Propentofylline targets TROY, a novel microglial signaling pathway

Glioblastoma multiforme (GBM) is the most common and aggressive primary brain cancer, with a median survival of less than 2 years after diagnosis with current available therapies. The tumor microenvironment serves a critical role in tumor invasion and progression, with microglia as a critical player. Our laboratory has previously demonstrated that propentofylline, an atypical methylxanthine with central nervous system glial modulating and anti-inflammatory actions, significantly decreases tumor growth in a GBM rodent model by preferentially targeting microglia. In the present study, we used the CNS-1 rat glioma model to elucidate the mechanisms of propentofylline. Here we demonstrate that propentofylline targets TROY, a novel signaling molecule up-regulated in infiltrating microglia, and not macrophages, in response to CNS-1 cells. We identify Pyk2, Rac1 and pJNK as the downstream signaling molecules of TROY through western blot analysis and siRNA transfection. We demonstrate that inhibition of TROY expression in microglia by siRNA transfection significantly inhibits microglial migration towards CNS-1 cells similar to 10 μM propentofylline treatment. These results identify TROY as a novel molecule expressed in microglia, involved in their migration and targeted by propentofylline. Furthermore, these results describe a signaling molecule that is differentially expressed between microglia and macrophages in the tumor microenvironment.     

A novel mechanism for the store-operated calcium influx pathway

Activation of store-operated channels (SOCs) and capacitative calcium influx are triggered by depletion of intracellular calcium stores. However, the exact molecular mechanism of such communication remains unclear. Recently, we demonstrated that native SOC channels can be activated by calcium influx factor (CIF) that is produced upon depletion of calcium stores, and showed that Ca(2+)-independent phospholipase A(2) (iPLA(2)) has an important role in the store-operated calcium influx pathway. Here, we identify the key plasma-membrane-delimited events that result in activation of SOC channels. We also propose a novel molecular mechanism in which CIF displaces inhibitory calmodulin (CaM) from iPLA(2), resulting in activation of iPLA(2) and generation of lysophospholipids that in turn activate soc channels and capacitative calcium influx. Upon refilling of the stores and termination of CIF production, CaM rebinds to iPLA(2), inhibits it, and the activity of SOC channels and capacitative calcium influx is terminated.     

Identification of novel MAP kinase pathway signaling targets by functional proteomics and mass spectrometry

Functional proteomics provides a powerful method for monitoring global molecular responses following activation of signal transduction pathways, reporting altered protein posttranslational modification and expression. Here we combine functional proteomics with selective activation and inhibition of MKK1/2, in order to identify cellular targets regulated by the MKK/ERK cascade. Twenty-five targets of this signaling pathway were identified, of which only five were previously characterized as MKK/ERK effectors. The remaining targets suggest novel roles for this signaling cascade in cellular processes of nuclear transport, nucleotide excision repair, nucleosome assembly, membrane trafficking, and cytoskeletal regulation. This study represents an application of functional proteomics toward identifying regulated targets of a discrete signal transduction pathway and demonstrates the utility of this discovery-based strategy in elucidating novel MAP kinase pathway effectors.     

Proteins of the Hedgehog signaling pathway as therapeutic targets against cancer

The Hedgehog pathway plays a crucial role in growth and patterning during embryonic development and is involved in stem cell maintenance and proliferation in adult tissues. Mutations that increase the overall activity of the pathway are often associated with a higher incidence of cancers. This article focuses on the mutations, misfoldings and deregulations of the Hedgehog pathway proteins that have been reported to be involved in different tumors, and on small molecules targeting these proteins shown to slow down the growth of certain tumors in various animal models. We propose that proteomics could be a powerful tool to identify new targets of the Hedgehog pathway, enabling the discovery of effective and novel treatments for cancers.     

A novel NF-kappa B-inducing kinase-MAPK signaling pathway up-regulates NF-kappa B activity in melanoma cells.

Constitutive activation of NF-kappa B is an emerging hallmark of various types of tumors including breast, colon, pancreatic, ovarian, and melanoma. In melanoma cells, the basal expression of the CXC chemokine, CXCL1, is constitutively up-regulated. This up-regulation can be attributed in part to constitutive activation of NF-kappa B. Previous studies have shown an elevated basal I kappa B kinase (IKK) activity in Hs294T melanoma cells, which leads to an increased rate of I kappa B phosphorylation and degradation. This increase in I kappa B-alpha phosphorylation and degradation leads to an approximately 19-fold higher nuclear localization of NF-kappa B. However, the upstream IKK kinase activity is up-regulated by only about 2-fold and cannot account for the observed increase in NF-kappa B activity. We now demonstrate that NF-kappa B-inducing kinase (NIK) is highly expressed in melanoma cells, and IKK-associated NIK activity is enhanced in these cells compared with the normal cells. Kinase-dead NIK blocked constitutive NF-kappa B or CXCL1 promoter activity in Hs294T melanoma cells, but not in control normal human epidermal melanocytes. Transient overexpression of wild type NIK results in increased phosphorylation of extracellular signal-regulated kinases 1 and 2 (ERK1/2), which is inhibited in a concentration-dependent manner by PD98059, an inhibitor of p42/44 MAPK. Moreover, the NF-kappa B promoter activity decreased with overexpression of dominant negative ERK expression constructs, and EMSA analyses further support the hypothesis that ERK acts upstream of NF-kappa B and regulates the NF-kappa B DNA binding activity. Taken together, our data implicate involvement of I kappa B kinase and MAPK signaling cascades in NIK-induced constitutive activation of NF-kappa B.     

A novel dimeric dipeptide mimetic of the BDNF selectively activates the MAPK-Erk signaling pathway

On the basis of the structure of beta-turn of loop 2 of brain-derived neurotrophic factor (BDNF), its new dimeric dipeptide mimetic bis-(N-hexanoyl-L-seryl-L-lysine) hexamethylenediamide (GTS-201) was created. It activated TrkB and Erk, did not activate Akt, and exhibited neuroprotective activity in vitro at concentrations of 10^–5–10^–8 M. Unlike the mimetics that activate Erk and Akt, GTS-201 did not exhibit antidepressant properties. For the manifestation of the antidepressant activity of BDNF mimetics, the activation of its both major signaling pathways is required.     

Proteins of the Ras pathway as novel potential anticancer therapeutic targets

Ras proteins are molecular switches that constitute a pivotal element in the control of cellular responses to many incoming signals, and in particular mitogenic stimulations. They act through multiple effector pathways that carry out the biological functions of Ras in cells. Since mutations that constitutively activate Ras proteins have been found in a high proportion of human malignancies and participate in oncogenesis, a number of therapeutic anticancer strategies aimed against the activity or action of Ras proteins have been developed. This paper reviews the principal aspects of the Ras signaling pathway and describes some of the attempts to develop antitumor drugs based on this concept. This revised version was published online in July 2006 with corrections to the Cover Date.