“Silenced” polydendrocytes: a new cell type within the oligodendrocyte progenitor cell population?

Oligodendrocyte progenitor cells (OPCs) were first described more than two decades ago. Novel labeling techniques have shown them to be cells with more than just progenitor functions, with their classification as a fourth glial cell type in addition to astrocytes, oligodendrocytes, and microglial cells. Another term used for this cell type is polydendrocytes, owing to both their morphology and to the evolving knowledge about their diverse functions. Recently, an exclusive hallmark of neurons—the generation of action potentials—became debatable, because a subset of polydendrocytes was reported to generate action potentials in response to adequate stimuli. The new technique of inducible reporter gene expression has brought new insights into the fate and function of polydendrocytes. In recent studies, so-called “silenced” OPCs were detected in cortical tissue, and which underwent proliferation with subsequent cell cycle exit, but without any signs of differentiation. Within this review, we focus on the identification of this new subset of polydendrocytes and their possible functions within cortical networks.     

Loss of protein-tyrosine phosphatase α (PTPα) increases proliferation and delays maturation of oligodendrocyte progenitor cells

Tightly controlled termination of proliferation determines when oligodendrocyte progenitor cells (OPCs) can initiate differentiation and mature into myelin-forming cells. Protein-tyrosine phosphatase α (PTPα) promotes OPC differentiation, but its role in proliferation is unknown. Here we report that loss of PTPα enhanced in vitro proliferation and survival and decreased cell cycle exit and growth factor dependence of OPCs but not neural stem/progenitor cells. PTPα(-/-) mice have more oligodendrocyte lineage cells in embryonic forebrain and delayed OPC maturation. On the molecular level, PTPα-deficient mouse OPCs and rat CG4 cells have decreased Fyn and increased Ras, Cdc42, Rac1, and Rho activities, and reduced expression of the Cdk inhibitor p27Kip1. Moreover, Fyn was required to suppress Ras and Rho and for p27Kip1 accumulation, and Rho inhibition in PTPα-deficient cells restored expression of p27Kip1. We propose that PTPα-Fyn signaling negatively regulates OPC proliferation by down-regulating Ras and Rho, leading to p27Kip1 accumulation and cell cycle exit. Thus, PTPα acts in OPCs to limit self-renewal and facilitate differentiation.     

IFN-γ-induced apoptosis of human embryonic stem cell derived oligodendrocyte progenitor cells is restricted by CXCR2 signaling

Engraftment of human embryonic stem cell (hESC)-derived OPCs in animal models of demyelination results in remyelination and clinical recovery, supporting the feasibility of cell replacement therapies in promoting repair of damaged neural tissue. A critical gap in our understanding of the mechanisms associated with repair revolves around the effects of the local microenvironment on transplanted cell survival. We have determined that treatment of human ESC-derived OPCs with the pleiotropic cytokine IFN-γ promotes apoptosis that is associated with mitochondrial cytochrome c released into the cytosol with subsequent caspase 3 activation. IFN-γ-induced apoptosis is mediated, in part, by secretion of the CXC chemokine ligand 10 (CXCL10) from IFN-γ-treated cells. Signaling through the chemokine receptor CXCR2 by the ligand CXCL1 functions in a tonic manner by muting apoptosis and this is associated with reduced levels of cytosolic cytochrome c and impaired cleavage of caspase 3. These findings support a role for both IFN-γ and CXCL10 in contributing to neuropathology by promoting OPC apoptosis. In addition, these data suggest that hOPCs used for therapeutic treatment for human neurologic disease/damage are susceptible to death through exposure to local inflammatory cytokines present within the inflammatory milieu.     

Comparison of morphological effects of PGE2 and TGFβ on osteoclastogenesis induced by RANKL in mouse bone marrow cell cultures

RANKL, in the presence of M-CSF, induces the development and fusion of TRAP+ osteoclasts in mouse bone marrow cultures at 3–5 days. Early during culture (day 3), most cells are small (up to six nuclei). At lower cell densities, these osteoclasts exhibit a rounded morphology with cytoplasm extending around the cells but, at higher densities, this changes to a stellate morphology with the cytoplasm being retracted around the nuclei with numerous localised cytoplasmic extensions. Under optimal conditions, osteoclast fusion results in conglomerates of many cells, which become large cytoplasmic masses on day 4. PGE2 and TGFβ have both been shown to increase osteoclast development in this model and their effects on the morphology of osteoclasts during fusion and differentiation have been compared under all these conditions. PGE2 or TGFβ increase osteoclast numbers and size and also the number of nuclei, indicating increased osteoclast development and fusion. TGFβ increases the size of rounded osteoclasts (with respect to the number of nuclei) more than PGE2, suggesting that TGFβ increases cytoplasmic extension. TGFβ increases the size and number of nuclei in stellate cells but particularly increases the number and length of the cytoplasmic extensions, in contrast to PGE2. Fusion of these extensions with other osteoclasts results in large networks of interconnected cells. On day 4, spreading cells develop but these are still interconnected by cytoplasmic links, a phenomenon not seen in control wells or after treatment with PGE2. TGFβ is more effective than PGE2 in increasing fusion in the formation of cell conglomerates and cytoplasmic masses. PGE2 decreases overall cell density resulting in additional indirect effects on osteoclast numbers and morphology. However, PGE2 particularly promotes the formation of large mature spreading osteoclasts later during culture.     

