Smad3 Knockout Research Articles

SARS-CoV-2 N Protein Induces Acute Kidney Injury via Smad3-Dependent G1 Cell Cycle Arrest Mechanism.

COVID‐19 is infected by severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) and can cause severe multiple organ injury and death. Kidney is one of major target organs of COVID‐19 and acute kidney injury (AKI) is common in critically ill COVID‐19 patients. However, mechanisms through which COVID‐19 causes AKI remain largely unknown and treatment remains unspecific and ineffective. Here, the authors report that normal kidney‐specifically overexpressing SARS‐CoV‐2 N develops AKI, which worsens in mice under ischemic condition. Mechanistically, it is uncovered that SARS‐CoV‐2 N‐induced AKI is Smad3‐dependent as SARS‐CoV‐2 N protein can interact with Smad3 and enhance TGF‐β/Smad3 signaling to cause tubular epithelial cell death and AKI via the G1 cell cycle arrest mechanism. This is further confirmed in Smad3 knockout mice and cells in which deletion of Smad3 protects against SARS‐CoV‐2 N protein‐induced cell death and AKI in vivo and in vitro. Most significantly, it is also found that targeting Smad3 with a Smad3 pharmacological inhibitor is able to inhibit SARS‐CoV‐2 N‐induced AKI. In conclusion, the authors identify that SARS‐CoV‐2 N protein is a key mediator for AKI and induces AKI via the Smad3‐dependent G1 cell cycle arrest mechanism. Targeting Smad3 may represent as a novel therapy for COVID‐19‐asscoaited AKI.

814 SMAD4 AS A POTENTIAL GATEKEEPER FOR GENOMIC INSTABILITY AND MTOR-MEDIATED TUMORIGENESIS IN ESOPHAGEAL ADENOCARCINOMA

Abstract Extensive genomic analysis of patient samples has identified genes whose mutation or loss map malignant progression from Barrett’s metaplasia, through low- (CDKN2A) and high-grade dysplasia (TP53), to invasive adenocarcinoma (SMAD4). Interestingly, loss of SMAD4 has been found to occur exclusively in the invasive disease stage, but the reason for this is unknown. This work aimed to characterise the role of SMAD4 in esophageal adenocarcinoma (EAC) tumorigenesis and identify novel therapeutic targets for SMAD4-deficient EAC. Methods We developed a novel in vivo tumorigenesis model that demonstrates progression of dysplastic Barrett’s esophagus (BE) to invasive EAC upon knockout of SMAD4. We conducted parallel genome-wide CRISPR-Cas9 knockout screens, both in vitro and in vivo, on a background of either wildtype-SMAD4 or SMAD4-knockout dysplastic BE cells to identify co-operative drivers of tumorigenesis in vivo, as well as synthetic lethal interactions to identify potential therapeutic targets in SMAD4-deficient EAC. Functional validation of hits was performed using cell-based assays and drugs targeting candidate molecular targets. Results We identified a synthetic lethal relationship between SMAD4-deficiency and cell cycle checkpoint inhibition, suggesting a role for SMAD4 in maintaining genomic stability and a potential novel therapeutic avenue for SMAD4-deficient EAC. A concurrent in vivo CRISPR-Cas9 tumorigenesis screen produced tumors 4-fold faster than loss of SMAD4 alone and identified regulators of mTOR signalling and SMAD4 as co-operative drivers of tumorigenesis in EAC. Interestingly, these tumorigenic cells exhibited an inherent dependency on specific translation mechanisms downstream of mTOR. Meanwhile, wildtype-SMAD4 BE cells failed to thrive in vivo with mTOR modifications alone, indicating a true co-operative effect at play with SMAD4 loss. Conclusion This study uncovered a potential gatekeeping role of SMAD4 in maintaining genomic stability and inhibiting mTOR-mediated EAC tumorigenesis. In sum, loss of SMAD4 was found to increase genomic instability, thereby rendering EAC cells sensitive to cell cycle checkpoint impediment, whilst simultaneously co-operating with modulated mTOR signalling to promote tumorigenesis in EAC xenograft models.

