Uremia Impedes Skeletal Myocyte Myomixer Expression and Fusogenic Activity: Implication for Uremic Sarcopenia.

In patients with chronic kidney disease (CKD), skeletal muscle mass and function are known to occasionally decline. However, the muscle regeneration and differentiation process in uremia has not been extensively studied. In mice with CKD induced by adenine-containing diet, the tibialis anterior muscle injured using a barium chloride injection method recovered poorly as compared to control mice. In the cultured murine skeletal myocytes, stimulation with indoxyl sulfate (IS), a representative uremic toxin, morphologically jeopardized the differentiation, which was counteracted by L-ascorbic acid (L-AsA) treatment. Transcriptome analysis of cultured myocytes identified a set of genes whose expression was down-regulated by IS stimulation but up-regulated by L-AsA treatment. Gene silencing of myomixer, one of the genes in the set, impaired myocyte fusion during differentiation. By contrast, lentiviral overexpression of myomixer compensated for a hypomorphic phenotype caused by IS treatment. The split-luciferase technique demonstrated that IS stimulation negatively affected early myofusion activity that was rescued by L-AsA treatment. Lastly, in mice with CKD compared with control mice, myomixer expression in the muscle tissue in addition to the muscle weight after the injury was reduced, both of which were restored with L-AsA treatment. Collectively, data showed that the uremic milieu impairs the expression of myomixer and impedes the myofusion process. Considering frequent musculoskeletal injuries in uremic patients, defective myocyte fusion followed by delayed muscle damage recovery could underlie their muscle loss and weakness.

Downregulation of PGRMC1 accelerates differentiation and fusion of a human trophoblast cell line.

Mononuclear cytotrophoblasts (CTs) differentiate and fuse to form multinuclear syncytiotrophoblasts (STs), which produce human chorionic gonadotropin (hCG) and progesterone to maintain pregnancy. Impaired differentiation and fusion of CTs to form STs are associated with hypertensive disorders of pregnancy and fetal growth restriction. Progesterone receptor membrane component 1 (PGRMC1) is a multifunctional single transmembrane heme-binding protein. We previously demonstrated that downregulation of PGRMC1 promotes endometrial stromal cell differentiation (decidualization). Here, we explored the role of PGRMC1 in trophoblast differentiation and fusion. PGRMC1 expression was lower in STs than in CTs of first-trimester placental tissues. PGRMC1 expression in BeWo cells (a trophoblast-derived choriocarcinoma cell line) decreased upon dibutyryl-cAMP (db-cAMP)-induced differentiation. Both inhibition and knockdown of PGRMC1 stimulated hCG production in the presence of db-cAMP. Furthermore, a quantitative cell fusion assay we developed revealed that inhibition and knockdown of PGRMC1 enhanced db-cAMP-stimulated cell fusion. Peroxisome proliferator-activated receptor γ (PPARγ) agonists decreased PGRMC1 expression and stimulated the cell fusion in BeWo cells. These findings suggest that downregulation of PGRMC1 expression in part through activation of PPARγ during trophoblast differentiation promotes hCG production and cell fusion for formation and maintenance of placental villi during pregnancy.

Protective effects of hachimijiogan (HJG), a Japanese Kampo medicine, on cancer cachectic muscle wasting in mice.

Myogenesis is required to generate skeletal muscle tissue and to maintain skeletal muscle mass. Decreased myogenesis under various pathogenic conditions results in muscular atrophy. Through a small screening of Japanese traditional (Kampo) medicines, hachimijiogan (HJG) was shown to promote the myogenic differentiation of C2C12 myoblasts through the upregulation of myogenin. In tumor-bearing cancer-cachectic mice, HJG was also found to have a protective effect against cancer-cachectic muscle wasting. This effect was significant when HJG was administered in combination with aerobic exercise by treadmill running. Moreover, HJG ameliorated the cellular atrophy of C2C12 myotubes induced by treatment with conditioned medium derived from a colon-26 cancer cell culture. In addition, HJG suppressed H2O2-dependent myotube atrophy, suggesting that HJG could reverse the atrophic phenotypes by eliminating reactive oxygen species.

