CircLARP4 Suppresses Cell Proliferation, Invasion and Glycolysis and Promotes Apoptosis in Non-Small Cell Lung Cancer by Targeting miR-135b.

BACKGROUND: CircLARP4 is reported to act as a tumor suppressor in some cancers. However, the detailed roles and molecular basis of circLARP4 in non-small cell lung cancer (NSCLC) tumorigenesis are still unclear. The aim of the study is to explore the potential roles and molecular basis of circLARP4 in NSCLC tumorigenesis. MATERIALS AND METHODS: qRT-PCR was taken to detect circLARP4 and miR-135b expressions. MTT assay, transwell invasion assay and flow cytometry analysis were applied to evaluate cell proliferation, invasion and apoptosis, respectively. Glycolysis was assessed by measuring hexokinase2 (HK2) expression, glucose consumption and lactate production. Association between circLARP4 and miR-135a was examined by luciferase reporter and RIP assays. The changes of the phosphatase and tension homolog (PTEN)/protein kinase B (AKT)/hypoxia-inducible factor-1α (HIF-1α) pathway were evaluated by Western blot. The nude mouse xenograft models were applied to verify the regulation of circLARP4 in vivo. RESULTS: CircLARP4 was decreased in NSCLC tissues and cells. CircLARP4 overexpression blocked cell proliferation and invasion, and facilitated apoptosis in NSCLC cells. Meanwhile, circLARP4 overexpression suppressed glycolysis in NSCLC cells, as evidenced by the reduced HK2, glucose consumption and lactate production levels. Further analyses proved a downregulation of miR-135b by circLARP4 in a ceRNA-dependent manner in NSCLC cells. CircLARP4-mediated tumor suppression on NSCLC progression was partially overturned by overexpressing miR-135b. Moreover, we confirmed that circLARP4 had antitumor effect on xenograft tumors and downregulated miR-135b. Furthermore, circLARP4 overexpression inhibited the PTEN/AKT/HIF-1α pathway in NSCLC cells and xenograft tumors by downregulating miR-135b. CONCLUSION: Our findings suggested that circLARP4 suppressed NSCLC progression by sponging miR-135b through inactivation of the PTEN/AKT/HIF-1α pathway, which broadens our understanding concerning the roles of circLARP4 in NSCLC tumorigenesis.

Msi2 plays a carcinogenic role in esophageal squamous cell carcinoma via regulation of the Wnt/ß-catenin and Hedgehog signaling pathways.

Msi2 has been widely reported to be upregulated and strongly associated with fast progress and poor prognosis in many cancers. However, the expression and role of Msi2 in esophageal squamous cell carcinoma (ESCC) remain unknown. In this study, we found that Msi2 was upregulated in ESCC clinical samples, and was significantly associated with tumor size, differentiation status, and lymph node metastasis in ESCC patients. Multivariate Cox regression analysis showed that Msi2 was an independent predictor for disease-free survival (DFS) and overall survival (OS). Moreover, knockdown of Msi2 impaired ESCC cell proliferation, epithelial-mesenchymal transition (EMT) and migration, while overexpression of Msi2 promoted ESCC cell proliferation, EMT and migration in vitro. Animal experiments also confirmed that Msi2 promoted ESCC cell proliferation in vivo. Mechanistically, Msi2 promoted ESCC cell proliferation, EMT and migration via regulation of the Wnt/ß-catenin and Hedgehog (Hh) signaling pathways. Taken together, our study suggested that Msi2 could serve as a candidate for diagnosis and prognosis and as a potential therapeutic target in ESCC.

DDX23-Linc00630-HDAC1 axis activates the Notch pathway to promote metastasis.

Emerging studies demonstrated the roles of long non-coding RNAs (LncRNAs) are being implicated in the progression of many cancers. Here we report the discovery of a critical role for the linc00630 in the development of Non-Small-Cell Lung Cancers (NSCLCs). Screening from the microarray of six paired NSCLCs and adjacent non-tumor tissues, linc00630 showed a significantly higher RNA levels in NSCLCs. With the higher level confirmed in a separate cohort 90 NSCLCs patients, overexpressed of linc00630 also positive associated with tumor size, TNM tumor stage, lymph node status positive and overall patient outcomes. Linc00630 overexpression increased cell proliferation and metastasis in vitro and in vivo whereas linc00630 silencing had opposite effects. By RNA pull-down and mass spectrometry we identified Histone deacetylases 1 (HDAC1) and DEAD-box helicase 23 (DDX23) as the linc00630-binding protein that associated with mechanism of linc00630. DDX23 can specific bind with the promoter of Linc00630 to up-regulate the RNA level and high level of linc00630 strength the protein stability of HDAC1 to regulate the downstream pathway.Our study demonstrates the effectiveness of Linc00630 oligonucleotide-based promotion of NSCLCs metastasis and proliferation, illuminating a new basis of DDX23-Linc00630-HDAC1 signal axis for understanding its pathogenicity, which could be further developed as a valuable therapeutic strategy.