Abstract 2670: Dedifferentiation-induced oncogenic stemness in the intestinal epithelium: implications in tumorigenesis

Abstract In vivo mouse models support stem cells as the cell of origin for cancer in the intestine, while histological evidence from colon cancer patients indicates that dysplasia originates from the mature epithelium. The inherent plasticity of the intestinal epithelium makes both of these scenarios plausible. In the top-down model, tumorigenesis begins at the mucosal surface or villi that consists only of differentiated cells, while in the bottom-up model stem cells in the proliferative crypt compartment initiate the tumor. However, the implications of the differences between the bottom-up and the top-down model on carcinogenesis, if any, are unknown. Consistent with the paradigm of intestinal epithelial plasticity allowing cell fate adaptation, my previous studies have reported dedifferentiation of the villi cells leading to tumorigenic stemness in the Smad4 knockout:β-catenin gain-of-function (Smad4KO:β-cateninGOF) conditional mutant mice. Dedifferentiation in this mutant is marked by the appearance of stem cell markers in the mutant villi, followed by development of structures resembling the proliferative crypts, referred to as ectopic crypts, that eventually develop into tumors; thus mimicking the top-down model of tumorigenesis. Our goal is to understand the implications of tumorigenesis from dedifferentiation as opposed to that from the endogenous crypts. To this end, we analyzed the progressive changes in the mutant intestinal epithelium over time before and after the appearance of ectopic crypts in the villi. We find that dedifferentiation is preceded by an increase in hypoxia - specifically in the villi only. The increase in hypoxia, however, is transient and is not observed in the ectopic crypts or the ensuing tumors, suggesting that certain hypoxia-induced changes that promote tumorigenesis persist even in the absence of hypoxia. Most strikingly, we find that the mutation activates notch signaling in the villi even before the formation ectopic crypts develop. Notch signaling is fundamental to cell fate decision and stem cell function in the intestinal epithelium, but is restricted to the crypts in a normal intestine; thus implicating Notch signaling in the oncogenic stemness in the Smad4KO:β-cateninGOF mutant villi. Since Notch signaling has context-specific functions and is positively regulated by hypoxia, we examined differential effects of the ectopic Notch signaling on tumorigenesis. When compared to the endogenous crypts, we find increased expression of the possible markers of tumor aggressiveness, as well as attenuated negative feed-back regulation of Wnt signaling in the ectopic crypts. We are investigating the underlying mechanism and implications of these findings in tumor progression, employing both in vivo and ex vivo approaches using crypt and villi-derived organoids from the Smad4KO:β-cateninGOF mutant mice. Citation Format: Ansu O. Perekatt, Kylee Wrath, Dahlia Matouba, Christina Li, jeel shah, Connor Mills, Kyle Seabold. Dedifferentiation-induced oncogenic stemness in the intestinal epithelium: implications in tumorigenesis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 2670.

EcTracker: Tracking and elucidating ectopic expression leveraging large-scale scRNA-seq studies.

Dramatic genomic alterations, either inducible or in a pathological state, dismantle the core regulatory networks, leading to the activation of normally silent genes. Despite possessing immense therapeutic potential, accurate detection of these transcripts is an ever-challenging task, as it requires prior knowledge of the physiological gene expression levels. Here, we introduce EcTracker, an R-/Shiny-based single-cell data analysis web server that bestows a plethora of functionalities that collectively enable the quantitative and qualitative assessments of bona fide cell types or tissue-specific transcripts and, conversely, the ectopically expressed genes in the single-cell ribonucleic acid sequencing datasets. Moreover, it also allows regulon analysis to identify the key transcriptional factors regulating the user-selected gene signatures. To demonstrate the EcTracker functionality, we reanalyzed the CRISPR interference (CRISPRi) dataset of the human embryonic stem cells differentiated into endoderm lineage and identified the prominent enrichment of a specific gene signature in the SMAD2 knockout cells whose identity was ambiguous in the original study. The key distinguishing features of EcTracker lie within its processing speed, availability of multiple add-on modules, interactive graphical user interface and comprehensiveness. In summary, EcTracker provides an easy-to-perform, integrative and end-to-end single-cell data analysis platform that allows decoding of cellular identities, identification of ectopically expressed genes and their regulatory networks, and therefore, collectively imparts a novel dimension for analyzing single-cell datasets.

Smad7 attenuates TGF-β-mediated aging-related hypofunction of submandibular glands.

