Circ-GGA3 promotes the biological functions of human lens epithelial cells depending on the regulation of miR-497-5p/SMAD4 axis.

The cause of posterior capsular opacification (PCO) is the dysfunction of lens epithelial cells (LECs). Circular RNA (circRNA) was found to regulate cell biological functions, including LECs. However, the role of circ-GGA3 in PCO formation is unclear. Quantitative real-time PCR was used to measure the expression of circ-GGA3, miR-497-5p and SMAD4. Cell proliferation, invasion and migration were determined via MTT assay, EdU staining, transwell assay and wound healing assay. The protein expression of epithelial-mesenchymal transition (EMT) markers, fibrosis markers, TGF-ß/SMAD pathway markers and SMAD4 were determined by western blot assay. The interaction between miR-497-5p and circ-GGA3 or SMAD4 was confirmed using dual-luciferase reporter assay. Circ-GGA3 was highly expressed in PCO patients, and its silencing inhibited the proliferation, invasion, migration, EMT process and fibrosis of TGF-ß2-induced LECs. Circ-GGA3 could sponge miR-497-5p to regulate SMAD4. Further experiments revealed that miR-497-5p inhibitor recovered the negative regulation of circ-GGA3 knockdown on the biological functions of TGF-ß2-induced LECs, and SMAD4 overexpression also abolished the suppressive effect of miR-497-5p. In addition, circ-GGA3/miR-497-5p/SMAD4 axis could activate the TGF-ß/SMAD pathway. Our results indicated that circ-GGA3 could enhance the biological functions of LECs, suggesting that circ-GGA3 might be a potential target for PCO therapy.

Inactivation of the three GGA genes in HeLa cells partially compromises lysosomal enzyme sorting.

The Golgi-localized, gamma-ear containing, ADP-ribosylation factor-binding proteins (GGAs 1, 2, and 3) are multidomain proteins that bind mannose 6-phosphate receptors (MPRs) at the Golgi and play a role, along with adaptor protein complex 1 (AP-1), in the sorting of newly synthesized lysosomal hydrolases to the endolysosomal system. However, the relative importance of the two types of coat proteins in this process is still unclear. Here, we report that inactivation of all three GGA genes in HeLa cells decreased the sorting efficiency of cathepsin D from 97% to 73% relative to wild-type, with marked redistribution of the cation-independent MPR from peripheral punctae to the trans-Golgi network. In comparison, GNPTAB-/- HeLa cells with complete inactivation of the mannose 6-phosphate pathway sorted only 20% of the cathepsin D. We conclude that the residual sorting of cathepsin D in the GGA triple-knockout cells is mediated by AP-1.

GGA3 interacts with L-type prostaglandin D synthase and regulates the recycling and signaling of the DP1 receptor for prostaglandin D2 in a Rab4-dependent mechanism.

Mechanisms controlling the recycling of G protein-coupled receptors (GPCRs) remain largely unclear. We report that GGA3 (Golgi-associated, γ adaptin ear containing, ADP-ribosylation factor-binding protein 3) regulates the recycling and signaling of the PGD2 receptor DP1 through a new mechanism. An endogenous interaction between DP1 and GGA3 was detected by co-immunoprecipitation in HeLa cells. The interaction was promoted by DP1 agonist stimulation, which was supported by increased DP1-GGA3 colocalization in confocal microscopy. Pulldown assays showed that GGA3 interacts with the intracellular loop 2 and C-terminus of DP1, whereas the receptor interacts with the VHS domain of GGA3. The Arf-binding deficient GGA3 N194A mutant had the same effect as wild-type GGA3 on DP1 trafficking, suggesting a new mechanism for GGA3 in recycling. Depletion of Rab4 inhibited the GGA3 effect on DP1 recycling, revealing a Rab4-dependent mechanism. Interestingly, depletion of L-PGDS (L-type prostaglandin synthase, the enzyme that produces the agonist for DP1) impaired the ability of GGA3 to mediate DP1 recycling, while GGA3 knockdown prevented L-PGDS from promoting DP1 recycling, indicating that both proteins function interdependently. A novel interaction was observed between co-immunoprecipitated endogenous L-PGDS and GGA3 proteins in HeLa cells, and in vitro using purified recombinant proteins. Redistribution of L-PGDS towards GGA3- and Rab4-positive vesicles was induced by DP1 activation. Silencing of GGA3 inhibited ERK1/2 activation following DP1 stimulation. Altogether, our data reveal a novel function for GGA3, in a newly described association with L-PGDS, in the recycling and signaling of a GPCR, namely DP1.

