Calcium responses mediated by type 2 IP3-receptors are required for osmotic volume regulation of retinal glial cells in mice

Prevention of osmotic swelling of retinal glial (Müller) cells is required to avoid detrimental decreases in the extracellular space volume during intense neuronal activity. Here, we show that glial cells in slices of the wildtype mouse retina maintain the volume of their somata constant up to ∼4 min of perfusion with a hypoosmolar solution. However, calcium chelation with BAPTA/AM induced a rapid swelling of glial cell bodies. In glial cells of retinas from inositol-1,4,5-trisphosphate-receptor type 2-deficient (IP₃R2^−/−) mice, hypotonic conditions caused swelling of the cell bodies without delay. Exogenous ATP (acting at P2Y₁ receptors) prevented the swelling of glial cells in retinal slices from wildtype but not from IP₃R2^−/− mice. Müller cells from IP₃R2^−/− mice displayed a strongly reduced amplitude of the ATP-evoked calcium responses as compared to cells from wildtype mice. It is concluded that endogenous calcium signaling mediated by IP₃R2 is required for the osmotic volume regulation of retinal glial cells.     

Selection process generating peptide aptamers and analysis of their binding to the TiO2 surface of a surface acoustic wave sensor

The set-up presented in this article is intended for the selection of peptides which serve as specific binders to suitable materials. Additionally, the interaction of such binders with material surfaces can be characterized. Using this approach, a subset of peptides which adhere to the mineral TiO(2) was generated by means of a cell surface display library. The peptides are constrained by a thioredoxin scaffold. Selection of proteins was carried out on a silicium wafer sputtered with TiO(2) in anatase conformation. To verify binders and to analyze the binding kinetics of the diluted suspension of the purified proteins, the chip-based S-sens K5 surface acoustic wave sensor system was used. The surface of the sensor chips was also TiO(2), resembling the material of the Si wafer selection target retaining the peptides. Several peptides were identified. The respective binding behavior differed. The data derived from real-time interaction analysis were evaluated to select for strong and specific binders. For one of these peptides, the binding kinetics was analyzed. On- and off-rate binding constants were extracted from the fitted curves. With the resulting association rate constant k(on) and the dissociation constant k(off), the affinity of the peptide for the TiO(2) surface was calculated, represented by the equilibrium dissociation constant K(D)=81 nM.     

Differential Interferon Responses Enhance Viral Epitope Generation by Myocardial Immunoproteasomes in Murine Enterovirus Myocarditis

Murine models of coxsackievirus B3 (CVB3)-induced myocarditis mimic the divergent human disease course of cardiotropic viral infection, with host-specific outcomes ranging from complete recovery in resistant mice to chronic disease in susceptible hosts. To identify susceptibility factors that modulate the course of viral myocarditis, we show that type-I interferon (IFN) responses are considerably impaired in acute CVB3-induced myocarditis in susceptible mice, which have been linked to immunoproteasome (IP) formation. Here we report that in concurrence with distinctive type-I IFN kinetics, myocardial IP formation peaked early after infection in resistant mice and was postponed with maximum IP expression concomitant to massive inflammation and predominant type-II IFN responses in susceptible mice. IP activity is linked to a strong enhancement of antigenic viral peptide presentation. To investigate the impact of myocardial IPs in CVB3-induced myocarditis, we identified two novel CVB3 T cell epitopes, virus capsid protein 2 [285-293] and polymerase 3D [2170-2177]. Analysis of myocardial IPs in CVB3-induced myocarditis revealed that myocardial IP expression resulted in efficient epitope generation. As opposed to the susceptible host, myocardial IP expression at early stages of disease corresponded to enhanced CVB3 epitope generation in the hearts of resistant mice. We propose that this process may precondition the infected heart for adaptive immune responses. In conclusion, type-I IFN-induced myocardial IP activity at early stages coincides with less severe disease manifestation in CVB3-induced myocarditis.Myocarditis is often induced by cardiotropic viruses: in about 20% of patients, viral myocarditis leads to its sequela dilated cardiomyopathy, which is linked to chronic inflammation and persistence of cardiotropic viruses.^1,2,3,4 Dilated cardiomyopathy is the most common cause of heart failure in young patients and appears to be a major cause of sudden unexpected death in this cohort. Enteroviruses, including group-B coxsackieviruses, have been linked to the development of myocarditis and dilated cardiomyopathy associated with adverse prognosis.^5,6 Well-established murine models of coxsackievirus B3 (CVB3) myocarditis mimic the human disease progress and are valuable in delineating the underlying mechanisms that determine the divergent courses of myocarditis^7,8,9,10: resistant C57BL/6 mice eliminate the virus following mild acute myocarditis; no chronic inflammation is detected. In contrast, major histocompatibility complex (MHC)-matched A.BY/SnJ mice develop severe acute infection and ongoing chronic myocarditis, thus conferring susceptibility to chronic disease.^7,9Host responses to viral infection trigger the release of interferons (IFNs). IFNs of the α/β subtype are assigned to type I IFNs, whereas IFN-γ is the only type II IFN. IFNs exert numerous antiviral effects in innate and adaptive immunity.¹¹ Although type I IFN-receptor-deficiency was not associated with a dramatic effect on early viral replication in the heart, type I IFN signaling was found to be essential for the prevention of early death due to CVB3-infection.¹² The extraordinary impact of type I IFNs was substantiated in a recent study illustrating acute fulminant infection and chronic disease progression in IFN-β deficient mice.¹³ Deletion of type II IFN receptors was not associated with enhanced mortality in CVB3-infection.¹² IFN-γ responses were shown to be protective in cellular immunity in CVB3-infection.⁹ In addition, expression of IFN-γ conferred protection in enterovirus myocarditis, which may be linked to the activation of nitric oxide-mediated antiviral activity of macrophages.^14,15 Thus, both type I and type II IFN are active in CVB3- myocarditis.One downstream effect of IFN signaling is the induction of immunoproteasome (IP) formation in the target organ of the immune response. Particularly IFN-γ was shown to induce IP expression.^16,17,18 Efficient generation of viral epitopes that stimulate CD8⁺ T cells strongly relies on host-cell IP and, in addition, protein degradation by proteasomes is also essential in the regulation of inflammatory and stress responses, cell cyclus, and apoptosis control.¹⁹ The 20S proteasome as the catalytic core of the proteasome resembles a cylinder-shaped structure of stacked heptameric rings formed by either α or β subunits. The proteolytic function of the so-called standard proteasome is restricted to the β1, β2, and β5 subunit.²⁰ Three alternative catalytic subunits, the so-called immunosubunits β1i, β2i, and β5i, which are incorporated into 20S proteasomes, thus forming IP with altered catalytic characteristics, are expressed on cytokine stimulation.^21,22 It is highly notable that IP activity is linked to a strong enhancement of antigenic viral peptide presentation.^{23,24,25,26,27}Cardiac proteasomes contribute to the modulation of cardiac function in health and disease.²⁸ However, apart from the reported observation that IPs are expressed in the myocardium in acute CVB3 myocarditis, their functional impact has not been studied so far.¹⁰ The present study focuses on IFN-induced myocardial IP activity in CVB3 myocarditis.     

