Small Molecule Screening Research Articles

High potency 3-carboxy-2-methylbenzofuran pendrin inhibitors as novel diuretics

Pendrin (SLC26A4) is an anion exchanger expressed in epithelial cells of kidney and lung. Pendrin inhibition is a potential treatment approach for edema, hypertension and inflammatory lung diseases. We have previously identified first-in-class pendrin inhibitors by high-throughput screening, albeit with low potency for pendrin inhibition (IC50 ∼10 μM). Here, we performed a de novo small molecule screen with follow-on structure-activity studies to identify more potent pendrin inhibitors. Screening of 50,000 synthetic small molecules identified four novel classes of pendrin inhibitors with diverse scaffolds, including 5-benzyloxy-2-methylbenzofurans, N-aryl urea substituted 5-methyltryptamines, N-aryl urea substituted anthranilic acid, and substituted N-benzyl 3-carboxyindoles. The most potent inhibitor from the initial screen, a 3-carboxy-2-methylbenzofuran (1a), had IC50 of 4.1 μM. Structure-activity studies using 732 benzofuran analogs identified 1d with IC50 ∼ 0.5 μM for pendrin inhibition. Selectivity studies showed that 1d has minimal or no activity against related ion channels/transporters including SLC26A3, SLC26A6, SLC26A9 and CFTR at high concentrations. 1d administration to mice at 10 mg/kg had no effect on urine volume when used alone, but potentiated the diuretic effect of furosemide by 45%. In conclusion, we have identified novel pendrin inhibitors with greatly improved potency and good in vivo efficacy. These compounds can be used as pharmacological tools to study the roles of pendrin, and potentially developed as drug candidates for edema, hypertension and lung diseases.

Virtual screening and molecular dynamics studies of novel small molecules targeting Schistosoma mansoni DHODH: identification of potential inhibitors.

The online version contains supplementary material available at 10.1007/s40203-024-00281-6.

Abstract I005: Exploiting the immunoregulatory effect of double-stranded RNAs for cancer therapeutics

Abstract Introns are found in all eukaryotes and are one of the defining characteristics of eukaryotes. After transcription, pre-mRNAs undergo splicing, and introns are excised in the lariat structure. Since excised introns are degraded quickly after debranching, they have been considered as byproducts of gene expression, and their post-splicing role in the cells remains unclear. Here, we find that the inhibition of intron debranching process by depleting a debranching enzyme, DBR1, results in hyperactivation of protein kinase R (PKR) due to accumulation of intron lariat-derived transposable elements (TEs) that can adopt double-stranded secondary structure. Through in vitro PKR-binding assay, we show that PKR strongly binds to intron lariat RNAs harboring TEs, especially inverted Alu repeats. Interestingly, these TE-containing lariat RNAs are retained in the nucleus, but are released to the cytosol during mitosis, where they activate PKR, resulting in aberrant mitotic progression and apoptosis. We further exploit the lariat RNA-PKR interaction during mitosis and show that DBR1 depletion and anti-mitotic chemotherapy drugs can synergistically induce cancer cell death both in vitro and in vivo. Lastly, we perform docking simulation-based screening of DBR1-inhibitory small molecules. Collectively, our findings underscore the significance of intron turnover in avoiding innate immune activation and further suggest a potential strategy to enhance the efficacy of anti-mitotic drugs by targeting intron processing. Citation Format: Keonyong Lee, Jayoung Ku, Tria Asri Widowati, Namwook Kim, Soo Young Park, Han Suk Ryu,Yoosik Kim. Exploiting the immunoregulatory effect of double-stranded RNAs for cancer therapeutics [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: RNAs as Drivers, Targets, and Therapeutics in Cancer; 2024 Nov 14-17; Bellevue, Washington. Philadelphia (PA): AACR; Mol Cancer Ther 2024;23(11_Suppl):Abstract nr I005.

CSTF2 Supports Hypoxia Tolerance in Hepatocellular Carcinoma by Enabling m6A Modification Evasion of PGK1 to Enhance Glycolysis.