Methods to Investigate the ß-Arrestin-Mediated Control of ARF6 Activation to Regulate Trafficking and Actin Cytoskeleton Remodeling.

ADP-ribosylation factors (ARF) are GTPases that act to control the activation of numerous signaling events and cellular responses. The ARF6 isoform, present at the plasma membrane, can be activated by the angiotensin II type 1 receptor (AT1R), a process dependent upon ß-arrestin recruitment to the activated receptor. Here, we describe classical methods used to assess ß-arrestin-dependent activation of ARF6 following agonist stimulation of cells. In addition, because ARF6 and ß-arrestin can form a complex, we describe the procedures used to detect the interaction of ß-arrestin with this GTPase.

Up-regulated GGA3 promotes non-small cell lung cancer proliferation by regulating TrkA receptor.

BACKGROUND: GGA3 has been reported to be related to cellular events such as cell survival, cell migration and cell apoptosis through different molecular mechanisms, which imply the potential role in tumorigenesis. However, the function of GGA3 in non-small cell lung cancer (NSCLC) is not clear. This research aims to reveal the effect of GGA3 on NSCLC proliferation and its underlying mechanisms. METHODS: The mRNA expression of GGA3 and TrkA, and association between GGA3 and TrkA in NSCLC tissues were analyzed based on data from TCGA database. And the mRNA expression level of GGA3 in NSCLC cell lines was determined by qRT-PCR. Expression level of GGA3 in A549 cell was detected by qRT-PCR and western blot after transfected with pcDNA3.1-GGA3. Cell counting kit 8, transwell, and flow cytometry assays were performed to detect A549 cell proliferation, aggressiveness, and apoptosis. Western blot was applied to assess the protein expression during apoptosis and TrkA-AKT/ERK signaling pathway. RESULTS: High expression of GGA3 was presented in NSCLC tissues and cell lines. In addition, overexpression of GGA3 could promote proliferation, invasion, and migration of A549 cell, but inhibit the apoptosis of A549 cell. After depletion of GGA3, the expression of anti-apoptotic protein Bcl-2 was increased, and the expression of pro-apoptotic protein Bax and Active Caspase 3 were reduced. Moreover, we found the expression of TrkA, p-AKT and p-ERK in pcDNA3.1-GGA3 group were obviously up-regulated in contrast with the sham group, which suggested that the induced effect of GGA3 on NSCLC cells might be performed via the TrkA-AKT/ERK signaling pathway. CONCLUSIONS: Taken together, overexpressed GGA3 in NSCLC could promote the A549 cells tumorigenesis partly through TrkA-AKT/ERK signaling pathway, supplying a theoretical basis for revealing the mechanism for NSCLC.

BACE1 elevation engendered by GGA3 deletion increases ß-amyloid pathology in association with APP elevation and decreased CHL1 processing in 5XFAD mice.

BACKGROUND: ß-site amyloid precursor protein cleaving enzyme 1 (BACE1) is the rate-limiting enzyme in the production of amyloid beta (Aß), the toxic peptide that accumulates in the brains of Alzheimer's disease (AD) patients. Our previous studies have shown that the clathrin adaptor Golgi-localized γ-ear-containing ARF binding protein 3 (GGA3) plays a key role in the trafficking of BACE1 to lysosomes, where it is normally degraded. GGA3 depletion results in BACE1 stabilization both in vitro and in vivo. Moreover, levels of GGA3 are reduced and inversely related to BACE1 levels in post-mortem brains of AD patients. METHOD: In order to assess the effect of GGA3 deletion on AD-like phenotypes, we crossed GGA3 -/- mice with 5XFAD mice. BACE1-mediated processing of APP and the cell adhesion molecule L1 like protein (CHL1) was measured as well as levels of Aß42 and amyloid burden. RESULTS: In 5XFAD mice, we found that hippocampal and cortical levels of GGA3 decreased while BACE1 levels increased with age, similar to what is observed in human AD brains. GGA3 deletion prevented age-dependent elevation of BACE1 in GGA3KO;5XFAD mice. We also found that GGA3 deletion resulted in increased hippocampal levels of Aß42 and amyloid burden in 5XFAD mice at 12 months of age. While levels of BACE1 did not change with age and gender in GGAKO;5XFAD mice, amyloid precursor protein (APP) levels increased with age and were higher in female mice. Moreover, elevation of APP was associated with a decreased BACE1-mediated processing of CHL1 not only in 12 months old 5XFAD mice but also in human brains from subjects affected by Down syndrome, most likely due to substrate competition. CONCLUSION: This study demonstrates that GGA3 depletion is a leading candidate mechanism underlying elevation of BACE1 in AD. Furthermore, our findings suggest that BACE1 inhibition could exacerbate mechanism-based side effects in conditions associated with APP elevation (e.g. Down syndrome) owing to impairment of BACE1-mediated processing of CHL1. Therefore, therapeutic approaches aimed to restore GGA3 function and to prevent the down stream effects of its depletion (e.g. BACE1 elevation) represent an attractive alternative to BACE inhibition for the prevention/treatment of AD.

