Neurite outgrowth induced by stimulation of angiotensin II AT2 receptors in SH-SY5Y neuroblastoma cells involves c-Src activation.

Neuroblastoma, the most common extracranial solid tumor occurring in childhood, originates from the aberrant proliferation of neural crest cells. Accordingly, the mechanism underling neuronal differentiation could provide new strategies for neuroblastoma treatment. It is well known that neurite outgrowth could be induced by Angiotensin II (Ang II) AT2 receptors; however, the signaling mechanism and its possible interaction with NGF (neural growth factor) receptors remain unclear. Here, we show that Ang II and CGP42112A (AT2 receptor agonist) promote neuronal differentiation by inducing neurite outgrowth and ßIII-tubulin expression in SH-SY5Y neuroblastoma cells. In addition, we demonstrate that treatment with PD123319 (AT2 receptor antagonist) reverts Ang II or CGP42112A-induced differentiation. By using specific pharmacological inhibitors we established that neurite outgrowth induced by CGP42112A requires the activation of MEK (mitogen-activated protein kinase kinase), SphK (sphingosine kinase) and c-Src but not PI3K (phosphatidylinositol 3-kinase). Certainly, CGP42112A stimulated a rapid and transient (30 s, 1 min) phosphorylation of c-Src at residue Y416 (indicative of activation), following by a Src deactivation as indicated by phosphorylation of Y527. Moreover, inhibition of the NGF receptor tyrosine kinase A (TrkA) reduced neurite outgrowth induced by Ang II and CGP42112A. In summary, we demonstrated that AT2 receptor-stimulated neurite outgrowth in SH-SY5Y cells involves the induction of MEK, SphK and c-Src and suggests a possible transactivation of TrkA. In that regard, AT2 signaling pathway is a key player in neuronal differentiation and might be a potential target for therapeutic treatments.

Extracellular acidosis stimulates breast cancer cell motility through aryl hydrocarbon receptor and c-src kinase activation.

A reduction in extracellular pH (pHe) is a characteristic of most malignant tumors. The aryl hydrocarbon receptor (AhR) is a transcription factor localized in a cytosolic complex with c-Src, which allows it to trigger nongenomic effects through c-Src. Considering that the slightly acidic tumor microenvironment promotes breast cancer progression in a similar way to the AhR/c-Src axis, our aim was to evaluate whether this pathway could be activated by low pHe. We examined the effect of pHe 6.5 on AhR/c-Src axis using two breast cancer cell lines (MDA-MB-231 and LM3) and mammary epithelial cells (NMuMG) and found that acidosis increased c-Src phosphorylation only in tumor cells. Moreover, the presence of AhR inhibitors prevented c-Src activation. Low pHe reduced intracellular pH (pHi), while amiloride treatment, which is known to reduce pHi, induced c-Src phosphorylation through AhR. Analyses were conducted on cell migration and metalloproteases (MMP)-2 and -9 activities, with results showing an acidosis-induced increase in MDA-MB-231 and LM3 cell migration and MMP-9 activity, but no changes in NMuMG cells. Moreover, all these effects were blocked by AhR and c-Src inhibitors. In conclusion, acidosis stimulates the AhR/c-Src axis only in breast cancer cells, increasing cell migration and MMP-9 activity. Although the AhR activation mechanism still remains elusive, a reduction in pHi may be thought to be involved. These findings suggest a critical role for the AhR/c-Src axis in breast tumor progression stimulated by an acidic microenvironment.

Allopregnanolone Promotes Migration and Invasion of Human Glioblastoma Cells through the Protein Tyrosine Kinase c-Src Activation.

Glioblastomas (GBs) are the most aggressive and common primary malignant brain tumors. Steroid hormone progesterone (P4) and its neuroactive metabolites, such as allopregnanolone (3α-THP) are synthesized by neural, glial, and malignant GB cells. P4 promotes cellular proliferation, migration, and invasion of human GB cells at physiological concentrations. It has been reported that 3α-THP promotes GB cell proliferation. Here we investigated the effects of 3α-THP on GB cell migration and invasion, the participation of the enzymes involved in its metabolism (AKR1C1-4), and the role of the c-Src kinase in 3α-THP effects in GBs. 3α-THP 100 nM promoted migration and invasion of U251, U87, and LN229 human-derived GB cell lines. We observed that U251, LN229, and T98G cell lines exhibited a higher protein content of AKR1C1-4 than normal human astrocytes. AKR1C1-4 silencing did not modify 3α-THP effects on migration and invasion. 3α-THP activated c-Src protein at 10 min (U251 cells) and 15 min (U87 and LN229 cells). Interestingly, the pharmacological inhibition of c-Src decreases the promoting effects of 3α-THP on cell migration and invasion. Together, these data indicate that 3α-THP promotes GB migration and invasion through c-Src activation.

