Establishment and characterization of mouse lines useful for endogenous protein degradation via an improved auxin-inducible degron system (AID2).

The development of new technologies opens new avenues in the research field. Gene knockout is a key method for analyzing gene function in mice. Currently, conditional gene knockout strategies are employed to examine temporal and spatial gene function. However, phenotypes are sometimes not observed because of the time required for depletion due to the long half-life of the target proteins. Protein knockdown using an improved auxin-inducible degron system, AID2, overcomes such difficulties owing to rapid and efficient target depletion. We observed depletion of AID-tagged proteins within a few to several hours by a simple intraperitoneal injection of the auxin analog, 5-Ph-IAA, which is much shorter than the time required for target depletion using conditional gene knockout. Importantly, the loss of protein is reversible, making protein knockdown useful to measure the effects of transient loss of protein function. Here, we also established several mouse lines useful for AID2-medicated protein knockdown, which include knock-in mouse lines in the ROSA26 locus; one expresses TIR1(F74G), and the other is the reporter expressing AID-mCherry. We also established a germ-cell-specific TIR1 line and confirmed the protein knockdown specificity. In addition, we introduced an AID tag to an endogenous protein, DCP2 via the CAS9-mediated gene editing method. We confirmed that the protein was effectively eliminated by TIR1(F74G), which resulted in the similar phenotype observed in knockout mouse within 20 h.

Antibody-Mediated Protein Knockdown Reveals Distal-less Functions for Eyespots and Parafocal Elements in Butterfly Wing Color Pattern Development.

One of the important genes for eyespot development in butterfly wings is Distal-less. Its function has been evaluated via several methods, including CRISPR/Cas9 genome editing. However, functional inhibition may be performed at the right time at the right place using a different method. Here, we used a novel protein delivery method for pupal wing tissues in vivo to inactivate a target protein, Distal-less, with a polyclonal anti-Distal-less antibody using the blue pansy butterfly Junonia orithya. We first demonstrated that various antibodies including the anti-Distal-less antibody were delivered to wing epithelial cells in vivo in this species. Treatment with the anti-Distal-less antibody reduced eyespot size, confirming the positive role of Distal-less in eyespot development. The treatment eliminated or deformed a parafocal element, suggesting a positive role of Distal-less in the development of the parafocal element. This result also suggested the integrity of an eyespot and its corresponding parafocal element as the border symmetry system. Taken together, these findings demonstrate that the antibody-mediated protein knockdown method is a useful tool for functional assays of proteins, such as Distal-less, expressed in pupal wing tissues, and that Distal-less functions for eyespots and parafocal elements in butterfly wing color pattern development.

In Silico Design, Synthesis, and Evaluation of PROTAC Against Hematopoietic Prostaglandin D Synthase.

Chemical protein knockdown technology using proteolysis-targeting chimeras (PROTACs) to hijack the endogenous ubiquitin-proteasome system is a powerful strategy to degrade disease-related proteins. This chapter describes in silico design of a hematopoietic prostaglandin D synthase (H-PGDS) degrader, PROTAC(H-PGDS), using a docking simulation of the ternary complex of H-PGDS/PROTAC/E3 ligase as well as the synthesis of the designed PROTAC(H-PGDS)s and evaluation of their H-PGDS degradation activity.

Kaposi's sarcoma-associated herpesvirus (KSHV) LANA prevents KSHV episomes from degradation.