Novel cell-based system to assay cell-cell fusion during myotube formation.

A live assay tool has been established to uncover the precise molecular mechanisms underlying complex cell fusion events in myoblasts. The novel cell-based assay, HiMy (HiBiT-based myoblast fusion), utilizes a recently developed split-luciferase technology. The assay successfully detected cell fusion in differentiating C2C12 myoblast cultures. This allowed us to measure mixing of the cytoplasm, which occurred several hours after the initiation of C2C12 differentiation. Unlike what was reported earlier, the fusion was detected a few hours after the initiation of differentiation. Thus, this assay is sensitive enough to monitor fusion events before they become detectable using conventional methods. Furthermore, a panel of laboratory compounds, including a variety of inhibitors of cellular enzymes or activities, were assayed using the HiMy assay. Lovastatin, a cholesterol biogenesis inhibitor, decreased HiMy activity by approximately 50%. In contrast, mevalonolactone, a precursor for cholesterol synthesis, increased fusion activity. These results confirmed the previous finding that the amount of cellular cholesterol positively correlates with the rate of myoblast fusion during myogenesis. These results indicate that the novel cell fusion assay is a quick, accurate, and robust method to monitor intercellular fusion events.

Radiosensitization Effect of Gold Nanoparticles on Plasmid DNA Damage Induced by Therapeutic MV X-rays.

Gold nanoparticles (AuNPs) can be used with megavolt (MV) X-rays to exert radiosensitization effects, as demonstrated in cell survival assays and mouse experiments. However, the detailed mechanisms are not clear; besides physical dose enhancement, several chemical and biological processes have been proposed. Reducing the AuNP concentration while achieving sufficient enhancement is necessary for the clinical application of AuNPs. Here, we used positively charged (+) AuNPs to determine the radiosensitization effects of AuNPs combined with MV X-rays on DNA damage in vitro. We examined the effect of low concentrations of AuNPs on DNA damage and reactive oxygen species (ROS) generation. DNA damage was promoted by 1.4 nm +AuNP with dose enhancement factors of 1.4 ± 0.2 for single-strand breaks and 1.2 ± 0.1 for double-strand breaks. +AuNPs combined with MV X-rays induced radiosensitization at the DNA level, indicating that the effects were physical and/or chemical. Although -AuNPs induced similar ROS levels, they did not cause considerable DNA damage. Thus, dose enhancement by low concentrations of +AuNPs may have occurred with the increase in the local +AuNP concentration around DNA or via DNA binding. +AuNPs showed stronger radiosensitization effects than -AuNPs. Combining +AuNPs with MV X-rays in radiation therapy may improve clinical outcomes.

Aerobic Exercise Ameliorates Cancer Cachexia-Induced Muscle Wasting through Adiponectin Signaling.

Cachexia is a multifactorial syndrome characterized by muscle loss that cannot be reversed by conventional nutritional support. To uncover the molecular basis underlying the onset of cancer cachectic muscle wasting and establish an effective intervention against muscle loss, we used a cancer cachectic mouse model and examined the effects of aerobic exercise. Aerobic exercise successfully suppressed muscle atrophy and activated adiponectin signaling. Next, a cellular model for cancer cachectic muscle atrophy using C2C12 myotubes was prepared by treating myotubes with a conditioned medium from a culture of colon-26 cancer cells. Treatment of the atrophic myotubes with recombinant adiponectin was protective against the thinning of cells through the increased production of p-mTOR and suppression of LC3-II. Altogether, these findings suggest that the activation of adiponectin signaling could be part of the molecular mechanisms by which aerobic exercise ameliorates cancer cachexia-induced muscle wasting.

The SUN2-nesprin-2 LINC complex and KIF20A function in the Golgi dispersal.

