TSC2-null Cells Research Articles

7908 GPNMB Promotes Tumor Growth And Is A Biomarker For Lymphangioleiomyomatosis (LAM)

Abstract Disclosure: E. Gibbons: None. M. Taya: None. H. Wu: None. S. Lopa: None. J. Moss: None. E.P. Henske: None. F.X. McCormack: None. S.R. Hammes: None. Lymphangioleiomyomatosis (LAM) is a rare, progressive cystic lung disease affecting almost exclusively female-sexed individuals. The cysts represent regions of lung destruction caused by smooth muscle tumors containing mutations in one of the two tuberous sclerosis (TSC) genes. mTORC1 inhibition slows but does not stop LAM advancement. Furthermore, monitoring disease progression is hindered by insufficient biomarkers. Therefore, new treatment options and biomarkers are needed. LAM cells express melanocytic markers, including Glycoprotein Non-Metastatic Melanoma Protein B (GPNMB). The function of GPNMB in LAM is currently unknown; however, GPNMB’s unique cell surface expression on tumor versus benign cells makes GPNMB a potential therapeutic target, and persistent release of its extracellular ectodomain suggests potential as a serum biomarker. Here we establish that GPNMB regulates TSC2-null tumor cell invasion as well as TSC2-null xenograft tumor growth, and that GPNMB expression is dependent on mTORC1 signaling. Further, we show that GPNMB’s ectodomain is released from the cell surface of TSC2-null cells by ADAM10 and 17 proteases, and we identify the protease target sequence on GPNMB. In fact, mutating this cleavage sequence so that the GPNMB ectodomain can no longer be shed results in cessation of TSC2-null tumor growth. Finally, we demonstrate that GPNMB’s ectodomain is present at higher levels in LAM patient serum compared to healthy controls, and that ectodomain levels decrease with mTORC1 inhibition, making it a potential LAM biomarker. Presentation: 6/3/2024

7908 GPNMB Promotes Tumor Growth and is a Biomarker for Lymphangioleiomyomatosis (LAM)

Abstract Disclosure: E. Gibbons: None. M. Taya: None. H. Wu: None. S. Lopa: None. J. Moss: None. E.P. Henske: None. F.X. McCormack: None. S.R. Hammes: None. Lymphangioleiomyomatosis (LAM) is a rare, progressive cystic lung disease affecting almost exclusively female-sexed individuals. The cysts represent regions of lung destruction caused by smooth muscle tumors containing mutations in one of the two tuberous sclerosis (TSC) genes. mTORC1 inhibition slows but does not stop LAM advancement. Furthermore, monitoring disease progression is hindered by insufficient biomarkers. Therefore, new treatment options and biomarkers are needed. LAM cells express melanocytic markers, including Glycoprotein Non-Metastatic Melanoma Protein B (GPNMB). The function of GPNMB in LAM is currently unknown; however, GPNMB’s unique cell surface expression on tumor versus benign cells makes GPNMB a potential therapeutic target, and persistent release of its extracellular ectodomain suggests potential as a serum biomarker. Here we establish that GPNMB regulates TSC2-null tumor cell invasion as well as TSC2-null xenograft tumor growth, and that GPNMB expression is dependent on mTORC1 signaling. Further, we show that GPNMB’s ectodomain is released from the cell surface of TSC2-null cells by ADAM10 and 17 proteases, and we identify the protease target sequence on GPNMB. In fact, mutating this cleavage sequence so that the GPNMB ectodomain can no longer be shed results in cessation of TSC2-null tumor growth. Finally, we demonstrate that GPNMB’s ectodomain is present at higher levels in LAM patient serum compared to healthy controls, and that ectodomain levels decrease with mTORC1 inhibition, making it a potential LAM biomarker. Presentation: 6/3/2024

