Hyaluronidase2 (Hyal2) modulates low shear stress-induced glycocalyx impairment via the LKB1/AMPK/NADPH oxidase-dependent pathway.

RAGE signaling mediates post-injury arterial neointima formation by suppression of liver kinase B1 and AMPK activity

IntroductionAMP-activated protein kinase (AMPK) maintains cultured chondrocyte matrix homeostasis in response to inflammatory cytokines. AMPK activity is decreased in human knee osteoarthritis (OA) chondrocytes. Liver kinase B1 (LKB1) is one of the upstream activators of AMPK. Hence, we examined the relationship between LKB1 and AMPK activity in OA and aging cartilages, and in chondrocytes subjected to inflammatory cytokine treatment and biomechanical compression injury, and performed translational studies of AMPK pharmacologic activation.MethodsWe assessed activity (phosphorylation) of LKB1 and AMPKα in mouse knee OA cartilage, in aging mouse cartilage (6 to 24 months), and in chondrocytes after mechanical injury by dynamic compression, via immunohistochemistry or western blot. We knocked down LKB1 by siRNA transfection. Nitric oxide, matrix metalloproteinase (MMP)-3, and MMP-13 release were measured by Griess reaction and ELISA, respectively.ResultsKnockdown of LKB1 attenuated chondrocyte AMPK activity, and increased nitric oxide, MMP-3 and MMP-13 release (P <0.05) in response to IL-1β and TNFα. Both LKB1 and AMPK activity were decreased in mouse knee OA and aged knee cartilage, and in bovine chondrocytes after biomechanical injury. Pretreatment of bovine chondrocytes with AMPK activators AICAR and A-769662 inhibited both AMPKα dephosphorylation and catabolic responses after biomechanical injury.ConclusionLKB1 is required for chondrocyte AMPK activity, thereby inhibiting matrix catabolic responses to inflammatory cytokines. Concurrent loss of LKB1 and AMPK activity in articular chondrocytes is associated with OA, aging and biomechanical injury. Conversely, pharmacologic AMPK activation attenuates catabolic responses to biomechanical injury, suggesting a potentially novel approach to inhibit OA development and progression.

AMP-activated protein kinase (AMPK) is an energy-sensing serine/threonine kinase involved in metabolic regulation. It is phosphorylated by the upstream liver kinase B1 (LKB1) or calcium/calmodulin-dependent kinase kinase 2 (CaMKKβ). In cultured cells, AMPK activation correlates with LKB1 activity. The phosphorylation activates AMPK, shifting metabolism toward catabolism and promoting mitogenesis. In muscles, inactivity reduces AMPK activation, shifting the phenotype of oxidative muscles toward a more glycolytic profile. Here, we compared the basal level of AMPK activation in glycolytic and oxidative muscles and analyzed whether this relates to LKB1 or CaMKKβ. Using Western blotting, we assessed AMPK expression and phosphorylation in soleus, gastrocnemius (GAST), extensor digitorum longus (EDL), and heart from C57BL6J mice. We also assessed LKB1 and CaMKKβ expression, and CaMKKβ activity in tissue homogenates. AMPK activation was higher in oxidative (soleus and heart) than in glycolytic muscles (gastrocnemius and EDL). This correlated with AMPK α1-isoform expression, but not LKB1 and CaMKKβ. LKB1 expression was sex dependent and lower in male than female muscles. CaMKKβ expression was very low in skeletal muscles and did not phosphorylate AMPK in muscle lysates. The higher AMPK activation in oxidative muscles is in line with the fact that activated AMPK maintains an oxidative phenotype. However, this could not be explained by LKB1 and CaMKKβ. These results suggest that the regulation of AMPK activation is more complex in muscle than in cultured cells. As AMPK has been proposed as a therapeutic target for several diseases, future research should consider AMPK isoform expression and localization, and energetic compartmentalization.NEW & NOTEWORTHY It is important to understand how AMP-activated kinase, AMPK, is regulated, as it is a potential therapeutic target for several diseases. AMPK is activated by liver kinase B1, LKB1, and calcium/calmodulin-dependent kinase kinase 2, CaMKKβ. In cultured cells, AMPK activation correlates with LKB1 expression. In contrast, we show that AMPK-activation was higher in oxidative than glycolytic muscle, without correlating with LKB1 or CaMKKβ expression. Thus, AMPK regulation is more complex in highly compartmentalized muscle cells.