Pen-2 is dispensable for endoproteolysis of presenilin 1, and nicastrin-Aph subcomplex is important for both γ-secretase assembly and substrate recruitment.

γ-secretase is a protease complex with at least four components: presenilin, nicastrin (NCT), anterior pharynx-defective 1 (Aph-1), and presenilin enhancer 2 (Pen-2). In this study, using knockout cell lines and small interfering RNA technology, our data demonstrated that the disappeared presenilin 1 C-terminal fragment (PS1C) caused by knockdown of pen-2 or knockout of NCT or Aph-1 was recovered by the addition of proteasome inhibitors, indicating that Pen-2, as well as NCT and Aph-1α, is dispensable for presenilin endoproteolysis. Our data also demonstrate that the formation of the nicastrin-Aph-1 subcomplex plays not only an important role in γ-secretase complex assembly but also in recruiting substrate C-terminal fragment of amyloid precursor protein generated by ß-cleavage. Ablating any one component resulted in the instability of other components of the γ-secretase complex, and the presence of all three of the other components is required for full maturation of NCT.

Death receptor 6 induces apoptosis not through type I or type II pathways, but via a unique mitochondria-dependent pathway by interacting with Bax protein.

Cells undergo apoptosis through two major pathways, the extrinsic pathway (death receptor pathway) and the intrinsic pathway (the mitochondrial pathway). These two pathways can be linked by caspase-8-activated truncated Bid formation. Very recently, death receptor 6 (DR6) was shown to be involved in the neurodegeneration observed in Alzheimer disease. DR6, also known as TNFRSF21, is a relatively new member of the death receptor family, and it was found that DR6 induces apoptosis when it is overexpressed. However, how the death signal mediated by DR6 is transduced intracellularly is not known. To this end, we have examined the roles of caspases, apoptogenic mitochondrial factor cytochrome c, and the Bcl-2 family proteins in DR6-induced apoptosis. Our data demonstrated that Bax translocation is absolutely required for DR6-induced apoptosis. On the other hand, inhibition of caspase-8 and knockdown of Bid have no effect on DR6-induced apoptosis. Our results strongly suggest that DR6-induced apoptosis occurs through a new pathway that is different from the type I and type II pathways through interacting with Bax.

Residues at P2-P1 positions of epsilon- and zeta-cleavage sites are important in formation of beta-amyloid peptide.

Most of the Alzheimer's disease (AD)-linked mutations in amyloid precursor protein (APP), which cause abnormal production of beta-amyloid (Abeta), are localized at the major beta-secretase-and gamma-secretase cleavage sites. In this study, using an APP-knockout mouse neuronal cell line, our data demonstrated that at the P2-P1 positions of the epsilon-cleavage site at Abeta49 and the zeta-cleavage site at Abeta46, aromatic amino acids caused a strong reduction in total Abeta. On the other hand, residues with a long side chain caused a decrease in Abeta(40) and a concomitant increase in Abeta(42) and Abeta(38). These findings indicate that the structures of the substituting residues at these key positions strongly determine the efficiency and preference of gamma-secretase-mediated APP processing, which determines the ratio of different secreted Abeta species, a crucial factor in the disease development. Our findings provide new insight into the mechanisms of gamma-secretase-mediated APP processing and, specifically, into why most AD-linked APP mutations are localized at major gamma-secretase cleavage sites. This information may contribute to the development of methods of prevention and treatment of Alzheimer's disease aimed at modulating gamma-secretase activity.

The GxxxG motif in the transmembrane domain of AbetaPP plays an essential role in the interaction of CTF beta with the gamma-secretase complex and the formation of amyloid-beta.

Gamma-secretase-mediated processing of the amyloid-beta protein precursor (AbetaPP) is a crucial step in the formation of the amyloid-beta peptide (Abeta), but little is known about how the substrate AbetaPP interacts with the gamma-secretase complex. To understand the molecular events involved in gamma-secretase-mediated AbetaPP processing and Abeta formation, in the present study we determined the role of a well conserved GxxxG motif in the transmembrane domain of AbetaPP. Our data clearly demonstrate that substitution of aspartic acid for the key glycine residues in the GxxxG motif almost completely abolished the formation of Abeta. Furthermore, our data revealed that substitution of aspartic acid for the glycine in this GxxxG motif disrupts the interaction of AbetaPP with the gamma-secretase complex. Thus, the present study revealed an essential role for the GxxxG motif in the interaction of AbetaPP with the gamma-secretase complex and the formation of Abeta.