Fructose ingestion modifies NMDA receptors and exacerbates the seizures induced by kainic acid.

Fructose ingestion elicits a diversity of brain alterations, but it is unknown how it affects N-methyl-D-Aspartate receptors (NMDAr). Here, we analyzed the expression of NMDAr subunits and protein kinases after the long-term dietary fructose intake. Since NMDAr are related to epileptogenesis, we also examined whether fructose increases the susceptibility to seizures after the microinjection of kainic acid (KA) in the rat hippocampus. Wistar rats were randomly divided into water (control) and fructose groups. For twelve weeks, groups had ad libitum access to water or fructose solution (10% w/v). After treatment, hippocampal protein expression of NMDAr subunits and protein kinases involved in NMDAr regulation were analyzed. Additionally, electroencephalographic and behavioral changes related to seizures were evaluated after the microinjection of a sub-convulsive dose of KA in the hippocampus. Fructose induced the decrease of NR1 and, conversely, the increase of NR2A subunits expression in the hippocampus. Also, the phosphorylation of protein kinase C alpha (PKCα) and c-Src increased significantly. No electroencephalographic or behavioral patterns related to convulsive motor seizures were observed in the control group. However, all the rats that ingested fructose showed stage 3 seizures (forelimb clonus) and a significant increase in the number of wet-dog shakes. Moreover, electroencephalographic recordings revealed pronounced epileptiform activity and increased total spectral power at 30 and 60 min after the microinjection of KA. This study shows for the first time that fructose intake exacerbates the seizures induced by KA. Therefore, we propose that this proconvulsant effect could be mediated by changes in NMDAr subunits expression and increased activation of kinases modulating NMDAr function.

The Angiotensin II Type 1 Receptor-Associated Protein Attenuates Angiotensin II-Mediated Inhibition of the Renal Outer Medullary Potassium Channel in Collecting Duct Cells.

Adjustments in renal K+ excretion constitute a central mechanism for K+ homeostasis. The renal outer medullary potassium (ROMK) channel accounts for the major K+ secretory route in collecting ducts during basal conditions. Activation of the angiotensin II (Ang II) type 1 receptor (AT1R) by Ang II is known to inhibit ROMK activity under the setting of K+ dietary restriction, underscoring the role of the AT1R in K+ conservation. The present study aimed to investigate whether an AT1R binding partner, the AT1R-associated protein (ATRAP), impacts Ang II-mediated ROMK regulation in collecting duct cells and, if so, to gain insight into the potential underlying mechanisms. To this end, we overexpressed either ATRAP or ß-galactosidase (LacZ; used as a control), in M-1 cells, a model line of cortical collecting duct cells. We then assessed ROMK channel activity by employing a novel fluorescence-based microplate assay. Experiments were performed in the presence of 10-10 M Ang II or vehicle for 40 min. We observed that Ang II-induced a significant inhibition of ROMK in LacZ, but not in ATRAP-overexpressed M-1 cells. Inhibition of ROMK-mediated K+ secretion by Ang II was accompanied by lower ROMK cell surface expression. Conversely, Ang II did not affect the ROMK-cell surface abundance in M-1 cells transfected with ATRAP. Additionally, diminished response to Ang II in M-1 cells overexpressing ATRAP was accompanied by decreased c-Src phosphorylation at the tyrosine 416. Unexpectedly, reduced phospho-c-Src levels were also found in M-1 cells, overexpressing ATRAP treated with vehicle, suggesting that ATRAP can also downregulate this kinase independently of Ang II-AT1R activation. Collectively, our data support that ATRAP attenuates inhibition of ROMK by Ang II in collecting duct cells, presumably by reducing c-Src activation and blocking ROMK internalization. The potential role of ATRAP in K+ homeostasis and/or disorders awaits further investigation.

Non-Genomic Actions of Estrogens on the DNA Repair Pathways Are Associated With Chemotherapy Resistance in Breast Cancer.