Protein knockdown with an inducible degradation system is a powerful tool for studying proteins of interest in living cells. Here, we adopted the auxin-inducible degron (AID) approach to detail Kaposi's sarcoma-associated herpesvirus (KSHV) latency-associated nuclear antigen (LANA) function in latency maintenance and inducible viral lytic gene expression. We fused the mini-auxin-inducible degron (mAID) tag at the LANA N-terminus with KSHV bacterial artificial chromosome 16 recombination, and iSLK cells were stably infected with the recombinant KSHV encoding mAID-LANA. Incubation with 5-phenyl-indole-3-acetic acid, a derivative of natural auxin, rapidly degraded LANA within 1.5 h. In contrast to our hypothesis, depletion of LANA alone did not trigger lytic reactivation but rather decreased inducible lytic gene expression when we stimulated reactivation with a combination of ORF50 protein expression and sodium butyrate. Decreased overall lytic gene induction seemed to be associated with a rapid loss of KSHV genomes in the absence of LANA. The rapid loss of viral genomic DNA was blocked by a lysosomal inhibitor, chloroquine. Furthermore, siRNA-mediated knockdown of cellular innate immune proteins, cyclic AMP-GMP synthase (cGAS) and simulator of interferon genes (STING), and other autophagy-related genes rescued the degradation of viral genomic DNA upon LANA depletion. Reduction of the viral genome was not observed in 293FT cells that lack the expression of cGAS. These results suggest that LANA actively prevents viral genomic DNA from sensing by cGAS-STING signaling axis, adding novel insights into the role of LANA in latent genome maintenance.IMPORTANCESensing of pathogens' components is a fundamental cellular immune response. Pathogens have therefore evolved strategies to evade such cellular immune responses. KSHV LANA is a multifunctional protein and plays an essential role in maintaining the latent infection by tethering viral genomic DNA to the host chromosome. We adopted the inducible protein knockdown approach and found that depletion of LANA induced rapid degradation of viral genomic DNA, which is mediated by innate immune DNA sensors and autophagy pathway. These observations suggest that LANA may play a role in hiding KSHV episome from innate immune DNA sensors. Our study thus provides new insights into the role of LANA in latency maintenance.

Recent advancements in targeted protein knockdown technologies-emerging paradigms for targeted therapy.

A generalized therapeutic strategy for various disease conditions, including cancer, is to deplete or inactivate harmful protein targets. Various forms of protein or gene silencing molecules, e.g., small molecule inhibitors, RNA interference (RNAi), and microRNAs (miRNAs) have been used against druggable targets. Over the past few years, targeted protein degradation (TPD) approaches have been developed for direct degradation of candidate proteins. Among the TPD approaches, proteolysis targeting chimeras (PROTACs) have emerged as one of the most promising approaches for the selective elimination of proteins via the ubiquitin-proteasome system. Other than PROTACs, TPD methods with potential therapeutic use include intrabody-mediated protein knockdown and tripartite motif-21 (TRIM-21) mediated TRIM-Away. In this review, protein knockdown approaches, their modes of action, and their advantages over conventional gene knockdown approaches are summarized. In cancers, disease-associated protein functions are often executed by specific post-translational modifications (PTMs). The role of TRIM-Away is highlighted in the direct knockdown of PTM forms of target proteins. Moreover, the application challenges and the prospective clinical use of TPD approaches in various diseases are also discussed.

P-body dynamics revealed by DDX6 protein knockdown via the auxin-inducible degron system.

The transcriptome dynamically changes via several transcriptional and post-transcriptional mechanisms. RNA-binding proteins contribute to such mechanisms to regulate the cellular status. DDX6 is one such protein and a core component of processing bodies (P-bodies), membrane-less cytosolic substructures where RNA and proteins localize and are functionally regulated. Despite the importance of DDX6, owing to the lack of tightly controlled methods for protein knockdown, it was difficult to assess in high time resolution how its depletion exactly affects the P-body assembly structure. Therefore, we adopted an advanced protein degradation method, the auxin-induced degron (AID) system, to degrade DDX6 acutely in ES cells. By introducing AID-tagged DDX6 and the E3 ligase subunit of OsTIR1 into ES cells, we successfully degraded DDX6 following auxin analog (indole-3-acetic acid, IAA) treatment. The degradation rate of DDX6 was slower than that of the cytosolic reporter protein EGFP but was enhanced by increasing the OsTIR1 dosage. Lastly, we confirmed that a substantial portion of P-bodies disappears around the time of 1 hr after IAA addition consistent with DDX6 depletion detected by western blot. In accordance with this, we detected transcriptome changes by 6 hr after IAA treatment. Therefore, we demonstrated the applicability of the AID method to gain insight into the function of P-bodies and their protein components.

