TBK1 Inhibitor Research Articles

TBK1 Reprograms Metabolism in Breast Cancer: An Integrated Omics Approach.

Metabolic rewiring is required for cancer cells to survive in harsh microenvironments and is considered to be a hallmark of cancer. Specific metabolic adaptations are required for a tumor to become invasive and metastatic. Cell division and metabolism are inherently interconnected, and several cell cycle modulators directly regulate metabolism. Here, we report that TBK1, which is a noncanonical IKK kinase with known roles in cell cycle regulation and TLR signaling, affects cellular metabolism in cancer cells. While TBK1 is reported to be overexpressed in several cancers and its enhanced protein level correlates with poor prognosis, the underlying molecular mechanism involved in the tumor-promoting role of TBK1 is not fully understood. In this study, we show a novel role of TBK1 in regulating cancer cell metabolism using combined metabolomics, transcriptomics, and pharmacological approaches. We find that TBK1 mediates the regulation of nucleotide and energy metabolism through aldo-keto reductase B10 (AKRB10) and thymidine phosphorylase (TYMP) genes, suggesting that this TBK1-mediated metabolic rewiring contributes to its oncogenic function. In addition, we find that TBK1 inhibitors can act synergistically with AKRB10 and TYMP inhibitors to reduce cell viability. These findings raise the possibility that combining these inhibitors might be beneficial in combating cancers that show elevated levels of TBK1.

In Silico Insights: QSAR Modeling of TBK1 Kinase Inhibitors for Enhanced Drug Discovery.

TBK1, or TANK-binding kinase 1, is an enzyme that functions as a serine/threonine protein kinase. It plays a crucial role in various cellular processes, including the innate immune response to viruses, cell proliferation, apoptosis, autophagy, and antitumor immunity. Dysregulation of TBK1 activity can lead to autoimmune diseases, neurodegenerative disorders, and cancer. Due to its central role in these critical pathways, TBK1 is a significant focus of research for therapeutic drug development. In this paper, we explore data from the CAS Content Collection regarding TBK1 and its implication in a large assortment of diseases and disorders. With the demand for developing efficient TBK1 inhibitors being outlined, we focus on utilizing a machine learning approach for developing predictive models for TBK1 inhibition, derived from the fragment-functional analysis descriptors. Using the extensive CAS Content Collection, we assembled a training set of TBK1 inhibitors with experimentally measured IC50 values. We explored several machine learning techniques combined with various molecular descriptors to derive and select the best TBK1 inhibitor QSAR models. Certain significant structural alerts that potentially contribute to inhibition of TBK1 are outlined and discussed. The merit of the article stems from identifying the most adequate TBK1 QSAR models and subsequent successful development of advanced positive training data to facilitate and enhance drug discovery for an important therapeutic target such as TBK1 inhibitors, based on an extensive, wide-ranging set of scientific information provided by the CAS Content Collection.

Amlexanox targeted inhibition of TBK1 regulates immune cell function to exacerbate DSS-induced inflammatory bowel disease.

Amlexanox (ALX) is a small molecule drug for the treatment of inflammatory, autoimmune, metabolic and tumor diseases. At present, there are no studies on whether ALX has a therapeutic effect on inflammatory bowel disease (IBD). In this study, we used a mouse model of dextran sulfate sodium (DSS)-induced colitis to investigate the effect of ALX targeted inhibition of TBK1 on colitis. We found that the severity of colitis in mice was correlated with TBK1 expression. Notably, although ALX inhibited the activation of the TBK1-NF-κB/TBK1-IRF3 pro-inflammatory signaling pathway, it exacerbated colitis and reduced survival in mice. The results of drug safety experiments ruled out a relationship between this exacerbating effect and drug toxicity. In addition, ELISA results showed that ALX promoted the secretion of IL-1β and IFN-α, and inhibited the production of cytokines IL-6, TNF-α, IL-10, TGF-β and secretory IgA. Flow cytometry results further showed that ALX promoted T cell proliferation, activation and differentiation, and thus played a pro-inflammatory role; Also, ALX inhibited the generation of dendritic cells and the polarization of macrophages to M1 type, thus exerting anti-inflammatory effect. These data suggest that the regulation of ALX on the function of different immune cells is different, so the effect on the inflammatory response is bidirectional. In conclusion, our study demonstrates that simply inhibiting TBK1 in all immune cells is not effective for the treatment of colitis. Further investigation the anti-inflammatory mechanism of ALX on dendritic cells and macrophages may provide a new strategy for the treatment of IBD.