Regulation of Cell Migration and ß1 Integrin Trafficking by the Endosomal Adaptor GGA3.

The integrin family of cell adhesion receptors link extracellular matrices to intracellular signaling pathways and the actin cytoskeleton; and regulate cell migration, proliferation and survival in normal and diseased tissues. The subcellular location of integrin receptors is critical for their function and deregulated trafficking is implicated in various human diseases. Here we identify a role for Golgi-localized gamma-ear containing Arf-binding protein 3 (GGA3), in regulating trafficking of ß1 integrin. GGA3 knockdown reduces cell surface and total levels of α2, α5 and ß1 integrin subunits, inhibits cell spreading, reduces focal adhesion number, as well as cell migration. In the absence of GGA3, integrins are increasingly retained inside the cell, traffic toward the perinuclear lysosomal compartment and their degradation is enhanced. Integrin traffic and maintenance of integrin levels are dependent on the integrity of the Arf binding site of GGA3. Furthermore, sorting nexin 17 (SNX17), a critical regulator of integrin recycling, becomes mislocalized to enlarged late endosomes upon GGA3 depletion. These data support a model whereby GGA3, through its ability to regulate SNX17 endosomal localization and through interaction with Arf6 diverts integrins from the degradative pathway supporting cell migration.

Nuclear 82-kDa choline acetyltransferase decreases amyloidogenic APP metabolism in neurons from APP/PS1 transgenic mice.

Alzheimer disease (AD) is associated with increased amyloidogenic processing of amyloid precursor protein (APP) to ß-amyloid peptides (Aß), cholinergic neuron loss with decreased choline acetyltransferase (ChAT) activity, and cognitive dysfunction. Both 69-kDa ChAT and 82-kDa ChAT are expressed in cholinergic neurons in human brain and spinal cord with 82-kDa ChAT localized predominantly to neuronal nuclei, suggesting potential alternative functional roles for the enzyme. By gene microarray analysis, we found that 82-kDa ChAT-expressing IMR32 neural cells have altered expression of genes involved in diverse cellular functions. Importantly, genes for several proteins that regulate APP processing along amyloidogenic and non-amyloidogenic pathways are differentially expressed in 82-kDa ChAT-containing cells. The predicted net effect based on observed changes in expression patterns of these genes would be decreased amyloidogenic APP processing with decreased Aß production. This functional outcome was verified experimentally as a significant decrease in BACE1 protein levels and activity and a concomitant reduction in the release of endogenous Aß1-42 from neurons cultured from brains of AD-model APP/PS1 transgenic mice. The expression of 82-kDa ChAT in neurons increased levels of GGA3, which is involved in trafficking BACE1 to lysosomes for degradation. shRNA-induced decreases in GGA3 protein levels attenuated the 82-kDa ChAT-mediated decreases in BACE1 protein and activity and Aß1-42 release. Evidence that 82-kDa ChAT can enhance GGA3 gene expression is shown by enhanced GGA3 gene promoter activity in SN56 neural cells expressing this ChAT protein. These studies indicate a novel relationship between cholinergic neurons and APP processing, with 82-kDa ChAT acting as a negative regulator of Aß production. This decreased formation of Aß could result in protection for cholinergic neurons, as well as protection of other cells in the vicinity that are sensitive to increased levels of Aß. Decreasing levels of 82-kDa ChAT due to increasing age or neurodegeneration could alter the balance towards increasing Aß production, with this potentiating the decline in function of cholinergic neurons.