Direct knockdown of phospho-PTM targets mediated by TRIM21 can improve personalized treatment in breast cancer.

PURPOSE: In this work for the first time, we showed specific and direct knockdown of important oncogenic proteins of interest and their phospho-PTM targets in tripartite motif containing-21 (TRIM21) overexpressing breast cancer (BC) cells. We revealed the functional and therapeutic consequences of this protein knockdown approach called 'TRIM-ing'. METHODS: To target HER2, HER3, STAT3 or their activated forms, electroporation and puls-in transfection were standardized for mAb delivery in AU565 and MCF7 BC cell lines. Cancer cells were treated with HER2-targeted medicines (Trastuzumab and Neratinib) or STAT3 targeted inhibitors (Stattic and Niclosamide) with or without respective target TRIM-ing. Real-time PCR, immunoblotting, immunofluorescence, cytotoxicity, short- and long-term cell survival assessments were done following standard methodologies. 3-D structure modelling was used to verify the binding of mAb onto the STAT3 target. RESULTS: TRIM-ing of HER2 or HER3 receptors or their activated phospho-forms in BC cells showed rapid degradation of respective protein forms, shattering down the downstream signaling (p-ERK, p-AKT) that lasts for up to 7-8 days. This significantly inhibited BC survival (p < 0.001), showing a synergistic therapeutic effect with HER2 medicine trastuzumab or neratinib. Additionally, specific TRIM-ing ability of canonical pY705 or non-canonical pS727 PTMs of STAT3 protein was demonstrated in MCF7 cells, causing significant cytotoxicity (p < 0.05). TRIM-ing of STAT3 PTM, when combined with the same PTM-specific inhibitors, a synergistic treatment effect was observed. CONCLUSION: The work demonstrated that TRIM-ing could directly reduce various oncogenic targets or their specific activated form inside the cancer cells without compensatory pathway activation, a conundrum limiting the therapeutic benefit of current personalized medicines.

Acute Protein Depletion Strategies to Functionally Dissect the 3D Genome.

The organization of the genome inside the nucleus facilitates many nuclear processes. Because the nuclear genome is highly dynamic and often regulated by essential proteins, rapid depletion strategies are necessary to perform loss-of-function analyses. Fortunately, in recent years, various methods have been developed to manipulate the cellular levels of a protein directly and acutely. Here, we describe different methods that have been developed to rapidly deplete proteins from cells, with a focus on auxin inducible degron and dTAG methods, as these are most commonly used in 3D genome organization studies. We outline best practices for designing a knockin strategy, as well as generation and validation of knockin cell lines. Acute depletion strategies have been transformative for the study of the 3D genome and will be important tools for delineating the processes and factors that determine organization of the genome inside the nucleus.

In vivo Protein Interference: Oral Administration of Recombinant Yeast-Mediated Partial Leptin Reduction for Obesity Control.

Obesity-related diseases are always the major health problems that concern the whole world. Serial studies have reported that obesity development is closely related to the out-of-control leptin encoded by the obesity gene (ob). The latest report declaimed "Less Is More," a model explaining that partial leptin reduction triggers leptin sensitization and contributes to obesity control. Here, we came up with a novel concept, in vivo protein interference (iPRTi), an interesting protein knock-down strategy for in vivo partial leptin reduction. First, the specific immune response against leptin induced by the oral administration of ob recombinant yeast was confirmed. Subsequentally, leptin resistance was observed in diet-induced obese mice, and oral administration with ob recombinant yeast declined the circulating leptin and reduced significantly the body weight gain. To further investigate whether the iPRTi strategy is capable of obesity management, the diet-induced obese mice were administrated with ob recombinant yeast. All the indexes examined including the circulating leptin, triglyceride, and total cholesterol, as well as food intake and weight gain, demonstrated a positive effect of the iPRTi strategy on obesity control. In short, this study provides a novel strategy for the potential application of recombinant yeast for the therapy of obese individuals with leptin resistance.