9308 GPNMB Promotes Tumor Growth And Is A Biomarker For Lymphangioleiomyomatosis (LAM)

Abstract Disclosure: E. Gibbons: None. M. Taya: None. H. Wu: None. S. Lopa: None. J. Moss: None. E.P. Henske: None. F.X. McCormack: None. S.R. Hammes: None. Lymphangioleiomyomatosis (LAM) is a rare, progressive cystic lung disease affecting almost exclusively female-sexed individuals. The cysts represent regions of lung destruction caused by smooth muscle tumors containing mutations in one of the two tuberous sclerosis (TSC) genes. mTORC1 inhibition slows but does not stop LAM advancement. Furthermore, monitoring disease progression is hindered by insufficient biomarkers. Therefore, new treatment options and biomarkers are needed. LAM cells express melanocytic markers, including Glycoprotein Non-Metastatic Melanoma Protein B (GPNMB). The function of GPNMB in LAM is currently unknown; however, GPNMB’s unique cell surface expression on tumor versus benign cells makes GPNMB a potential therapeutic target, and persistent release of its extracellular ectodomain suggests potential as a serum biomarker. Here we establish that GPNMB regulates TSC2-null tumor cell invasion as well as TSC2-null xenograft tumor growth, and that GPNMB expression is dependent on mTORC1 signaling. Further, we show that GPNMB’s ectodomain is released from the cell surface of TSC2-null cells by ADAM10 and 17 proteases, and we identify the protease target sequence on GPNMB. In fact, mutating this cleavage sequence so that the GPNMB ectodomain can no longer be shed results in cessation of TSC2-null tumor growth. Finally, we demonstrate that GPNMB’s ectodomain is present at higher levels in LAM patient serum compared to healthy controls, and that ectodomain levels decrease with mTORC1 inhibition, making it a potential LAM biomarker. Presentation: 6/3/2024

Repurposing Nitazoxanide for Potential Treatment of Rare Disease Lymphangioleiomyomatosis

Lymphangioleiomyomatosis (LAM) is a rare genetic lung disease. Unfortunately, treatment with the mTORC1 inhibitor Rapamycin only slows disease progression, and incomplete responses are common. Thus, there remains an urgent need to identify new targets for the development of curative LAM treatments. Nitazoxanide (NTZ) is an orally bioavailable antiprotozoal small molecule drug approved for the treatment of diarrhea caused by Giardia lamblia or Cryptosporidium parvum in children and adults, with a demonstrated mTORC1 inhibitory effect in several human cell lines. NTZ’s excellent safety profile characterized by its more than 20 years of clinical use makes it a promising candidate for repurposing. Our rationale for this study was to further investigate NTZ’s effect using in vitro and in vivo LAM models and to elucidate the underlying molecular mechanism beyond mTORC1 inhibition. For this purpose, we investigated cell proliferation, cell viability, and changes in protein phosphorylation and expression in primary human cell cultures derived from LAM lung samples before translating our results into a syngeneic mouse model utilizing Tsc2-null cells. NTZ reduced cell growth for all tested cell lines at a dose of about 30 µM. Lower doses than that had no effect on cell viability, but doses above 45 µM lowered the viability by about 10 to 15% compared to control. Interestingly, our western blot revealed no inhibition of mTORC1 and only a mild effect on active ß-Catenin. Instead, NTZ had a pronounced effect on reducing pAkt. In the mouse model, prophylactic NTZ treatment via the intraperitoneal and oral routes had some effects on reducing lung lesions and improving body weight retention, but the results remain inconclusive.

Glycoprotein non-metastatic melanoma protein B promotes tumor growth and is a biomarker for lymphangioleiomyomatosis.

Lymphangioleiomyomatosis (LAM) is a rare, progressive cystic lung disease affecting almost exclusively female-sexed individuals. The cysts represent regions of lung destruction caused by smooth muscle tumors containing mutations in one of the two tuberous sclerosis (TSC) genes. mTORC1 inhibition slows but does not stop LAM advancement. Furthermore, monitoring disease progression is hindered by insufficient biomarkers. Therefore, new treatment options and biomarkers are needed. LAM cells express melanocytic markers, including glycoprotein non-metastatic melanoma protein B (GPNMB). The function of GPNMB in LAM is currently unknown; however, GPNMB's unique cell surface expression on tumor versus benign cells makes GPNMB a potential therapeutic target, and persistent release of its extracellular ectodomain suggests potential as a serum biomarker. Here, we establish that GPNMB expression is dependent on mTORC1 signaling, and that GPNMB regulates TSC2-null tumor cell invasion in vitro. Further, we demonstrate that GPNMB enhances TSC2-null xenograft tumor growth in vivo, and that ectodomain release is required for this xenograft growth. We also show that GPNMB's ectodomain is released from the cell surface of TSC2-null cells by proteases ADAM10 and 17, and we identify the protease target sequence on GPNMB. Finally, we demonstrate that GPNMB's ectodomain is present at higher levels in LAM patient serum compared to healthy controls and that ectodomain levels decrease with mTORC1 inhibition, making it a potential LAM biomarker.

