Knockdown of GPSM1 Inhibits the Proliferation and Promotes the Apoptosis of B-Cell Acute Lymphoblastic Leukemia Cells by Suppressing the ADCY6-RAPGEF3-JNK Signaling Pathway.

B-cell acute lymphoblastic leukemia (B-ALL) is the common type of blood cancer. Although the remission rate has increased, the current treatment options for B-ALL are usually related to adverse reactions and recurrence, so it is necessary to find other treatment options. G protein signaling modulator 1 (GPSM1) is one of several factors that affect the basic activity of the G protein signaling system, but its role in B-ALL has not yet been clarified. In this study, we analyzed the expression of GPSM1 in the Oncomine database and found that the GPSM1 levels were higher in B-ALL cells than in peripheral blood mononuclear cells (PBMCs). Analyses of the Gene Expression Profiling Interactive Analysis (GEPIA) demonstrated that patients with high GPSM1 levels had shorter survival times than those with low levels. Additionally, gene set enrichment analysis (GSEA) suggested that GPSM1 was positively correlated with proliferation, G protein-coupled receptor (GPCR) ligand binding, Gαs signaling and calcium signaling pathways. In further experiments, GPSM1 was found to be highly expressed in Acute lymphoblastic leukemia (ALL) cell lines, and downregulation of GPSM1 inhibited proliferation and promoted cell cycle arrest and apoptosis in BALL-1 and Reh cells. Moreover, knockdown of GPSM1 suppressed ADCY6 and RAPGEF3 expression in BALL-1 and Reh cells. Furthermore, we reported that GPSM1 regulated JNK expression via ADCY6-RAPGEF3. The present study demonstrates that GPSM1 promotes tumor growth in BALL-1 and Reh cells by modulating ADCY6-RAPGEF3-JNK signaling.

Genetic variations in GPSM3 associated with protection from rheumatoid arthritis affect its transcript abundance.

G protein signaling modulator 3 (GPSM3) is a regulator of G protein-coupled receptor signaling, with expression restricted to leukocytes and lymphoid organs. Previous genome-wide association studies have highlighted single-nucleotide polymorphisms (SNPs; rs204989 and rs204991) in a region upstream of the GPSM3 transcription start site as being inversely correlated to the prevalence of rheumatoid arthritis (RA)-this association is supported by the protection afforded to Gpsm3-deficient mice in models of inflammatory arthritis. Here, we assessed the functional consequences of these polymorphisms. We collected biospecimens from 50 volunteers with RA diagnoses, 50 RA-free volunteers matched to the aforementioned group and 100 unmatched healthy young volunteers. We genotyped these individuals for GPSM3 (rs204989, rs204991), CCL21 (rs2812378) and HLA gene region (rs6457620) polymorphisms, and found no significant differences in minor allele frequencies between the RA and disease-free cohorts. However, we identified that individuals homozygous for SNPs rs204989 and rs204991 had decreased GPSM3 transcript abundance relative to individuals homozygous for the major allele. In vitro promoter activity studies suggest that SNP rs204989 is the primary cause of this decrease in transcript levels. Knockdown of GPSM3 in THP-1 cells, a human monocytic cell line, was found to disrupt ex vivo migration to the chemokine MCP-1.

Knockdown of RhoGDIα induces apoptosis and increases lung cancer cell chemosensitivity to paclitaxel.

This study aimed to investigate the effects of RhoGDIα knockdown on apoptosis and the chemosensitivity of lung cancer cells to paclitaxel. The signaling proteins involved were also assessed. RhoGDIα expression was assessed by RT-PCR, Western blotting and immunohistochemistry. Apoptosis was determined by flow cytometric assessment, and cell viability was measured with the MTT assay. Phosphorylation levels of signaling proteins, ERK, JNK, Akt, Bad and IκBα were tested by Western blotting and immunohistochemistry. Positivity for RhoGDIα in lung cancer tissues was significantly higher than in paracancerous tissues. Downregulation of RhoGDIα was associated with significantly increased apoptosis and repressed cell viability. This effect could be due to the consequent upregulation of p-JNK, as well as decreased levels of p-ERK, p-Bad and p-IκBα. Knockdown of RhoGDIα strengthened the effect on apoptosis and inhibition of cell viability induced by paclitaxel treatment. This chemosensitization effect could be a result of the intensification of pro-apoptotic JNK activation, and repression of anti-apoptotic p-ERK, p-Bad and p-IκBα expression stimulated by paclitaxel. In summary, our study indicated that RhoGDIα could be a promising therapeutic target, and the combination of RhoGDIα siRNA and paclitaxel might be a valuable potential therapy for lung cancer treatment.