TBK1 pharmacological inhibition mitigates osteoarthritis through attenuating inflammation and cellular senescence in chondrocytes

ObjectivesTANK-binding kinase 1 (TBK1) is pivotal in autoimmune and inflammatory diseases, yet its role in osteoarthritis (OA) remains elusive. This study sought to elucidate the effect of the TBK1 inhibitor BX795 on OA and to delineate the underlying mechanism by which it mitigates OA. MethodsInterleukin-1 Beta (IL-1β) was utilized to simulate inflammatory responses and extracellular matrix degradation in vitro. In vivo, OA was induced in 8-week-old mice through destabilization of the medial meniscus surgery. The impact of BX795 on OA was evaluated using histological analysis, X-ray, micro-CT, and the von Frey test. Additionally, Western blot, RT-qPCR, and immunofluorescence assays were conducted to investigate the underlying mechanisms of BX795. ResultsPhosphorylated TBK1 (P-TBK1) levels were found to be elevated in OA knee cartilage of both human and mice. Furthermore, intra-articular injection of BX795 ameliorated cartilage degeneration and alleviated OA-associated pain. BX795 also counteracted the suppression of anabolic processes and the augmentation of catabolic activity, inflammation, and senescence observed in the OA mice. In vitro studies revealed that BX795 reduced P-TBK1 levels and reversed the effects of anabolism inhibition, catabolism promotion, and senescence induction triggered by IL-1β. Mechanistically, BX795 inhibited the IL-1β-induced activation of the cGAS–STING and TLR3–TRIF signaling pathways in chondrocytes. ConclusionsPharmacological inhibition of TBK1 with BX795 protects articular cartilage by inhibiting the activation of the cGAS–STING and TLR3–TRIF signaling pathways. This action attenuates inflammatory responses and cellular senescence, positioning BX795 as a promising therapeutic candidate for OA treatment. The translational potential of this articleThis study furnishes experimental evidence and offers a potential mechanistic explanation supporting the efficacy of BX795 as a promising candidate for OA treatment.

Duck STING mediates antiviral autophagy directing the interferon signaling pathway to inhibit duck plague virus infection

Migratory birds are important vectors for virus transmission, how migratory birds recognize viruses and viruses are sustained in birds is still enigmatic. As an animal model for waterfowl among migratory birds, studying and dissecting the antiviral immunity and viral evasion in duck cells may pave a path to deciphering these puzzles. Here, we studied the mechanism of antiviral autophagy mediated by duck STING in DEF cells. The results collaborated that duck STING could significantly enhance LC3B-II/I turnover, LC3B-EGFP puncta formation, and mCherry/EGFP ratio, indicating that duck STING could induce autophagy. The autophagy induced by duck STING is not affected by shRNA knockdown of ATG5 expression, deletion of the C-terminal tail of STING, or TBK1 inhibitor BX795 treatment, indicating that duck STING activated non-classical selective autophagy is independent of interaction with TBK1, TBK1 phosphorylation, and interferon (IFN) signaling. The STING R235A mutant and Sar1A/B kinase mutant abolished duck STING induced autophagy, suggesting binding with cGAMP and COPII complex mediated transport are the critical prerequisite. Duck STING interacted with LC3B through LIR motifs to induce autophagy, the LIR 4/7 motif mutants of duck STING abolished the interaction with LC3B, and neither activated autophagy nor IFN expression, indicating that duck STING associates with LC3B directed autophagy and dictated innate immunity activation. Finally, we found that duck STING mediated autophagy significantly inhibited duck plague virus (DPV) infection via ubiquitously degraded viral proteins. Our study may shed light on one scenario about the control and evasion of diseases transmitted by migratory birds.

Inhibition of Usp14 ameliorates renal ischemia-reperfusion injury by reducing Tfap2a stabilization and facilitating mitophagy

Mitochondrial dysfunction is recognized as a pivotal contributor to the pathogenesis of renal ischemia-reperfusion (IR) injury. Mitophagy, the process responsible for removing damaged protein aggregates, stands as a critical mechanism safeguarding cells against IR injury. Currently, the role of deubiquitination in regulating mitophagy still needs to be completely elucidated. This study aimed to evaluate the impact of ubiquitin-specific peptidase 14 (Usp14), a deubiquitinase, in IR injury by influencing mitophagy. Utilizing a murine model of renal IR injury, Usp14 silencing was found to ameliorate kidney injury, leading to decreased levels of serum creatinine and blood urea nitrogen, alongside diminished oxidative stress and inflammation. In renal epithelial cells subjected to hypoxia/reoxygenation (H/R), Usp14 knockdown increased cell viability and reduced apoptosis. Further mechanistic studies revealed that Usp14 interacted with and deubiquitinated transcription factor AP-2 alpha (Tfap2a), thereby suppressing its downstream target gene, TANK binding kinase 1 (Tbk1), to influence mitophagy. Tfap2a overexpression or Tbk1 inhibition reversed the protective effects of Usp14 silencing on renal tubular cell injury and its facilitation of mitophagy. In summary, our study demonstrated the renoprotective role of Usp14 knockdown in mitigating renal IR injury by promoting Tfap2a-mediated Tbk1 upregulation and mitophagy. These findings advocate for exploring Usp14 inhibition as a promising therapeutic avenue for mitigating IR injury, primarily by enhancing the clearance of damaged mitochondria through augmented mitophagy.

