Compound K protects MIN6N8 pancreatic β‐cells against palmitate‐induced apoptosis through modulating SAPK/JNK activation

Chronic elevation of NEFAs (non‐esterified fatty acids) due to insulin resistance and obesity has been shown to be associated with increased β‐cell apoptosis and with the aetiology of the reduced β‐cell mass of Type 2 diabetes. SAPK (stress‐activated protein kinase)/JNK (c‐Jun N‐terminal kinase) have been implicated in the control of apoptosis. C‐K [compound K; 20‐O‐β‐d ‐glucopyranosyl‐20(S)‐protopanaxadiol] is the main intestinal bacterial metabolite of protopanaxadiol ginsenosides. Currently, little is known about the effects of C‐K on β‐cells with the presence of NEFAs. The aim of the present study was to investigate the in vitro protective effect of C‐K on MIN6N8 mouse insulinoma β‐cells against NEFA‐induced apoptosis, as well as the modulating effect on SAPK/JNK activation. Our results have shown that C‐K inhibited the palmitate‐induced apoptosis through modulating SAPK/JNK activation. We conclude that C‐K protects against β‐cell death and that, by anti‐apoptotic activity, C‐K may contribute to the previously reported anti‐diabetic actions of ginseng.     

NR4A1 counteracts JNK activation incurred by ER stress or ROS in pancreatic β‐cells for protection

Sustained hyperglycaemia and hyperlipidaemia incur endoplasmic reticulum stress (ER stress) and reactive oxygen species (ROS) overproduction in pancreatic β‐cells. ER stress or ROS causes c‐Jun N‐terminal kinase (JNK) activation, and the activated JNK triggers apoptosis in different cells. Nuclear receptor subfamily 4 group A member 1 (NR4A1) is an inducible multi‐stress response factor. The aim of this study was to explore the role of NR4A1 in counteracting JNK activation induced by ER stress or ROS and the related mechanism. qPCR, Western blotting, dual‐luciferase reporter and ChIP assays were applied to detect gene expression or regulation by NR4A1. Immunofluorescence was used to detect a specific protein expression in β‐cells. Our data showed that NR4A1 reduced the phosphorylated JNK (p‐JNK) in MIN6 cells encountering ER stress or ROS and reduced MKK4 protein in a proteasome‐dependent manner. We found that NR4A1 increased the expression of cbl‐b (an E3 ligase); knocking down cbl‐b expression increased MKK4 and p‐JNK levels under ER stress or ROS conditions. We elucidated that NR4A1 enhanced the transactivation of cbl‐b promoter by physical association. We further confirmed that cbl‐b expression in β‐cells was reduced in NR4A1‐knockout mice compared with WT mice. NR4A1 down‐regulates JNK activation by ER stress or ROS in β‐cells via enhancing cbl‐b expression.     

ATF3 represses PDX-1 expression in pancreatic β-cells

The downregulation of PDX-1 expression plays an important role in development of type 2 diabetes. However, the negative regulator of PDX-1 expression is not well known. In this study, we analyzed the mouse PDX-1 promoter to characterize the effects of ATF3 on PDX-1 expression in pancreatic β-cells. Both thapsigargin treatment, an inducer of ER stress, and ATF3 expression decreased PDX-1 expression in pancreatic β-cells, MIN6N8. Furthermore, they also repressed the activity of −4.5 Kb promoter of mouse PDX-1 gene. Transfection studies with 5′ deleted-reporters showed that ATF3 repressed the activity of 0.9 Kb PDX-1 promoter, whereas it did not affect the activity of 0.7 Kb PDX-1 promoter, suggesting that ATF3 responsive element is located between the −903 and −702. An electrophoretic mobility shift assay and chromatin immunoprecipitation assay demonstrated that ATF3 binds directly to the promoter region spanning from −759 to −738. Moreover, mutation of the putative ATF/CRE site between −752 and −745 abrogated ATF3-mediated transrepression of the PDX-1 promoter. PDX-1 was decreased in MIN6N8 cells treated with high glucose or high palmitate, whereas ATF3 was increased, indicating that ATF3 plays a role in hyperglycemia or hyperlipidemia-mediated downregulation of PDX-1 expression. Collectively, these results demonstrate that ATF3 represses PDX-1 expression via binding to an ATF3-responsive element in its promoter, which plays an important role in suppression of pancreatic β-cells function.     