THU551 Glycoprotein-NMB (GPNMB) Is A Potential Lymphangioleiomyomatosis (LAM) Therapeutic Target And Biomarker

Abstract Disclosure: E. Gibbons: None. S.R. Hammes: None. Lymphangioleiomyomatosis (LAM) is a rare, progressive, destructive cystic lung disease affecting almost exclusively female-sexed individuals. Mutations in the tuberous sclerosis (TSC1 or TSC2) genes constitutively activate the mTORC1 pathway, promoting hyperproliferation of smooth muscle cells, creating small tumors throughout the lungs. These tumors, through largely unknown mechanisms, result in the formation of large cysts that replace normal alveolar space. Inhibition of mTORC1 with Sirolimus slows but does not stop LAM progression; therefore, there is a need for new LAM treatment options and biomarkers. Due to LAM’s estrogen sensitivity, female specificity, and metastatic nature, we previously proposed LAM cells originate from the uterine myometrium. We therefore designed a uterine-specific TSC2-null mouse model where all the mice generate uterine tumors characteristic of LAM and half develop lung metastases, suggesting that indeed LAM tumors may be derived from the uterus. Using bulk RNASeq analysis of uterine tissue from our mouse model, when focusing on genes regulated by estrogen and TSC2, we discovered increased expression of melanocytic markers, including Glycoprotein Non-Metastatic Melanoma Protein B (GPNMB), a known oncogenic protein in other cancers. GPNMB was not only highly expressed in our mouse model; it was also expressed intracellularly and on the cell surface of TSC2-null cell lines and in LAM tumor cells from patient lungs and uteri. Notably, the extracellular domain of GPNMB was released from the surface of TSC2-null cell lines, suggesting that the ectodomain may also be released from TSC2-null cells in LAM patients. Here we show that, GPNMB protein and mRNA expression increased when the cells were serum starved, mimicking conditions of a tumor microenvironment. This increase was dependent on mTORC1 signaling and mRNA transcription. Knocking down GPNMB expression by siRNA had minimal effects on TSC2-null cells pro-tumorigenic functions in vitro aside from decreasing invasion. However, knocking out GPNMB in TSC2-null cells using CRISPR/Cas9 significantly decreased mouse xenograft tumor growth. Additionally, treating mice with a GPNMB antibody drug conjugate abrogated xenograft growth, highlighting GPNMB’s potential as a therapeutic target. Also, GPNMB’s ectodomain was released from the cell surface of TSC2-null cells by the proteases Adam10 and 17. Of note, the ectodomain is implicated in mediating GPNMB’s effects on tumor growth, suggesting that Adam10/17 inhibition may mitigate TSC2-null tumor growth. Importantly, the GPNMB ectodomain is a potential serum biomarker of LAM, as there was a significant increase in GPNMB ectodomain levels in patient serum as compared with healthy controls. Furthermore, serum GPNMB levels decreased in most patients after Sirolimus treatment, implicating GPNMB as a potential marker for responsiveness to treatment. Presentation: Thursday, June 15, 2023

Upregulation of acid ceramidase contributes to tumor progression in tuberous sclerosis complex.

Tuberous sclerosis complex (TSC) is characterized by multisystem, low-grade neoplasia involving the lung, kidneys, brain, and heart. Lymphangioleiomyomatosis (LAM) is a progressive pulmonary disease affecting almost exclusively women. TSC and LAM are both caused by mutations in TSC1 and TSC2 that result in mTORC1 hyperactivation. Here, we report that single-cell RNA sequencing of LAM lungs identified activation of genes in the sphingolipid biosynthesis pathway. Accordingly, the expression of acid ceramidase (ASAH1) and dihydroceramide desaturase (DEGS1), key enzymes controlling sphingolipid and ceramide metabolism, was significantly increased in TSC2-null cells. TSC2 negatively regulated the biosynthesis of tumorigenic sphingolipids, and suppression of ASAH1 by shRNA or the inhibitor ARN14976 (17a) resulted in markedly decreased TSC2-null cell viability. In vivo, 17a significantly decreased the growth of TSC2-null cell-derived mouse xenografts and short-term lung colonization by TSC2-null cells. Combined rapamycin and 17a treatment synergistically inhibited renal cystadenoma growth in Tsc2+/- mice, consistent with increased ASAH1 expression and activity being rapamycin insensitive. Collectively, the present study identifies rapamycin-insensitive ASAH1 upregulation in TSC2-null cells and tumors and provides evidence that targeting aberrant sphingolipid biosynthesis pathways has potential therapeutic value in mechanistic target of rapamycin complex 1-hyperactive neoplasms, including TSC and LAM.

Estradiol Augments Tumor-Induced Neutrophil Production to Promote Tumor Cell Actions in Lymphangioleiomyomatosis Models.