Abstract 4616: TBK1 and GSK3 mediated TRAF2 phosphorylation confers resistance to PI3K-AKT inhibition in breast cancer cells

Abstract Breast cancer (BC) is the most frequently diagnosed malignancy and the second leading cause of cancer mortality in Western women. As is the case for most other solid tumors, metastasis and drug resistance are the main causes of death. In ~80% of BC cases, the PI3K-AKT pathway is aberrantly activated, due to the alterations in genes encoding the pathway components, such as Ras, Her2, PTEN, PIK3C and AKT. Consequently, over 100 clinical trials are currently underway worldwide to evaluate the therapeutic efficacy of PI3K and AKT inhibitors in BC; however, initial data revealed that inhibition of this pathway is either not effective or often results in development of resistance and relapse of the disease. Thus, identification of additional targets and therapeutic combinations are urgently needed. We previously reported that TBK1-mediated TRAF2 Ser-11 phosphorylation enhances NF-κB activation to promote cancer cell survival under conditions of cellular stresses. Recently, we discovered that GSK3β directly phosphorylates TRAF2 at Thr-7 upon Ser-11 phosphorylation by TBK1, and that phosphorylation of both Thr-7 and Ser-11 is essential for sustained NF-κB activation and BC cell resistance to PI3K-AKT inhibition. TBK1 and its close homologue IKKε are overexpressed in ~70% of BC and play critical roles in BC cell survival. GSK3β is a constitutively active kinase activity in unstimulated normal cells, but its activity is suppressed in most cancer cell types by AKT-mediated phosphorylation. These published reports and our new findings suggest that inhibition of AKT in BC cells leads to increased phosphorylation of TRAF2 by TBK1 and GSK3β, which confers resistance to PI3K-ATK inhibition. Bioinformatic analyses revealed that TRAF2 and GSK3β are also overexpressed in invasive BC, and significantly correlate with poor prognosis. As expected, inhibition of both AKT and TBK1 or GSK3b synergistically induced apoptosis in BC cell lines in vitro and significantly suppressed xenograft BC tumor growth in vivo. Thus, our data suggest that further investigation of the efficacies of combined PI3K/AKT and TBK1/GSK3β inhibition in PDX models of BC has the potential to develop new strategies for BC treatment. Citation Format: Hasem Habelhah, Laiqun Zhang. TBK1 and GSK3 mediated TRAF2 phosphorylation confers resistance to PI3K-AKT inhibition in breast cancer cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 4616.

Identification of TBK1 inhibitors against breast cancer using a computational approach supported by machine learning.

Introduction: The cytosolic Ser/Thr kinase TBK1 is of utmost importance in facilitating signals that facilitate tumor migration and growth. TBK1-related signaling plays important role in tumor progression, and there is need to work on new methods and workflows to identify new molecules for potential treatments for TBK1-affecting oncologies such as breast cancer. Methods: Here, we propose the machine learning assisted computational drug discovery approach to identify TBK1 inhibitors. Through our computational ML-integrated approach, we identified four novel inhibitors that could be used as new hit molecules for TBK1 inhibition. Results and Discussion: All these four molecules displayed solvent based free energy values of -48.78, -47.56, -46.78 and -45.47Kcal/mol and glide docking score of -10.4, -9.84, -10.03, -10.06Kcal/mol respectively. The molecules displayed highly stable RMSD plots, hydrogen bond patterns and MMPBSA score close to or higher than BX795 molecule. In future, all these compounds can be further refined or validated by in vitro as well as in vivo activity. Also, we have found two novel groups that have the potential to be utilized in a fragment-based design strategy for the discovery and development of novel inhibitors targeting TBK1. Our method for identifying small molecule inhibitors can be used to make fundamental advances in drug design methods for the TBK1 protein which will further help to reduce breast cancer incidence.

TBK1, a prioritized drug repurposing target for amyotrophic lateral sclerosis: evidence from druggable genome Mendelian randomization and pharmacological verification in vitro