Liver Kinase B1 (LKB1), encoded by Serine-Threonine Kinase 11 (STK11), is a master kinase that regulates cell migration, polarity, proliferation, and metabolism through downstream adenosine monophosphate-activated protein kinase (AMPK) and AMPK-related kinase signalling. Since genetic screens identified STK11 mutations in Peutz-Jeghers Syndrome, STK11 mutants have been implicated in tumourigenesis labelling it as a tumour suppressor. In support of this, several compounds reduce tumour burden through upregulating LKB1 signalling, and LKB1-AMPK agonists are cytotoxic to tumour cells. However, in certain contexts, its role in cancer is paradoxical as LKB1 promotes tumour cell survival by mediating resistance against metabolic and oxidative stressors. LKB1 deficiency has also enhanced the selectivity and cytotoxicity of several cancer therapies. Taken together, there is a need to develop LKB1-specific pharmacological compounds, but prior to developing LKB1 inhibitors, further work is needed to understand LKB1 activity and regulation. However, investigating LKB1 activity is strenuous as cell/tissue type, mutations to the LKB1 signalling pathway, STE-20-related kinase adaptor protein (STRAD) binding, Mouse protein 25-STRAD binding, splicing variants, nucleocytoplasmic shuttling, post-translational modifications, and kinase conformation impact the functional status of LKB1. For these reasons, guidelines to standardize experimental strategies to study LKB1 activity, associate proteins, spliced isoforms, post-translational modifications, and regulation are of upmost importance to the development of LKB1-specific therapies. Therefore, to assess the therapeutic relevancy of LKB1 inhibitors, this review summarizes the importance of LKB1 in cell physiology, highlights contributors to LKB1 activation, and outlines the benefits and risks associated with targeting LKB1.

Signal transduction by the Smad pathway elicits critical biological responses to many extracellular polypeptide factors, including TGFβ and bone morphogenetic protein. Regulation of Smad signaling imparts several cytoplasmic and nuclear mechanisms, some of which entail protein phosphorylation. Previous work established a protein complex between Smad4 and the scaffolding protein LKB1-interacting protein 1 (LIP1). LKB1 is a well studied tumor suppressor kinase that regulates cell growth and polarity. Here, we analyzed the LKB1-LIP1 and the Smad4-LIP1 protein complexes and found that LIP1 can self-oligomerize. We further demonstrate that LKB1 is capable of phosphorylating Smad4 on Thr77 of its DNA-binding domain. LKB1 inhibits Smad4 from binding to either TGFβ- or bone morphogenetic protein-specific promoter sequences, which correlates with the negative regulatory effect LKB1 exerts on Smad4-dependent transcription. Accordingly, LKB1 negatively regulates TGFβ gene responses and epithelial-mesenchymal transition. Thus, LKB1 and LIP1 provide negative control of TGFβ signaling.

BackgroundWe reported that zinc neurotoxicity, a key mechanism of ischemic neuronal death, was mediated by poly ADP-ribose polymerase (PARP) over-activation following NAD+/ATP depletion in cortical cultures. Because AMP-activated protein kinase (AMPK) can be activated by ATP depletion, and AMPK plays a key role in excitotoxicity and ischemic neuronal death, we examined whether AMPK could be involved in zinc neurotoxicity in mouse cortical neuronal cultures.ResultsCompound C, an AMPK inhibitor, significantly attenuated zinc-induced neuronal death. Activation of AMPK was detected beginning 2 h after a 10-min exposure of mouse cortical neurons to 300 μM zinc, although a significant change in AMP level was not detected until 4 h after zinc treatment. Thus, AMPK activation might not have been induced by an increase in intracellular AMP in zinc neurotoxicity. Furthermore, we observed that liver kinase B1 (LKB1) but not Ca2+/calmodulin-dependent protein kinase kinase β (CaMKKβ), was involved in AMPK activation. Although STO-609, a chemical inhibitor of CaMKKβ, significantly attenuated zinc neurotoxicity, zinc-induced AMPK activation was not affected, which suggested that CaMKKβ was not involved in AMPK activation. Knockdown of LKB1 by siRNA significantly reduced zinc neurotoxicity, as well as zinc-induced AMPK activation, which indicated a possible role for LKB1 as an upstream kinase for AMPK activation. In addition, mRNA and protein levels of Bim, a pro-apoptotic Bcl-2 family member, were noticeably increased by zinc in an AMPK-dependent manner. Finally, caspase-3 activation in zinc-induced neuronal death was mediated by LKB1 and AMPK activation.ConclusionsThe results suggested that AMPK mediated zinc-induced neuronal death via up-regulation of Bim and activation of caspase-3. Rapid activation of AMPK was detected after exposure of cortical neuronal cultures to zinc, which was induced by LKB1 activation but not increased intracellular AMP levels or CaMKKβ activation. Hence, blockade of AMPK in the brain may protect against zinc neurotoxicity, which is likely to occur after acute brain injury.

