Regulation Of Protein-protein Interactions Research Articles

Recent Developments in 14-3-3 Stabilizers for Regulating Protein-Protein Interactions: An Update.

14-3-3 proteins play a crucial role in the regulation of protein-protein interactions, impacting various cellular processes and disease mechanisms. Recent advancements have led to the development of stabilizers that enhance the binding of 14-3-3 proteins to clients, presenting promising therapeutic potentials. This perspective provides an updated overview of the latest developments in the field of 14-3-3 stabilizers, with a focus on their design, synthesis, and biological evaluation. We discuss the structural basis for the interaction between 14-3-3 proteins and their ligands, highlighting key modifications that enhance binding affinity and selectivity. Additionally, we explore the therapeutic applications of 14-3-3 stabilizers across major therapeutic areas such as cancer, metabolic disorders, and neurodegenerative diseases. By summarizing recent research findings and technological advancements, this perspective aims to shed light on the current state of 14-3-3 stabilizer developments and outline future directions for optimizing these compounds as effective therapeutic agents.

Manipulation and Structural Activity of AcpM in Mycobacterium tuberculosis.

Mycobacterium tuberculosis (Mtb) is a leading cause of death, with an escalating global occurrence of drug-resistant infections that are partially attributed to cell wall mycolic acids derived from type II fatty acid biosynthesis (FAS-II). Here, the central acyl carrier protein, AcpM, contributes to the regulation of complex and specific protein-protein interactions (PPIs), though the orchestration of these events remain largely unresolved due to unique features of AcpM. Limitations include complexities in generating modified AcpM in a single state. Herein, we report a streamlined method to generate homogeneous samples of modified AcpM for applications in structure and functional studies. We apply these to generate solvatochromic labeled crypto-AcpM, where fluorescence response reports cargo sequestration and chain flipping upon interaction with four FAS-II enzymes. We find an increased fluorescence in a truncated form, AcpM80, indicating that the 35-residue C-terminus is involved in modulating the chemical environment surrounding the substrate and contributing to the regulation of PPIs. This study establishes an efficient chemo-enzymatic strategy to generate AcpM analogs for biophysical studies to aid in understanding the processes driving Mtb pathogenicity and drug resistance.

Abstract B009: The RNA binding activity of the BRAF Kinase

Abstract Multiprotein complexes are key molecular switches of oncogenic signal transduction pathways that relay the flux of information coming from transmembrane receptors and distribute signals to a myriad of effectors. As such the regulation of protein-protein interactions is crucial in signal transduction pathways. For instance, activation of the mitogen-activated protein kinases pathway (MAPK) occurs through a cascade of phosphorylation and protein-protein interactions (PPIs) and is often deregulated in cancer. RNA-protein interactions play key roles in biological processes. More than a thousand RNA binding proteins (RBPs) influence the fate of mRNAs and non-coding RNAs in different ways. It is however less described how RNAs can in turn influence the functions of proteins to which they bind. Here we propose that RNAs scaffold PPIs in the MAPK pathway, thereby fine-tuning oncogenic signaling. We focused our study on cutaneous melanoma for which the MAPK is activated in more than 70% of the cases due to activating mutations in BRAF and NRAS. Using UV-CrossLinking ImmunoPrecipitation (CLIP) experiments, we found that several proteins of the MAPK pathway, including BRAF (but not MEK and ERK) interact with RNAs in RAS-activated melanoma cells. In addition, using a PLA- based imaging technique that allows the visualisation of the proximity of two given proteins, we showed that RNAs promote the stabilisation of BRAF-PPIs, suggesting a scaffolding role of RNAs in the MAPK pathway. Loss of BRAF RNA binding activity (achieved with a single point mutation) is associated with decreased BRAF dimerization and signaling. The oncogenic mutant protein BRAF (V600E) also interacts with RNA in a variety of melanoma cell lines including a BRAF inhibitor-resistant melanoma cell line in which the dimerization of BRAF and CRAF is partly dependent on RNA. Identifying BRAF-bound RNAs will open new therapeutic strategies targeting RNA-protein interactions. We also envision that the level of BRAF-RNA interactions could serve as a predictive marker of response to BRAF (V600E) inhibitors. Citation Format: Alexia Le Barch, Sabrina Mennour, Patricia Uguen, Stephan Vagner. The RNA binding activity of the BRAF Kinase [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 B009.