Lymphangioleiomyomatosis (LAM) is a rare cystic lung disease caused by smooth muscle cell-like tumors containing tuberous sclerosis (TSC) gene mutations and found almost exclusively in females. Patient studies suggest LAM progression is estrogen dependent, an observation supported by in vivo mouse models. However, in vitro data using TSC-null cell lines demonstrate modest estradiol (E2) responses, suggesting E2 effects in vivo may involve pathways independent of direct tumor stimulation. We previously reported tumor-dependent neutrophil expansion and promotion of TSC2-null tumor growth in an E2-sensitive LAM mouse model. We therefore hypothesized that E2 stimulates tumor growth in part by promoting neutrophil production. Here we report that E2-enhanced lung colonization of TSC2-null cells is indeed dependent on neutrophils. We demonstrate that E2 induces granulopoiesis via estrogen receptor α in male and female bone marrow cultures. With our novel TSC2-null mouse myometrial cell line, we show that factors released from these cells drive E2-sensitive neutrophil production. Last, we analyzed single-cell RNA sequencing data from LAM patients and demonstrate the presence of tumor-activated neutrophils. Our data suggest a powerful positive feedback loop whereby E2 and tumor factors induce neutrophil expansion, which in turn intensifies tumor growth and production of neutrophil-stimulating factors, resulting in continued TSC2-null tumor growth.

Targeting SPHK1/S1PR3-regulated S-1-P metabolic disorder triggers autophagic cell death in pulmonary lymphangiomyomatosis (LAM)

Lymphangioleiomyomatosis (LAM), a progressive pulmonary disease exclusively affecting females, is caused by defects or mutations in the coding gene tuberous sclerosis complex 1 (TSC1) or TSC2, causing the mammalian target of rapamycin complex 1 (mTORC1) activation and autophagy inhibition. Clinically, rapamycin shows limited cytocidal effects, and LAM recurs after drug withdrawal. In this study, we demonstrated that TSC2 negatively regulated the sphingolipid metabolism pathway and the expressions of sphingosine kinase 1 (SPHK1) and sphingosine-1-phosphate receptor 3 (S1PR3) were significantly elevated in LAM patient-derived TSC2-deficient cells compared to TSC2-addback cells, insensitive to rapamycin treatment and estrogen stimulation. Knockdown of SPHK1 showed reduced viability, migration and invasion in TSC2-deficient cells. Selective SPHK1 antagonist PF543 potently suppressed the viability of TSC2-deficient cells and induced autophagy-mediated cell death. Meanwhile, the cognate receptor S1PR3 was identified to mediating the tumorigenic effects of sphingosine-1-phosphate (S1P). Treatment with TY52156, a selective antagonist for S1PR3, or genetic silencing using S1PR3-siRNA suppressed the viability of TSC2-deficient cells. Both SPHK1 and S1PR3 inhibitors markedly exhibited antitumor effect in a xenograft model of TSC2-null cells, restored autophagy level, and triggered cell death. Together, we identified novel rapamycin-insensitive sphingosine metabolic signatures in TSC2-null LAM cells. Therapeutic targeting of aberrant SPHK1/S1P/S1PR3 signaling may have potent therapeutic benefit for patients with TSC/LAM or other hyperactive mTOR neoplasms with autophagy inhibition.

An mTORC1-mediated negative feedback loop constrains amino acid-induced FLCN-Rag activation in renal cells with TSC2 loss

The mechanistic target of rapamycin complex 1 (mTORC1) integrates inputs from growth factors and nutrients, but how mTORC1 autoregulates its activity remains unclear. The MiT/TFE transcription factors are phosphorylated and inactivated by mTORC1 following lysosomal recruitment by RagC/D GTPases in response to amino acid stimulation. We find that starvation-induced lysosomal localization of the RagC/D GAP complex, FLCN:FNIP2, is markedly impaired in a mTORC1-sensitive manner in renal cells with TSC2 loss, resulting in unexpected TFEB hypophosphorylation and activation upon feeding. TFEB phosphorylation in TSC2-null renal cells is partially restored by destabilization of the lysosomal folliculin complex (LFC) induced by FLCN mutants and is fully rescued by forced lysosomal localization of the FLCN:FNIP2 dimer. Our data indicate that a negative feedback loop constrains amino acid-induced, FLCN:FNIP2-mediated RagC activity in renal cells with constitutive mTORC1 signaling, and the resulting MiT/TFE hyperactivation may drive oncogenesis with loss of the TSC2 tumor suppressor.