Estrogens have been implicated in the etiology of breast cancer for a long time. It has been stated that long-term exposure to estrogens is associated with a higher incidence of breast cancer, since estradiol (E2) stimulates breast cell growth; however, its effect on DNA damage/repair is only starting to be investigated. Recent studies have documented that estrogens are able to modify the DNA damage response (DDR) and DNA repair mechanisms. On the other hand, it has been proposed that DDR machinery can be altered by estrogen signaling pathways, that can be related to cancer progression and chemoresistance. We have demonstrated that E2 promotes c-Src activation and breast cancer cell motility, through a non-genomic pathway. This review discusses scientific evidence supporting this non-genomic mechanism where estrogen modifies the DNA repair pathways, and its relationship to potential causes of chemoresistance.

c-Src kinase contributes on endothelial cells mechanotransduction in a heat shock protein 70-dependent turnover manner.

Shear stress changes are associated with a repertory of signaling cascade modulating vascular phenotype. As shear stress-related tensional forces might be associated with pathophysiological susceptibility, a more comprehensive molecular map needs to be addressed. Thus, we subjected human umbilical vein endothelial cells (HUVECs) to a circuit of different tensional forces in vitro considering the following three groups: (a) physiological blood flow shear stress condition (named Normo), (b) a hypertensive blood flow shear stress (named Hyper), and (c) these hyper-stressed cells were returned to Normo condition (named Return). The samples were properly collected to allow different methodologies analysis. Our data showed a pivotal involvement of c-Src on driving the mechanotransduction cascade by modulating signaling related with adhesion, survival (PI3K/Akt) and proliferative phenotype. Moreover, c-Src seems to develop important role during extracellular matrix remodeling. Additionally, proteomic analysis showed strong involvement of heat shock protein 70 (HSP70) in the hypertensive-stressed cells; it being significantly decreased in return phenotype. This result prompted us to investigate 20S proteasome as an intracellular proteolytic alternative route to promote the turnover of those proteins. Surprisingly, our data reveled significant overexpression of sets of proteasome subunit α-type (PSMA) and ß-type (PSMB) genes. In conjunction, our data showed c-Src as a pivotal protein to drive mechanotransduction in endothelial cells in a HSP70-dependent turnover scenario. Because shear patterns is associated with pathophysiological changes, such as atherosclerosis and hypertension, these results paved new road to understand the molecular mechanism on driving mechanotransduction in endothelial cells and, if drugable, these targets must be considered within pharmacological treatment optimization.

Platelet activity is negatively modulated by tumor necrosis factor alpha through reductions of cytosolic calcium levels and integrin alphaIIbbeta3 phosphorylation.

INTRODUCTION: Tumor necrosis factor-alpha (TNF-α) exerts a critical role in inflammatory events through two distinct receptors, TNFR1 and TNFR2. Platelets have been recognized as important inflammatory cells, but little is known about the effects of TNF-α on the platelet activity. OBJECTIVES: In the present study we have studied the role of TNF-α on ADP-induced platelet aggregation and its downstream signaling (c-Src and fibrinogen receptor phosphorylation, cytosolic Ca2+ mobilization, cAMP and cGMP levels and cell viability). METHODS AND RESULTS: Washed rat platelets were incubated with TNF-α (1-3000 pg/ml) for different time-periods (5-60 min) before the addition of ADP (5 µM) to induce platelet aggregation. TNF-α concentration- and time-dependently inhibits ADP-induced aggregation, which was significantly prevented by incubation with the non-selective TNF-α receptor antagonist R7050. TNF-α (300 pg/ml, 30 min) decreases thrombin-induced elevation of cytosolic Ca++ levels by 2.2- fold compared to untreated platelets. TNF-α decreases the cAMP levels, while significantly increases the intracellular cyclic cGMP levels. However, the pre-incubation of platelets with the guanylyl cyclase inhibitor ODQ, despite decreasing the cGMP levels, does not modify the inhibitory effect of TNF-α on ADP-induced platelet aggregation. Additionally, western blotting analysis showed that TNF-α significantly reduced (Tyr 416)-c-Src and (Tyr773)-ß3 subunit of αIIbß3 integrin phosphorylation. TNF-α does not affect the platelet viability in any condition tested. CONCLUSION: Therefore, our results show that TNF-α negatively modulates ADP-induced aggregation via TNFR1/TNFR2 receptors by reducing cytosolic Ca++ levels and by inhibiting c-Src and fibrinogen receptor activation, which take place through cAMP- and cGMP-independent mechanisms.