Expression of β‐1,4‐galactosyltransferase I in rat Schwann cells

Glycosylation is one of the most important post‐translational modifications. It is clear that the single step of β‐1,4‐galactosylation is performed by a family of β‐1,4‐galactosyltransferases (β‐1,4‐GalTs), and that each member of this family may play a distinct role in different tissues and cells. In the present study, real‐time PCR revealed that the β‐1,4‐GalT I mRNA reached peaks at 2 weeks after sciatic nerve crush and 3 days after sciatic nerve transection. Combined in situ hybridization for β‐1,4‐GalT I mRNA and immunohistochemistry for S100 showed that β‐1,4‐GalT I mRNAs were mainly located in Schwann cells after sciatic nerve injury. In conclusion, β‐1,4‐GalT I might play important roles in Schwann cells during the regeneration and degeneration of the injured sciatic nerve. In other pathology, such as inflammation, we found that LPS administration affected β‐1,4‐GalT I mRNA expression in sciatic nerve in a time‐ and dose‐dependent manner, and β‐1,4‐GalT I mRNA is expressed mainly in Schwann cells. These results indicated that β‐1,4‐GalT I plays an important role in the inflammation reaction induced by intraperitoneal injection of LPS. Similarly, we found that β‐1,4‐GalT I in Schwann cells in vitro was affected in a time‐ and concentration‐dependent manner in response to LPS stimulation. All these results suggest that β‐1,4‐GalT I play an important role in Schwann cells in vivo and vitro during pathology. In addition, β‐1,4‐GalT I production was drastically suppressed by U0126 (ERK inhibitor), SB203580 (p38 inhibitor), or SP600125 (SAPK/JNK inhibitor), which indicated that Schwann cells which regulated β‐1,4‐GalT I expression after LPS stimulation were via ERK, SAPK/JNK, and P38 MAP kinase signal pathways. J. Cell. Biochem. 108: 75–86, 2009. © 2009 Wiley‐Liss, Inc.     

The Orphan Nuclear Receptor NR4A1 Protects Pancreatic β-Cells from Endoplasmic Reticulum (ER) Stress-mediated Apoptosis

The role of NR4A1 in apoptosis is controversial. Pancreatic β-cells often face endoplasmic reticulum (ER) stress under adverse conditions such as high free fatty acid (FFA) concentrations and sustained hyperglycemia. Severe ER stress results in β-cell apoptosis. The aim of this study was to analyze the role of NR4A1 in ER stress-mediated β-cell apoptosis and to characterize the related mechanisms. We confirmed that upon treatment with the ER stress inducers thapsigargin (TG) or palmitic acid (PA), the mRNA and protein levels of NR4A1 rapidly increased in both MIN6 cells and mouse islets. NR4A1 overexpression in MIN6 cells conferred resistance to cell loss induced by TG or PA, as assessed by MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assay, and TUNEL assays indicated that NR4A1 overexpression also protected against ER stress-induced apoptosis. This conclusion was further confirmed by experiments exploiting siRNA to knockdown NR4A1 expression in MIN6 cells or exploiting NR4A1 knock-out mice. NR4A1 overexpression in MIN6 cells reduced C/EBP homologous protein (CHOP) expression and Caspase3 activation induced by TG or PA. NR4A1 overexpression in MIN6 cells or mouse islets resulted in Survivin up-regulation. A critical regulatory element was identified in Survivin promoter (−1872 bp to −1866 bp) with a putative NR4A1 binding site; ChIP assays demonstrated that NR4A1 physically associates with the Survivin promoter. In conclusion, NR4A1 protects pancreatic β-cells against ER stress-mediated apoptosis by up-regulating Survivin expression and down-regulating CHOP expression, which we termed as “positive and negative regulation.”     