RF19 | PSUN351 Glycoprotein-NMB (GPNMB) is Pro-Tumorigenic in Lymphangioleiomyomatosis (LAM)

Abstract Lymphangioleiomyomatosis (LAM) is an estrogen-sensitive lung disease found almost exclusively in women. LAM is characterized by the hyperproliferation of smooth muscle cells creating small tumors throughout the lungs, resulting in the formation of large cysts that replace normal alveolar space. Growth of these tumors and progression of cyst development leads to loss of pulmonary function, and sometimes subsequent lung transplantation. LAM tumor cells contain mutations in one of the tuberous sclerosis genes (TSC1 or TSC2), leading to constitutive activation of the mTORC1 pathway. In fact, mTOR inhibitors are commonly used to treat LAM; however, these drugs are not always effective and have significant side effects, suggesting the need for new therapeutic targets. Additionally, tumors recur even after lung transplantation and LAM cells are found in circulating body fluids, suggesting a metastatic nature of LAM, and a question of the origin of the LAM cell. Due to LAM's estrogen sensitivity, female specificity, and metastatic nature, we previously proposed that LAM cells originate from the uterine myometrium. We therefore designed a uterine-specific TSC2-null mouse model where all of the mice generate uterine tumors characteristic of LAM and half develop lung metastases, suggesting that indeed LAM tumors may be derived from the uterus. Notably, our collaborators recently utilized single cell RNA sequencing with human LAM lung lesions, and found that TSC2-null cells have a strong uterine profile. Using bulk RNASeq analysis of uterine tissue from our mouse model, when focusing on genes regulated by estrogen and TSC2, we discovered increased expression of melanocytic markers, including Glycoprotein Non-Metastatic Melanoma Protein B (GPNMB). GPNMB is known to be oncogenic in other cancers and has been shown to be expressed intracellularly in benign cells, but both intracellularly and on the cell surface of tumor cells making GPNMB a good cell surface drug target. This melanocytic marker was not only highly expressed in our mouse model, it was also expressed in TSC2-null cell lines, as well as in human LAM patient lung and uteri samples. Knocking down GPNMB expression by siRNA directed against GPNMB mRNA decreased proliferation, migration, and invasion in TSC2-null cells. We also found that GPNMB's large ectodomain is released from the cell surface of TSC2-null cells and potentially mediated by the protease, Adam10. The ectodomain specifically is implicated in mediating GPNMB's effects on tumor growth. Finally, knocking out GPNMB in TSC2-null cells using CRISPR/Cas9 decreased xenograft tumor growth in mice. Overall, our data thus far demonstrate that GPNMB promotes TSC2-null tumor growth and metastasis. Importantly, the GPNMB ectodomain is a potential biomarker of human LAM, as we detect a significant difference in GPNMB ectodomain levels in patient blood as compared with healthy controls. Presentation: Sunday, June 12, 2022 12:30 p.m. - 2:30 p.m., Sunday, June 12, 2022 12:36 p.m. - 12:41 p.m.

RF07 | PSUN350 Estradiol Effects on Polymorphonuclear Cell Production and Actions Contribute to Estrogen-mediated Lymphangioleiomyomatosis (LAM) Progression

Abstract Lymphangioleiomyomatosis (LAM) is a rare lung disease seen almost exclusively in female sexed individuals and characterized by slowly growing, metastatic smooth muscle cell-like adenomas that cause cyst formation in the lung parenchyma and irreversible loss of pulmonary function. Given the female specificity of disease manifestation, metastatic nature, and estrogen sensitivity of LAM cells, we previously proposed that LAM cells originate in the myometrium. Our subsequent reports showed that inactivation of TSC2 in the mouse uterus results in notable LAM features in the setting of primary myometrial tumors. Additionally, we established that estrogen is required to maintain LAM-like tumor progression in a uterine-specific Tsc2-knockout murine model. However, the observed estrogen sensitivity in vivo is more markedly pronounced than that of our estrogen receptor-positive TSC2-null cells when stimulated with estradiol in vitro, suggesting that estradiol may act elsewhere in vivo to promote LAM progression. Recent immunophenotyping of LAM-like TSC2-null uterine tumors revealed preferential increase in polymorphonuclear cell (PMNs) numbers of the tumor microenvironment; we also determined that PMNs are important regulators of tumor growth. Therefore, we hypothesize that, in addition to direct effects of estrogen on tumor cells, estrogen might also stimulate tumor growth by promoting PMN production in the bone marrow and actions in the tumor microenvironment. Here, we show that estrogen availability influences PMN mobilization in naïve and tumor-burdened mice. Using bone marrow cultures and CFC assay, we demonstrate that estradiol is a potent inducer of PMN production in chronic inflammatory conditions. Employing both pharmacologic agents and estrogen receptor (ER)-null bone marrow, we showed that ERα is necessary for promoting induction of PMN fate for myeloid progenitors. While we see that the migratory, invasive, and proliferative capacities of TSC2-null cell lines are not augmented when stimulated with E2 directly, experiments are underway to assess the extent to which estrogen promotes the pro-tumorigenic function of PMNs co-cultured with TSC2-null cell lines. Together these data provide insight into the robust effect of in vivo estrogen stimulation as estradiol may be a dual effector in LAM tumor progression and great target for anti-LAM therapeutic strategy. Presentation: Saturday, June 11, 2022 1:00 p.m. - 1:05 p.m., Sunday, June 12, 2022 12:30 p.m. - 2:30 p.m.