Submandibular glands have essential functions in taste, mastication, swallowing, and digestion. Submandibular gland hypofunction is prevalent in the elderly, impairing the patients' quality of life. Current clinical treatment strategies have not decelerated or reversed the pathological process of submandibular gland hypofunction. Therefore, novel restoration strategies should be explored. However, studies on the mechanism of aging-related submandibular gland hypofunction remain very limited. The role of the TGF-β/Smad pathway in fibrosis has been studied in other organs. Therefore, this study aimed to elucidate the role of TGF-β/Smad signaling in the aging-related submandibular gland hypofunction. The results showed that Smad7 knockout in mice decreased the salivary flow rate. H&E, Masson trichrome, and immunohistochemistry staining of MCP-1 and α-SMA showed that Smad7 knockout in mice resulted in lymphocytic infiltration, acinar cell atrophy, and interstitial fibrosis. The Western blotting of collagen I and III also confirmed extensive fibrosis. We then found that Smad7 depletion resulted in the TGF-β-mediated fibrosis via mir-21, mir-29, and np_5318, and NFκB-driven inflammation activation. This study confirmed the inhibitory role of Smad7 in the aging-related submandibular gland hypofunction. Therefore, it provided a promising treatment target for aging-related dysfunction and sialadenitis of submandibular gland.

Loss of SMAD4 Is Sufficient to Promote Tumorigenesis in a Model of Dysplastic Barrett's Esophagus.

Background & AimsEsophageal adenocarcinoma (EAC) develops from its precursor Barrett’s esophagus through intermediate stages of low- and high-grade dysplasia. However, knowledge of genetic drivers and molecular mechanisms implicated in disease progression is limited. Herein, we investigated the effect of Mothers against decapentaplegic homolog 4 (SMAD4) loss on transforming growth factor β (TGF-β) signaling functionality and in vivo tumorigenicity in high-grade dysplastic Barrett’s cells.MethodsAn in vivo xenograft model was used to test tumorigenicity of SMAD4 knockdown or knockout in CP-B high-grade dysplastic Barrett’s cells. RT2 polymerase chain reaction arrays were used to analyze TGF-β signaling functionality, and low-coverage whole-genome sequencing was performed to detect copy number alterations upon SMAD4 loss.ResultsWe found that SMAD4 knockout significantly alters the TGF-β pathway target gene expression profile. SMAD4 knockout positively regulates potential oncogenes such as CRYAB, ACTA2, and CDC6, whereas the CDKN2A/B tumor-suppressor locus was regulated negatively. We verified that SMAD4 in combination with CDC6-CDKN2A/B or CRYAB genetic alterations in patient tumors have significant predictive value for poor prognosis. Importantly, we investigated the effect of SMAD4 inactivation in Barrett’s tumorigenesis. We found that genetic knockdown or knockout of SMAD4 was sufficient to promote tumorigenesis in dysplastic Barrett’s esophagus cells in vivo. Progression to invasive EAC was accompanied by distinctive and consistent copy number alterations in SMAD4 knockdown or knockout xenografts.ConclusionsAltogether, up-regulation of oncogenes, down-regulation of tumor-suppressor genes, and chromosomal instability within the tumors after SMAD4 loss implicates SMAD4 as a protector of genome integrity in EAC development and progression. Foremost, SMAD4 loss promotes tumorigenesis from dysplastic Barrett’s toward EAC.

Smad3 deficiency promotes beta cell proliferation and function in db/db mice via restoring Pax6 expression.

Rationale: Transforming Growth Factor-beta (TGF-β) /Smad3 signaling has been shown to play important roles in fibrotic and inflammatory diseases, but its role in beta cell function and type 2 diabetes is unknown.Methods: The role of Smad3 in beta cell function under type 2 diabetes condition was investigated by genetically deleting Smad3 from db/db mice. Phenotypic changes of pancreatic islets and beta cell function were compared between Smad3 knockout db/db (Smad3KO-db/db) mice and Smad3 wild-type db/db (Smad3WT-db/db) mice, and other littermate controls. Islet-specific RNA-sequencing was performed to identify Smad3-dependent differentially expressed genes associated with type 2 diabetes. In vitro beta cell proliferation assay and insulin secretion assay were carried out to validate the mechanism by which Smad3 regulates beta cell proliferation and function.Results: The results showed that Smad3 deficiency completely protected against diabetes-associated beta cell loss and dysfunction in db/db mice. By islet-specific RNA-sequencing, we identified 8160 Smad3-dependent differentially expressed genes associated with type 2 diabetes, where Smad3 deficiency markedly prevented the down-regulation of those genes. Mechanistically, Smad3 deficiency preserved the expression of beta cell development mediator Pax6 in islet, thereby enhancing beta cell proliferation and function in db/db mice in vivo and in Min6 cells in vitro.Conclusions: Taken together, we discovered a pathogenic role of Smad3 in beta cell loss and dysfunction via targeting the protective Pax6. Thus, Smad3 may represent as a novel therapeutic target for type 2 diabetes prevention and treatment.