The morphology of the Golgi complex is influenced by the cellular context, which strictly correlates with nuclear functions; however, the mechanism underlying this association remains elusive. The inner nuclear membrane SUN proteins, SUN1 and SUN2, have diverse functions together with the outer nuclear membrane nesprin proteins, which comprise the LINC complex. We found that depletion of SUN1 leads to Golgi complex dispersion with maintenance of ministacks and retained function for vesicle transport through the Golgi complex. In addition, SUN2 associates with microtubule plus-end-directed motor KIF20A, possibly via nesprin-2. KIF20A plays a role in the Golgi dispersion in conjunction with the SUN2-nesprin-2 LINC complex in SUN1-depleted cells, suggesting that SUN1 suppresses the function of the SUN2-nesprin-2 LINC complex under a steady-state condition. Further, SUN1-knockout mice, which show impaired cerebellar development and cerebellar ataxia, presented altered Golgi morphology in Purkinje cells. These findings revealed a regulation of the Golgi organization by the LINC complex.

Median nerve injury does not contribute to early onset of decreased grip strength due to repetitive reaching and grasping tasks in rats.

BACKGROUND: Workplace risk factors, such as repetitive tasks, can cause work-related musculoskeletal disorders. In a rat model, decreased grip strength and median nerve injury develop following repetitive reaching and grasping tasks, involving negligible force. OBJECTIVE: We investigated whether median nerve injury is involved in the early onset of decreased grip strength due to such tasks METHODS: Sprague-Dawley rats were divided into: non-task-performing (0-week) and task-performing (1-, 2-, and 3-week) groups. After an initial training period, the task-performing groups continued to perform the task for 2 h/day, 3 days/week, for 1-3 weeks. Grip strength and relative muscle weight of the flexor digitorum superficialis (FDS) muscle were measured. Median nerve injury was evaluated by histopathology and immunohistochemistry. RESULTS: Grip strength of the reach limb (forelimb used in tasks) was significantly lower in the 3-week group compared with the other groups and was significantly lower than that of the non-reach limb in all groups. There were no significant differences in the relative FDS muscle weights of either limb among groups. No evidence of median nerve demyelination was observed and no cells expressed activating transcription factor-3, a specific marker of peripheral nerve injury, in the anterior horn of the spinal cord. CONCLUSION: Median nerve injury does not contribute to the decreased grip strength caused by 3 weeks of repetitive reaching and grasping tasks, involving negligible force, in rats.

Author Correction: GGA2 interacts with EGFR cytoplasmic domain to stabilize the receptor expression and promote cell growth.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Role of the BDNF-TrkB pathway in KCC2 regulation and rehabilitation following neuronal injury: A mini review.

In most mature neurons, low levels of intracellular Cl- concentrations ([Cl-]i) are maintained by channels and transporters, particularly the K+-Cl- cotransporter 2 (KCC2), which is the only Cl- extruder in most neurons. Recent studies have implicated KCC2 expression in the molecular mechanisms underlying neuronal disorders, such as spasticity, epilepsy and neuropathic pain. Alterations in KCC2 expression have been associated with brain-derived neurotrophic factor (BDNF) and its receptor tropomyosin-related kinase B (TrkB). The present review summarizes recent progress regarding the roles of Cl- regulators in immature and mature neurons. Moreover, we focus on the role of KCC2 regulation via the BDNF-TrkB pathway in spinal cord injury and rehabilitation, as prior studies have shown that the BDNF-TrkB pathway can affect both the pathological development and functional amelioration of spinal cord injuries. Evidence suggests that rehabilitation using active exercise and mechanical stimulation can attenuate spasticity and neuropathic pain in animal models, likely due to the upregulation of KCC2 expression via the BDNF-TrkB pathway. Moreover, research suggests that such rehabilitation efforts may recover KCC2 expression without the use of exogenous BDNF.

Correction: Clathrin adaptor GGA1 modulates myogenesis of C2C12 myoblasts.

[This corrects the article DOI: 10.1371/journal.pone.0207533.].

Clathrin adaptor GGA1 modulates myogenesis of C2C12 myoblasts.