Cleavage stimulation factor subunit 2 (CSTF2) is a fundamental factor in the regulation of 3'-end cleavage and alternative polyadenylation of pre-mRNAs. Previous work has identified a tumor-promoting role of CSTF2, suggesting that it may represent a potential therapeutic target. Here, we aimed to elucidate the mechanistic function of CSTF2 in hepatocellular carcinoma (HCC). CSTF2 upregulation was frequent in HCC, and elevated levels of CSTF2 correlated with poor patient prognosis. While CSTF2 inhibition did not suppress HCC growth under non-stress conditions, it supported tolerance and survival of HCC cells under hypoxic conditions. Mechanistically, CSTF2 increased PGK1 protein production to enhance glycolysis, thereby sustaining the energy supply under hypoxic conditions. CSTF2 shortened the 3' untranslated region (3' UTR) of phosphoglycerate kinase 1 (PGK1) pre-mRNA by binding near the proximal polyadenylation site (pPAS). This shortening led to a loss of N6-methyladenosine (m6A) modification sites that are bound by YTH N6-methyladenosine RNA-binding protein F2 (YTHDF2) and increase degradation of PGK1 mRNA. Concurrently, hypoxia increased m6A modification of PGK1 mRNA near the pPAS that was recognized by the YTH N6-methyladenosine RNA-binding protein C1 (YTHDC1), which recruited CSTF2 to enhance the shortening of the PGK1 3'-UTR. A small molecule screen identified masitinib as an inhibitor of CSTF2. Masitinib counteracted PGK1 upregulation by CSTF2 and suppressed the growth of HCC xenograft and patient-derived organoid models. In conclusion, this study revealed a function of CSTF2 in supporting HCC survival under hypoxia conditions through m6A modification evasion and metabolic reprogramming, indicating inhibiting CSTF2 may overcome hypoxia tolerance in HCC.

Tiny but mighty: small molecules as vaccine adjuvants

Screening small molecule (SM) libraries now replaces traditional methods for vaccine adjuvant discovery. A study by Soni et al. highlights the use of primary human cells in high-throughput screening (HTS), leading to the discovery of a novel SM TLR7/8 agonist, PVP-037. This compound successfully restored vaccine-induced immune responses in aged mice.

CRISPRi/a screens in human iPSC-cardiomyocytes identify glycolytic activation as a druggable target for doxorubicin-induced cardiotoxicity

Doxorubicin is limited in its therapeutic utility due to its life-threatening cardiovascular side effects. Here, we present an integrated drug discovery pipeline combining human induced pluripotent stem cell (iPSC)-derived cardiomyocytes (iCMs), CRISPR interference and activation (CRISPRi/a) bidirectional pooled screens, and a small-molecule screening to identify therapeutic targets mitigating doxorubicin-induced cardiotoxicity (DIC) without compromising its oncological effects. The screens revealed several previously unreported candidate genes contributing to DIC, including carbonic anhydrase 12 (CA12). Genetic inhibition of CA12 protected iCMs against DIC by improving cell survival, sarcomere structural integrity, contractile function, and calcium handling. Indisulam, a CA12 antagonist, can effectively attenuate DIC in iCMs, engineered heart tissue, and animal models. Mechanistically, doxorubicin-induced CA12 potentiated a glycolytic activation in cardiomyocytes, contributing to DIC by interfering with cellular metabolism and functions. Collectively, our study provides a roadmap for future drug discovery efforts, potentially leading to more targeted therapies with minimal off-target toxicity.

ROSHAMBO: Open-Source Molecular Alignment and 3D Similarity Scoring.

Efficient virtual screening techniques are critical in drug discovery for identifying potential drug candidates. We present an open-source package for molecular alignment and 3D similarity calculations optimized for large-scale virtual screening of small molecules. This work parallels widely used proprietary tools and offers an approach complementary to structure-based virtual screening. Our package employs the PAPER software for optimizing molecular alignments based on Gaussian volume overlaps. GPU acceleration is utilized to significantly reduce computational time and resource requirements. After obtaining the optimal alignments between the target and the query molecules, both shape and color (based on pharmacophore features) scores are computed to assess molecular similarity, with aligned molecules optionally being output in sdf format. The package was benchmarked using the DUDE-Z public data sets. Results demonstrated the package's near-state-of-the-art performance and robustness across multiple target classes, with speed that enables many routine ligand-based drug discovery workflows. As an open-source and freely available resource (github.com/molecularinformatics/roshambo) with both a convenient Python API and command line interface, our package also addresses the need for accessible and efficient virtual screening tools in drug discovery.