Effects of gamma-secretase cleavage-region mutations on APP processing and Abeta formation: interpretation with sequential cleavage and alpha-helical model.

Overwhelming evidence supports the amyloid hypothesis of Alzheimer's disease that stipulates that the relative level of the 42 amino acid beta-amyloid peptide (Abeta(42)) in relationship to Abeta(40) is critical to the pathogenesis of the disease. While it is clear that the multi-subunit gamma secretase is responsible for cleavage of the amyloid precursor protein (APP) into Abeta(42) and Abeta(40), the exact molecular mechanisms regulating the production of the various Abeta species remain elusive. To elucidate the underlying mechanisms, we replaced individual amino acid residues from positions 43 to 52 of Abeta with phenylalanine to examine the effects on the production of Abeta(40) and Abeta(42). All mutants, except for V50F, resulted in a decrease in total Abeta with a more prominent reduction in Abeta for residues 45, 48, and 51, following an every three residue repetition pattern. In addition, the mutations with the strongest reductions in total Abeta had the largest increases in the ratio of Abeta(42)/Abeta(40). Curiously, the T43F, V44F, and T48F mutations caused a striking decrease in the accumulation of membrane bound Abeta(46), albeit by a different mechanism. Our data suggest that initial cleavage of APP at the epsilon site is crucial in the generation of Abeta. The implicated sequential cleavage and an alpha-helical model may lead to a better understanding of the gamma-secretase-mediated APP processing and may also provide useful information for therapy and drug design aimed at altering Abeta production.

Both the N-terminal fragment and the protein-protein interaction domain (PDZ domain) are required for the pro-apoptotic activity of presenilin-associated protein PSAP.

Presenilin-associated protein (PSAP) was originally identified as a PS1-associated, PDZ domain protein. In a subsequent study, PSAP was found to be a mitochondrial apoptotic molecule. In this study, we cloned the PSAP gene and found that it is composed of 12 exons and localizes on chromosome 6. To better understand the structure and function of PSAP, we have generated a series of antibodies that recognize different regions of PSAP. Using these antibodies, we found that PSAP is expressed in four isoforms as a result of differential splicing of exon 8 in addition to the use of either the first or the second ATG codon as the start codon. We also found that all these isoforms are localized in the mitochondria and are pro-apoptotic. Furthermore, our data revealed that the PDZ domain and N-terminal fragment are required for the pro-apoptotic activity of PSAP.

The same gamma-secretase accounts for the multiple intramembrane cleavages of APP.

It has been hypothesized that different C-terminus of beta-amyloid peptide (Abeta) may be generated by different gamma-secretase activities. Recently, we have identified a new zeta-cleavage site at Abeta46, leading to an important finding that the C-terminus of Abeta is produced by a series of sequential cleavages. This finding prompted us to examine the effects of the known gamma-secretase inhibitors on different steps of the gamma-secretase-mediated sequential cleavages and specifically their effects on the formation and turnover of the intermediate Abeta(46). Our results demonstrate that some of the known inhibitors, such as L-685,458 and III-31C as well as inhibitors IV and V, inhibit the formation of secreted Abeta(40/42) by inhibiting the formation of the intermediate Abeta(46). However, most of the other inhibitors show no inhibitory effect on the formation of the intermediate Abeta(46), but rather inhibit the turnover of Abeta(46), resulting in its accumulation. In addition, the non-steroidal anti-inflammatory drugs (NSAIDs) ibuprofen and sulindac sulfide have no effect on the formation and turnover of Abeta(46), but rather modulate the ratio of secreted Abeta at a step after the formation of Abeta(40) and Abeta(42). Thus, our data strongly suggest that the multi-sequential intramembrane cleavages of amyloid precursor protein C (APP) are likely catalyzed by the same gamma-secretase.

Calpain inhibitor MDL28170 modulates Abeta formation by inhibiting the formation of intermediate Abeta46 and protecting Abeta from degradation.

The observations that three major cleavages within the transmembrane domain of APP, namely, the gamma-cleavage, -cleavage, and the newly identified zeta-cleavage, are involved in the generation of secreted Abeta40 and Abeta42 prompted us to determine how the calpain inhibitor III MDL 28170 influences these three cleavages and Abeta formation. With the use of a cell culture system, our data demonstrate that 1) at either high concentrations, or at a low range of concentrations, at early time points, MDL 28170 inhibits the formation of secreted Abeta40 and Abeta42. However, this effect is due to inhibition of the intermediate Abeta46 generation by zeta-cleavage and not due to direct inhibition of the gamma-cleavage that produces Abeta40/42 from Abeta46; 2) at low range of concentrations and at late time points, MDL 28170 causes an increase in secreted Abeta40/42 that likely results from inhibition of degradation of both the initial substrate, CTFbeta, and the final product, Abeta40/42, of gamma-secretase. These data strongly suggest that formation of Abeta46 is a key step in the gamma-secretase mediated generation of Abeta40/42 and provide a new target for the development of Abeta inhibitors. These data also suggest that calpain and related proteases, which are sensitive to MDL 28170, play an important role in the accumulation of secreted Abeta.