Essential Role of Osteopontin in Smoking-Related Interstitial Lung Diseases

Smoking-related interstitial lung diseases are characterized by the accumulation of macrophages and Langerhans cells, and fibrotic remodeling, which are linked to osteopontin (OPN) expression. Therefore, OPN levels were investigated in bronchoalveolar lavage (BAL) cells in 11 patients with pulmonary Langerhans cell histiocytosis (PLCH), 15 patients with desquamative interstitial pneumonitis (DIP), 10 patients with idiopathic pulmonary fibrosis, 5 patients with sarcoidosis, 13 otherwise healthy smokers, and 19 non-smoking controls. Furthermore, OPN overexpression was examined in rat lungs using adenoviral gene transfer. We found that BAL cells from patients with either PLCH or DIP spontaneously produced abundant amounts of OPN. BAL cells from healthy smokers produced 15-fold less OPN, and those cells from non-smoking healthy volunteers produced no OPN. BAL cells from patients with either idiopathic pulmonary fibrosis or sarcoidosis produced significantly less OPN, as compared with patients with PLCH. These data were confirmed by immunochemistry. Nicotine stimulation increased production of both OPN and granulocyte-macrophage colony stimulating factor by alveolar macrophages from smokers. Nicotinic acetylcholine receptor expression resembled the pattern of spontaneous OPN production and was dramatically increased in both PLCH and DIP. OPN overexpression in rat lungs induced lesions similar to PLCH with marked alveolar and interstitial accumulation of Langerhans cells. Our findings suggest a pathogenetic role of increased OPN production in both PLCH and DIP by promoting the accumulation of macrophages and Langerhans cells.Cigarette smoke is linked to a variety of lung diseases including chronic obstructive pulmonary disease, lung cancer, and interstitial lung diseases. Respiratory bronchiolar interstitial lung disease, desquamative interstitial pneumonitis (DIP), and pulmonary Langerhans cell histiocytosis (PLCH) belong to the group of smoking-related interstitial lung diseases.^1,2,3 Cigarette smoke is a complex mixture of more than 4000 compounds and is known to cause systemic and pulmonary effects.⁴ However, the underlying mechanisms as to how cigarette smoking leads to the changes observed in smoking-related interstitial lung diseases are largely unknown.^1,2,3Cigarette smoke induces inflammation, oxidative stress, and tissue injury, and has an important effect on the number, distribution, and activation state of macrophages and Langerhans cells.^5,6 There is a strong epidemiological link between PLCH and smoking. PLCH is characterized by the accumulation of activated Langerhans cells originating from the distal bronchiole walls.^1,2,3,7 The accumulations of Langerhans cells are poorly demarcated and extend to the adjacent alveoli, which often contain an abundance of pigmented macrophages. These areas show morphological changes similar to DIP.^7,8 In DIP, the predominant feature is the accumulation of alveolar macrophages, densely filling the alveolar lumen, combined with moderate fibrotic interstitial remodeling.^1,2As measured by bronchoalveolar lavage (BAL) in healthy individuals, cigarette smoking induces a 5- to 10-fold increase in alveolar macrophages in a dose-response curve.^9,10,11 It was shown that concentrations of granulocyte-macrophage colony stimulating factor (GMCSF) in patients with PLCH are increased,¹² but the mechanisms that lead to the expansion of the pulmonary macrophage pool and fibrosis in smokers are poorly understood.^1,2,3 Based on the findings of a microarray study, Woodruff et al¹³ have recently proposed that alveolar macrophages from smokers exhibit a distinctive macrophage activation state that is accompanied by increased OPN expression. Osteopontin is a glycoprotein found in the extracellular matrix of bone.¹⁴ However, multiple studies have reported cytokine properties of OPN in cell-mediated immunity.¹⁴ Further, OPN exhibits a strong chemotactic activity for macrophages, monocytes, Langerhans cells, and dendritic cells.^15,16,17In the context of these findings we speculated that OPN might be involved in the pathogenesis of smoking-related lung interstitial diseases. We found abundant OPN production by alveolar macrophages from patients with PLCH and DIP. Alveolar macrophages from both healthy smokers and patients with DIP and PLCH show up-regulated nicotine receptor expression as a sign of chronic nicotine stimulation. Further, nicotine directly induced OPN and GMCSF in alveolar macrophages. Our data provides evidence for a role of osteopontin in the pathogenesis of smoking- related interstitial lung diseases.     