Molecular Design, Synthesis, and Evaluation of SNIPER (ER) that Induces Targeted Protein Degradation of ERα.

Manipulation of protein stability using small molecules has a great potential for both basic research and clinical therapy. Based on our protein knockdown technology, we developed chimeric degrader molecules SNIPER(ER)s that target the estrogen receptor alpha (ERα) for degradation via the ubiquitin-proteasome system. This chapter describes the design and synthesis of SNIPER(ER) compounds and methods for the evaluation of their activity in cellular systems and in a tumor xenograft model.

The auxin-inducible degron 2 (AID2) system enables controlled protein knockdown during embryogenesis and development in Caenorhabditis elegans.

Targeted protein degradation using the auxin-inducible degron (AID) system is garnering attention in the research field of Caenorhabditis elegans, because of the rapid and efficient target depletion it affords, which can be controlled by treating the animals with the phytohormone auxin. However, the current AID system has drawbacks, i.e., leaky degradation in the absence of auxin and the requirement for high auxin doses. Furthermore, it is challenging to deplete degron-fused proteins in embryos because of their eggshell, which blocks auxin permeability. Here, we apply an improved AID2 system utilizing AtTIR1(F79G) and 5-phenyl-indole-3-acetic acid (5-Ph-IAA) to C. elegans and demonstrated that it confers better degradation control vs the previous system by suppressing leaky degradation and inducing sharp degradation using 1,300-fold lower 5-Ph-IAA doses. We successfully degraded the endogenous histone H2A.Z protein fused to an mAID degron and disclosed its requirement in larval growth and reproduction, regardless of the presence of maternally inherited H2A.Z molecules. Moreover, we developed an eggshell-permeable 5-Ph-IAA analog, 5-Ph-IAA-AM, that affords an enhanced degradation in laid embryos. Our improved system will contribute to the disclosure of the roles of proteins in C. elegans, in particular those that are involved in embryogenesis and development, through temporally controlled protein degradation.

Peptide Stapling Improves the Sustainability of a Peptide-Based Chimeric Molecule That Induces Targeted Protein Degradation.

Peptide-based target protein degradation inducers called PROTACs/SNIPERs have low cell penetrability and poor intracellular stability as drawbacks. These shortcomings can be overcome by easily modifying these peptides by conjugation with cell penetrating peptides and side-chain stapling. In this study, we succeeded in developing the stapled peptide stPERML-R7, which is based on the estrogen receptor alpha (ERα)-binding peptide PERML and composed of natural amino acids. stPERML-R7, which includes a hepta-arginine motif and a hydrocarbon stapling moiety, showed increased α-helicity and similar binding affinity toward ERα when compared with those of the parent peptide PERML. Furthermore, we used stPERML-R7 to develop a peptide-based degrader LCL-stPERML-R7 targeting ERα by conjugating stPERML-R7 with a small molecule LCL161 (LCL) that recruits the E3 ligase IAPs to induce proteasomal degradation via ubiquitylation. The chimeric peptide LCL-stPERML-R7 induced sustained degradation of ERα and potently inhibited ERα-mediated transcription more effectively than the unstapled chimera LCL-PERML-R7. These results suggest that a stapled structure is effective in maintaining the intracellular activity of peptide-based degraders.

In vivo synthetic chemistry of proteolysis targeting chimeras (PROTACs).

Chemical knockdown of therapeutic targets using proteolysis targeting chimeras (PROTACs) is a rapidly developing field in drug discovery, but PROTACs are bifunctional molecules that generally show poor bioavailability due to their relatively high molecular weight. Recent developments aimed at the development of next-generation PROTACs include the in vivo synthesis of PROTAC molecules, and the exploitation of PROTACs as chemical tools for in vivo synthesis of ubiquitinated proteins. This short review covers recent advances in these areas and discusses the prospects for in vivo synthetic PROTAC technology.

Design, Synthesis, and Biological Evaluation of Lysine Demethylase 5†C Degraders.