gamma-Cleavage is dependent on zeta-cleavage during the proteolytic processing of amyloid precursor protein within its transmembrane domain.

beta-Amyloid precursor protein apparently undergoes at least three major cleavages, gamma-, epsilon-, and the newly identified zeta-cleavage, within its transmembrane domain to produce secreted beta-amyloid protein (Abeta). However, the roles of epsilon- and zeta-cleavages in the formation of secreted Abeta and the relationship among these three cleavages, namely epsilon-, zeta-, and gamma-cleavages, remain elusive. We investigated these issues by attempting to determine the formation and turnover of the intermediate products generated by these cleavages, in the presence or absence of known gamma-secretase inhibitors. By using a differential inhibition strategy, our data demonstrate that Abeta(46) is an intermediate precursor of secreted Abeta. Our co-immunoprecipitation data also reveal that, as an intermediate, Abeta(46) is tightly associated with presenilin in intact cells. Furthermore, we identified a long Abeta species that is most likely the long sought after intermediate product, Abeta(49), generated by epsilon-cleavage, and this Abeta(49) is further processed by zeta- and gamma-cleavages to generate Abeta(46) and ultimately the secreted Abeta(40/42). More interestingly, our data demonstrate that gamma-cleavage not only occurs last but also depends on zeta-cleavage occurring prior to it, indicating that zeta-cleavage is crucial for the formation of secreted Abeta. Thus, we conclude that the C terminus of secreted Abeta is most likely generated by a series of sequential cleavages, namely first epsilon-cleavage which is then followed by zeta- and gamma-cleavages, and that Abeta(46) produced by zeta-cleavage is the precursor of secreted Abeta(40/42).

Identification of a new presenilin-dependent zeta-cleavage site within the transmembrane domain of amyloid precursor protein.

Gamma-secretase cleavage of beta-amyloid precursor protein (APP) is crucial in the pathogenesis of Alzheimer disease, because it is the decisive step in the formation of the C terminus of beta-amyloid protein (Abeta). To better understand the molecular events involved in gamma-secretase cleavage of APP, in this study we report the identification of a new intracellular long Abeta species containing residues 1-46 (Abeta46), which led to the identification of a novel zeta-cleavage site between the known gamma- and epsilon-cleavage sites within the transmembrane domain of APP. Our data clearly demonstrate that the new zeta-cleavage is a presenilin-dependent event. It is also noted that the new zeta-cleavage site at Abeta46 is the APP717 mutation site. Furthermore, we show that the new zeta-cleavage is inhibited by gamma-secretase inhibitors known as transition state analogs but less affected by inhibitors known as non-transition state gamma-secretase inhibitors. Thus, the identification of Abeta46 establishes a system to determine the specificity or the preference of the known gamma-secretase inhibitors by examining their effects on the formation or turnover of Abeta46.

The novel presenilin-1-associated protein is a proapoptotic mitochondrial protein.

Recent studies have suggested a possible role for presenilin proteins in apoptotic cell death observed in Alzheimer's disease. The mechanism by which presenilin proteins regulate apoptotic cell death is not well understood. Using the yeast two-hybrid system, we previously isolated a novel protein, presenilin-associated protein (PSAP) that specifically interacts with the C terminus of presenilin 1 (PS1), but not presenilin 2 (PS2). Here we report that PSAP is a mitochondrial resident protein sharing homology with mitochondrial carrier protein. PSAP was detected in a mitochondria-enriched fraction, and PSAP immunofluorescence was present in a punctate pattern that colocalized with a mitochondrial marker. More interestingly, overexpression of PSAP caused apoptotic death. PSAP-induced apoptosis was documented using multiple independent approaches, including membrane blebbing, chromosome condensation and fragmentation, DNA laddering, cleavage of the death substrate poly(ADP-ribose) polymerase, and flow cytometry. PSAP-induced cell death was accompanied by cytochrome c release from mitochondria and caspase-3 activation. Moreover, the general caspase inhibitor benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone, which blocked cell death, did not block the release of cytochrome c from mitochondria caused by overexpression of PSAP, indicating that PSAP-induced cytochrome c release was independent of caspase activity. The mitochondrial localization and proapoptotic activity of PSAP suggest that it is an important regulator of apoptosis.