During myogenesis, myogenic stem cells undergo several sequential events, including cell division, migration, and cell-cell fusion, leading to the formation of multinuclear myotubes, which are the precursors of myofibers. To understand the molecular mechanisms underlying these complex processes, an RNA interference-based gene depletion approach was used. Golgi associated, gamma adaptin ear containing, ARF binding protein 1 (GGA1), a Golgi-resident monomeric clathrin adaptor, was found to be required for the process of myotube formation in C2C12 cells, a cultured murine myoblast cell line. Gga1 mRNA expression was upregulated during myogenesis, and Gga1 depletion prevented the formation of large multi-nucleated myotubes. Moreover, inhibition of lysosomal proteases in Gga1 knockdown myoblasts increased the amount of insulin receptor, suggesting that GGA1 is involved in the cell surface expression and sorting of the insulin receptor. These results suggested that GGA1 plays a significant role in the formation and maturation of myotubes by targeting the insulin receptor to the cell surface to establish functionally mature myofibers.

Intracellular localization of GGA accessory protein p56 in cell lines and central nervous system neurons.

Adaptor protein complex-1 (AP-1) and Golgi associated, γ-adaptin ear containing, Arf binding proteins (GGAs) are clathrin adaptors that regulate membrane trafficking between the trans-Golgi network (TGN) and endosomes. p56 is a clathrin adaptor accessory protein that may modulate the function of GGAs in mammalian cell lines. However, the precise relationship between p56 and the three GGAs (GGA1-3), as well as the physiological role of p56 in tissue cells, remain unknown. To this end, we generated an antibody against p56 and determined its cellular localization. In ARPE-19 cells and mouse embryonic fibroblasts, p56 was found to be localized as fine puncta in the TGN. Interestingly, the depletion of each clathrin adaptor by RNAi revealed that this localization was dependent on the expression of GGA1, but not that of GGA2, GGA3, or AP-1. Using immunohistofluorescence microscopy in the mouse central nervous system (CNS), p56 was clearly detected as scattered cytoplasmic puncta in spinal motor neurons, cerebellar Purkinje cells, and pyramidal neurons of the hippocampus and cerebral cortex. Moreover, double labeling with organelle markers revealed that the majority of these puncta were closely associated with the TGN; however, a small fraction was associated with endosomes or lysosomes in spinal motor neurons. Collectively, these results indicate a functional association of p56 with GGA1, suggesting an important role of p56 in larger CNS neurons.

GGA2 interacts with EGFR cytoplasmic domain to stabilize the receptor expression and promote cell growth.

Epidermal growth factor receptor (EGFR) signaling and its downregulation upon ligand binding have been extensively documented. However, the mechanisms by which cells maintain steady-state EGFR expression remain poorly understood. Here, we report a novel role of Golgi-localized, γ-adaptin ear-containing, ADP ribosylation factor-binding protein 2 (GGA2) in the control of EGFR turnover. Whereas GGA1- or GGA3-depletion increased EGFR expression, GGA2-depletion by RNAi greatly reduced steady-state expression of EGFR, reflecting enhanced lysosomal degradation of EGFR. Subsequent pull-down assays showed interactions of VHS-GAT domains from three GGAs with the cytoplasmic juxtamembrane region (jxt) of EGFR, which was dependent on N108 in the VHS domain. Proximity ligation assay also revealed the steady-state interaction between GGA2 and EGFR in situ. Moreover, reduced expression of EGFR in GGA2-depleted cells was reversed by additional depletion of GGA1 or GGA3, suggesting that GGA1 and GGA3 promote EGFR degradation. In addition, GGA2-depleted cells had reduced EGF signaling and cell proliferation in cell culture and xenograft experiments. Finally, GGA2 was upregulated in 30.8% of human hepatocellular carcinomas and 23.3% of colorectal cancers. Together, these results indicate that GGA2 supports cell growth by interacting with EGFR for sustaining the receptor expression.

Proteasome dysfunction activates autophagy and the Keap1-Nrf2 pathway.

