needs to be performed by using different detection methods than the primary screening and re-screening to rule out false positives.
Note: The experiment should be set up negative control, positive control (if any) and blank control.
【Case 1】
In this article, The customer used a Kinase Inhibitor Library (HY-L009 ) and a high-throughput system for the kinase activity assay of CaMKII-δ9, the most abundant CaMKIl-δ splicing variant in the human heart, to screen and validate a highly active and selective CaMKIl-δ small molecule inhibitor Hesperadin is a lead compound with dual functions of cardiac protection and antitumor activity.
Preliminary screening: A screening system was first established using the recombinant CaMKII-δ9 protein to test the inhibition of an inhibitor library of 4,160 compounds (partially purchased from MCE), with KN93 ?as a positive control (Figures 5A and 5B). At a concentration of 10 μM, 33 molecules inhibited the activity of CaMKII-δ9 by more than 95%.
Re-screening: The 33 molecules obtained in the preliminary screening were tested for IC50 which inhibited the activity of CaMKII-δ9 kinase.
Verification of lead compounds: On the basis of re-screening, the top 10 compounds with the lowest IC50 were selected (FIG. 5C) to further analyze the protective effects on cardiomyocytes.
Finally, the team screened Hesperadin, an Aurora B kinase inhibitor with anti-tumor activity, in vitro, which could specifically inhibit CaMKII-δ in the heart in an ATP-competitive manner. In addition, in BALB/c nude mouse models implanted with human cancer cells in vivo, Hesperadin delayed tumor growth but did not cause cardiomyocyte death or heart damage (Fig 6).
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【Case 2】
Y107H, a mutant of tumor suppressor gene TP53, can increase the risk of cancer in mice. The authors selected 2,000+ compounds from the MCE anti-cancer compound library (HY-L025 ) through primary screening and secondary screening. To obtain compounds that induce Y107H mutated HCT116 colorectal cancer cells (clonal A11 and C2) to preferentially deactivate, and to explore the potential mechanism of Y107H's action in colon cancer.
Validation of candidate compounds: Two of the screened compounds, the glutaminase inhibitors CB-839 and BPTES , showed increased sensitivity in Y107H mutated colorectal cancer cells treated with two candidate compounds using independent cell viability assays (Alamar Blue) (Figures 8A and 8B). CB-839 (200 mg/kg) can significantly inhibit tumor growth in NSG mice (Y107H cell group).
The lead compound is obtained, and the structure can be further optimized to promote the better function of the drug.
MCE Compound Library
As a leading global supplier of research chemicals and bioactive compounds, MCE currently offers a library of 200+ ready-to-use active compounds, totaling 20,000+ bioactive small molecules for high-throughput screening (HTS) and high content screening (HCS). It is a professional tool for research on new drug screening and new indication discovery!
Bioactive compounds are easy to penetrate the cell membrane, act on specific target proteins in cells, regulate intracellular signaling pathways, and then cause some changes in cell phenotype. MCE provides 20,000+ compounds with clear reports, known activities and clear targets. All products in the compound library target comprehensive targets, involving a wide range of signaling pathways, can be used for signaling pathway research and new drug development.
New drug discovery is a time-consuming and high-cost process, a large number of potential drugs never enter clinical testing, and even when compounds do enter clinical development, less than 15% are ultimately approved, so drug repurposing is attractive and pragmatic [7]. Approved drugs and compounds through clinical phase I have good biological activity, pharmacokinetic properties and safety, which can reduce the risk of drug development failure, shorten the research and development cycle, and reduce research and development costs. The MCE includes 5,000+ drugs that are suitable for study in new indications.
Natural products are produced in nature, including primary metabolites and secondary metabolites. Natural products and their derivatives still make up a large proportion of approved drugs globally, but as shown in Figure 9, natural products may be underutilized in high-throughput screening [8]. Therefore, the biodiversity and potential biological activity of natural products are important sources for the development of lead compounds in drug discovery. MCE contains 5,000+ natural products with rich sources and diverse structures, and is an important source of lead compounds.
As the cornerstone of traditional Chinese medicine, Chinese herbal ingredients have a wide variety of chemical structures and high selectivity, and are considered to be the ideal starting point for molecular design. It is estimated that no less than 50% of small molecule clinical drugs approved worldwide are derived directly or indirectly from herbal ingredients [9]. TCM monomer is the active ingredient in Chinese herbal medicine, which has many medicinal properties, such as antioxidant, anticancer, antibacterial and so on, and is an important source of new drug development. The MCE contains 3,000+ monomer compounds of Chinese herbal origin and is a useful tool for screening medicines of Chinese herbal origin.
Fragment-based drug development (FBDD) usually starts with chemical fragments with low binding affinity to the target, low chemical structure complexity, and low molecular weight (≤300 Da), which is very suitable for the discovery of lead compounds and functional probes. Fragment compounds can cover a wide chemical space, save experimental costs, and provide diversified hits [10]. MCE included 22,000+ fragments of compounds, all in line with the "RO3 principle", that is, molecular weight ≤300 Da, hydrogen donors ≤3, hydrogen acceptors ≤3, cLogP≤3.
MCE has been helping global customers with scientific research, so far, MCE has known activity library, drug diversity library, characteristic fragment library and drug screening, lead compound optimization platform, providing one-stop drug discovery and research services for global scientific research customers and new drug research and development customers. If you have any needs, please contact us anytime.