Lysine demethylase 5 C (KDM5C) controls epigenetic gene expression and is attracting great interest in the field of chemical epigenetics. KDM5C has emerged as a therapeutic target for anti-prostate cancer agents, and recently we identified triazole 1 as an inhibitor of KDM5C. Compound 1 exhibited highly potent KDM5C-inhibitory activity in in vitro enzyme assays, but did not show strong anticancer effects. Therefore, a different approach is needed for the development of anticancer agents targeting KDM5C. Here, we attempted to identify KDM5C degraders by focusing on a protein-knockdown strategy. Compound 3 b, which was designed based on compound 1, degraded KDM5C and inhibited the growth of prostate cancer PC-3 cells more strongly than compound 1. These findings suggest that KDM5C degraders are more effective as anticancer agents than compounds that only inhibit the catalytic activity of KDM5C.

[Development of Biological Response Modifiers Based on Unique Medicinal Chemical Strategy].

Chemical biology and structural development studies performed at The University of Tokyo during 1977-2020 are outlined chronologically. The studies are divided into three parts, i.e., (i) chemical biology of chemical carcinogenesis and molecular design of anti-tumor agents, (ii) structural development studies on biological response modifiers, and (iii) studies on so-called dramatype drug discovery focusing on pharmacological chaperones and protein knockdown-inducers. The first part describes analysis of DNA modification by Glu-P-1, which is a typical carcinogenic heterocyclic amine found in cooked foods, as well as molecular design of DNA-cleaving agents with anti-tumor properties. The second part deals with structural development studies of nuclear receptor ligands and various biological response modifiers derived from thalidomide, including the ligand superfamily concept and the multi-template strategy. The third part describes pharmacological chaperones that should be useful for the treatment of protein misfolding diseases, including Niemann-Pick type C disease and retinitis pigmentosa, and a protein knockdown strategy aimed at degradation of neurodegenerative-disease-causing polyglutamic aggregative proteins.

Redesigned TetR-Aptamer System To Control Gene Expression in Plasmodium falciparum.

One of the most powerful approaches to understanding gene function involves turning genes on and off at will and measuring the impact at the cellular or organismal level. This particularly applies to the cohort of essential genes where traditional gene knockouts are inviable. In Plasmodium falciparum, conditional control of gene expression has been achieved by using multicomponent systems in which individual modules interact with each other to regulate DNA recombination, transcription, or posttranscriptional processes. The recently devised TetR-DOZI aptamer system relies on the ligand-regulatable interaction of a protein module with synthetic RNA aptamers to control the translation of a target gene. This technique has been successfully employed to study essential genes in P. falciparum and involves the insertion of several aptamer copies into the 3' untranslated regions (UTRs), which provide control over mRNA fate. However, aptamer repeats are prone to recombination and one or more copies can be lost from the system, resulting in a loss of control over target gene expression. We rectified this issue by redesigning the aptamer array to minimize recombination while preserving the control elements. As proof of concept, we compared the original and modified arrays for their ability to knock down the levels of a putative essential apicoplast protein (PF3D7_0815700) and demonstrated that the modified array is highly stable and efficient. This redesign will enhance the utility of a tool that is quickly becoming a favored strategy for genetic studies in P. falciparumIMPORTANCE Malaria elimination efforts have been repeatedly hindered by the evolution and spread of multidrug-resistant strains of Plasmodium falciparum The absence of a commercially available vaccine emphasizes the need for a better understanding of Plasmodium biology in order to further translational research. This has been partly facilitated by targeted gene deletion strategies for the functional analysis of parasite genes. However, genes that are essential for parasite replication in erythrocytes are refractory to such methods, and require conditional knockdown or knockout approaches to dissect their function. One such approach is the TetR-DOZI system that employs multiple synthetic aptamers in the untranslated regions of target genes to control their expression in a tetracycline-dependent manner. Maintaining modified parasites with intact aptamer copies has been challenging since these repeats can be lost by recombination. By interspacing the aptamers with unique sequences, we created a stable genetic system that remains effective at controlling target gene expression.