Thimet oligopeptidase (THOP 1) distribution in cane toad (Bufo Marinus, Linnaeus, 1758) brain

Thimet oligopeptides (THOP 1) is a metal-dependent peptidase involved in the metabolism of neuropeptides and the presentation of peptides via MHC-1. It has been shown to play a role in the regulation of protein-protein interactions and the metabolism of intracellular peptides. THOP 1 is associated with important biological processes such as metabolism and neurodegenerative diseases, among others. The objective of this study is to elucidate the distribution of THOP 1 in the Bufo marinus brain. The analysis of THOP 1 amino acid sequences indicates that they have been conserved throughout evolution, with significant homology observed across various phyla. When comparing amphibians with other species, more than 70% identity can be identified. Immunohistochemistry analysis of the toad's brain has demonstrated that the enzyme has a ubiquitous distribution, consistent with previous findings in mammals. THOP 1 can be found in important areas of the brain, such as bulb, thalamic nuclei, striatum, hypothalamus, and among others. Nonetheless, THOP 1 is consistently localized within the nucleus, a pattern also observed in the rat brain. Therefore, based on these results, the toad appears to be an excellent model for studying the general biology of THOP 1, given the substantial homology of this enzyme with mammals and its similarity in distribution within the brain.

A transient vesicular glue for amplification and temporal regulation of biocatalytic reaction networks.

Regulation of enzyme activity and biocatalytic cascades on compartmentalized cellular components is key to the adaptation of cellular processes such as signal transduction and metabolism in response to varying external conditions. Synthetic molecular glues have enabled enzyme inhibition and regulation of protein-protein interactions. So far, all the molecular glue systems based on covalent interactions operated under steady-state conditions. To emulate dynamic biological processes under dissipative conditions, we introduce herein a transient supramolecular glue with a controllable lifetime. The transient system uses multivalent supramolecular interactions between guanidinium group-bearing surfactants and adenosine triphosphate (ATP), resulting in bilayer vesicle structures. Unlike the conventional chemical agents for dissipative assemblies, ATP here plays the dual role of providing a structural component for the assembly as well as presenting active functional groups to "glue" enzymes on the surface. While gluing of the enzymes on the vesicles achieves augmented catalysis, oscillation of ATP concentration allows temporal control of the catalytic activities similar to the dissipative cellular nanoreactors. We further demonstrate temporal upregulation and control of complex biocatalytic reaction networks on the vesicles. Altogether, the temporal activation of biocatalytic cascades on the dissipative vesicular glue presents an adaptable and dynamic system emulating heterogeneous cellular processes, opening up avenues for effective protocell construction and therapeutic interventions.

Interfacial Peptides as Affinity Modulating Agents of Protein-Protein Interactions.

The identification of disease-related protein-protein interactions (PPIs) creates objective conditions for their pharmacological modulation. The contact area (interfaces) of the vast majority of PPIs has some features, such as geometrical and biochemical complementarities, “hot spots”, as well as an extremely low mutation rate that give us key knowledge to influence these PPIs. Exogenous regulation of PPIs is aimed at both inhibiting the assembly and/or destabilization of protein complexes. Often, the design of such modulators is associated with some specific problems in targeted delivery, cell penetration and proteolytic stability, as well as selective binding to cellular targets. Recent progress in interfacial peptide design has been achieved in solving all these difficulties and has provided a good efficiency in preclinical models (in vitro and in vivo). The most promising peptide-containing therapeutic formulations are under investigation in clinical trials. In this review, we update the current state-of-the-art in the field of interfacial peptides as potent modulators of a number of disease-related PPIs. Over the past years, the scientific interest has been focused on following clinically significant heterodimeric PPIs MDM2/p53, PD-1/PD-L1, HIF/HIF, NRF2/KEAP1, RbAp48/MTA1, HSP90/CDC37, BIRC5/CRM1, BIRC5/XIAP, YAP/TAZ–TEAD, TWEAK/FN14, Bcl-2/Bax, YY1/AKT, CD40/CD40L and MINT2/APP.