Aberrant cell metabolism is rapidly establishing itself as a critical hallmark of human malignancies. Cancer cells are faced with huge metabolic demands to support rapid tumor growth, yet are commonly starved for nutrients. In response, cancer cells hijack alternative signaling pathways during these times of energy and metabolic stress to sustain viability. Metastatic epithelial ovarian cancer (EOC) cells are faced with additional stressors during transcoelomic spread, such as detachment from a matrix substratum and inhospitable conditions in peritoneal fluid. However, EOC cells have a natural ability to aggregate when in suspension to form multicellular aggregates, or spheroids, which supports a survival advantage for cells when transiting the peritoneal space during metastatic progression. Therefore, we utilize an in vitro spheroid culture model system to investigate signaling pathways altered in EOC cells that may be implicated in ovarian cancer pathobiology and promote metastasis. For example, we have shown that spheroid formation induces cellular quiescence and autophagy, two disparate processes which promote EOC cell survival and resistance to platinum-based chemotherapeutics. In addition, we discovered that EOC spheroids have significantly reduced mitochondrial activity and ATP levels compared with matched proliferating adherent cells. Liver kinase B1 (LKB1) acts as a chief responder to intracellular stress due to reduced energy and nutrients by eliciting general growth suppression during these starvation-like conditions. Thus, we hypothesized that LKB1 activity is increased in EOC spheroids to promote tumor cell dormancy and cell survival. Although the STK11 gene encoding LKB1 is heterozygously deleted in 84% of serous ovarian tumors, we demonstrate that almost all ovarian tumor cells and established EOC cell lines retain intact LKB1 expression. In fact, LKB1 protein expression increases when EOC cells form spheroids and this coincides with induced serine-428 phosphorylation, a modification that is required for LKB1 growth suppressive activity. To address the potential functional requirement of LKB1 in EOC spheroids, we first performed transient knockdown of STK11 to block LKB1 expression. Indeed, reduced LKB1 renders spheroids susceptible to cell death and increases sensitivity to carboplatin. Next, we utilized Cas9-mediated genome editing of the STK11 locus to completely ablate LKB1 expression in HEYA8 and OVCAR8 cells. STK11-knockout HEYA8 and OVCAR8 cells yielded significantly decreased spheroid number and viability compared with parental cell lines. In a reciprocal fashion, forced re-expression of LKB1 in CaOV3 and TOV21G cells—two EOC cell lines which harbor inactivating STK11 mutations—reduces cell growth and colony formation in proliferating adherent culture. Proliferation and dispersion of CaOV3-LKB1 and TOV21G-LKB1 cells from re-attached spheroids are also reduced. Taken together, LKB1 has growth suppressive effects in EOC cells, yet it serves the additional purpose to promote cell survival in spheroids. The canonical target of LKB1 is AMP-activated protein kinase (AMPK), which is thought to elicit the majority of LKB1 growth suppressive effects during stress metabolism signaling. As expected, AMPK phosphorylation at threonine-172 is also induced upon spheroid formation. Using STK11-knockout EOC cells, however, we demonstrate that LKB1 is not required to phosphorylate AMPK in spheroids; more importantly, knockdown of PRKAA1 encoding the catalytic alpha-subunit of AMPK has no effect on spheroid cell viability. Thus, our results suggest that LKB1 utilizes alternative mechanisms to regulate the dormancy phenotype in EOC spheroids. Future work will entail direct experiments testing whether LKB1-mediated stress metabolism signaling has the potential to promote EOC metastasis and recurrence of chemo-resistant disease. Citation Format: Trevor G. Shepherd, Yudith Ramos Valdes, Teresa Peart, Meera Shah, Gabriel E. DiMattia. Stress management: LKB1 controls growth and survival of dormant epithelial ovarian cancer spheroid cells. [abstract]. In: Proceedings of the AACR Special Conference on Advances in Ovarian Cancer Research: Exploiting Vulnerabilities; Oct 17-20, 2015; Orlando, FL. Philadelphia (PA): AACR; Clin Cancer Res 2016;22(2 Suppl):Abstract nr B51.