TGF-β-induced cell motility requires downregulation of ARHGAPs to sustain Rac1 activity

Transforming growth factor-β (TGF-β) signaling promotes cancer progression. In particular, the epithelial–mesenchymal transition (EMT) induced by TGF-β is considered crucial to the malignant phenotype of cancer cells. Here, we report that the EMT-associated cellular responses induced by TGF-β are mediated by distinct signaling pathways that diverge at Smad3. By expressing chimeric Smad1/Smad3 proteins in SMAD3 knockout A549 cells, we found that the β4 region in the Smad3 MH1 domain is essential for TGF-β-induced cell motility, but is not essential for other EMT-associated responses including epithelial marker downregulation. TGF-β was previously reported to enhance cell motility by activating Rac1 via phosphoinositide 3-kinase. Intriguingly, TGF-β-dependent signaling mediated by Smad3's β4 region causes the downregulation of multiple mRNAs that encode GTPase activating proteins that target Rac1 (ARHGAPs), thereby attenuating Rac1 inactivation. Therefore, two independent pathways downstream of TGF-β type I receptor contribute cooperatively to sustained Rac1 activation, thereby leading to enhanced cell motility.

Smad3-Targeted Therapy Protects against Cisplatin-Induced AKI by Attenuating Programmed Cell Death and Inflammation via a NOX4-Dependent Mechanism

Background: Transforming growth factor-β (TGF-β)/Smad signaling is the central mediator in renal fibrosis, yet its functional role in acute kidney injury (AKI) is not fully understood. Recent evidence showed that TGF-β/Smad3 may be involved in the pathogenesis of AKI, but its functional role and mechanism of action in cisplatin-induced AKI are unclear. Objectives: Demonstrating that Smad3 may play certain roles in cisplatin nephropathy due to its potential effect on programmed cell death and inflammation. Methods: Here, we established a cisplatin-induced AKI mouse model with Smad3 knockout mice and created stable in vitro models with Smad3 knockdown tubular epithelial cells. In addition, we tested the potential of Smad3-targeted therapy using 2 in vivo protocols – lentivirus-mediated Smad3 silencing in vivo and use of naringenin, a monomer used in traditional Chinese medicine and a natural inhibitor of Smad3. Results: Disruption of Smad3 attenuated cisplatin-induced kidney injury, inflammation, and NADPH oxidase 4-dependent oxidative stress. We found that Smad3-targeted therapy protected against loss of renal function and alleviated apoptosis, RIPK-mediated necroptosis, renal inflammation, and oxidative stress in cisplatin nephropathy. Conclusions: These findings show that Smad3 promotes cisplatin-induced AKI and Smad3-targeted therapy protects against this pathological process. These findings have substantial clinical relevance, as they suggest a therapeutic target for AKI.

Abstract 3054: Targeting TGF-β signaling for obesity/insulin resistance-associated hepatocellular carcinoma

Abstract Background: Recently, obesity, insulin resistance/type 2 diabetes mellitus and fatty liver disease, i.e., key components of the metabolic syndrome, have been recognized as risk factors for hepatocellular carcinoma (HCC). Obesity and dysmetabolism serve as drivers of oncogenesis in the setting of abnormal hepatic morphology and physiology, and hepatic steatosis may provide the promoting microenvironment for the development of HCC. Dysregulated signaling in the transforming growth factor (TGF)-β pathway plays a central role in immunomodulation, inflammation, and fibrogenesis in the HCC microenvironment. We used a carcinogen Diethylnitrosamine (DEN)-induced HCC mouse model in genetically obese mice [heterozygous Agouti yellow (Ay/a)] and haplo-knock out of Smad3 (a kinase downstream of type II receptor for TGFβ to study the detailed mechanism by which Smad3-dependent TGF-β signaling regulates obesity-associated dysmetabolism in HCC, and to determine whether inhibition of TGF-β signaling could inhibit obesity-associated HCC. Methods: Ay/a mice in C57B/L genetic background were bred with Smad3 knockout mouse (Smad3+/−). Obese and insulin-resistant Ay/a mice were treated with DEN (i.p. 25mg/kg) at 14 days of age to induce HCC. Ay/a mice and DEN-induce HCC mice were treated with TGF-β receptor 2 inhibitor (EW7919, 20 mg/kg orally 3 times/week for 8 weeks). We performed RNA sequencing analysis for 40 mouse liver samples from the groups of mice above. Results: 1. Haplodeficiency of Smad3 significantly decreased obesity Ay/a mouse weight and suppressed fatty liver development. 2. Treatment of TGF-β receptor 2 inhibitor to Ay mice successfully blocked weight gain in Ay/a mice. 3. DEN-induced hepatocarcinogenesis in Ay/a mice occurred significantly earlier than in lean (a/a) C57B/L mice. 4. Inhibition of TGF-β signaling by Smad3 haplodeficiency significantly upregulated lipid catabolic processes and downregulated cytokine-induce leukocyte migration in the fatty livers of Ay/a mice. 5. Inhibition of TGF-β signaling by genetic or pharmacologic inhibitors significantly suppressed HCC development in Ay/a mice. Conclusion: We demonstrated a specific cancer promoting role of TGF-β in metabolic reprogramming in liver cancer cells, highlighting the TGF-β signaling pathway as a potential therapeutic target in obesity/insulin resistance-associated HCC. Citation Format: Jian Chen, Xiaoping Su, Andres Rojas, Robert S Bresalier, John R. Stroehlein, Sai-ching Yeung. Targeting TGF-β signaling for obesity/insulin resistance-associated hepatocellular carcinoma [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 3054.