The ubiquitin-proteasome system and autophagy are crucially important for proteostasis in cells. These pathways are interdependent, and dysfunction in either pathway causes accumulation of ubiquitin-positive aggregates, a hallmark of human pathological conditions. To elucidate in vivo compensatory action(s) against proteasomal dysfunction, we developed mice with reduced proteasome activity in their livers. The mutant mice exhibited severe liver damage, accompanied by formation of aggregates positive for ubiquitin and p62/Sqstm1, an adaptor protein for both selective autophagy and the anti-oxidative Keap1-Nrf2 pathway. These aggregates were selectively entrapped by autophagosomes, and pathological features of livers with impaired proteasome activity were exacerbated by simultaneous suppression of autophagy. In contrast, concomitant loss of p62/Sqstm1 had no apparent effect on the liver pathology though p62/Sqstm1 was indispensable for the aggregates formation. Furthermore, defective proteasome function led to transcriptional activation of the Nrf2, which served as a physiological adaptation. Our in vivo data suggest that cells contain networks of cellular defense mechanisms against defective proteostasis.

A cluster of thin tubular structures mediates transformation of the endoplasmic reticulum to autophagic isolation membrane.

Recent findings have suggested that the autophagic isolation membrane (IM) might originate from a domain of the endoplasmic reticulum (ER) called the omegasome. However, the morphological relationships between ER, omegasome, and IM remain unclear. In the present study, we found that hybrid structures composed of a double FYVE domain-containing protein 1 (DFCP1)-positive omegasome and the IM accumulated in Atg3-deficient mouse embryonic fibroblasts (MEFs). Moreover, correlative light and electron microscopy and immunoelectron microscopy revealed that green fluorescent protein (GFP)-tagged DFCP1 was localized on tubular or vesicular elements adjacent to the IM rims. Through detailed morphological analyses, including optimization of a fixation method and electron tomography, we observed a cluster of thin tubular structures between the IM edges and ER, part of which were continuous with IM and/or ER. The formation of these thin tubular clusters was observed in several cell lines and MEFs deficient for Atg5, Atg7, or Atg16L1 but not in FIP200-deficient cells, suggesting that they were relevant to the earlier events in autophagosome formation. Taken together, our findings indicate that these tubular profiles represent a part of the omegasome that links the ER with the IM.

ArfGAP3 regulates the transport of cation-independent mannose 6-phosphate receptor in the post-Golgi compartment.

ArfGAPs are known to be involved in cargo sorting in COPI transport. However, the role of ArfGAPs in post-Golgi membrane traffic has not been defined. To determine the function of ArfGAPs in post-Golgi traffic, we used small interfering RNA to examine each of 25 ArfGAPs for effects on cation-independent mannose 6-phosphate receptor (CIMPR) localization. We found that downregulation of ArfGAP3 resulted in the peripheral localization of CIMPR. The effect was specific for ArfGAP3 and dependent on its GAP activity, because the phenotype was rescued by ArfGAP3 but not by ArfGAP1, ArfGAP2, or the GAP domain mutants of ArfGAP3. ArfGAP3 localized to the trans-Golgi network and early endosomes. In cells with reduced expression of ArfGAP3, Cathepsin D maturation was slowed and its secretion was accelerated. Also retrograde transport from the endosomes to the trans-Golgi network of endogenous CIMPR, but not truncated CIMPR lacking the luminal domain, was perturbed in cells with reduced expression of ArfGAP3. Furthermore the exit of epidermal growth factor receptor (EGFR) from the early endosomes and degradation of EGFR after EGF stimulation was slowed in cells with reduced expression of ArfGAP3. ArfGAP3 associates with Golgi-localized, γ-ear-containing, ADP-ribosylation factor binding proteins (GGAs), and ArfGAP3 knockdown reduces membrane association of GGAs. A possible mechanism explaining our results is that ArfGAP3 regulates transport from early endosomes to late endosomes. We suggest a model in which ArfGAP3 regulates Golgi association of GGA clathrin adaptors.

AP-1 clathrin adaptor and CG8538/Aftiphilin are involved in Notch signaling during eye development in Drosophila melanogaster.