δ-Aminolevulinic acid effects on neuronal and glial tumor cell lines

Acute intermittent porphyria (AIP) or precursor syndrome is a well described neuropathic clinical entity with incompletely known etiology. The most prominent biological abnormalities associated with this syndrome are elevations in serum and hepatic -aminolevulinic acid (ALA) and porphobilinogen (PBG). We determined the impact of ALA and PBG on human neuroblastoma and glioblastoma tumor cell survival as measured by the MTT assay. ALA proved to be cytotoxic in neuroblastoma cells, while PBG lacked cytotoxic effects. This cytotoxic effect of ALA could be enhanced by deferoxamine and diminished by heme, presumably through modulation of ALA synthesis. In conclusion, ALA excess may prove to be associated with the development of neuropathy in AIP.     

Structure of proteins under pressure: Covalent binding effects of biliverdin on β-lactoglobulin

High pressure (HP) is a particularly powerful tool to study protein folding/unfolding, revealing subtle structural rearrangements. Bovine β-lactoglobulin (BLG), a protein of interest in food science, exhibits a strong propensity to bind various bioactive molecules. We probed the effects of the binding of biliverdin (BV), a tetrapyrrole linear chromophore, on the stability of BLG under pressure, by combining in situ HP small-angle neutron scattering (SANS) and HP-UV absorption spectroscopy. Although BV induces a slight destabilization of BLG during HP-induced unfolding, a ligand excess strongly prevents BLG oligomerization. Moreover, at SANS resolution, an excess of BV induces the complete recovery of the protein “native” 3D structure after HP removal, despite the presence of the BV covalently bound adduct. Mass spectrometry highlights the crucial role of cysteine residues in the competitive and protective effects of BV during pressure denaturation of BLG through SH/S-S exchange.     

Regulation of breast cancer-induced bone lesions by β-catenin protein signaling

Breast cancer patients have an extremely high rate of bone metastases. Morphological analyses of the bones in most of the patients have revealed the mixed bone lesions, comprising both osteolytic and osteoblastic elements. β-Catenin plays a key role in both embryonic skeletogenesis and postnatal bone regeneration. Although this pathway is also involved in many bone malignancy, such as osteosarcoma and prostate cancer-induced bone metastases, its regulation of breast cancer bone metastases remains unknown. Here, we provide evidence that the β-catenin signaling pathway has a significant impact on the bone lesion phenotype. In this study, we established a novel mouse model of mixed bone lesions using intratibial injection of TM40D-MB cells, a breast cancer cell line that is highly metastatic to bone. We found that both upstream and downstream molecules of the β-catenin pathway are up-regulated in TM40D-MB cells compared with non-bone metastatic TM40D cells. TM40D-MB cells also have a higher T cell factor (TCF) reporter activity than TM40D cells. Inactivation of β-catenin in TM40D-MB cells through expression of a dominant negative TCF4 not only increases osteoclast differentiation in a tumor-bone co-culture system and enhances osteolytic bone destruction in mice, but also inhibits osteoblast differentiation. Surprisingly, although tumor cells overexpressing β-catenin did induce a slight increase of osteoblast differentiation in vitro, these cells display a minimal effect on osteoblastic bone formation in mice. These data collectively demonstrate that β-catenin acts as an important determinant in mixed bone lesions, especially in controlling osteoblastic effect within tumor-harboring bone environment.     

Structure determination of α-helical membrane proteins by solution-state NMR: Emphasis on retinal proteins

The biochemical processes of living cells involve a numerous series of reactions that work with exceptional specificity and efficiency. The tight control of this intricate reaction network stems from the architecture of the proteins that drive the chemical reactions and mediate protein–protein interactions. Indeed, the structure of these proteins will determine both their function and interaction partners. A detailed understanding of the proximity and orientation of pivotal functional groups can reveal the molecular mechanistic basis for the activity of a protein. Together with X-ray crystallography and electron microscopy, NMR spectroscopy plays an important role in solving three-dimensional structures of proteins at atomic resolution. In the challenging field of membrane proteins, retinal-binding proteins are often employed as model systems and prototypes to develop biophysical techniques for the study of structural and functional mechanistic aspects. The recent determination of two 3D structures of seven-helical trans-membrane retinal proteins by solution-state NMR spectroscopy highlights the potential of solution NMR techniques in contributing to our understanding of membrane proteins. This review summarizes the multiple strategies available for expression of isotopically labeled membrane proteins. Different environments for mimicking lipid bilayers will be presented, along with the most important NMR methods and labeling schemes used to generate high-quality NMR spectra. The article concludes with an overview of types of conformational restraints used for generation of high-resolution structures of membrane proteins. This article is part of a Special Issue entitled: Retinal Proteins — You can teach an old dog new tricks.     