BackgroundThere is a lack of effective therapeutic strategies for amyotrophic lateral sclerosis (ALS); therefore, drug repurposing might provide a rapid approach to meet the urgent need for treatment.MethodsTo identify therapeutic targets associated with ALS, we conducted Mendelian randomization (MR) analysis and colocalization analysis using cis-eQTL of druggable gene and ALS GWAS data collections to determine annotated druggable gene targets that exhibited significant associations with ALS. By subsequent repurposing drug discovery coupled with inclusion criteria selection, we identified several drug candidates corresponding to their druggable gene targets that have been genetically validated. The pharmacological assays were then conducted to further assess the efficacy of genetics-supported repurposed drugs for potential ALS therapy in various cellular models.ResultsThrough MR analysis, we identified potential ALS druggable genes in the blood, including TBK1 [OR 1.30, 95%CI (1.19, 1.42)], TNFSF12 [OR 1.36, 95%CI (1.19, 1.56)], GPX3 [OR 1.28, 95%CI (1.15, 1.43)], TNFSF13 [OR 0.45, 95%CI (0.32, 0.64)], and CD68 [OR 0.38, 95%CI (0.24, 0.58)]. Additionally, we identified potential ALS druggable genes in the brain, including RESP18 [OR 1.11, 95%CI (1.07, 1.16)], GPX3 [OR 0.57, 95%CI (0.48, 0.68)], GDF9 [OR 0.77, 95%CI (0.67, 0.88)], and PTPRN [OR 0.17, 95%CI (0.08, 0.34)]. Among them, TBK1, TNFSF12, RESP18, and GPX3 were confirmed in further colocalization analysis. We identified five drugs with repurposing opportunities targeting TBK1, TNFSF12, and GPX3, namely fostamatinib (R788), amlexanox (AMX), BIIB-023, RG-7212, and glutathione as potential repurposing drugs. R788 and AMX were prioritized due to their genetic supports, safety profiles, and cost-effectiveness evaluation. Further pharmacological analysis revealed that R788 and AMX mitigated neuroinflammation in ALS cell models characterized by overly active cGAS/STING signaling that was induced by MSA-2 or ALS-related toxic proteins (TDP-43 and SOD1), through the inhibition of TBK1 phosphorylation.ConclusionsOur MR analyses provided genetic evidence supporting TBK1, TNFSF12, RESP18, and GPX3 as druggable genes for ALS treatment. Among the drug candidates targeting the above genes with repurposing opportunities, FDA-approved drug-R788 and AMX served as effective TBK1 inhibitors. The subsequent pharmacological studies validated the potential of R788 and AMX for treating specific ALS subtypes through the inhibition of TBK1 phosphorylation.

Prediction of synergistic gemcitabine-based combination treatment through a novel tumor stemness biomarker NANOG in pancreatic cancer.

Gemcitabine remains a first-class chemotherapeutic drug for pancreatic cancer. However, due to the rapid development of gemcitabine resistance in pancreatic cancer, gemcitabine alone or in combination with other anti-cancer drugs only showed limited effect in the clinic. It is extremely challenging to effectively and efficiently determine the optimal drug regimens. Thus, identification of appropriate prediction biomarkers is critical for the rational design of gemcitabine-based therapeutic options. Herein, a pancreatic cancer stem cell (PCSC) model exhibiting chemoresistance to gemcitabine was used to test the activity of clinical cancer drugs in the presence or absence of gemcitabine. As determined by combinatorial treatment, several types of drugs resensitized gemcitabine-resistant PCSCs to gemcitabine, with sorafenib (EGFR inhibitor)/gemcitabine and sunitinib (TBK1 inhibitors)/gemcitabine drug combinations being the most preferred treatments for PCSCs. Following the validation of the PCSC model by an antibody array test of 15-gene expression of stemness biomarkers, NANOG showed markedly different expression in PCSCs compared to the parental cells. From comprehensive analysis of stem cell index versus combination index, a stemness-related correlation model was successfully constructed to demonstrate the correlation between NANOG expression and synergism. Cancer cell stemness was ascertained to be highly relevant to NANOG overexpression that can be abrogated by synergized gemcitabine-drug combinations. Therefore, NANOG works as a therapeutic biomarker for predicating efficient combinatorial treatment of gemcitabine in pancreatic cancer.

Inactivation of the DNA-sensing pathway facilitates oncolytic herpes simplex virus inhibition of pancreatic ductal adenocarcinoma growth

Oncolytic viruses are a new class of therapeutic agents for the treatment of cancer that have shown promising results in clinical trials. Oncolytic virus-mediated tumor rejection is highly dependent on viral replication in tumor cells to induce cell death. However, the antiviral immune response of tumor cells limits the replication capacity of oncolytic viruses. We hypothesized that inhibition of the antiviral immune response in infected cells would enhance the antitumor effect. Here, we confirmed that ablation of the key adaptor protein of cellular immunity, STING, significantly suppressed the antiviral immune response and promoted oncolytic herpes simplex virus-1 (oHSV1) proliferation in tumor cells. In a murine pancreatic ductal adenocarcinoma (PDAC) model, oHSV1 enhanced tumor suppression and prolonged the survival of mice in the absence of STING. On this basis, we further found that the TBK1 inhibitor can also significantly enhance the tumor-control ability of oHSV1. Our studies provide a novel strategy for oncolytic virus therapy by inhibiting the intrinsic antiviral response in solid tumors to improve antitumor efficacy.