Condensate remodeling reorganizes innate SS18 in synovial sarcomagenesis

SS18-SSX onco-fusion protein formed through aberrant chromosomal translocation t (X, 18; p11, q11), is the hallmark and plays a critical role in synovial sarcomagenesis. The recent works indicated that both the pathological SS18-SSX tumorigenic fusion and the corresponding intrinsic physiological SS18 protein can form condensates but appear to have disparate properties. The underlying regulatory mechanism and the consequent biological significance remain largely unknown. We show that the physical properties of oncogenic fusion protein SS18-SSX condensates within cells undergo alterations compared to the proto-oncogene protein SS18. By small-molecule screening and mutant assay, we identified the recognition of H2AK119ub histone modification could account for the distinctive properties of SS18-SSX1 condensates. Notably, we show that SS18-SSX1 condensates have impact on SS18 condensates and hijack that in a phase separation manner, resulting in the relocation of protein SS18 to the H2AK119ub modification targeted by SS18-SSX1. Consequently, this leads to the downregulation of tumor suppressor genes occupied by SS18 physiologically, like CAV1 and DAB2. These results reveal the underlying mechanism of genomic disorder and tumorigenesis caused by the remodeling of oncoprotein SS18-SSX1 condensates at the macroscopic level.

Comparative small molecule screening of primary human acute leukemias, engineered human leukemia and leukemia cell lines.

Targeted therapeutics for high-risk cancers remain an unmet medical need. Here we report the results of a large-scale screen of over 11,000 molecules for their ability to inhibit the survival and growth in vitro of human leukemic cells from multiple sources including patient samples, de novo generated human leukemia models, and established human leukemic cell lines. The responses of cells from de novo models were most similar to those of patient samples, both of which showed striking differences from the cell-line responses. Analysis of differences in subtype-specific therapeutic vulnerabilities made possible by the scale of this screen enabled the identification of new specific modulators of apoptosis, while also highlighting the complex polypharmacology of anti-leukemic small molecules such as shikonin. These findings introduce a new platform for uncovering new therapeutic options for high-risk human leukemia, in addition to reinforcing the importance of the test sample choice for effective drug discovery.

Chemoproteogenomic stratification of the missense variant cysteinome

Cancer genomes are rife with genetic variants; one key outcome of this variation is widespread gain-of-cysteine mutations. These acquired cysteines can be both driver mutations and sites targeted by precision therapies. However, despite their ubiquity, nearly all acquired cysteines remain unidentified via chemoproteomics; identification is a critical step to enable functional analysis, including assessment of potential druggability and susceptibility to oxidation. Here, we pair cysteine chemoproteomics—a technique that enables proteome-wide pinpointing of functional, redox sensitive, and potentially druggable residues—with genomics to reveal the hidden landscape of cysteine genetic variation. Our chemoproteogenomics platform integrates chemoproteomic, whole exome, and RNA-seq data, with a customized two-stage false discovery rate (FDR) error controlled proteomic search, which is further enhanced with a user-friendly FragPipe interface. Chemoproteogenomics analysis reveals that cysteine acquisition is a ubiquitous feature of both healthy and cancer genomes that is further elevated in the context of decreased DNA repair. Reference cysteines proximal to missense variants are also found to be pervasive, supporting heretofore untapped opportunities for variant-specific chemical probe development campaigns. As chemoproteogenomics is further distinguished by sample-matched combinatorial variant databases and is compatible with redox proteomics and small molecule screening, we expect widespread utility in guiding proteoform-specific biology and therapeutic discovery.

Bay 11-7082, an NF-κB Inhibitor, Prevents Post-Inflammatory Hyperpigmentation Through Inhibition of Inflammation and Melanogenesis.

Post-inflammatory hyperpigmentation (PIH) is a very common disorder of cutaneous hyperpigmentation, which poses a persistent management challenge in the fields of dermatology and esthetics. This study was designed to explore the anti-melanogenic and anti-inflammatory effects of Bay 11-7082, an NF-κB inhibitor, using small-molecule screening, to determine its potential application for PIH prevention. The molecular mechanisms were investigated invitro and exvivo in epidermis-humanized mice using melanin content, RT-PCR, and immunoblotting. Bay 11-7082 suppressed proinflammatory cytokines and ameliorated 2,4-dinitrofluorobenzene (DNFB)-induced contact dermatitis on day 15. The suppression of melanin synthesis by Bay 11-7082 was attributed to the reduction of MITF, which was induced by extracellular signal-regulated kinase activation. Bay 11-7082 reduced epidermal melanin accumulation in UVB-stimulated exvivo human epidermis as well as in the ear and tail skin of K14-stem cell factor (SCF) transgenic mice. Topical administration of Bay 11-7082 improved PIH on day 35 in the post-DNFB dorsal skin of K14-SCF transgenic mice. In conclusion, Bay 11-7082 can be considered a promising candidate for the development of a preventive topical agent for PIH.