Expression profile of RhoGDI2 in lung cancers and role of RhoGDI2 in lung cancer metastasis.

Rho GDP dissociation inhibitors (RhoGDIs) are important regulators of the GTP hydrolase activity and biological functions of Rho GTPases. RhoGDI2 has been shown to be a metastasis suppressor in bladder cancer and several other cancers. However, the underlying mechanism, effector targets, and the cognate biological functions of RhoGDI2 are not fully understood. To investigate the possible role of RhoGDI2 in lung cancer tumorigenesis and metastasis, the expression pattern of RhoGDI2 in various lung cancer tissue samples and lung cancer-derived cell lines were profiled at both mRNA and protein levels. Furthermore, possible interplay between PI3K/Akt/mTOR pathway activation/inhibition and RhoGDI2 signalling is examined in lung cancer-related cell lines. Our results suggest that RhoGDI2 is likely to be involved in lung tumor malignancy and metastasis.

RhoGDI signaling provides targets for cancer therapy.

Rho GDP-Dissociation Inhibitors (RhoGDIs) are important regulators of the Rho family of small GTPases. The expression of RhoGDIs is altered in a variety of cancers and they have been shown to mediate several processes during tumorigenesis and cancer progression. Using examples of RhoGDI-mediated signaling and expression patterns in endothelial cells as well as pancreatic, breast, and bladder cancer, the multitude of potential cancer therapeutic targets presented by a better understanding of their function is illustrated. Several novel therapeutic strategies are proposed for intervening in RhoGDI signaling, and potential complications arising from their implementation are discussed.

Involvement of RhoGDI2 in the resistance of colon cancer cells to 5-fluorouracil.

BACKGROUND/AIMS: The acquisition of resistance to 5-FU is one of the most prominent obstacles to successful chemotherapy, and the mechanisms underlying the resistance are not fully understood. The aim of this study is to identify novel mediators of 5-FU resistance in colon cancer cells. METHODOLOGY: LoVo colon cancer cells were induced to 5-FU resistance in vitro. The global protein profiles between LoVo and its 5-FU resistant derivative cell line LoVo/5-FU were analyzed by two dimensional gel electrophoresis-based comparative proteomics. The identified proteins expression was confirmed by Western blot analysis. The cytotoxicity of 5-FU was measured in LoVo/5-FU after knockdown of RhoGDI2 (one of the identified protien). RESULTS: Three differentially expressed proteins were identified. RhoGDI2 and CapG were upregulated, whereas proapoptotic protein Maspin was down-regulated in LoVo/5-FU and validated by Western blotting. Furthermore, knockdown of RhoGDI2 expression by transfection with the RhoGDI2-specific siRNA significantly reduced the resistance to 5-FU in LoVo/5-FU (p < 0.05). CONCLUSIONS: These novel data suggest that these differentially expressed proteins may contribute to the development of 5-FU resistance in colon cancer cells.

Neuromedin U is regulated by the metastasis suppressor RhoGDI2 and is a novel promoter of tumor formation, lung metastasis and cancer cachexia.

Most deaths from urinary bladder cancer are owing to metastatic disease. A reduction in Rho GDP Dissociation Inhibitor 2 (RhoGDI2) protein has been associated with increased risk of metastasis in patients with locally advanced bladder cancer, whereas in animal models, RhoGDI2 reconstitution in cells without expression results in lung metastasis suppression. Recently, we noted an inverse correlation between tumor RhoGDI2 and Neuromedin U (NMU) expression, suggesting that NMU might be a target of the lung metastasis suppressor effect of RhoGDI2. Here we evaluated whether NMU is regulated by RhoGDI2 and is functionally important in tumor progression. We used small interfering RNA knockdown of endogenous RhoGDI2 in poorly tumorigenic and non-metastatic human bladder cancer T24 cells and observed increased NMU RNA expression. Although NMU overexpression did not increase the monolayer growth of T24 or related T24T poorly metastatic human bladder cancer cells, it did augment anchorage-independent growth for the latter. Overexpression of NMU in T24 and T24T cells significantly promoted tumor formation of both cell lines in nude mice, but did not alter the growth rate of established tumors. Furthermore, NMU-overexpressing xenografts were associated with lower animal body weight than control tumors, indicating a possible role of NMU in cancer cachexia. NMU overexpression in T24T cells significantly enhanced their lung metastatic ability. Bioluminescent in vivo imaging revealed that lung metastases in T24T grew faster than the same tumors in the subcutaneous microenvironment. In conclusion, NMU is a RhoGDI2-regulated gene that appears important for tumorigenicity, lung metastasis and cancer cachexia, and thus a promising therapeutic target in cancer.

