Golgi tethering factor golgin-97 suppresses breast cancer cell invasiveness by modulating NF-κB activity.

BACKGROUND: Golgin-97 is a tethering factor in the trans-Golgi network (TGN) and is crucial for vesicular trafficking and maintaining cell polarity. However, the significance of golgin-97 in human diseases such as cancer remains unclear. METHODS: We searched for a potential role of golgin-97 in cancers using Kaplan-Meier Plotter ( http://kmplot.com ) and Oncomine ( www.oncomine.org ) datasets. Specific functions of golgin-97 in migration and invasion were examined in golgin-97-knockdown and golgin-97-overexpressing cells. cDNA microarray, pathway analysis and qPCR were used to identify gene profiles regulated by golgin-97. The role of golgin-97 in NF-κB signaling pathway was examined by using subcellular fractionation, luciferase reporter assay, western blot analysis and immunofluorescence assay (IFA). RESULTS: We found that low expression of golgin-97 correlated with poor overall survival of cancer patients and was associated with invasiveness in breast cancer cells. Golgin-97 knockdown promoted cell migration and invasion, whereas re-expression of golgin-97 restored the above phenotypes in breast cancer cells. Microarray and pathway analyses revealed that golgin-97 knockdown induced the expression of several invasion-promoting genes that were transcriptionally regulated by NF-κB p65. Mechanistically, golgin-97 knockdown significantly reduced IκBα protein levels and activated NF-κB, whereas neither IκBα levels nor NF-κB activity was changed in TGN46- or GCC185-knockdown cells. Conversely, golgin-97 overexpression suppressed NF-κB activity and restored the levels of IκBα in golgin-97-knockdown cells. Interestingly, the results of Golgi-disturbing agent treatment revealed that the loss of Golgi integrity was not involved in the NF-κB activation induced by golgin-97 knockdown. Moreover, both TGN-bound and cytosolic golgin-97 inhibited NF-κB activation, indicating that golgin-97 functions as an NF-κB suppressor regardless of its subcellular localization. CONCLUSION: Our results collectively demonstrate a novel and suppressive role of golgin-97 in cancer invasiveness. We also provide a new avenue for exploring the relationship between the TGN, golgin-97 and NF-κB signaling in tumor progression.

Binding of the extreme carboxyl-terminus of PAK-interacting exchange factor ß (ßPIX) to myosin 18A (MYO18A) is required for epithelial cell migration.

The PAK2/ßPIX/GIT1 (p21-activated kinase 2/PAK-interacting exchange factor-ß/G protein-coupled receptor kinase-interactor 1) complex has been shown to distribute to both membrane ruffles and focal adhesions of cells, where it plays an important role in regulating focal adhesion turnover. However, the detailed mechanism underlying this regulation is largely unknown. We previously reported that MYO18Aα interacts via its carboxyl terminus with the PAK2/ßPIX/GIT1 complex through direct binding to ßPIX, and that knockdown of MYO18Aα in epithelial cells causes accumulation of the complex in focal adhesions and decreased cell migration ability (Hsu et al., 2010). The current study characterized the detailed MYO18Aα-ßPIX interaction mechanism and the biological significance of this interaction. We found that deletion of the carboxyl-terminal globular domain of MYO18Aα profoundly altered the cellular localization of ßPIX and inhibited cell migration. ßPIX interacts through its most carboxyl-terminus, PAWDETNL (639-646), with MYO18Aα and partially colocalized with MYO18Aα in membrane ruffles of cells, whereas ßPIX(1-638), a mutant with deletion of PAWDETNL, accumulated in focal adhesions. Both focal adhesion numbers and area in ßPIX(1-638)-expressing cells were greater than those in cells expressing wild-type ßPIX(FL). Further experiments using deletion mutants of MYO18A and ßPIX showed that disruption of MYO18A-ßPIX interaction not only impaired cell motility but also decreased Rac1 activity. Collectively, our data unravel the interaction regions between MYO18A and ßPIX and provide evidence for the critical role of this interaction in regulating cellular localization of ßPIX, Rac1 activity, and adhesion and migration in epithelial cells.