Glycoprotein-NMB (GPNMB) is Pro-Tumorigenic in Lymphangioleiomyomatosis (LAM)

Abstract Lymphangioleiomyomatosis (LAM) is an estrogen-sensitive lung disease found almost exclusively in women. LAM is characterized by the hyperproliferation of smooth muscle cells creating small tumors throughout the lungs, resulting in the formation of large cysts that replace normal alveolar space. Growth of these tumors and progression of the cyst development leads to pulmonary function loss, and sometimes subsequent lung transplantation. However, LAM recurs after transplantation and LAM cells can be found circulating in body fluids suggesting a metastatic nature of the disease. Due to LAM’s estrogen sensitivity, female specificity, and metastatic nature, we previously proposed that LAM cells originate from the uterine myometrium. We therefore designed a uterine-specific TSC2-null mouse model where all of the mice generate uterine tumors characteristic of LAM and half develop lung metastases. Using RNASeq analysis of uterine tissue from this mouse model, when focusing on genes regulated by estrogen and TSC2, we discovered increased expression of melanocytic markers, including Glycoprotein Non-Metastatic Melanoma Protein B (GPNMB), which is known to be oncogenic in other cancers. GPNMB was not only highly expressed in our mouse model, it was also expressed in TSC2-null cell lines, and LAM patient lungs and uteri. Interestingly, serum GPNMB is a potential biomarker, as LAM patients have higher serum GPNMB levels compared to healthy controls. Knocking down GPNMB expression by siRNA decreased proliferation, migration, and invasion in TSC2-null cells. Further, knocking out GPNMB in TSC2-null cells using CRISPR/Cas9 decreased xenograft tumor growth in mice and GPNMB is a potential therapeutic target for LAM. Supported by grants from NIH (R01 CA193583, T32HL066988), the LAM Foundation, and DOD

Estradiol Effects on Polymorphonuclear Cell Production and Actions Contribute to Estrogen-Mediated Lymphangioleiomyomatosis (LAM) Progression

Abstract The estrogen sensitivity of Lymphangioleiomyomatosis (LAM)—a rare lung disease involving the slow growth of smooth muscle-like adenomas that result in cystic change in the lung parenchyma—is traditionally examined to assess the direct effects of estradiol on the tumor cells. However, we have observed that the estrogen sensitivity of in vitro models is markedly less pronounced than that of in vivo models, suggesting that estradiol may act elsewhere to promote tumor progression. We have previously reported that polymorphonuclear cells (PMNs) are preferentially increased in the immune microenvironment and regulate growth of LAM-like TSC2-null uterine tumors. We hypothesized that, in addition to direct effects of estrogen on tumor cells, estrogen might also stimulate tumor growth by promoting PMN production in the bone marrow and actions in the tumor microenvironment. Here, we show that estrogen availability influences the levels of PMNs in naïve and tumor-burdened mice. Using bone marrow cultures and CFC assay, we demonstrate that estradiol is a potent inducer of PMN production in chronic inflammatory conditions. Employing both pharmacologic agents and estrogen receptor (ER)-null bone marrow, we showed that ER□ is necessary for promoting a PMN fate for myeloid progenitors. While we see that the migratory, invasive, and proliferative capacities of TSC2-null cell lines are not augmented when stimulated with E2 directly, evidence shows estrogen promotes the pro-tumorigenic function of PMNs co-cultured with TSC2-null cell lines. These data provide insight into the robust effect of in vivoestrogen stimulation as estradiol may be a dual effector in LAM tumor progression and great target for anti-LAM therapeutic strategy. Supported by grants from NIH (R01CA193583, F31 CA254132-01).

Aberrant mTOR/autophagy/Nurr1 signaling is critical for TSC-associated tumor development.