Regulation of extracellular proteins and α-amylase secretion by temperature inBacillus subtilis

α-Amylase was found to be the main protein secreted byBacillus subtilis, corresponding to 90, 87 and 60% of total extracellular proteins at 30, 40 and 45°C, respectively. A change in temperature can affect the pattern of proteins secreted as detected by gel electrophoresis.¹⁴C-Leucine incorporation into extracellular proteins and their proportion at the end of the growth phase was higher at 30°C than that at 40 or 45°C. The effect of temperature on α-amylase synthesis as determined by its enzymic activity and on the extracellular protein synthesis followed a similar pattern.     

Regulation of Steatohepatitis and PPARγ Signaling by Distinct AP-1 Dimers

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Denaturation of proteins by ascorbic acid: Effects on dopamine-β-hydroxylase

Under conditions that are optimum for DH, ascorbic acid denatures serum albumin, -globulin, catalase, and D\H. With ascorbate plus Cu²⁺, the proteins arc almost completely destroyed. Pyrazole protects DH and albumin, but not catalase. Superoxide dismutase (SOD) is not denatured by ascorbate, with or without Cu²⁺, and in combination with catalytic amounts of catalase or Fe²⁺ it stimulates maximum DH activity. In other words, a combination of catalase and SOD, or Fe²⁺ and SOD, will protect DH. Excessive amounts of catalase and/or other protein, either native or denatured will prevent the effects of superoxide and/or ascorbate, but cannot replace the requirements for catalytic quantities of catalase or Fe²⁺. The results suggest that the rate of hydroxylation of tyramine may be limited by superoxide, but that the latter per se does not denature DH as does hydrogen peroxide. The in vitro activation of oxygen by DH is a toxic process, involving the production of both hydrogen peroxide and superoxide and possibly other free radicals. In the absence of precise regulation of the production and concentrations of these compounds, the enzyme is denatured.     

Regulation of the cytotoxic effect of human ‘normal killer cells’ on tumor cell lines by neuraminidase-treated T-lymphocytes

Summary Subpopulations of peripheral blood lymhocytes (PBL) from healthy individuals were separated according to their capacity to form various rosettes and tested for their cytotoxic activity on cell lines of urinary bladder and breast carcinomas. The subpopulation exerting the highest natural cytotoxic activity was characterized by the presence of cell surface Fc-receptors and by the lack of receptors for sheep red blood cells and for C'3 on their surface. Treatment with vibrio cholera neuraminidase (VCN) increased the cytotoxicity of unseparated PBL to a level twice as high as that of untreated PBL. The attachment of T-lymphocytes to tumor monolayers was increased several fold after VCN-treatment, while the attachment of other lymphocyte subpopulations was not. Evidence is presented that the augmentation of the cytotoxicity of PBL following VCN-treatment results from the interaction of VCN-treated T-lymphocytes, attached to target cells, with normal killer cells. It is suggested that augmentation of the activity of killer cells by T-lymphocytes may play a role in antitumor defense mechanisms.Abbreviations CMC Cell-mediated cytolysis - E-rosettes Rosettes formed with sheep red blood cells - EA-rosettes Rosettes formed with red blood cells coated with antibody - EAC'-rosettes Rosettes formed with red blood cells coated with antibody and complement - FCS Heat inactivated fetal calf serum - PBL Peripheral blood lymphocytes - RBC Red blood cells - RF-TAL E-rosette forming, target-attached lymphocytes - SRBC Sheep red blood cells - VCN Vibrio cholera neuraminidase     

The effect of interferon-β on mouse neural progenitor cell survival and differentiation

Interferon-β (IFN-β) is a mainstay therapy for relapse-remitting multiple sclerosis (MS). However, the direct effects of IFN-β on the central nervous system (CNS) are not well understood. To determine whether IFN-β has direct neuroprotective effects on CNS cells, we treated adult mouse neural progenitor cells (NPCs) in vitro with IFN-β and examined the effects on proliferation, apoptosis, and differentiation. We found that mouse NPCs express high levels of IFNα/β receptor (IFNAR). In response to IFN-β treatment, no effect was observed on differentiation or proliferation. However, IFN-β treated mouse NPCs demonstrated decreased apoptosis upon growth factor withdrawal. Pathway-specific polymerase chain reaction (PCR) arrays demonstrated that IFN-β treatment upregulated the STAT 1 and 2 signaling pathway, as well as GFRA2, NOD1, Caspases 1 and 12, and TNFSF10. These results suggest that IFN-β can directly affect NPC survival, possibly playing a neuroprotective role in the CNS by modulating neurotrophic factors.