SUMOylation regulates LKB1 localization and its oncogenic activity in liver cancer

Liver kinase B1 (LKB1) is a serine/threonine kinase that functions as a tumor suppressor and regulates cell polarity, proliferation, and metabolism. Mutations in LKB1 are associated with Peutz-Jeghers syndrome as well as sporadic cervical and lung cancers. Although LKB1-null mice develop invasive endometrial cancers, the role and regulation of LKB1 in the pathogenesis of human endometrial cancer are not well defined and are the focus of these studies. LKB1 protein and messenger RNA (mRNA) expression levels were evaluated in high-grade and low-grade endometrioid endometrial cancer (EEC) and cell lines by reverse transcriptase-polymerase chain reaction analysis, Western blot analysis, and immunohistochemistry. Mutational and promoter analyses of the LKB1 gene (serine/threonine kinase 11 [STK11]) were performed to identify the mechanisms that contribute to the loss of LKB1 in high-grade EEC. Analysis of the LKB1 gene in low-grade and high-grade EECs revealed no genetic mutations, suggesting that alterations in LKB1 transcription may be responsible for LKB1 protein loss in high-grade EEC. Analysis of the LKB1 promoter revealed 4 putative tumor protein 53 (p53) binding sites. Quantitative chromatin immunoprecipitation demonstrated that p53 bound directly to 1 of these sites and increased LKB1 promoter activity 140-fold. LKB1 promoter activity, mRNA, and protein levels were suppressed after silencing of p53 with small interfering RNA and were elevated in cells that overexpressed p53. Levels of p53 mRNA and protein expression were decreased in high-grade EEC and were positively correlated with LKB1 protein levels (Spearman correlation, r=0.601; P<.001). LKB1 is a direct transcriptional target of p53. The loss of wild-type p53 in high-grade EEC may contribute to the LKB1 loss observed in these more aggressive tumors.