Tuberous sclerosis complex (TSC), an inherited neurocutaneous disease, is caused by mutations in either the TSC1 or TSC2 gene. This genetic disorder is characterized by the growth of benign tumors in the brain, kidneys, and other organs. As a member of the orphan nuclear receptor family, nuclear receptor related 1 (Nurr1) plays a vital role in some neuropathological diseases and several types of benign or malignant tumors. Here, we explored the potential regulatory role of TSC1/2 signaling in Nurr1 and the effect of Nurr1 in TSC-related tumors. We found that Nurr1 expression was drastically decreased by the disruption of the TSC1/2 complex in Tsc2-null cells, genetically modified mouse models of TSC, cortical tubers of TSC patients, and kidney tumor tissue obtained from a TSC patient. Deficient TSC1/2 complex downregulated Nurr1 expression in an mTOR-dependent manner. Moreover, hyperactivation of mTOR reduced Nurr1 expression via suppression of autophagy. In addition, Nurr1 overexpression inhibited cell proliferation and suppressed cell cycle progression. Therefore, TSC/mTOR/autophagy/Nurr1 signaling is partially responsible for the tumorigenesis of TSC. Taken together, Nurr1 may be a novel therapeutic target for TSC-associated tumors, and Nurr1 agonists or reagents that induce Nurr1 expression may be used for the treatment of TSC.

Structure of prodigiosin from Serratia marcescens NJZT-1 and its cytotoxicity on TSC2-null cells

Prodigiosin, a secondary metabolite extracted from Serratia marcescens (S. marcescens), could induce apoptosis in various cancer cells, with however low toxicity on normal cells. The red pigment was extracted from a strain S. marcescens NJZT-1 isolated from soil, which had antibacterial activity. Spectral analyses (LC-ESI-MS, UV-VIS spectrophotometry, infrared spectra and HPLC) and TLC indicated the presence of prodigiosin in the extracellular bacterial culture extracts. The red pigment effectively killed the TSC2-null cells, whose mutation resulted in the progressive and systemic disease LAM. Our findings provide interesting evidence and important basis for the development of new therapeutic compounds with high potential effects against TSC2-null cells.

Estradiol Augments the Production and Actions of Polymorphonuclear Cells to Promote Lymphangioleiomyomatosis (LAM) Progression

Affecting almost exclusively women, lymphangioleiomyomatosis (LAM) is a rare lung disease characterized by slowly growing, estrogen-sensitive metastatic smooth muscle cell-like adenomas that result in cystic lung changes and loss of pulmonary function. LAM tumors are caused by mutations in either TSC1 or TSC2 genes that induces defective inhibition of the mTORC1 pathway, leading to increased mTORC1 activity and augmented cell proliferation. We have previously reported that estrogen ablation in our uterine-specific Tsc2 knockout mouse, which grows tumors with characteristic LAM features and lung colonization potential, effects notable regression of tumors. Thus, estrogen is required for to maintain heightened mTORC1 activity and LAM-like tumor progression. Interestingly, the observed estrogen sensitivity in vivo is more markedly pronounced than that of our estrogen receptor-positive TSC2-null cells when stimulated with estradiol in vitro, suggesting that estradiol may act elsewhere—in mTORC1 independent manner—in vivo to promote LAM progression. Flow cytometry revealed large numbers of Ly-6Cint Ly-6Ghigh myeloid cells—polymorphonuclear cells or PMNs—in the blood and myometrial tumors of our uterine-specific Tsc2-null mice. Accordingly, we found that Tsc2-null tumors required PMNs for normal disease progression, as Gr-1 (Ly-6C/Ly-6G) depletion or inhibition of PMN recruitment reduced tumor growth. Therefore, we hypothesized that, in addition to direct effects of estrogen on tumor cells, estrogen might also stimulate tumor growth by promoting PMN production in the bone marrow and actions in the tumor microenvironment. Using bone marrow cultures, we found that estradiol is indeed a potent inducer of PMN production. This effect occurs equally in both male and female bone marrow. Employing both pharmacologic agents and bone marrow from ERα; knockout mice, we showed that ERα; is necessary for promoting a PMN fate for myeloid progenitors. Additionally, we have evidence implicating estrogen in the pro-tumorigenic function of PMNs co-cultured with TSC2-null cell lines. Overall, these data suggest that estradiol maybe facilitating crosstalk in LAM tumors, directly stimulating tumor cells while also promoting the production and actions of PMNs, which in turn promote tumor growth.