Selective downregulation of EGF receptor and downstream MAPK pathway in human cancer cell lines by active components partially purified from the seeds of Livistona chinensis R. Brown.

Deregulation of protein kinase-mediated signaling events is one of the major causes to malignant transformation. In this work, we tried to purify protein kinase inhibitory activity and antitumor activity from ethanol extracts of the seeds of Livistona chinensis R. Brown (LC), a traditional herb used for the treatment of nasopharyngeal carcinoma (NPC). Both activities were found to be co-purified in various chromatography steps, and a highly purified fraction, LC-X, was obtained and its biological effects were characterized further. LC-X inhibited the activities of various protein kinases in vitro, including PAK2, PKA, PKC, GSK-3alpha, CK2, mitogen-activated protein kinase (MAPK), and JNK1, with IC(50) between approximately 1 and 40microg/ml. The proliferation of two NPC (NPC-TW02 and -TW04) and one breast cancer (MCF-7) cell lines, but not the epidermoid (A431) and cervical (HeLa) carcinoma cell lines, were significantly blocked by LC-X at the dose of >50microg/ml. Cell cycle arrested at G(2)/M phase and apoptosis were detected in NPC-TW02 cells treated with LC-X for 24h. Further studies revealed that epidermal growth factor (EGF)-induced activation of epidermal growth factor receptor (EGFR) and MAPK could be potently inhibited by LC-X in both NPC-TW02 and A431cells in a dose-dependent manner. More interestingly, the level of EGFR protein detected by Western blot decreased drastically in LC-X-treated A431 and NPC-TW02 cells in a dose- and time-dependent fashion. Further analysis of the plasma membrane and cytosolic fractions from LC-X-treated and untreated A431 cells showed that a 170kDa protein selectively disappeared from the plasma membrane of LC-X-treated cells. The protein was identified as EGFR by MALDI-TOF mass spectrometry, indicating EGFR as a selective target for LC-X. Moreover, the electrophoretic mobility of purified EGFR in SDS-PAGE was altered dramatically post LC-X treatment, suggesting that LC-X may chemically modify EGFR. In conclusion, the active components with both antitumor and protein kinases inhibitor activities were highly purified from LC, which can inhibit the EGF signaling events mainly through EGFR modification. Blockage of the functions of EGFR may account for the antitumor activity of these active components.

Identification of MYO18A as a novel interacting partner of the PAK2/betaPIX/GIT1 complex and its potential function in modulating epithelial cell migration.

The p21-activated kinase (PAK) 2 is known to be involved in numerous biological functions, including the regulation of actin reorganization and cell motility. To better understand the mechanisms underlying this regulation, we herein used a proteomic approach to identify PAK2-interacting proteins in human epidermoid carcinoma A431 cells. We found that MYO18A, an emerging member of the myosin superfamily, is a novel PAK2 binding partner. Using a siRNA knockdown strategy and in vitro binding assay, we discovered that MYO18A binds to PAK2 through the betaPIX/GIT1 complex. Under normal conditions, MYO18A and PAK2 colocalized in lamellipodia and membrane ruffles. Interestingly, knockdown of MYO18A in cells did not prevent formation of the PAK2/betaPIX/GIT1 complex, but rather apparently changed its localization to focal adhesions. Moreover, MYO18A-depleted cells showed dramatic changes in morphology and actin stress fiber and membrane ruffle formation and displayed increases in the number and size of focal adhesions. Migration assays revealed that MYO18A-depleted cells had decreased cell motility, and reexpression of MYO18A restored their migration ability. Collectively, our findings indicate that MYO18A is a novel binding partner of the PAK2/betaPIX/GIT1 complex and suggest that MYO18A may play an important role in regulating epithelial cell migration via affecting multiple cell machineries.