The role of synaptic protein NSF in the development and progression of neurological diseases.

This document provides a comprehensive examination of the pivotal function of the N-ethylmaleimide-sensitive factor (NSF) protein in synaptic function. The NSF protein directly participates in critical biological processes, including the cyclic movement of synaptic vesicles (SVs) between exocytosis and endocytosis, the release and transmission of neurotransmitters, and the development of synaptic plasticity through interactions with various proteins, such as SNARE proteins and neurotransmitter receptors. This review also described the multiple functions of NSF in intracellular membrane fusion events and its close associations with several neurological disorders, such as Parkinson's disease, Alzheimer's disease, and epilepsy. Subsequent studies should concentrate on determining high-resolution structures of NSF in different domains, identifying its specific alterations in various diseases, and screening small molecule regulators of NSF from multiple perspectives. These research endeavors aim to reveal new therapeutic targets associated with the biological functions of NSF and disease mechanisms.

Covalent Inhibitors of S100A4 Block the Formation of a Pro-Metastasis Non-Muscle Myosin 2A Complex.

The S100 protein family functions as protein-protein interaction adaptors regulated by Ca2+ binding. Formation of various S100 complexes plays a central role in cell functions, from calcium homeostasis to cell signaling, and is implicated in cell growth, migration, and tumorigenesis. We established a suite of biochemical and cellular assays for small molecule screening based on known S100 protein-protein interactions. From 25 human S100 proteins, we focused our attention on S100A4 because of its well-established role in cancer progression and metastasizes by interacting with nonmuscle myosin II (NMII). We identified several potent and selective inhibitors of this interaction and established the covalent nature of binding, confirmed by mass spectrometry and crystal structures. 5b showed on-target activity in cells and inhibition of cancer cell migration. The identified S100A4 inhibitors can serve as a basis for the discovery of new cancer drugs operating via a novel mode of action.

Small Molecule Screening Identifies HSP90 as a Modifier of RNA Foci in Myotonic Dystrophy Type 1.

Myotonic dystrophy type 1 (DM1) is a multisystemic disorder caused by a CTG triplet repeat expansion within the 3' untranslated region of the DMPK gene. Expression of the expanded allele generates RNA containing long tracts of CUG repeats (CUGexp RNA) that form hairpin structures and accumulate in nuclear RNA foci; however, the factors that control DMPK expression and the formation of CUGexp RNA foci remain largely unknown. We performed an unbiased small molecule screen in an immortalized human DM1 skeletal muscle myoblast cell line and identified HSP90 as a modifier of endogenous RNA foci. Small molecule inhibition of HSP90 leads to enhancement of RNA foci and upregulation of DMPK mRNA levels. Knockdown and overexpression of HSP90 in undifferentiated DM1 myoblasts validated the impact of HSP90 with upregulation and downregulation of DMPK mRNA, respectively. Furthermore, we identified p-STAT3 as a downstream mediator of HSP90 impacting levels of DMPK mRNA and RNA foci. Interestingly, differentiated cells exhibited an opposite effect of HSP90 inhibition displaying downregulation of DMPK mRNA through a mechanism independent of p-STAT3 involvement. This study has revealed a novel mediator for DMPK mRNA and foci regulation in DM1 cells with the potential to identify targets for future therapeutic intervention.

Streamlined analysis of drug targets by proteome integral solubility alteration indicates organ-specific engagement

Proteins are the primary targets of almost all small molecule drugs. However, even the most selectively designed drugs can potentially target several unknown proteins. Identification of potential drug targets can facilitate design of new drugs and repurposing of existing ones. Current state-of-the-art proteomics methodologies enable screening of thousands of proteins against a limited number of drug molecules. Here we report the development of a label-free quantitative proteomics approach that enables proteome-wide screening of small organic molecules in a scalable, reproducible, and rapid manner by streamlining the proteome integral solubility alteration (PISA) assay. We used rat organs ex-vivo to determine organ specific targets of medical drugs and enzyme inhibitors to identify drug targets for common drugs such as Ibuprofen. Finally, global drug profiling revealed overarching trends of how small molecules affect the proteome through either direct or indirect protein interactions.