Thapsigargin down-regulates protein levels of GRP78/BiP in INS-1E cells

Pancreatic β-cells have a well-developed endoplasmic reticulum (ER) and express large amounts of chaperones and protein disulfide isomerases (PDI) to meet the high demand for synthesis of proteins. We have observed an unexpected decrease in chaperone protein level in the β-cell model INS-1E after exposure to the ER stress inducing agent thapsigargin. As these cells are a commonly used model for primary β-cells and has been shown to be vulnerable to ER stress, we hypothesize these cells are incapable of mounting a chaperone defense upon activation of ER stress. To investigate the chaperone expression during an ER stress response, induced by thapsigargin in INS-1E cells, we used quantitative mass spectrometry based proteomics. The results displayed a decrease of GRP78/BiP, PDIA3 and PDIA6. Decrease of GRP78/BiP was verified by Western blot and occurred in parallel with enhanced levels of p-eIF2α and CHOP. In contrast to INS-1E cells, GRP78/BiP was not decreased in MIN6 cell or rat and mouse islets after thapsigargin exposure. Investigation of the decreased protein levels of GRP78/BiP indicates that this is not a consequence of reduced mRNA expression. Rather the reduction results from the combined effect of reduced protein synthesis and enhanced proteosomal degradation and possibly also degradation via autophagy. Induction of ER stress with thapsigargin leads to lower protein levels of GRP78/BiP, PDIA3 and PDIA6 in INS-1E cells which may contribute to the susceptibility of ER stress in this β-cell model.     

Inhibition of palmitate‐induced GADD34 expression augments apoptosis in mouse insulinoma cells (MIN6)

Saturated fatty acids like palmitate induce endoplasmic reticulum (ER) stress in pancreatic beta‐cells, an event linked to apoptotic loss of β‐cells in type 2 diabetes. Sustained activation of the ER stress response leads to expression of growth arrest and DNA damage‐inducible protein 34 (GADD34), a regulatory subunit of protein phosphatase 1. In the present study, we have used small interfering RNA in order to knockdown GADD34 expression in insulin‐producing MIN6 cells prior to induction of ER stress by palmitate and evaluated its consequences on RNA‐activated protein kinase‐like ER‐localized eIF2alpha kinase (PERK) signalling and apoptosis. Salubrinal, a specific inhibitor of eukaryotic initiation factor 2α (eIF2α) dephosphorylation, was used as a comparison. Salubrinal treatment augmented palmitate‐induced ER stress and increased GADD34 levels. Both GADD34 knockdown and salubrinal treatment potentiated the cytotoxic effects of palmitate as evidenced by increased DNA fragmentation and activation of caspase 3, with the fundamental difference that the former did not involve enhanced levels of GADD34. The data from this study suggest that sustained activation of PERK signalling and eIF2α phosphorylation sensitizes insulin‐producing MIN6 cells to lipoapoptosis independently of GADD34 expression levels. Copyright © 2014 John Wiley & Sons, Ltd.     

ATF3 negatively regulates adiponectin receptor 1 expression

Adiponectin is an adipocyte-derived hormone that has antidiabetic and antiatherogenic effects through two membrane receptors, adiponectin receptor 1 (AdipoR1) and adiponectin receptor 2 (AdipoR2). Although it has been reported that the expression of AdipoR1 and AdipoR2 is regulated under physiological and pathophysiological states, their regulation is largely unknown. Previously, we demonstrated that endoplasmic reticulum (ER) stress or obesity-inducible ATF3 negatively regulates the expression of adiponectin and AdipoR2. Here, we investigated the regulation of another adiponectin receptor, AdipoR1 by ATF3, to determine if ATF3 may contribute to impairment of adiponectin signaling by repressing the expression of both adiponectin and adiponectin receptors. We found that treatment with thapsigargin, a stimulator of ATF3 expression as an inducer of ER stress, decreased AdipoR1 expression in insulin-sensitive cells (HepG2, C2C12) and insulin secreting cells (MIN6N8). Furthermore, overexpression of lentivirus carrying-ATF3 decreased AdipoR1 expression in those cells, demonstrating that ATF3 downregulates AdipoR1 expression. Next, we investigated the effects of ATF3 on human AdipoR1 promoter activity and identified an ATF3-responsive region in the promoter. Both thapsigargin treatment and ATF3 expression repressed AdipoR1 promoter activity. Transfection studies using mutant constructs containing 5′-deletions in the human AdipoR1 promoter revealed that putative ATF/CRE site is located between the −248 and −224, TGACGCGG. Chromatin immunoprecipitation assay demonstrated that ATF3 directly binds to human AdipoR1 promoter spanning from −248 to −224. Finally, deletion of the putative ATF/CRE site abrogated ATF3-mediated transrepression of the AdipoR1 promoter. Importantly, ATF3 expression was increased in hyperglycemia or TNF-α-treated C2C12 cells in which AdipoR1 expression was decreased, suggesting that ATF3 may contribute to downregulation of AdipoR1 by hyperglycemia and TNF-α. Collectively, these results demonstrate that ATF3 negatively regulates human AdipoR1 expression via binding to an ATF3-responsive region in the promoter, which plays an important role in attenuation of adiponectin signaling and induction of insulin resistance.     