246-LB: Smad3 Deficiency Promotes Beta-Cell Proliferation by Augmenting Glucose-Stimulated UPR

Understanding the mechanism governing β cell proliferation is essential for the in vitro expansion of β cells and the replacement therapy for patients with diabetes. We recently found that deletion of Smad3, a downstream effector of TGF-β signaling, promoted β cell proliferation, while the underlying mechanisms remain elusive. It’s reported that high glucose stimulates β cell proliferation through unfold protein response (UPR). In this study, we tested the hypothesis that whether deficiency of Smad3 promotes β cell proliferation by regulating UPR. As a result, we found that knockout of Smad3 promoted β cell proliferation in diabetic db/db mice, but not in healthy db/m mice. Interestingly, islets from db/db mice of Smad3 knockout presented increased UPR compared with db/m mice of Smad3 knockout. In cultured islet cells, deletion of Smad3 increased β cell proliferation under high glucose (20mM) conditions, which was associated with up-regulated and non-decompensated UPR. Further studies showed that inhibition of UPR with an inhibitor 4-PBA abolished the pro-proliferative effect of Smad3 deficiency in β cells. In conclusion, Smad3 deficiency increases β cell proliferation by augmenting UPR. Therefore, targeting Smad3 may be an effective therapy for diabetes. Disclosure H. Wang: None. H. He: None. X. Huang: None. L. Wang: None. R.C. Ma: Advisory Panel; Self; AstraZeneca. Stock/Shareholder; Self; GemVCare. Other Relationship; Self; AstraZeneca, Bayer Healthcare Pharmaceuticals Inc., Merck & Co., Inc., Novo Nordisk A/S, Pfizer Inc., Sanofi-Aventis, Tricida Inc. H. Lan: None. Funding Research Grants Council of Hong Kong (C7018-16G, R4012-18); Health and Medical Research Fund of Hong Kong (14152321, 05161326, 06173986)

Novel Non-integrating DNA Nano-S/MAR Vectors Restore Gene Function in Isogenic Patient-Derived Pancreatic Tumor Models

We describe herein non-integrating minimally sized nano-S/MAR DNA vectors, which can be used to genetically modify dividing cells in place of integrating vectors. They represent a unique genetic tool, which avoids vector-mediated damage. Previous work has shown that DNA vectors comprising a mammalian S/MAR element can provide persistent mitotic stability over hundreds of cell divisions, resisting epigenetic silencing and thereby allowing sustained transgene expression. The composition of the original S/MAR vectors does present some inherent limitations that can provoke cellular toxicity. Herein, we present a new system, the nano-S/MAR, which drives higher transgene expression and has improved efficiency of establishment, due to the minimal impact on cellular processes and perturbation of the endogenous transcriptome. We show that these features enable the hitherto challenging genetic modification of patient-derived cells to stably restore the tumor suppressor gene SMAD4 to a patient-derived SMAD4 knockout pancreatic cancer line. Nano-S/MAR modification does not alter the molecular or phenotypic integrity of the patient-derived cells in cell culture and xenograft mouse models. In conclusion, we show that these DNA vectors can be used to persistently modify a range of cells, providing sustained transgene expression while avoiding the risks of insertional mutagenesis and other vector-mediated toxicity.