Most epithelial ovarian cancer (EOC) patients with metastatic disease initially respond to cytotoxic chemotherapy, yet almost all will relapse with resistant disease. Thus, improving patient outcomes will require novel approaches to limit metastasis and overcome chemo-resistance. Liver Kinase B1 (LKB1), encoded by the STK11 gene, is a key intracellular regulator of metabolic stress and is considered a putative tumor suppressor in some cancers. However, we have demonstrated that LKB1 is intact and required for EOC cell viability and growth in an in vitro spheroid model of ovarian cancer metastasis. We propose that LKB1 signaling enables malignant EOC cells to maintain viability and survive in metabolically challenging environments like that encountered during intraperitoneal metastasis. To further investigate the therapeutic potential of targeting LKB1 activity in metastatic EOC, we generated STK11-knockout cell lines—normal FT190 cells, and EOC cell lines OVCAR8, HeyA8, and iOvCa147—using CRISPR technology. STK11KO resulted in decreased malignant properties of EOC cells in vitro, including clonogenicity and anchorage-independent growth; however, loss of LKB1 in FT190 cells had no effect on cell proliferation, clonogenicity, or anchorage-independent growth, indicating LKB1 does not likely act as a tumor suppressor in EOC. Loss of LKB1 sensitized EOC cells to the growth-inhibiting effects of specific metabolic stresses. OVCAR8-STK11KO cells were more sensitive to nutrient deprivation in adherent culture, and to carboplatin and paclitaxel treatment in spheroid culture, as compared with OVCAR8 cells. Among the three EOC cell lines, STK11KO yielded variable sensitivity to inhibition of mitochondrial ATP production via oligomycin treatment. Interestingly, STK11KO did not affect induction of AMP-activated protein kinase (AMPK) phosphorylation in EOC spheroids, indicating that metabolic stress signaling to support EOC cell survival in spheroids during metastasis may occur via alternative pathways. In support of our previous knockdown results, EOC spheroids completely lacking LKB1 had markedly impaired growth in suspension culture compared to parental cell controls. In contrast, FT190 spheroids exhibited rapid cell attrition in spheroid culture regardless of LKB1 status. These results indicate that LKB1 may be specifically required in EOC cells to evade anoikis during metastatic spread. Finally, to test directly whether loss of LKB1 activity affects the metastatic potential of EOC cells, we performed intraperitoneal injections of OVCAR8-STK11KO and HeyA8-STK11KO cells with their respective parental cell controls. Loss of LKB1 in both aggressive EOC cell lines exhibited a dramatic reduction on tumor burden. STK11KO significantly decreased the establishment of large, solid tumor masses, reduced adhesion of OVCAR8 tumor nodules, and even changed the metastatic trajectory of HeyA8 cells with evidence of tumor cell growth only as a thin layer on peritoneal walls. Histologic analysis revealed evidence of extensive necrosis in STK11KO tumors, which was likely the major contributor to reduced tumor burden. These results strongly indicate that loss of LKB1 activity abrogates the metabolic stress response necessary during EOC metastasis both in spheroids and establishment of intraperitoneal tumors. Overall, LKB1 or its AMPK-independent signaling mediators represent unique yet very potent therapeutic vulnerabilities in metastatic EOC. Citation Format: Adrian Buensuceso, Yudith R. Valdes, Rene Figueredo, Gabriel E. DiMattia, Trevor G. Shepherd. The metabolic stress mediator LKB1 is required for ovarian cancer metastasis. [abstract]. In: Proceedings of the AACR Conference: Addressing Critical Questions in Ovarian Cancer Research and Treatment; Oct 1-4, 2017; Pittsburgh, PA. Philadelphia (PA): AACR; Clin Cancer Res 2018;24(15_Suppl):Abstract nr A12.

Oltipraz, a cancer chemopreventive agent, has an anti-steatotic effect via liver X receptor-α (LXRα) inhibition. Here we have assessed the biological activity of a major metabolite of oltipraz (M2) against liver steatosis and steatohepatitis and the underlying mechanism(s). Blood biochemistry and histopathology were assessed in high-fat diet (HFD)-fed mice treated with M2. An in vitroHepG2 cell model was used to study the mechanism of action. Immunoblotting, real-time PCR and luciferase reporter assays were performed to measure target protein or gene expression levels. M2 treatment inhibited HFD-induced steatohepatitis and diminished oxidative stress in liver. It increased expression of genes encoding proteins involved in mitochondrial fuel oxidation. Mitochondrial DNA content and oxygen consumption rate were enhanced. Moreover, M2 treatment repressed activity of LXRα and induction of its target genes, indicating anti-lipogenic effects. M2 activated AMP-activated protein kinase (AMPK). Inhibition of AMPK by over-expression of dominant negative AMPK (DN-AMPK) or by Compound C prevented M2 from inducing genes for fatty acid oxidation and repressed sterol regulatory element binding protein-1c (SREBP-1c) expression. M2 activated liver kinase B1 (LKB1) and increased the AMP/ATP ratio. LKB1 knockdown failed to reverse target protein modulations or AMPK activation by M2, supporting the proposal that both LKB1 and increased AMP/ATP ratio contribute to its anti-steatotic effect. M2 inhibited liver steatosis and steatohepatitis by enhancing mitochondrial fuel oxidation and inhibiting lipogenesis. These effects reflected activation of AMPK elicited by increases in LKB1 activity and AMP/ATP ratio.