Novel approach to protein-protein interaction assessment

Past decades, the study of proteins and small molecules interaction has been at least lagging behind the study of other types of interactions such as protein-protein, protein-DNA and protein-RNA. The aim of this study is to evaluate the effect of low-molecular biologically active compounds, lactate and pyruvate, on protein-protein interactions and to provide quantitative assessment. Using AB0 blood groups system model and labeled monoclonal anti-A and anti-B antibodies we studied the effect of natural metabolites lactate and pyruvate on antigen-antibody interaction. Erythrocytes of A(II) and B(III) blood groups were incubated with lactate and pyruvate before the agglutination reaction. Then the agglutination reaction was performed. Visualization of agglutination complexes was carried out by means of confocal laser scanning microscopy with further processing of noise pixels. A series of in vitro experiments with further visualization and mathematical processing showed the co-directed but more pronounced effect of lactate on the antigen-antibody reaction as compared to pyruvate. In case of influence on antigen A the aggregation process intensification was noted, while this process was inhibited in case of influence on antigen B. The obtained results demonstrate possibility of using small molecules, in particular lactate and pyruvate, as molecular probes and prospects of erythrocytes with antigenic determinants of AB0 system expressed on their membranes for studying protein-protein interactions due to visualization clarity and possibility of quantitative assessment of this process. It is proved that lactate and pyruvate can act as regulators of protein-protein interactions on the example of antigen-antibody reaction.

Evaluation of protein-ligand interactions using the luminescent interaction assay FlimPIA with streptavidin-biotin linkage

Post-translational modifications, such as phosphorylation, are crucial in the regulation of protein-protein interactions and protein function in cell signaling. Here, we studied the interaction between the transactivation domain peptide of cancer suppressor protein p53 and its negative regulator Mdm2 using a novel protein-protein interaction assay, based on the modified FlimPIA using the streptavidin-biotin interaction to link the p53 peptide and the probe enzyme. We succeeded in detecting an attenuation in the affinity of p53 towards Mdm2 caused by the phosphorylation at Thr18. It showed that the targets, which are not easy to fuse with the FlimPIA probes, such as phosphorylated peptides can be used in this system. Also, the use of streptavidin nanobeads was found effective to get clearer signal, probably due to concentration of the detection system onto the bead surface. The system was further applied to the detection of FKBP-FRB interaction using biotinylated FKBP domain, which suggested another potential merit of this system that allows to avoid misfolding and steric hindrance often observed for the fusion protein approach.

Mapping Transient Protein Interactions at the Nanoscale in Living Mammalian Cells

Protein-protein interactions (PPIs) form the basis of cellular processes, regulating cell behavior and fate. PPIs can be extremely transient in nature, which hinders their detection. In addition, traditional biochemical methods provided limited information on the spatial distribution and temporal dynamics of PPIs that is crucial for their regulation in the crowded cellular environment. Given the pivotal role of membrane micro- and nanodomains in the regulation of PPIs at the plasma membrane, the development of methods to visualize PPIs with a high spatial resolution is imperative. Here, we present a super-resolution fluorescence microscopy technique that can detect and map short-lived transient protein-protein interactions on a nanometer scale in the cellular environment. This imaging method is based on single-molecule fluorescence microscopy and exploits the effect of the difference in the mobility between cytosolic and membrane-bound proteins in the recorded fluorescence signals. After the development of the proof of concept using a model system based on membrane-bound modular protein domains and fluorescently labeled peptides, we applied this imaging approach to investigate the interactions of cytosolic proteins involved in the epidermal growth factor signaling pathway (namely, Grb2, c-Raf, and PLCγ1). The detected clusters of Grb2 and c-Raf were correlated with the distribution of the receptor at the plasma membrane. Additionally, the interactions of wild type PLCγ1 were compared with those detected with truncated mutants, which provided important information regarding the role played by specific domains in the interaction with the membrane. The results presented here demonstrate the potential of this technique to unravel the role of membrane heterogeneity in the spatiotemporal regulation of cell signaling.

Macrocyclic peptides as regulators of protein-protein interactions

Abstract Protein-protein interactions (PPIs) are recognized as attractive therapeutic targets. However targeting PPIs especially intracellular ones has been proven extremely difficult for conventional drug-like small molecules, and biological drugs such as monoclonal antibodies have difficulty in reaching intracellular targets. Macrocyclic peptides are promising candidates of PPI regulators for their potential in combining high potency and biological stability together. Cell permeability of macrocyclic peptides may also be achieved by structural modifications or conjugation to a cell-penetrating sequence. Significant progress has been made in this research area in recent years. Important technology progress and recent examples of macrocyclic peptide PPI modulators are reviewed.