Identification of probe-quality degraders for Poly(ADP-ribose) polymerase-1 (PARP-1).

Poly(ADP-ribose) polymerase-1 (PARP-1), a critical DNA repair enzyme in the base excision repair pathway, has been pursued as an attractive cancer therapeutic target. Intervention with PARP-1 has been proved to be more sensitive to cancer cells carrying BRCA1/2 mutations. Several PARP-1 inhibitors have been available on market for the treatment of breast, ovarian and prostatic cancer. Promisingly, the newly developed proteolysis targeting chimaeras (PROTACs) may provide a more potential strategy based on the degradation of PARP-1. Here we report the design, synthesis, and evaluation of a proteolysis targeting chimaera (PROTAC) based on the combination of PARP-1 inhibitor olaparib and the CRBN (cereblon) ligand lenalidomide. In SW620 cells, our probe-quality degrader compound 2 effectively induced PARP-1 degradation which results in anti-proliferation, cells apoptosis, cell cycle arresting, and cancer cells migratory inhibition. Thus, our findings qualify a new chemical probe for PARP-1 knockdown.

Design and synthesis of peptide-based chimeric molecules to induce degradation of the estrogen and androgen receptors.

Peptide-based inducers of estrogen receptor (ER) α and androgen receptor (AR) degradations via the ubiquitin-proteasome system (UPS) were developed. The designated inducers were composed of two biologically active scaffolds: the helical peptide PERM3, which is an LXXLL-like mimic of the coactivator SRC-1, and various small molecules (MV1, LCL161, VH032, and POM) that bind to E3 ligases (IAPs, VHL, and cereblon, respectively), to induce ubiquitylation of nuclear receptors that bind to SRC-1. All of the synthesized chimeric E3 ligand-containing molecules induced the UPS-mediated degradation of ERα and AR. The PERM3 peptide was applicable for the development of the ERα and AR degraders using these E3 ligands.

Drug Discovery Researches on Modulators of Lysine-Modifying Enzymes Based on Strategic Chemistry Approaches.

Enzymatic and post-translational modifications (PTMs) such as ubiquitination, acetylation, and methylation occur at lysine residues. The PTMs play critical roles in the regulation of the protein functions, and thus, various cellular processes. In addition, aberrations of the PTMs are associated with various diseases, such as cancer and neurodegenerative disorders. Therefore, we hypothesized that modulation of the PTMs and normalization of the PTM abnormalities could be useful as methods to control various cellular mechanisms and as a therapeutic strategy, respectively. To modulate the PTMs, we have focused on lysine-modifying enzymes and have pursued drug discovery researches on ubiquitination inducers, lysine deacetylase (KDAC) inhibitors, and lysine demethylase (KDM) inhibitors. For the identification of the modulators, we have used not only conventional drug design, such as structure-based drug design (SBDD) and ligand-based drug design (LBDD), but also "strategic chemistry approaches," such as drug design based on enzyme catalytic mechanism. As a result, we have identified several modulators which have pharmacological effects in animal models or in cellular studies. In this review, focusing on the drug design based on enzyme catalytic mechanism, our drug discovery researches have been discussed.

Application of protein knockdown strategy targeting ß-sheet structure to multiple disease-associated polyglutamine proteins.

Polyglutamine diseases are a class of neurodegenerative diseases associated with the accumulation of aggregated mutant proteins. We previously developed a class of degradation-inducing agents targeting the ß-sheet-rich structure typical of such aggregates, and we showed that these agents dose-, time-, and proteasome-dependently decrease the intracellular level of mutant huntingtin with an extended polyglutamine tract, which correlates well with the severity of Huntington's disease. Here, we demonstrate that the same agents also deplete other polyglutamine disease-related proteins: mutant ataxin-3 and ataxin-7 in cells from spino-cerebellar ataxia patients, and mutant atrophin-1 in cells from dentatorubral-pallidoluysian atrophy patients. Targeting cross-ß-sheet structure could be an effective design strategy to develop therapeutic agents for multiple neurodegenerative diseases.