Abstract IA004: Identification of potential new therapeutic targets in kidney cancer

Abstract VHL is the most important tumor suppressor in clear cell renal cell carcinoma (ccRCC). In the majority of ccRCC, as a result of VHL loss, HIF2a stabilization is sufficient and necessary for promoting ccRCC tumor growth. Despite the development of HIF2a specific inhibitors, the intrinsic and extrinsic resistance do exist, highlighting the importance of identifying additional therapeutic vulnerabilities in ccRCC. We have recently performed some genome-wide screening and identified new signaling pathways regulated by VHL, including ZHX2 and SFMBT1 that play important roles in ccRCC. In addition, we also identified some synthetic lethality binding partners for VHL loss in kidney cancer, including TBK1. However, it is challenging to target TBK1 in clinical practice due to lack of selectivity for TBK1 inhibitors and its role involved in innate immune signaling. To overcome this difficulty, one approach would be to identify a critical upstream regulator of TBK1 that can be targeted therapeutically, especially in ccRCC displaying hyper-activated TBK1 activity due to VHL loss. We have performed a kinome-wide screening and identified Doublecortin like kinase 2 (DCLK2), an enigmatic kinase involved in neuronal survival and growth cone regeneration upon injury, as a novel TBK1 regulator in ccRCC. Our functional assays demonstrate that DCLK2 is necessary and sufficient to promote ccRCC tumorigenesis through activating TBK1. In addition, we also characterized a DCLK2 short isoform (DCLK2203) that play a predominant role in ccRCC tumorigenesis. Our work suggests that DCLK2 is a novel TBK1 activator and potential therapeutic target in ccRCC. Citation Format: Qing Zhang. Identification of potential new therapeutic targets in kidney cancer [abstract]. In: Proceedings of the AACR Special Conference: Advances in Kidney Cancer Research; 2023 Jun 24-27; Austin, Texas. Philadelphia (PA): AACR; Cancer Res 2023;83(16 Suppl):Abstract nr IA004.

Abstract A003: Kinome-wide siRNA screening identifies DCLK2 as a TBK1 activator and therapeutic target for ccRCC

Abstract TBK1 has been identified as a potential therapeutic target in multiple cancers. However, it is challenging to target TBK1 in clinical practice due to lack of selectivity for TBK1 inhibitors and its role involved in innate immune signaling. To overcome this difficulty, one approach would be to identify a critical upstream regulator of TBK1 that can be targeted therapeutically, especially in clear cell Renal Cell Carcinoma (ccRCC) displaying hyper-activated TBK1 activity due to VHL loss. In this study, we perform a kinome-wide siRNA screening and identify Doublecortin like kinase 2 (DCLK2) as a novel TBK1 regulator in ccRCC. DCLK2 binds with TBK1 and directly phosphorylates TBK1 on Ser172. Depletion of DCLK2 inhibits anchorage independent colony growth of kidney cancer cells as well as kidney tumorigenesis in orthotopic xenograft models. DCLK2 gene product contains multiple isoforms. Among them, a short isoform called DCLK2203 expresses predominantly in ccRCC. Overexpression of DCLK2203 promotes ccRCC cell growth and tumorigenesis in vivo, which elicits its oncogenic signaling via activating TBK1 phosphorylation. Taken together, our work suggest that DCLK2 is a novel TBK1 activator and potential therapeutic target for ccRCC. Citation Format: Lianxin Hu, Qing Zhang. Kinome-wide siRNA screening identifies DCLK2 as a TBK1 activator and therapeutic target for ccRCC [abstract]. In: Proceedings of the AACR Special Conference: Advances in Kidney Cancer Research; 2023 Jun 24-27; Austin, Texas. Philadelphia (PA): AACR; Cancer Res 2023;83(16 Suppl):Abstract nr A003.

TRIM28 promotes the escape of gastric cancer cells from immune surveillance by increasing PD-L1 abundance

Immune checkpoint blockade (ICB) offers a new opportunity for treatment for gastric cancer (G.C.). Understanding the upstream regulation of immune checkpoints is crucial to further improve the efficacy of ICB therapy. Herein, using the CRISPR-Cas9-based genome-wide screening, we identified TRIM28 as one of the most significant regulators of PD-L1, a checkpoint protein, in G.C. cells. Mechanistically, TRIM28 directly binds to and stabilizes PD-L1 by inhibiting PD-L1 ubiquitination and promoting PD-L1 SUMOylation. Furthermore, TRIM28 facilitates K63 polyubiquitination of TBK1, activating TBK1-IRF1 and TBK1-mTOR pathways, resulting in enhanced PD-L1 transcription. It was found that TRIM28 was positively correlated with PD-L1 in G.C. cells. Moreover, high TRIM28 expression suggests poor survival in a cohort of 466 patients with G.C., and this observation is consistent while analyzing data from publicly available databases. Ectopic TRIM28 expression facilitated tumor growth, increased PD-L1 expression, and suppressed T cell activation in mice. Administration of the PD-L1 or TBK1 inhibitor significantly alleviated the TRIM28-induced tumor progression. Furthermore, combining the TBK1 inhibitor with CTLA4 immune checkpoint blockade has synergistic effects on G.C., and provides a novel strategy for G.C. therapy.