Roles of SUMO modification in pulmonary diseases

Small ubiquitin-related modifier(SUMO)is a small molecule that is structurally similar to ubiquitin.SUMOylation has emerged as an important post-translational modification.It profoundly influences the function of proteins, including the regulation of protein-protein interaction, the activity of protein transcription, DNA damage repair, gene regulation and biological rhythm.In recent years, evidence suggests that the SUMOylation plays crucial roles in lung.By binding to target proteins, SUMO is associated with pulmonary biological function and disease. Key words: Small ubiquitin-related modifier; Lung cancer; Acute lung injury; Mycoplasmal pneumonia

Isatin-induced increase in the affinity of human ferrochelatase and adrenodoxin reductase interaction.

Isatin (indol-2,3-dione) is an endogenous non-peptide regulator exhibiting a wide range of biological and pharmacological activities, which are poorly characterized in terms of their molecular mechanisms. Identification of many isatin-binding proteins in the mammalian brain and liver suggests that isatin may influence their functions. We have hypothesized that besides direct action on particular protein targets, isatin can act as a regulator of protein-protein interactions (PPIs). In this surface plasmon resonance-based biosensor study we have found that physiologically relevant concentrations of isatin (25-100 μM) increase affinity of interactions between human recombinant ferrochelatase (FECH) and NADPH-dependent adrenodoxin reductase (ADR). In the presence of increasing concentrations of isatin the Kd values demonstrated a significant (up to 6-fold) decrease. It is especially important that the interaction of isatin with each individual protein (FECH, ADR) was basically negligible and therefore could not contribute to the observed effect. This effect was specific only for the FECH/ADR complex formation and was not observed for other protein complexes studied: FECH/cytochrome b5(CYB5A) and FECH/SMAD4.

Mining and Quantifying In Vivo Molecular Interactions in Abiotic Stress Acclimation.

Stress acclimation is initialized by sensing the stressor, transducing the signal, and inducing the response. In particular, the signal transduction is driven by protein-protein interactions and the response might involve de novo complex formation, shifts in subcellular localization and, thus, transportation that is mediated by other proteins. The investigation of protein-protein interactions and their regulation upon abiotic stress is crucial for a deeper understanding of the underlying mechanisms. FRET measurements by sensitized emission allow for the analysis of protein-protein interactions in real time and have a high potential to provide new insights into the regulation of protein-protein interaction with respect to subcellular localization and time. Within this section protocols are provided which allow for FRET analysis on the single cell level, the image acquisition procedure is described in detail and ImageJ plugins are suggested for the data evaluation.

Autophosphorylation of Specific Threonine and Tyrosine Residues in Arabidopsis CERK1 is Essential for the Activation of Chitin-Induced Immune Signaling.

Pattern recognition receptors on the plant cell surface mediate the recognition of microbe/damage-associated molecular patterns (MAMPs/DAMPs) and activate downstream immune signaling. Autophosphorylation of signaling receptor-like kinases is a critical event for the activation of downstream responses but the function of each phosphorylation site in the regulation of immune signaling is not well understood. In this study, 41 Ser/Thr/Tyr and 15 Ser/Thr residues were identified as in vitro and in vivo autophosphorylation sites of Arabidopsis CERK1, which is essential for chitin signaling. Comprehensive analysis of transgenic plants expressing mutated CERK1 genes for each phosphorylation site in the cerk1-2 background indicated that the phosphorylation of T479 in the activation segment and Y428 located upstream of the catalytic loop is important for the activation of chitin-triggered defense responses. Contribution of the phosphorylation of T573 to the chitin responses was also suggested. In vitro evaluation of kinase activities of mutated kinase domains indicated that the phosphorylation of T479 and T573 is directly involved in the regulation of kinase activity of CERK1 but the phosphorylation of Y428 regulates chitin signaling independently of the regulation of kinase activity. These results indicated that the phosphorylation of specific residues in the kinase domain contributes to the regulation of downstream signaling either through the regulation of kinase activity or the different mechanisms, e.g. regulation of protein-protein interactions.

Quantitative LC-MS/MS Glycomic Analysis of Biological Samples Using AminoxyTMT.