Expression of the hyperphosphorylated tau attenuates ER stress-induced apoptosis with upregulation of unfolded protein response

The neural dysfunction in Alzheimer's disease (AD) could arise from endoplasmic reticulum (ER) stress and deficits of the unfolded protein response (UPR). To explore whether tau hyperphosphorylation, a hallmark of AD brain pathologies, plays a role in ER stress-induced alterations of cell viability, we established cell lines with stable expression of human tau (HEK293/tau) or the vector (HEK293/vec) and treated the cells with thapsigargin (TG), an ER stress inducer. We observed that the HEK293/tau cells were more resistant than the HEK293/vec cells to the TG-induced apoptosis, importantly, a time dependent increase of tau phosphorylation at Thr205 and Thr231 sites was positively correlated with the inhibition of apoptosis. We also observed that expression of tau upregulated phosphorylation of PERK, eIF2 and IRE1 with an increased cleavage of ATF6 and ATF4. The potentiation of UPR was also detected in HEK293/tau cells treated with other ER stress inducers, including staurosporine, camptothecin and hydrogen peroxide, in which a suppressed apoptosis was also shown. Our data suggest that tau hyperphosphorylation could attenuate the ER stress-induced apoptosis with the mechanism involving upregulation of UPR system.     

小鼠脑组织及培养神经元Neuro-2a 在内质网应激反应时的基因表达谱分析

内质网是真核细胞的重要细胞器。某些细胞内外因素如病原体感染等能引起从内质网到胞浆和胞核的信号传导途径活化,即内质网应激反应。但是,目前国内外尚无针对内质网应激反应的基因表达谱分析报道。本研究中,用3种已报道的内质网应激反应诱导剂,包括蛋白质糖基化抑制剂衣霉素(tunicamycin)、内质网Ca ²⁺-ATPases抑制剂毒胡萝卜素（thapsigargin）和乙脑病毒(Japanese encephalitis virus, JEV),分别处理小鼠颅腔和小鼠脑神经瘤细胞（Neuro-2a）,试剂处理组与未处理组的第二代RNA测序分析发现,衣霉素、毒胡萝卜素和乙脑病毒在体外和体内均引起分子伴侣基因Hsp70表达上调,诱导内质网应激反应。衣霉素、毒胡萝卜素和乙脑病毒体外处理诱导的内质网应激反应信号通路中,基因差异表达相似性高于体内处理组。乙脑病毒和糖基化抑制剂衣霉素体内外处理,主要诱导内质网应激反应的非折叠蛋白质反应信号通路,引起相关基因Atf4、Bip、Edem和Perk等表达上调。内质网Ca ²⁺-ATPases抑制剂毒胡萝卜素主要诱导内质网超负荷反应,激活NF-κB信号通路。乙脑病毒诱导的内质网应激反应相关差异表达基因数量最多,体外与体内合计有40种。乙脑病毒体内外处理上调的基因包括Bax、Casp12、Atf4、Bip、Edem和Perk等,下调的基因包括Sec23/24、Nef、Svip和Jnk等。糖基化抑制剂衣霉素体内外处理上调基因包括Gadd34、Atf4、Ermani和Bip等,下调基因包括Grp94、Atf6、Sec23/24和Nef等。内质网Ca ^-2+-ATPases抑制剂毒胡萝卜素体内外处理上调的基因包括Sec61、Trap和Ask1等。衣霉素、毒胡萝卜素和乙脑病毒体内外处理也通过内质网应激反应,调控与炎症或凋亡相关的MAPK信号通路和P53信号通路。本研究首次通过使用3种内质网应激反应诱导剂分别处理小鼠和细胞,揭示了体内外内质网应激反应引起的基因表达谱变化,为内质网应激反应相关疾病的治疗提供了新思路。     

Inhibition of x‐box binding protein 1 reduces tunicamycin‐induced apoptosis in aged murine macrophages