#4966 CELLULAR PRION PROTEIN ACTIVATES THE TBK1-IRF3 SIGNALING PATHWAY TO AGGRAVATE RENAL FIBROSIS

Abstract Background and Aims Chronic kidney disease (CKD) is an irreversible degenerative disease characterized by gradual loss of renal function, contributing to high morbidity and mortality as well as heavy economic cost to society. Clinically, there are few available strategies to slow CKD progression. Because the uremic phenotypes include many features of aging, CKD is considered as a premature aging syndrome. Neurodegenerative diseases, such as Alzheimer's disease, and Parkinson's disease are extensively studied aging-related diseases, in which cytotoxic proteins misfolding and aggregation in neural cells is the main characteristic. The misfolding and aggregation of the prion protein is tightly linked to the development of prion diseases. Interestingly, a remarkable elevation of cellular prion protein (PrPC) in the urine and plasma of CKD patients was reported. However, the role of PrPC in the pathogenesis of kidney diseases remains largely unknown. The aim of the current study is to investigate the role of PrPC in renal fibrosis. Methods Immunohistochemistry staining was conducted to evaluate the expression of PrPC in renal biopsies from CKD patients. Enzyme linked immunosorbent assay (ELISA) was performed to detect urinary PrPC of CKD patients. Animal model of renal fibrosis was induced by unilateral ureteral occlusion (UUO). Western blot, real time PCR and immunofluorescence staining were performed to evaluate the expression and distribution of PrPC. Proximal tubule specific Prnp knockout mice (PEPCK-Prnp-KO) was constructed to explore the pathogenic role of PrPC in renal fibrosis. Primary proximal tubular epithelial cells (PTCs) overexpressed PrPC were collected for RNA-seq analysis. TBK1 inhibitor amlexanox, and IRF3 siRNA were used to block TBK1-IRF3 pathway in rat tubular epithelial cells (NRK-52E), respectively. Amlexanox was administered orally to UUO mice. H&E, Masson and Sirius red staining were used to estimate renal pathology. Results The protein expression levels of PrPC both in renal biopsies and urine from CKD patients were elevated and significantly correlated with the severity of interstitial fibrosis and the decline of eGFR. PrPC proteins were significantly increased, and aggregated in proximal renal tubules in fibrotic renal tissues induced by UUO. Compared with wild-type littermates, PEPCK-Prnp-KO mice showed reduced extracellular matrix accumulation and interstitial inflammation at day 7 after UUO. PrPC provokes profibrotic response of renal tubular cells via the TBK1-IRF3 pathway. TBK1 inhibitor amlexanox or silencing endogenous IRF3 significantly inhibited PrPC-induced profibrogenic phenotypic transformation in NRK-52 cells. Amlexanox attenuated interstitial fibrosis induced by UUO. Conclusion Our experimental results indicate that PrPC-TBK1-IRF3 pathway plays a detrimental role in profibrogenic transformation of renal tubular cells and thus contributes to interstitial fibrosis. Blocking TBK1 activation is a plausible strategy for therapeutic intervention of chronic kidney disorders.

Abstract 3635: TBK1 inhibition potentiates the efficacy of AXL-targeted therapy by modulating tumor microenvironment in aggressive breast cancers