El hexaclorobenceno como factor de riesgo en el cáncer de mama / Hexachlorobenzene as a risk factor in breast cancer

Hexachlorobenzene (HCB) is a widespread environmental pollutant and an endocrine disruptor. Chronic exposure of humans to HCB elicits porphyria, neurologic symptoms, immune disorders and thyroid dysfunctions. It is a dioxin-like compound and a weak ligand of the AhR (aryl hydrocarbon receptor), a transcription factor that modulates genes related to detoxification, proliferation, migration and invasion. This study was carried out to revise the results of HCB action on mammary gland and breast cancer, summarizing the main ideas of its mechanism of action. HCB increases tumor development and active c-Src/EGFR (epidermal growth factor receptor) signaling pathways, while reducing tyrosine537-ER-alpha (estrogen receptor-alpha) phosphorylation, and promoting a phenotype with enhanced malignancy and lung metastasis in different animal models. In a rat mammary gland, HCB promotes an estrogenic microenvironment by activation of ER-alpha and Insulin/IGFs (insulin growth factors) pathways. HCB induces cell proliferation, promoting cell cycle progression and enhancing cyclin D1 expression and c-Src/p27 interaction in (ER-alpha) MCF-7 human breast cancer cell line. In (ER-alpha)(-) MDA-MB-231 breast cancer cells, the pesticide enhances cell migration and invasion as well as metalloproteases and TGF-beta1 (transformig growth factor-beta1) expression. In conclusion our current study suggests that alterations in the estrogenic microenvironment may influence the biological behavior of mammary gland or breast tumors, leading to preneoplastic lesions or enhanced malignancy, respectively. Our findings suggest that HCB may be a risk factor for human breast cancer progression.

El hexaclorobenceno (HCB) es un contaminante ambiental ampliamente distribuido y un desorganizador endocrino. Su exposición crónica en seres humanos produce porfiria, síntomas neurológicos, trastornos inmunitarios y disfunciones tiroideas. Es un agonista débil del receptor de hidrocarburos aromáticos (AhR), un factor de transcripción que modula genes relacionados con el metabolismo de xenobióticos, la proliferación, la migración y la invasión. Nuestro objetivo es revisar los efectos del HCB en la glándula mamaria y el cáncer mamario, resumiendo los principales mecanismos de acción. El HCB aumenta el desarrollo tumoral y activa vías de señalización de c-Src/receptor del factor de crecimiento epidérmico (EGFR), mientras que disminuye la fosforilación de tirosina 537/receptor de estrógenos alfa (RE-alfa), promoviendo un fenotipo de mayor malignidad y metástasis pulmonar en diferentes modelos con animales. En la glándula mamaria de rata genera un microambiente estrogénico por activación del RE-alfa y las vías de insulina/factores de crecimiento similares a la insulina (IGF). En células de cáncer mamario humanas MCF-7 (RE-alfa) induce proliferación celular, promoviendo la progresión del ciclo, aumentando la ciclina D1 y la interacción p27/c-Src. En MDA-MB-231 (-RE-alfa) estimula la migración e invasión, así como la expresión de metaloproteasas y factor de crecimiento transformante beta 1 (TGF-beta 1). Estos estudios indican que las alteraciones en el microambiente estrogénico podrían influir el comportamiento biológico de la glándula mamaria y los tumores, lo que provoca lesiones preneoplásicas o aumento en la malignidad tumoral mamaria. Nuestros hallazgos sugieren que el HCB podría ser un factor de riesgo para la progresión del cáncer de mama humano.

Hexachlorobenzene alters cell cycle by regulating p27-cyclin E-CDK2 and c-Src-p27 protein complexes.

Hexachlorobenzene (HCB) is an organochlorine pollutant widely distributed in the environment around the entire world. Previous reports from our group and others have demonstrated that this compound is as an endocrine disruptor. We have also reported that HCB presents a co-carcinogenic effect in N-Nitroso-N-methyl-urea-induced mammary tumours in rats. In this work, we studied the effects of HCB on cell cycle progression and cell cycle regulating protein expression in the estrogen-sensitive breast cancer cell line, MCF-7. Here, we show that HCB alters cell cycle in a concentration-dependent way. The lowest assessed concentration (0.005µM) promotes the cell cycle progression, enhances cyclin D1 expression, and reduces the nuclear localization of p27 accompanied by an increased interaction between p27 and c-Src kinase. On the other hand, 5µM HCB delays the cell cycle progression and promotes the formation of the cyclin E-CDK2-p27 protein complex. Our results show that HCB stimulates cell proliferation through cell cycle modulation and c-Src involvement in MCF-7 cells. Here, we report for the first time that differential mechanisms of action of HCB on mammary cell cycle progression are triggered at different concentrations of this pollutant.