Endoplasmic reticulum (ER) stress is induced by the accumulation of unfolded and misfolded proteins in the ER. Although apoptosis induced by ER stress has been implicated in several aging‐associated diseases, such as atherosclerosis, it is unclear how aging modifies ER stress response in macrophages. To decipher this relationship, we assessed apoptosis in macrophages isolated from young (1.5–2 months) and aged (16–18 months) mice and exposed the cells to the ER stress inducer tunicamycin. We found that aged macrophages exhibited more apoptosis than young macrophages, which was accompanied by reduced activation of phosphorylated inositol‐requiring enzyme‐1 (p‐IRE1α), one of the three key ER stress signal transducers. Reduced gene expression of x‐box binding protein 1 (XBP1), a downstream effector of IRE1α, enhanced p‐IRE1α levels and reduced apoptosis in aged, but not young macrophages treated with tunicamycin. These findings delineate a novel, age‐dependent interaction by which macrophages undergo apoptosis upon ER stress, and suggest an important protective role of IRE1α in aging‐associated ER stress‐induced apoptosis. This novel pathway may not only be important in our understanding of longevity, but may also have important implications for pathogenesis and potential treatment of aging‐associated diseases in general.     

Endoplasmic reticulum stress‐induced exosomal miR‐27a‐3p promotes immune escape in breast cancer via regulating PD‐L1 expression in macrophages

Immune escape of breast cancer cells contributes to breast cancer pathogenesis. Tumour microenvironment stresses that disrupt protein homeostasis can produce endoplasmic reticulum (ER) stress. The miRNA‐mediated translational repression of mRNAs has been extensively studied in regulating immune escape and ER stress in human cancers. In this study, we identified a novel microRNA (miR)‐27a‐3p and investigated its mechanistic role in promoting immune evasion. The binding affinity between miR‐27a‐3p and MAGI2 was predicted using bioinformatic analysis and verified by dual‐luciferase reporter assay. Ectopic expression and inhibition of miR‐27a‐3p in breast cancer cells were achieved by transduction with mimics and inhibitors. Besides, artificial modulation of MAGI2 and PTEN was done to explore their function in ER stress and immune escape of cancer cells. Of note, exosomes were derived from cancer cells and co‐cultured with macrophages for mechanistic studies. The experimental data suggested that ER stress biomarkers including GRP78, PERK, ATF6, IRE1α and PD‐L1 were overexpressed in breast cancer tissues relative to paracancerous tissues. Endoplasmic reticulum stress promoted exosome secretion and elevated exosomal miR‐27a‐3p expression. Elevation of miR‐27a‐3p and PD‐L1 levels in macrophages was observed in response to exosomes‐overexpressing miR‐27a‐3p in vivo and in vitro. miR‐27a‐3p could target and negatively regulate MAGI2, while MAGI2 down‐regulated PD‐L1 by up‐regulating PTEN to inactivate PI3K/AKT signalling pathway. Less CD4⁺, CD8⁺ T cells and IL‐2, and T cells apoptosis were observed in response to co‐culture of macrophages and CD3⁺ T cells. Conjointly, exosomal miR‐27a‐3p promotes immune evasion by up‐regulating PD‐L1 via MAGI2/PTEN/PI3K axis in breast cancer.     

Lentinan protects pancreatic β cells from STZ‐induced damage

Pancreatic β‐cell death or dysfunction mediated by oxidative stress underlies the development and progression of diabetes mellitus (DM). In this study, we evaluated the effect of lentinan (LNT), an active ingredient purified from the bodies of Lentinus edodes, on pancreatic β‐cell apoptosis and dysfunction caused by streptozotocin (STZ) and the possible mechanisms implicated. The rat insulinoma cell line INS‐1 were pre‐treated with the indicated concentration of LNT for 30 min. and then incubated for 24 hrs with or without 0.5 mM STZ. We found that STZ treatment causes apoptosis of INS‐1 cells by enhancement of intracellular reactive oxygen species (ROS) accumulation, inducible nitric oxide synthase (iNOS) expression and nitric oxide release and activation of the c‐jun N‐terminal kinase (JNK) and p38 mitogen‐activated protein kinase (MAPK) signalling pathways. However, LNT significantly increased cell viability and effectively attenuated STZ‐induced ROS production, iNOS expression and nitric oxide release and the activation of JNK and p38 MAPK in a dose‐dependent manner in vitro. Moreover, LNT dose‐dependently prevented STZ‐induced inhibition of insulin synthesis by blocking the activation of nuclear factor kappa beta and increasing the level of Pdx‐1 in INS‐1 cells. Together these findings suggest that LNT could protect against pancreatic β‐cell apoptosis and dysfunction caused by STZ and therefore may be a potential pharmacological agent for preventing pancreatic β‐cell damage caused by oxidative stress associated with diabetes.