Disruption of RhoGDI and RhoA regulation by a Rac1 specificity switch mutant.

Rho family GTPases are important regulators of the actin cytoskeleton. Activation of these proteins can be promoted by guanine nucleotide exchange factors containing Dbl and Pleckstrin homology domains resulting in membrane insertion of a Rho family member, whereas the inactive GDP-bound form is sequestered primarily in the cytoplasm, bound to the guanosine dissociation inhibitor RhoGDI. Dominant interfering variants of Rac1, but not Cdc42, inhibit beta1 integrin-promoted uptake of Yersinia pseudotuberculosis. Unexpectedly, we found that the Rac1(W56F) guanine nucleotide exchange factors specificity switch mutant blocked invasin-promoted uptake as well as Cdc42-dependent uptake of enteropathogenic Escherichia coli. Fluorescence resonance energy transfer experiments demonstrated that Rac1(W56F) retained the ability to be loaded with GTP, bind a downstream effector, and interact with RhoGDI. Mutational analyses of intragenic suppressors and coexpression studies demonstrated that binding of the Rac1(W56F) mutant to RhoGDI appeared to play a role in the inhibition of uptake. As RhoGDI inhibits RhoA, overactivation of RhoA may account for the uptake interference caused by Rac1(W56F). Consistent with this model, a dominant interfering form of RhoA restored significant uptake in the presence of the Rac1(W56F) mutant but had no effect on another interfering Rac1 form. Furthermore, the cellular GTP-RhoA level was elevated by the presence of Rac1(W56F) mutant protein. These data are consistent with the proposition that Rac1(W56F) blocks invasin-promoted uptake by preventing RhoGDI from inactivating RhoA. We conclude that RhoGDI allows cross-talk between Rho family members that promote potentially antagonistic processes, and disruption of this cross-talk can interfere with invasin-promoted uptake.

Rho GDP dissociation inhibitors as potential targets for anticancer treatment.

The Rho GDP dissociation inhibitors (RhoGDIs) are a major class of regulators of Rho GTPases and play essential roles in normal cell growth and malignant transformation. Although RhoGDIs are known to inhibit Rho activities, recent studies indicate that RhoGDIs can also act as positive regulators through their ability to target Rho GTPases to specific subcellular membranes or to protect the GTPases from degradation by caspases. RhoGDIs are aberrantly expressed in human tumors and this may contribute to Rho-induced cancer progression. This review will discuss the dual roles of RhoGDIs in the regulation of Rho GTPases, highlighting a possible role in regulating tumorigenicity. In addition, the potential for targeting RhoGDIs for anticancer therapy will be discussed.

D4-GDI, a Rho GTPase regulator, promotes breast cancer cell invasiveness.

D4-GDI is a Rho GDP dissociation inhibitor that is widely expressed in hematopoietic cells. Its possible expression and function in breast cancer cells has not been described. Here, we found that D4-GDI is expressed in a panel of breast cancer cell lines, but not in benign-derived mammary epithelial cells. Knockdown of D4-GDI expression in MDA-MB-231 cells by RNA interference blocks cell motility and invasion. The cells lacking D4-GDI grown on Matrigel revert to a normal breast epithelial phenotype characterized by the formation of cavitary structures. Silencing D4-GDI expression inhibits beta1-integrin expression and cell-matrix adhesion. Reintroduction of D4-GDI fully restored both beta1-integrin expression and cellular invasion. Knockdown of D4-GDI in BT549 cells results in a similar effect. These results show that D4-GDI modulates breast cancer cell invasive activities.

Biochemical suppression of small-molecule inhibitors: a strategy to identify inhibitor targets and signaling pathway components.

Identification of small-molecule targets remains an important challenge for chemical genetics. We report an approach for target identification and protein discovery based on functional suppression of chemical inhibition in vitro. We discovered pirl1, an inhibitor of actin assembly, in a screen conducted with cytoplasmic extracts. Pirl1 was used to partially inhibit actin assembly in the same assay, and concentrated biochemical fractions of cytoplasmic extracts were added to find activities that suppressed pirl1 inhibition. Two activities were detected, separately purified, and identified as Arp2/3 complex and Cdc42/RhoGDI complex, both known regulators of actin assembly. We show that pirl1 directly inhibits activation of Cdc42/RhoGDI, but that Arp2/3 complex represents a downstream suppressor. This work introduces a general method for using low-micromolar chemical inhibitors to identify both inhibitor targets and other components of a signaling pathway.