SMAD7 enhances adult β-cell proliferation without significantly affecting β-cell function in mice

The interplay between the transforming growth factor β (TGF-β) signaling proteins, SMAD family member 2 (SMAD2) and 3 (SMAD3), and the TGF-β-inhibiting SMAD, SMAD7, seems to play a vital role in proper pancreatic endocrine development and also in normal β-cell function in adult pancreatic islets. Here, we generated conditional SMAD7 knockout mice by crossing insulin1Cre mice with SMAD7fx/fx mice. We also created a β cell-specific SMAD7-overexpressing mouse line by crossing insulin1Dre mice with HPRT-SMAD7/RosaGFP mice. We analyzed β-cell function in adult islets when SMAD7 was either absent or overexpressed in β cells. Loss of SMAD7 in β cells inhibited proliferation, and SMAD7 overexpression enhanced cell proliferation. However, alterations in basic glucose homeostasis were not detectable following either SMAD7 deletion or overexpression in β cells. Our results show that both the absence and overexpression of SMAD7 affect TGF-β signaling and modulates β-cell proliferation but does not appear to alter β-cell function. Reversible SMAD7 overexpression may represent an attractive therapeutic option to enhance β-cell proliferation without negative effects on β-cell function.

Identification of primordial germ cell-like cells as liver metastasis initiating cells in mouse tumour models

Liver metastasis, characterized by the spread of tumors to the liver from other areas, represents a deadly disease with poor prognosis. Currently, there is no effective therapeutic strategies and/or agents to combat liver metastasis primarily due to the insufficient understanding of liver metastasis. To develop a promising strategy for targeting liver metastasis, understanding of a cell origin responsible for liver metastasis and how this cell can be pharmacologically eliminated are therefore crucial. Using diverse tumor models including p53−/− genetic mouse model and syngeneic tumor models, we identified primordial germ cell (PGC)-like tumor cells, which are enriched in earliest liver micro-metastasis (up to 99%), as a cell origin of liver metastasis. PGC-like tumor cells formed earliest micro-metastasis in liver and gradually differentiated into non-PGC-like tumor cells to constitute late macro-metastasis in the course of tumor metastasis. The liver metastasis-initiating cells (PGC-like tumor cells) display cell renewal and differentiation capabilities, resemble primordial germ cells (PGCs) in morphology and PGC marker gene expression, and express higher level of the genes linked to metastasis and immune escape compared with non-PGC-like tumor cells. Of note, Stellarhigh PGC-like tumor cells, but not Stellarlow non-PGC-like cells, sorted from primary tumors of p53−/− mice readily form liver metastasis. Depletion of PGC-like tumor cells through genetic depletion of any of key germ cell genes impairs liver metastasis, while increased PGC-like tumor cells by SMAD2 knockout is correlated with markedly enhanced liver metastasis. Finally, we present the proof of principle evidence that pharmacologically targeting BMP pathways serves as a promising strategy to eliminate PGC-like tumor cells leading to abrogating liver metastasis. Collectively, our study identifies PGC-like tumor cells as a cell origin of liver metastasis, whose depletion by genetically targeting core PGC developmental genes or pharmacologically inhibiting BMP pathways serves a promising strategy for targeting liver metastasis.

The role of Smad2 and Smad3 in regulating homeostatic functions of fibroblasts in vitro and in adult mice

The heart contains an abundant fibroblast population that may play a role in homeostasis, by maintaining the extracellular matrix (ECM) network, by regulating electrical impulse conduction, and by supporting survival and function of cardiomyocytes and vascular cells. Despite an explosion in our understanding of the role of fibroblasts in cardiac injury, the homeostatic functions of resident fibroblasts in adult hearts remain understudied. TGF-β-mediated signaling through the receptor-activated Smads, Smad2 and Smad3 critically regulates fibroblast function. We hypothesized that baseline expression of Smad2/3 in fibroblasts may play an important role in cardiac homeostasis. Smad2 and Smad3 were constitutively expressed in normal mouse hearts and in cardiac fibroblasts. In cultured cardiac fibroblasts, Smad2 and Smad3 played distinct roles in regulation of baseline ECM gene synthesis. Smad3 knockdown attenuated collagen I, collagen IV and fibronectin mRNA synthesis and reduced expression of the matricellular protein thrombospondin-1. Smad2 knockdown on the other hand attenuated expression of collagen V mRNA and reduced synthesis of fibronectin, periostin and versican. In vivo, inducible fibroblast-specific Smad2 knockout mice and fibroblast-specific Smad3 knockout mice had normal heart rate, preserved cardiac geometry, ventricular systolic and diastolic function, and normal myocardial structure. Fibroblast-specific Smad3, but not Smad2 loss modestly but significantly reduced collagen content. Our findings suggest that fibroblast-specific Smad3, but not Smad2, may play a role in regulation of baseline collagen synthesis in adult hearts. However, at least short term, these changes do not have any impact on homeostatic cardiac function.