Viruses normally reprogram the host cell metabolic pathways as well as metabolic sensors to facilitate their persistence. The serine-threonine liver kinase B1 (LKB1) is a master upstream kinase of 5'-AMP-activated protein kinase (AMPK) that senses the energy status and therefore regulates the intracellular metabolic homeostasis. Previous studies showed that AMPK restricts Kaposi's sarcoma-associated herpesvirus (KSHV) lytic replication in endothelial cells during primary infection and promotes primary effusion lymphoma (PEL) cell survival. However, the role of LKB1 in KSHV lytic reactivation and KSHV-associated malignancies is unclear. In this study, we found that LKB1 is phosphorylated or activated in KSHV-positive PEL cells. Mechanistically, KSHV-encoded vCyclin mediated LKB1 activation in PEL cells, as vCyclin knockout ablated, while vCyclin overexpression enhanced LKB1 activation. Furthermore, knockdown of LKB1 inactivated AMPK and induced KSHV reactivation, as indicated by the increased expression of viral lytic genes and the increased virions in supernatants. Accordingly, AMPK inhibition by functional knockdown or a pharmacologic inhibitor, Compound C, promoted KSHV reactivation in PEL cells. Furthermore, inhibition of either LKB1 or AMPKα1 efficiently induced cell death by apoptosis of PEL cells both in vitro and in vivo. Together, these results identify LKB1 as a vulnerable target for PEL, which could be potentially exploited for treating other virus-associated diseases.IMPORTANCEKaposi's sarcoma-associated herpesvirus (KSHV) is an oncogenic virus associated with several human cancers, such as primary effusion lymphoma (PEL). Here, we showed that serine-threonine liver kinase B1 (LKB1), upstream of 5' AMP-activated protein kinase (AMPK), is activated by KSHV-encoded vCyclin and maintains KSHV latency in PEL cells. Inhibition of either LKB1 or AMPK enhances KSHV lytic replication from latency, which at least partially accounts for PEL cell death by apoptosis. Compound C, a potent AMPK inhibitor, induced KSHV reactivation and efficiently inhibited PEL progression in vivo. Thus, our work revealed that LKB1 is a potential therapeutic target for KSHV-associated cancers.

Purpose: Liver kinase B1 (LKB1), also known as serine/threonine kinase 11, was considered as a tumor suppressor, which exhibited anti-cancer activity in a variety of cancers. However, the effect of LKB1 in thyroid cancer remains unclear.Methods: In the study, MTT assay, colony formation assay, flow cytometry, western blot analysis, wound healing assay, transwell assays, quantitative real-time PCR, HUVEC migration assay, ELISA assay, tube formation assay and nude mice xenograft were used to investigate the anti-cancer capacity of LKB1 in thyroid cancer in vitro and in vivo.Results: In the present study, we found that the expression of LKB1 was lower in thyroid cancer tissues and cell lines, compared with the adjacent normal tissue and thyroid epithelial cell. After construction of stable clone cells with ectopic LKB1 overexpression, the findings revealed that LKB1 overexpression exerted anti-proliferative and pro-apoptotic property in thyroid cancer TPC-1 and BCPAP cells. In addition, LKB1 overexpression could inhibit migration and invasion, downregulate MMP2 and MMP9 expressions, and reverse EMT in thyroid cancer cells. Furthermore, overexpression of LKB1 attenuated HUVEC recruitment, decreased the expression of VEGFA and inhibited the formation of new vessels in thyroid cancer cells. To validate the underlying mechanism of LKB1 in thyroid cancer, the results showed that LKB1 could positively regulate SIK1 in thyroid cancer TPC-1 and BCPAP cells. Additionally, the SIK1 inhibitor HG-9-91-01 could partially abrogate the anti-proliferative and anti-metastatic effect of LKB1, and reverse MET (mesenchymal-to-epithelial transition) mediated by LKB1 overexpression. Ultimately, the results in vivo revealed that LKB1 overexpression exhibited a strong inhibitory effect of tumorigenicity and presented anti-angiogenic characteristic in nude mice xenograft model.Conclusion: the results demonstrated that LKB1 could inhibit proliferation, metastasis phenotype and angiogenesis, and reverse EMT in thyroid cancer in vitro and vivo via the upregulation of SIK1, suggesting that LKB1 could be considered as a potential therapeutic target for the treatment of thyroid cancer.

POS0005 THE EFFECT OF LKB1 INHIBITION IN RA PATHOGENESIS

Effects of Panax notoginseng saponins on alleviating low shear induced endothelial inflammation and thrombosis via Piezo1 signalling