Estradiol Augments the Production and Actions of Polymorphonuclear Cells to Promote Lymphangioleiomyomatosis (LAM) Progression

Abstract Predominately affecting women of reproductive age, lymphangioleiomyomatosis (LAM) is a rare lung disease characterized by slowly growing, estrogen-sensitive metastatic smooth muscle cell-like adenomas that result in cystic lung changes and loss of pulmonary function. We have previously reported that estrogen is required to maintain LAM-like tumor progression in a uterine-specific Tsc2-knockout murine model. Interestingly, the observed estrogen sensitivity in vivo is more markedly pronounced than that of our estrogen receptor-positive TSC2-null cells when stimulated with estradiol (E2) in vitro, suggesting that estradiol may act elsewhere to promote LAM progression. We hypothesized that, in addition to direct effects of estrogen on tumor cells, estrogen might also stimulate tumor growth by promoting polymorphonuclear cell (PMN) production in the bone marrow and actions in the tumor microenvironment. Here, using bone marrow cultures, we demonstrate that estradiol is a potent inducer of PMN production. This effect occurs equally with both male and female bone marrow. Employing both pharmacologic agents and bone marrow from ER_ knockout mice, we showed that ER_ is necessary for promoting a PMN fate for myeloid progenitors. While we see that the migratory and invasive capacities of TSC2-null cell lines are not augmented when stimulated with E2 directly, evidence shows estrogen promotes the pro-tumorigenic function of PMNs co-cultured with TSC2-null cell lines. These data provide insight into the robust effect of in vivo estrogen stimulation as estradiol may be a dual effector in LAM tumor progression and great target for anti-LAM therapeutic strategy.

Evaluation of Hsp90 and mTOR inhibitors as potential drugs for the treatment of TSC1/TSC2 deficient cancer.

Inactivating mutations in either TSC1 or TSC2 cause Tuberous Sclerosis Complex, an autosomal dominant disorder, characterized by multi-system tumor and hamartoma development. Mutation and loss of function of TSC1 and/or TSC2 also occur in a variety of sporadic cancers, and rapamycin and related drugs show highly variable treatment benefit in patients with such cancers. The TSC1 and TSC2 proteins function in a complex that inhibits mTORC1, a key regulator of cell growth, which acts to enhance anabolic biosynthetic pathways. In this study, we identified and validated five cancer cell lines with TSC1 or TSC2 mutations and performed a kinase inhibitor drug screen with 197 compounds. The five cell lines were sensitive to several mTOR inhibitors, and cell cycle kinase and HSP90 kinase inhibitors. The IC50 for Torin1 and INK128, both mTOR kinase inhibitors, was significantly increased in three TSC2 null cell lines in which TSC2 expression was restored. Rapamycin was significantly more effective than either INK128 or ganetespib (an HSP90 inhibitor) in reducing the growth of TSC2 null SNU-398 cells in a xenograft model. Combination ganetespib-rapamycin showed no significant enhancement of growth suppression over rapamycin. Hence, although HSP90 inhibitors show strong inhibition of TSC1/TSC2 null cell line growth in vitro, ganetespib showed little benefit at standard dosage in vivo. In contrast, rapamycin which showed very modest growth inhibition in vitro was the best agent for in vivo treatment, but did not cause tumor regression, only growth delay.

Long-Term Effects of Sirolimus on Human Skin TSC2-Null Fibroblast‒Like Cells

Tuberous sclerosis complex (TSC) is an autosomal-dominant disorder characterized by hamartomatous tumors of the skin, kidneys, brain, and lungs. TSC is caused by mutations in the TSC1 and TSC2 genes, which result in hyperactivation of the mTOR, leading to dysregulated cell growth and autophagy. Rapamycin (sirolimus) shrinks TSC tumors, but the clinical benefits of sirolimus are not sustained after its withdrawal. In this study, we studied the cellular processes critical for tumor formation and growth, including cell proliferation and cell size. TSC2-/- and TSC2+/- cells were isolated from TSC skin tumors and normal-appearing skin, respectively. Cells were incubated with sirolimus for 72 hours. Withdrawal of sirolimus from TSC2-/- cells resulted in a highly proliferative phenotype and caused cells to enter the S phase of the cell cycle, with persistent phosphorylation of mTOR, p70 S6 kinase, ribosomal protein S6, and 4EB-P1; decreased cyclin D kinase inhibitors; and transient hyperactivation of protein kinase B. Sirolimus modulated the estrogen- and autophagy-dependent volume of TSC2-/- cells. These results suggest that sirolimus may decrease the size of TSC tumors by reducing TSC2-/- cell volume, altering the cell cycle, and reprogramming TSC2-null cells.