Protein glycosylation plays an important role in various biological processes, such as modification of protein function, regulation of protein-protein interactions, and control of turnover rates of proteins. Moreover, glycans have been considered as potential biomarkers for many mammalian diseases and development of aberrant glycosylation profiles is an important indicator of the pathology of a disease or cancer. Hence, quantitation is an important aspect of a comprehensive glycomics study. Although numerous MS-based quantitation strategies have been developed in the past several decades, some issues affecting sensitivity and accuracy of quantitation still exist, and the development of more effective quantitation strategies is still required. Aminoxy tandem mass tag (aminoxyTMT) reagents are recently commercialized isobaric tags which enable relative quantitation of up to six different glycan samples simultaneously. In this study, liquid chromatography and mass spectrometry conditions have been optimized to achieve reliable LC-MS/MS quantitative glycomic analysis using aminoxyTMT reagents. Samples were resuspended in 0.2 M sodium chloride solution to promote the formation of sodium adduct precursor ions, which leads to higher MS/MS reporter ion yields. This method was first evaluated with glycans from model glycoproteins and pooled human blood serum samples. The observed variation of reporter ion ratios was generally less than 10% relative to the theoretical ratio. Even for the highly complex minor N-glycans, the variation was still below 15%. This strategy was further applied to the glycomic profiling of N-glycans released from blood serum samples of patients with different esophageal diseases. Our results demonstrate the benefits of utilizing aminoxyTMT reagents for reliable quantitation of biological glycomic samples.

Glyceraldehyde-3-phosphate dehydrogenase: Aggregation mechanisms and impact on amyloid neurodegenerative diseases

The review analyses data on specific features of aggregation of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and possible role of this enzyme in the development of neurodegenerative diseases. Different post-translational modifications of the enzyme are considered: oxidation, nitrosylation, and S-glutathionylation of the active site sulfhydryl groups, as well as phosphorylation, glycation and homocysteinylation of other amino acid residues. Modification of the sulfhydryl groups of the enzyme inhibits the enzymatic activity of GAPDH, resulting in slowdown of glycolysis, and may lead to the dissociation of the cofactor NAD from the active site of the enzyme. The resulting apo-GAPDH (without NAD) is less stable and prone to dissociation, denaturation, and subsequent aggregation. These processes could play a crucial role in the translocation of GAPDH subunits from the cytoplasm into the nucleus, which is linked to the induction of apoptosis. Phosphorylation and glycation of GAPDH are presumably involved in the regulation of protein-protein interactions and intracellular localization of the enzyme. Besides, glycation by dicarbonyl compounds and aldehydes may directly inhibit glycolysis. Homocysteinylation of GAPDH may stabilize aggregates of the enzyme by additional disulfide bonding. All types of post-translational modifications affect aggregation of GAPDH. A special attention is given to the role of chaperones in the amyloidogenic transformation of proteins and to confirmation of the hypothesis on blocking of the chaperones by misfolded protein forms. The denatured GAPDH forms were shown to interact directly with amyloidogenic proteins (alpha-synuclein and amyloid-beta peptide) and to play a crucial role in blocking of chaperone system.

The N Terminus of Pro-endothelial Monocyte-activating Polypeptide II (EMAP II) Regulates Its Binding with the C Terminus, Arginyl-tRNA Synthetase, and Neurofilament Light Protein

Pro-endothelial monocyte-activating polypeptide II (EMAP II), one component of the multi-aminoacyl tRNA synthetase complex, plays multiple roles in physiological and pathological processes of protein translation, signal transduction, immunity, lung development, and tumor growth. Recent studies have determined that pro-EMAP II has an essential role in maintaining axon integrity in central and peripheral neural systems where deletion of the C terminus of pro-EMAP II has been reported in a consanguineous Israeli Bedouin kindred suffering from Pelizaeus-Merzbacher-like disease. We hypothesized that the N terminus of pro-EMAP II has an important role in the regulation of protein-protein interactions. Using a GFP reporter system, we defined a putative leucine zipper in the N terminus of human pro-EMAP II protein (amino acid residues 1-70) that can form specific strip-like punctate structures. Through GFP punctum analysis, we uncovered that the pro-EMAP II C terminus (amino acids 147-312) can repress GFP punctum formation. Pulldown assays confirmed that the binding between the pro-EMAP II N terminus and its C terminus is mediated by a putative leucine zipper. Furthermore, the pro-EMAP II 1-70 amino acid region was identified as the binding partner of arginyl-tRNA synthetase, a polypeptide of the multi-aminoacyl tRNA synthetase complex. We also determined that the punctate GFP pro-EMAP II 1-70 amino acid aggregate colocalizes and binds to the neurofilament light subunit protein that is associated with pathologic neurofilament network disorganization and degeneration of motor neurons. These findings indicate the structure and binding interaction of pro-EMAP II protein and suggest a role of this protein in pathological neurodegenerative diseases.