Small molecule modulation of insulin receptor-insulin like growth factor-1 receptor heterodimers in human endothelial cells

ObjectivesThe insulin receptor (IR) and insulin like growth factor-1 receptor (IGF-1R) are heterodimers consisting of two extracellular α-subunits and two transmembrane β -subunits. Insulin αβ and insulin like growth factor-1 αβ hemi-receptors can heterodimerize to form hybrids composed of one IR αβ and one IGF-1R αβ. The function of hybrids in the endothelium is unclear. We sought insight by developing a small molecule capable of reducing hybrid formation in endothelial cells. MethodsWe performed a high-throughput small molecule screening, based on a homology model of the apo hybrid structure. Endothelial cells were studied using western blotting and qPCR to determine the effects of small molecules that reduced hybrid formation. ResultsOur studies unveil a first-in-class quinoline-containing heterocyclic small molecule that reduces hybrids by >50% in human umbilical vein endothelial cells (HUVECs) with no effects on IR or IGF-1R. This small molecule reduced expression of the negative regulatory p85α subunit of phosphatidylinositol 3-kinase, increased basal phosphorylation of the downstream target Akt and enhanced insulin/insulin-like growth factor-1 and shear stress-induced serine phosphorylation of Akt. In primary saphenous vein endothelial cells (SVEC) from patients with type 2 diabetes mellitus undergoing coronary artery bypass (CABG) surgery, hybrid receptor expression was greater than in patients without type 2 diabetes mellitus. The small molecule significantly reduced hybrid expression in SVEC from patients with type 2 diabetes mellitus. ConclusionsWe identified a small molecule that decreases the formation of IR: IGF-1R hybrid receptors in human endothelial cells, without significant impact on the overall expression of IR or IGF-1R. In HUVECs, reduction of IR: IGF-1R hybrid receptors leads to an increase in insulin-induced serine phosphorylation of the critical downstream signalling kinase, Akt. The underpinning mechanism appears, at least in part to involve the attenuation of the inhibitory effect of IR: IGF-1R hybrid receptors on PI3-kinase signalling.

Chemical Proteomics Approaches for Screening Small Molecule Inhibitors Covalently Binding to SARS-Cov-2.

Although various strategies have been used to prevent and treat SARS-CoV-2, the spread and evolution of SARS-CoV-2 is still progressing rapidly. The emerging variants Omicron and its sublineage have a greater ability to spread and escape nearly all current monoclonal antibodies treatments, highlighting an urgent need to develop therapeutics targeting current and emerging Omicron variants or recombinants with breadth and potency. Here, some small molecule drugs are rapidly identified that could covalently binding to receptor binding domain (RBD) protein of Omicron through the combined application of artificial intelligence (AI) and activity-based protein profiling (ABPP) technology. The surface plasmon resonance (SPR) and pseudo-virus neutralization experiments further reveal that an FDA-approved drug gallic acid has robust neutralization potency against Omicron pseudo-virus with the IC50 values of 23.56 × 10-6 m. Taken together, a platform combining AI intelligence, biochemical, SPR, molecular docking, and pseudo-virus-based screening for rapid identification and evaluation of potential anti-SARS-CoV-2 small molecule drugs is established and the effectiveness of the platform is validated.

9377 Exploring Strategies To Reverse Cellular Characteristics Of Succinate Dehydrogenase B-loss Immortalized Chromaffin Cells