The long noncoding RNA Ptprd-IR is a novel molecular target for TGF-β1-mediated nephritis.

The role of microRNAs (miRNAs) in chronic kidney disease (CKD) is relatively well established, but much less is known about the role(s) of long noncoding RNAs (lncRNAs). Transforming growth factor β1 (TGF-β1) mediates inflammatory and fibrogenic signaling in CKD via the transcription factor Smad3; however, the extent of lncRNAs-based regulation of TGF-β1 signaling in CKD remains unknown. Herein, we identified np_4334, a lncRNA we named Ptprd-IR, whose promoter contains a highly-conserved site for Smad3 binding. Smad3 knockout (KO) eliminated Ptprd-IR upregulation in a murine model of obstructive nephropathy. Furthermore, Ptprd-IR KO in renal tubular epithelial cell cultures blocked TGF-β1- and interleukin-1β (IL-1β)-mediated NF-κB inflammatory signaling but did not impact TGF-β1-triggered Smad3 pathway activity and fibrosis. Accordingly, Ptprd-IR overexpression (OE) upregulated TGF-β1- and IL-1β-mediated NF-κB pathway activation and production of pro-inflammatory cytokines but did not influence TGF-β1-mediated fibrogenic signaling. Additionally, transfection of obstructed kidneys with Ptprd-IR-directed shRNA attenuated the inflammatory response via NF-κB but did not impact TGF-β1/Smad3-mediated fibrogenesis. Overall, our findings demonstrate that the lncRNA Ptprd-IR stimulates the inflammatory response in kidneys and advocate Ptprd-IR as a possible therapeutic target for CKD.

Abstract A58: TGF-beta inhibition and checkpoint blockade in mouse models for gastrointestinal cancer

Abstract Background: Gastrointestinal tumors are generally not responsive to checkpoint blockade unless they are hypermutated. Smad4 and p53 are frequently mutated in human gastrointestinal cancer. Methods: We conducted the intestinal epithelium-specific knockout of Smad4 and Trp53. Transcriptomic profiles were evaluated for spontaneous tumors that formed in these genetically engineered mice. Results: TGF-beta signaling pathway genes were overexpressed in bulk tumors formed in Villin-Cre;Smad4(F/F);Trp53(F/F). Efficacy of anti-PD-1 (10mg/kg IP BIW) and small-molecule ALK5 inhibitor (25mg/kg PO) was tested in syngeneic mice harboring heterotopic allografts of a cell line that was primarily cultured from a Smad4-null tumor. ALK5 inhibitor did not affect the growth of Smad4-null allograft as a monotherapy, but significantly enhanced the antiproliferative effect of anti-PD-1 as a combination treatment. Conclusion: TGF-beta pathway inhibition may be a promising approach to increase the efficacy of checkpoint blockade in gastrointestinal tumors. (NCC grants 1910021/1810951.) Citation Format: Kye S. Cho, Hark K. Kim. TGF-beta inhibition and checkpoint blockade in mouse models for gastrointestinal cancer [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2019 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2020;8(3 Suppl):Abstract nr A58.

Abstract 247: Phagocytosis-mediated Activation of Smad3 in Macrophages Mediates Anti-inflammatory Transition and Protects From Adverse Post-infarction Remodeling

Macrophages are essential regulators in tissue injury, repair and fibrosis. Although activation of TGF-β signaling cascades critically modulates macrophage phenotype in vitro, the in vivo role of macrophage TGF-β signaling in homeostasis and disease is unknown. Our study examined the role of macrophage-specific TGF-β/Smad3 signaling in a mouse model of myocardial infarction (MI). TGF-βs markedly activated Smad3 in isolated macrophages, without affecting Smad-independent pathways. Infarct macrophages, but not neutrophils exhibited Smad3 activation. Phagocytosis rapidly and directly activated macrophage Smad3, in the absence of active TGF-β1 release. Myeloid cell-specific Smad3 knockout mice (MyS3KO) had no baseline defects, but exhibited increased late mortality and accentuated remodeling following MI. Adverse outcome in MyS3KO mice after MI was associated with perturbations in phagocytic activity, with defective transition of macrophages to an anti-inflammatory phenotype and with scar expansion. Milk-fat globule EGF factor-8 (Mfge8) partly rescued the phagocytic defect of Smad3 null macrophages, without affecting inflammatory activity. Perturbed anti-inflammatory transition of Smad3 null macrophages was associated with marked attenuation of phagocytosis-mediated PPAR induction. We demonstrate that Smad3 is activated in phagocytic macrophages, critically regulates their function and mediates anti-inflammatory transition, and protects the infarcted heart from adverse remodeling.