Clathrin adaptor protein complex-1 (AP-1) and its accessory proteins play a role in the sorting of integral membrane proteins at the trans-Golgi network and endosomes. Their physiological functions in complex organisms, however, are not fully understood. In this study, we found that CG8538p, an uncharacterized Drosophila protein, shares significant structural and functional characteristics with Aftiphilin, a mammalian AP-1 accessory protein. The Drosophila Aftiphilin was shown to interact directly with the ear domain of γ-adaptin of Drosophila AP-1, but not with the GAE domain of Drosophila GGA. In S2 cells, Drosophila Aftiphilin and AP-1 formed a complex and colocalized at the Golgi compartment. Moreover, tissue-specific depletion of AP-1 or Aftiphilin in the developing eyes resulted in a disordered alignment of photoreceptor neurons in larval stage and roughened eyes with aberrant ommatidia in adult flies. Furthermore, AP-1-depleted photoreceptor neurons showed an intracellular accumulation of a Notch regulator, Scabrous, and downregulation of Notch by promoting its degradation in the lysosomes. These results suggest that AP-1 and Aftiphilin are cooperatively involved in the intracellular trafficking of Notch during eye development in Drosophila.

Visualization of TGN-endosome trafficking in mammalian and Drosophila cells.

Mannose 6-phosphate receptors (MPRs) are known to be shuttled between the trans-Golgi network (TGN) and endosomes, thereby several lysosomal hydrolases are delivered through the endocytic pathway into lysosomes. This interorganellar transport is mediated by transport intermediates, now called transport carriers. Previous studies employing green fluorescent protein (GFP)-based live-cell imaging demonstrated that these transport carriers are pleiomorphic structures composed of tubular and vesicular elements. Introducing a time-axis into light microscopic observations enabled us to identify transport carriers that are derived from or targeted at a distinct organelle. In this study, we describe several methods for the observation of GFP-tagged MPRs. Photobleaching the peripheral region of a cell before a time-lapse observation allows us to monitor TGN-derived transport carriers for longer periods (more than 4min). Events of their targeting into endosomes can be visualized by dual-color imaging of both GFP-MPRs and fluorescently tagged transferrin that is internalized by cells. By using a technique of fluorescence recovery after photobleaching (FRAP), we can analyze overall cycling kinetics of MPRs in a single cell. Transport of MPRs is regulated by several cytosolic factors like clathrin adaptors, AP1, and GGAs. The adaptors on the TGN membranes are exchanging with their cytosolic pool, which can also be analyzed by FRAP. In addition, the relationships of the MPR-containing transport carriers that left the TGN and the adaptors can be visualized by dual-color imaging. A similar system of membrane transport and its regulation is well documented in drosophila cells. As Drosophila melanogaster has only a single MPR (LERP), AP1, or GGA, it is an ideal model system for the understanding of specific functions of each cytosolic factor. To visualize these molecules in drosophila cells, however, we need to consider that multiple Golgi dots exist scattered in the cytoplasm. Thus, the Golgi dots or endosomes should be identified before live-cell imaging.

Functional characterization of protein-sorting machineries at the trans-Golgi network in Drosophila melanogaster.

Targeting of proteins to their final destination is a prerequisite for living cells to maintain their homeostasis. Clathrin functions as a coat that forms transport carriers called clathrin-coated vesicles (CCVs) at the plasma membrane and post-Golgi compartments. In this study, we established an experimental system using Schneider S2 cells derived from the fruit fly, Drosophila melanogaster, as a model system to study the physiological roles of clathrin adaptors, and to dissect the processes of CCV formation. We found that a clathrin adaptor Drosophila GGA (dGGA), a homolog of mammalian GGA proteins, localizes to the trans-Golgi network (TGN) and is capable of recruiting clathrin from the cytosol onto TGN membranes. dGGA itself is recruited from the cytosol to the TGN in an ARF1 small GTPase (dARF79F)-dependent manner. dGGA recognizes the cytoplasmic acidic-cluster-dileucine (ACLL) sorting signal of Lerp (lysosomal enzyme receptor protein), a homolog of mammalian mannose 6-phosphate receptors. Moreover, both dGGA and another type of TGN-localized clathrin adaptor, AP-1 (adaptor protein-1 complex), are shown to be involved in the trafficking of Lerp from the TGN to endosomes and/or lysosomes. Taken together, our findings indicate that the protein-sorting machinery in fly cells is well conserved relative to that in mammals, enabling the use of fly cells to dissect CCV biogenesis and clathrin-dependent protein trafficking at the TGN of higher eukaryotes.