Abstract Introduction: Triple-negative and inflammatory breast cancer (TNBC and IBC) are the most aggressive breast cancer subtypes. Novel actionable targets and complementary therapies are critically needed. AXL, a receptor tyrosine kinase, drives pleiotropic phenotypes of TNBC and IBC aggressiveness. Targeting AXL reduces IBC tumor growth in vivo and inhibits polarization of M2 macrophages. To identify novel tumor microenvironment (TME) targets to enhance the efficacy of AXL-targeted therapy, we conducted a synthetic lethal kinome siRNA screening. We identified TBK1 as a candidate to synergize with AXL growth inhibition. TBK1 is a serine/threonine protein kinase that regulates innate, adaptive responses and antitumor immune responses. We hypothesized that inhibition of TBK1 enhances the antitumor effect of AXL-targeted therapy in aggressive breast cancers. Methods: We used knockdown, knockout (KO) and inhibitors to suppress AXL and TBK1 pathways and tested the synergistic effect of targeting AXL and TBK1 on the growth of human SUM149 and BCX010 IBC cells, and HS578T TNBC cells in vitro. To determine the synergistic effect of targeting both pathways in vivo, we inoculated control or TBK1 KO murine TNBC 4T1.2 cells into BALB/c mice. We assessed the activity of AXL inhibitor TP-0903 in reducing tumor growth. Using multicolor flow cytometry, we studied the effects of targeting AXL and TBK1 on the TME. We tested the activity of TP-0903 combined with a TBK1 inhibitor in another TNBC mouse model, E0771. We used RNA-sequencing and real-time PCR/Western blot to determine the molecular mechanisms of how TBK1 inhibition synergizes AXL-targeted therapy in these cancers. Results: Compared with AXL or TBK1 suppression alone, genomic or pharmacologic suppression of AXL and TBK1 significantly reduced the growth of SUM149, BCX010, and HST578T cells in vitro. In both 4T1.2 and E0771 syngeneic mouse models, TP-0903 was more active in reducing tumor growth in TBK1-inhibited tumors than in control tumors. Tumors with TBK1 inhibition and treated with TP-0903 had a significantly higher population of cytotoxic T cells than control tumors. Depletion of CD8+ T cells blocked the synergistic effect of targeting AXL and TBK1 pathways on reducing tumor growth, suggesting that cytotoxic T cells contributed to the anti-tumor synergy of targeting AXL and TBK1. Mechanistically, TBK1 induced M2 macrophage migration via IRF3-regulated CCL5 secretion in SUM149 and HS578T cells, and AXL KO attenuated the polarization and migration of M2 macrophages by inhibiting the CCR5/CCL5 axis. Conclusions: Targeting TBK1 enhances the efficacy of AXL-targeted therapy in aggressive breast cancer by suppressing the paracrine effect of CCR5/CCL5 axis. This combination represents a novel and effective therapy modulating the TME of aggressive breast cancer, which warrants further investigation in the clinical setting. Citation Format: Lan Phi, Takashi Semba, Ngu V. Trinh, Fang Zou, Jason M. Foulks, Steven L. Warner, Savitri Krishnamurthy, James P. Long, James M. Reuben, Debu Tripathy, Naoto T. Ueno, Xiaoping Wang. TBK1 inhibition potentiates the efficacy of AXL-targeted therapy by modulating tumor microenvironment in aggressive breast cancers. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 3635.

Abstract 5727: Identification of synthetic lethal vulnerabilities in cancers with loss of function mutations in NOTCH

Abstract Loss of Function (LOF) mutations in the NOTCH receptors are found in several different cancers most notably in small cell lung cancer (SCLC) and squamous cell carcinomas (SCC). We previously developed genetically engineered mouse models (GEMM) of SCLC using CRISPR/Cas9 engineered to be NOTCH1-Mutant, NOTCH2-Mutant, and NOTCH-WT. Synthetic lethality provides a paradigm for targeting cancers with LOF mutations in tumor suppressor genes. In applying this paradigm, one looks for specific vulnerabilities that are created upon loss of the gene of interest. Using 6 cell lines developed from these CRISPR-based SCLC GEMMs which are isogenic to NOTCH, we performed CRISPR/Cas9 LOF negative selection screens (using an sgRNA library enriched in druggable enzymes) to identify synthetic lethal interactors with LOF NOTCH mutations. Our CRISPR/Cas9 screen identified TRIM28 (Tripartite Motif Containing 28, or KAP1) as a highly significant synthetic lethal interactor with NOTCH1 or NOTCH2. We validated the synthetic lethal interaction between NOTCH1/2 and TRIM28 using both human and mouse NOTCH-isogenic cell lines. Interestingly, RNA-sequencing of NOTCH2-Mutant or NOTCH-WT SCLC cell lines after TRIM28 CRISPR inactivation showed robust increases in endogenous retroviral (ERV) expression and the MDA5/RIG-I/MAVS RNA-sensing machinery leading to hyperactivation of the TBK1/IRF3/7 innate immune signaling pathway and the pro-inflammatory cytokine CXCL10 selectively in cells with NOTCH inactivated. Notably, inactivation of TBK1 activity or JAK-STAT activity using specific small molecule inhibitors of TBK1 or JAK completely reversed the synthetic lethality between NOTCH and TRIM28 suggesting that the synthetic lethality phenotype is a consequence of hyperactivation of innate immune signaling, which is known to be cytotoxic. Together our findings uncover a novel vulnerability in SCLCs with LOF NOTCH mutations and perhaps other cancers with LOF NOTCH mutations and suggest a strategy that could also potentiate anti-tumor immunity by increasing innate immune signaling in tumor cells. Citation Format: Deli Hong, Matthew A. Booker, Sidrah Anjum, Yixiang Li, Tran C. Thai, Michelle Y. Wang, David A. Barbie, Michael Y. Tolstorukov, Jun Qi, Matthew G. Oser. Identification of synthetic lethal vulnerabilities in cancers with loss of function mutations in NOTCH. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5727.