Macrophage Smad3 Protects the Infarcted Heart, Stimulating Phagocytosis and Regulating Inflammation.

TGF (transforming growth factor)-β is critically involved in myocardial injury, repair, and fibrosis, activating both Smad (small mothers against decapentaplegic)-dependent and non-Smad pathways. The in vivo role of TGF-β signaling in regulation of macrophage function is poorly understood. We hypothesized that in the infarcted myocardium, activation of TGF-β/Smad signaling in macrophages may regulate repair and remodeling. To investigate the role of macrophage-specific TGF-β Smad3 signaling in a mouse model of myocardial infarction and to dissect the mechanisms mediating Smad-dependent modulation of macrophage function. TGF-βs markedly activated Smad3 in macrophages, without affecting Smad-independent pathways. Phagocytosis rapidly and directly activated macrophage Smad3, in the absence of active TGF-β release. MyS3KO (myeloid cell-specific Smad3 knockout) mice had no baseline defects but exhibited increased late mortality and accentuated dilative postmyocardial infarction remodeling. Adverse outcome in infarcted MyS3KO mice was associated with perturbations in phagocytic activity, defective transition of macrophages to an anti-inflammatory phenotype, scar expansion, and accentuated apoptosis of border zone cardiomyocytes. In vitro, Smad3 null macrophages exhibited reduced expression of genes associated with eat-me signals, such as Mfge8 (milk fat globule-epidermal growth factor factor 8), and reduced capacity to produce the anti-inflammatory mediators IL (interleukin)-10 and TGF-β1, and the angiogenic growth factor VEGF (vascular endothelial growth factor). Mfge8 partly rescued the phagocytic defect of Smad3 null macrophages, without affecting inflammatory activity. Impaired anti-inflammatory actions of Smad3 null macrophages were associated with marked attenuation of phagocytosis-induced PPAR (peroxisome proliferator-activated receptor) expression. MyS3KO mice had no significant alterations in microvascular density and interstitial fibrosis in remodeling myocardial segments. We demonstrate that Smad3 critically regulates function of infarct macrophages, by mediating acquisition of a phagocytic phenotype and by contributing to anti-inflammatory transition. Smad3-dependent actions in macrophages protect the infarcted heart from adverse remodeling.

Distinct roles of myofibroblast-specific Smad2 and Smad3 signaling in repair and remodeling of the infarcted heart

TGF-βs regulate fibroblast responses, by activating Smad2 or Smad3 signaling, or via Smad-independent pathways. We have previously demonstrated that myofibroblast-specific Smad3 is critically implicated in repair of the infarcted heart. However, the role of fibroblast Smad2 in myocardial infarction remains unknown. This study investigates the role of myofibroblast-specific Smad2 signaling in myocardial infarction, and explores the mechanisms responsible for the distinct effects of Smad2 and Smad3. In a mouse model of non-reperfused myocardial infarction, Smad2 activation in infarct myofibroblasts peaked 7 days after coronary occlusion. In vitro, TGF-β1, -β2 and -β3, but not angiotensin 2 and bone morphogenetic proteins-2, −4 and −7, activated fibroblast Smad2. Myofibroblast-specific Smad2 and Smad3 knockout mice (FS2KO, FS3KO) and corresponding control littermates underwent non-reperfused infarction. In contrast to the increase in rupture rates and adverse remodeling in FS3KO mice, FS2KO animals had mortality comparable to Smad2 fl/fl controls, and exhibited a modest but transient improvement in dysfunction after 7 days of coronary occlusion. At the 28 day timepoint, FS2KO and Smad2 fl/fl mice had comparable adverse remodeling. Although both FS3KO and FS2KO animals had increased myofibroblast density in the infarct, only FS3KO mice exhibited impaired scar organization, associated with perturbed alignment of infarct myofibroblasts. In vitro, Smad3 but not Smad2 knockdown downmodulated fibroblast α2 and α5 integrin expression. Moreover, Smad3 knockdown reduced expression of the GTPase RhoA, whereas Smad2 knockdown markedly increased fibroblast RhoA levels. Smad3-dependent integrin expression may be important for fibroblast activation, whereas RhoA may transduce planar cell polarity pathway signals, essential for fibroblast alignment. Myofibroblast-specific Smad3, but not Smad2 is required for formation of aligned myofibroblast arrays in the infarct. The distinct in vivo effects of myofibroblast Smad2 and Smad3 may involve Smad3-dependent integrin synthesis, and contrasting effects of Smad2 and Smad3 on RhoA expression.