CFTR impairment upregulates c-Src activity through IL-1ß autocrine signaling.

Cystic Fibrosis (CF) is a disease caused by mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene. Previously, we found several genes showing a differential expression in CFDE cells (epithelial cells derived from a CF patient). One corresponded to c-Src; its expression and activity was found increased in CFDE cells, acting as a signaling molecule between the CFTR activity and MUC1 overexpression. Here we report that bronchial IB3-1 cells (CF cells) also showed increased c-Src activity compared to 'CFTR-corrected' S9 cells. In addition, three different Caco-2 cell lines, each stably transfected with a different CFTR-specific shRNAs, displayed increased c-Src activity. The IL-1ß receptor antagonist IL1RN reduced the c-Src activity of Caco-2/pRS26 cells (expressing a CFTR-specific shRNA). In addition, increased mitochondrial and cellular ROS levels were detected in Caco-2/pRS26 cells. ROS levels were partially reduced by incubation with PP2 (c-Src inhibitor) or IL1RN, and further reduced by using the NOX1/4 inhibitor GKT137831. Thus, IL-1ß→c-Src and IL-1ß→NOX signaling pathways appear to be responsible for the production of cellular and mitochondrial ROS in CFTR-KD cells. In conclusion, IL-1ß constitutes a new step in the CFTR signaling pathway, located upstream of c-Src, which is stimulated in cells with impaired CFTR activity.

c- Src and its role in cystic fibrosis.

Cystic fibrosis (CF) is a lethal inherited disease produced by mutations in the gene encoding the CFTR chloride channel. Loss of function in the CFTR gene is associated with a not much noticed increased expression and activity of the non-receptor protein-tyrosine kinase c-Src. CF is therefore the result from the loss of CFTR chloride transport function and its consequences, including a chronic and excessive c-Src signaling. On the other hand, c-Src, encoded by the SRC gene, is involved in diverse signaling mechanisms that regulate key cellular functions such as cell proliferation, apoptosis, oxidative stress, inflammation, and innate immunity. These c-Src-regulated cellular functions are also affected in CF; however, studies exploring a direct role of c-Src in the regulation of these cellular functions in CF are yet scarce and often controversial. Here we describe the c-Src regulation and functions, with emphasis in those altered in CF, and describe the role of CFTR as a "signaling molecule" that negatively modulates c-Src expression and activity. It is also discussed the emerging role of intracellular Cl- and IL-1ß as intermediate signaling effectors between CFTR and c-Src.

The involvement of FAK and Src in the invasion of cardiomyocytes by Trypanosoma cruzi.

The activation of signaling pathways involving protein tyrosine kinases (PTKs) has been demonstrated during Trypanosoma cruzi invasion. Herein, we describe the participation of FAK/Src in the invasion of cardiomyocytes by T. cruzi. The treatment of cardiomyocytes with genistein, a PTK inhibitor, significantly reduced T. cruzi invasion. Also, PP1, a potent Src-family protein inhibitor, and PF573228, a specific FAK inhibitor, also inhibited T. cruzi entry; maximal inhibition was achieved at concentrations of 25µM PP1 (53% inhibition) and 40µM PF573228 (50% inhibition). The suppression of FAK expression in siRNA-treated cells and tetracycline-uninduced Tet-FAK(WT)-46 cells significantly reduced T. cruzi invasion. The entry of T. cruzi is accompanied by changes in FAK and c-Src expression and phosphorylation. An enhancement of FAK activation occurs during the initial stages of T. cruzi-cardiomyocyte interaction (30 and 60min), with a concomitant increase in the level of c-Src expression and phosphorylation, suggesting that FAK/Src act as an integrated signaling pathway that coordinates parasite entry. These data provide novel insights into the signaling pathways that are involved in cardiomyocyte invasion by T. cruzi. A better understanding of the signal transduction networks involved in T. cruzi invasion may contribute to the development of more effective therapies for the treatment of Chagas' disease.