Quantitative in vivo fluorescence cross-correlation analyses highlight the importance of competitive effects in the regulation of protein-protein interactions.

Computer-assisted simulation is a promising approach for clarifying complicated signaling networks. However, this approach is currently limited by a deficiency of kinetic parameters determined in living cells. To overcome this problem, we applied fluorescence cross-correlation spectrometry (FCCS) to measure dissociation constant (Kd) values of signaling molecule complexes in living cells (in vivo Kd). Among the pairs of fluorescent molecules tested, that of monomerized enhanced green fluorescent protein (mEGFP) and HaloTag-tetramethylrhodamine was most suitable for the measurement of in vivo Kd by FCCS. Using this pair, we determined 22 in vivo Kd values of signaling molecule complexes comprising the epidermal growth factor receptor (EGFR)-Ras-extracellular signal-regulated kinase (ERK) mitogen-activated protein (MAP) kinase pathway. With these parameters, we developed a kinetic simulation model of the EGFR-Ras-ERK MAP kinase pathway and uncovered a potential role played by stoichiometry in Shc binding to EGFR during the peak activations of Ras, MEK, and ERK. Intriguingly, most of the in vivo Kd values determined in this study were higher than the in vitro Kd values reported previously, suggesting the significance of competitive bindings inside cells. These in vivo Kd values will provide a sound basis for the quantitative understanding of signal transduction.

The use of immobilized ubiquitin for biosensor analysis of the mitochondrial subinteractome

Protein ubiquitination is considered as an important mechanism that is responsible not only for specific labeling of proteins for their subsequent degradation but also for localization of proteins in the cell and regulation of protein-protein interactions. In the context of protein-protein interactions binding of (mono/poly)ubiquitinated molecules to proteins containing specific ubiquitin binding domains appear to play the decisive role. Although formation of the ubiquitin interactome has been demonstrated for cytosol, involvement of mitochondria and associated extramitochondrial proteins into such interactions still requires detailed investigation. In this study using an optical biosensor we have demonstrated binding of proteins of mouse brain mitochondrial lysates to immobilized monomeric ubiquitin. Model purified proteins, which are known to be associated with the outer mitochondrial compartment (glyceraldehyde-3-phosphate dehydorgenase, creatine phosphokinase), interacted with immobilized ubiquitin as well as with each other. This suggests that (poly)ubiquitinated chains may be involved in protein-protein interactions between ubiquitinated and non-ubiquitinated proteins and thus may contribute to formation of (mitochondrial) ubiquitin subinteractome.

Development of a Fluorescence Polarization Based High-Throughput Assay to Identify Casitas B-Lineage Lymphoma RING Domain Regulators

The E3 ubiquitin protein ligase Casitas B-lineage Lymphoma (Cbl) proteins and their binding partners play an important role in regulating signal transduction pathways. It is important to utilize regulators to study the protein-protein interactions (PPIs) between these proteins. However, finding specific small-molecule regulators of PPIs remains a significant challenge due to the fact that the interfaces involved in PPIs are not well suited for effective small molecule binding. We report the development of a competitive, homogeneous, high-throughput fluorescence polarization (FP) assay to identify small molecule regulators of Cbl (RING) domain. The FP assay was used to measure binding affinities and inhibition constants of UbCH7 peptides and small molecule regulators of Cbl (RING) domains, respectively. In order to rule out promiscuous, aggregation-based inhibition, two assay conditions were developed and compared side by side. Under optimized conditions, we screened a 10,000 natural compound library in detergent-free and detergent-present (0.01% Triton X-100) systems. The results indicate that the detergent-present system is more suitable for high-throughput screens. Three potential compounds, methylprotodioscin, leonuride and catalpol, have been identified that bind to Cbl (RING) domain and interfere with the Cbl (RING)-UbCH7 protein-protein interaction.