Hypoxic postconditioning restores mitophagy against transient global cerebral ischemia via Parkin-induced posttranslational modification of TBK1

Hypoxic postconditioning (HPC) has been reported to enhance Parkin-catalyzed mitochondrial ubiquitination to restore mitophagy in hippocampal CA1 against transient global cerebral ischemia (tGCI). However, the molecular mechanism leading ubiquitinated mitochondria to final clearance during HPC-mediated mitophagy after tGCI is unclear. This study aims to investigate whether HPC restores mitophagy after tGCI through Parkin-induced K63-linked poly-ubiquitination (K63-Ub) to activate tumor necrosis factor associated factor family member associated nuclear factor κB activator -binding kinase 1 (TBK1) in CA1 of male rats. We found that HPC maintained TBK1 expression, promoted p62 and TBK1 phosphorylation in mitochondria, and enhanced their recruitments to mitochondria in CA1 after tGCI. However, these effects were partially abolished by TBK1 inhibitor BX795. K63-Ub of mitochondrial TBK1 was disturbed at 26 h of reperfusion after tGCI, which was reversed by HPC. The maintenance of K63-Ub of mitochondrial TBK1 induced by HPC was counteracted under Parkin knockdown with AAV-mediated Prkn small-interfering RNA, accompanied by the suppression on TBK1 activation and the reduction of mitochondrial p62 phosphorylation. This innovative study indicated that HPC maintained K63-Ub of TBK1 in a Parkin-dependent manner to promote TBK1 phosphorylation, and then phosphorylated TBK1 activated p62 to restore mitophagy, thereby alleviating neuronal damage in CA1 after tGCI.

Ginsenoside Rd promotes omentin secretion in adipose through TBK1-AMPK to improve mitochondrial biogenesis via WNT5A/Ca2+ pathways in heart failure

Ginsenoside Rd is an active ingredient in Panax ginseng CA Mey and can be absorbed into the adipose tissue. Adipokines play an important role in the treatment of cardiovascular diseases. However, the potential benefit of Rd on heart failure (HF) and the underlying mechanism associated with the crosstalk between adipocytes and cardiomyocytes remains to be illustrated. Here, the results identified that Rd improved cardiac function and inhibited cardiac pathological changes in transverse aortic constriction (TAC), coronary ligation (CAL) and isoproterenol (ISO)-induced HF mice. And Rd promoted the release of omentin from the adipose tissue and up-regulated omentin expression in lipopolysaccharide (LPS)-induced 3T3-L1 adipocytes. Further, Rd could increase TBK1 and AMPK phosphorylation in adipocytes. And also, the TBK1-AMPK signaling pathway regulated the expression of omentin in LPS-induced adipocytes. Moreover, the omentin mRNA expression was significantly decreased by TBK1 knockdown in LPS-induced 3T3-L1 adipocytes. Additionally, molecular docking and SPR analysis confirmed that Rd had a certain binding ability with TBK1, and co-treatment with TBK1 inhibitors or TBK1 knockdown partially abolished the effect of Rd on increasing the omentin expression and the ratio of p-AMPK to AMPK in adipocytes. Moreover, we found that circulating omentin level diminished in the HF patients compared with healthy subjects. Meanwhile, the adipose tissue-specific overexpression of omentin improved cardiac function, reduced myocardial infarct size and ameliorated cardiac pathological features in CAL-induced HF mice. Consistently, exogenous omentin reduced mtROS levels and restored ΔψM to improve oxygen and glucose deprivation (OGD)-induced cardiomyocytes injury. Further, omentin inhibited the WNT5A/Ca2+ signaling pathway and promoted mitochondrial biogenesis function to ameliorate myocardial ischemia injury. However, WNT5A knockdown inhibited the impairment of mitochondrial biogenesis and partially counteracted the cardioprotective effect of omentin in vitro. Therefore, this study indicated that Rd promoted omentin secretion from adipocytes through the TBK1-AMPK pathway to improve mitochondrial biogenesis function via WNT5A/Ca2+ signaling pathway to ameliorate myocardial ischemia injury, which provided a new therapeutic mechanism and potential drugs for the treatment of HF.

TBK1 inhibitors enhance transfection efficiency by suppressing p62/SQSTM1 phosphorylation.

DNA transfection is an essential technique in the life sciences. Non-viral transfection reagents are widely used for transfection in basic science. However, low transfection efficiency is a problem in some cell types. This low efficiency can be primarily attributed to the intracellular degradation of transfected DNA by p62-dependent selective autophagy, specifically by p62 phosphorylated at the S403 residue (p62-S403-P). To achieve efficient DNA transfection, we focused on a phosphorylation process that generates p62-S403-P and investigated whether inhibition of this process affects transfection efficiency. One of the kinases that phosphorylate p62 is TBK1. The TBK1 gene depletion in murine embryonic fibroblast cells by genome editing caused a significant reduction or loss of p62-S405-P (equivalent to human S403-P) and enhanced transfection efficiency, suggesting that TBK1 is a major kinase that phosphorylates p62 at S403. Therefore, TBK1 is a viable target for drug treatment to increase transfection efficiency. Transfection efficiency was enhanced when cells were treated with one of the following TBK1 inhibitors BX795, MRT67307, or amlexanox. This effect was synergistically improved when the two inhibitors were used in combination. Our results indicate that TBK1 inhibitors enhanced transfection efficiency by suppressing p62 phosphorylation.