Abstract Disclosure: L. Rahimi: None. F. Al-Khazal: None. N. Becker: None. L. Maher, III: None. Carriers of loss-of-function alleles in genes encoding the four succinate dehydrogenase (SDH) subunits exhibit a heightened risk for pheochromocytoma/paraganglioma (PPGL), a rare neuroendocrine tumor of chromaffin cells. Tumorigenesis begins with the somatic loss of the remaining functional gene copy, resulting in a cell devoid of functional SDH. Compared to wild-type immortalized chromaffin cells (WT imCCs), SDHB-KO immortalized chromaffin cells (SDHB-KO imCCs) are larger, grow more slowly, display deformed mitochondria, show strikingly heightened succinate accumulation, and altered metabolism. Among several mechanisms proposed to link SDH deficiency with PPGL tumorigenesis, the accumulation of succinate as an oncometabolite is a leading hypothesis. We describe two attempts to suppress succinate accumulation in SDHB-KO imCCs. First, riboflavin has previously been shown to enhance residual SDHA flavinylation and enzymatic function, possibly reducing succinate levels by supporting conversion of accumulated succinate to fumarate in the absence of SDHB. We tested this by treating WT and SDHB-KO imCCs with 5 µM riboflavin for 2 weeks. Metabolomic analysis did not show decreased succinate, suggesting that enzyme activity of any remaining SDHA subunit was not rescued by increased flavinylation. Second, we envisioned a gene therapy approach to replace defective SDHB with a rescuing transgene. SDHB-KO imCCs received DNA encoding SDHB or SDHC cDNAs via transposon technology, confirmed by PCR and analyzed by western blot analyses. These studies showed that whereas WT imCCs successfully expressed processed transgene products in mitochondria, SDHB-KO imCCs could not process or transport rescuing SDH subunits into mitochondria. This shows that transposed SDHB-KO imCCs cannot properly express a rescuing SDHB subunit and do not revert to a wild-type phenotype. It is likely that the severely damaged mitochondria of SDHB-KO imCCs are incompetent to process and import rescuing SDHB subunits, so unprocessed protein accumulates without effect. This defect may lie in the mitochondrial targeting peptide recognition system because the targeting peptide of rescuing SDHB protein is not removed in SDHB-KO imCCs as judged by western blotting. In summary, we show the failure of two conceptually simple tactics to suppress succinate accumulation in SDHB-KO imCCs with highly defective mitochondria: rescue of SDHA by supporting flavinylation, or rescue of SDHB with a replacement gene copy. Further research may allow screening for small molecules that suppress succinate accumulation by other mechanisms. It remains to be determined if blocking succinate accumulation would be therapeutic in SDH-loss PPGL tumors. Presentation: 6/1/2024

High-throughput screening of the natural STK11 agonist dauricine: A biphenylisoquinoline alkaloid exerting anti-NSCLC effects and reversing gefitinib resistance

BackgroundSerine/threonine kinase 11 (STK11) deletion and downregulation caused cancer progression, and were widely associated with drug resistance. Accurate screening of natural small molecules about anti-cancer and anti-drug resistance is the key to the development and utilization of natural product application, which could promote traditional Chinese medicine in the treatment of cancer. Dauricine, which is derived from the rhizome of Menispermum dauricum DC., has certain potential but unexplored mechanism for the treatment of cancer. PurposeThe aim of this study was to screen and validate the role and mechanism of natural STK11 agonists with anti-drug resistance from plants in the treatment of NSCLC. MethodsA lentiviral STK11 overexpression cell model was employed for the screening of natural STK11 agonists. The efficacy of dauricine in the treatment of NSCLC was validated on PC-9 and HCC827 cells. In vivo validation of dauricine activity was performed using nude mouse models equipped with PC9 xenografts. To investigate the anti-resistant effects of dauricine, gefitinib-resistant PC9 cell models were constructed. ResultsAs a natural agonist of STK11, it causes the activation of the STK11/AMPK pathway and inhibits the growth of PC-9 cells. Dauricine synergises the inhibitory effect with gefitinib on PC9. The up-regulation of STK11 protein expression by dauricine was demonstrated in vitro and in vivo, while restoring the sensitivity of PC9/GR to gefitinib by down-regulating the protein expression of Nrf2 and Pgp. ConclusionDauricine, a natural agonist of STK11, effectively inhibited NSCLC, and its combination treatment with gefitinib reversed drug-resistant NSCLC.

Natural small molecule compounds targeting Wnt signaling pathway inhibit HPV infection

BackgroundHigh-risk human papillomavirus (HPV) infection is a major risk factor of HPV-related tumors, especially cervical cancer. To date, there is no specific drug for the treatment of HPV infection. PurposeTo explore the role of canonical Wnt signaling pathway in HPV16 infection and to screen inhibitors against HPV16 infection from natural small molecule compounds targeting the canonicalWnt pathway. MethodsWnt pathway inhibitor IWP-2 and FH535 were used to inhibit Wnt/β-catenin signaling pathway. HPV16-GFP pseudovirus infectivity were analyzed by fluorescence microscopy and fluorescence activated cell sorting. A small molecule screening of a total of CFDA-approved 29 natural compounds targeting the Wnt pathway was performed. ResultsWnt signaling pathway inhibitor suppressed HPV16-GFP pseudovirus infection in HaCat cells. Natural small molecule compounds screening identified 6-Gingerol, gossypol, tanshinone II2A, and EGCG as inhibitors of HPV16-GFP pseudovirus infection. ConclusionWnt signaling pathway is involved in the process of HPV infection of host cells. 6-Gingerol, gossypol, tanshinone II2A, and EGCG inhibited HPV16-GFP pseudovirus infection and suppressed Wnt/β-catenin pathway in HaCat cells.