Stem-cell-like glioma cells are resistant to TRAIL/Apo2L and exhibit down-regulation of caspase-8 by promoter methylation

Tumour necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL/Apo2L) is a promising cancer drug. However, many tumours are resistant to TRAIL-based therapies. Glioma cells with stem cell features (SCG), such as CD133 expression and neurosphere formation, have been recently identified to be more resistant to cytotoxic drugs than glioma cells lacking stem-cell-like features (NSCGs). Here we report that SCGs are completely resistant to 100–2,000 ng/ml TRAIL, whereas NSCGs revealed a moderate sensitivity to TRAIL. We found that SCGs exhibited only low levels of caspase-8 mRNA and protein, known to be indispensable for TRAIL-induced apoptosis. In addition, we detected hypermethylation of CASP8 promoter in SCGs, whereas NSCGs exhibited a non-methylated CASP8 promoter. Reexpression of caspase-8 by 5-Aza-2′-deoxycytidine was not sufficient to restore TRAIL sensitivity in SCGs cells, suggesting that additional factors cause TRAIL resistance in SCGs. Our data suggest that therapy with TRAIL, either as monotherapy or in combination with demethylating agents, is not effective in treating glioblastoma because SCGs are not targeted by such treatment.     

Does age matter? - A MRI study on peritumoral edema in newly diagnosed primary glioblastoma

Background  

Peritumoral edema is a characteristic feature of malignant glioma related to the extent of neovascularisation and to vascular endothelial growth factor (VEGF) expression.     

Antibody microarray analysis of the serum proteome in primary breast cancer patients

Noninvasive biomarkers are urgently needed for detecting breast cancer as early as possible since the risk of recurrence, morbidity, and mortality is closely related to disease stage at the time of primary surgery. There are currently no such biomarkers in clinical use as a diagnostic tool. Proteomic analysis of protein expression patterns in body fluids has potential for use in identifying biomarkers of breast cancer. The aim of this study was to compare protein expression levels in the sera of primary breast cancer patients and healthy controls. An antibody microarray tool with 23 antibodies immobilized on nitrocellulose slides was used to determine the levels of acute phase proteins, interleukins, and complement factors in the sera of 101 study participants (49 women with primary breast cancer and 52 healthy age-matched controls). Statistical analysis of reaction intensities identified 6 proteins that showed significantly (p < 0.05) different levels in breast cancer patients vs. healthy subjects. The neural network distinguished cancer patients from controls with a sensitivity of 69% and a specificity of 76%. Thus, antibody microarray analysis could be used as a tool for the development of improved diagnostics and biomarker discovery for breast cancer patients. Further validation of the results and de novo screening of new biomarkers could facilitate the early diagnosis of breast cancer.     

A population pharmacokinetic model for pegylated-asparaginase in children

We analysed 1221 serum activity measurements in 168 children from the Berlin-Frankfürt-Münster acute lymphoblastic leukaemia studies, ALL-BFM (Berlin-Frankfürt-Münster) 95 and ALL-BFM REZ, in order to develop a pharmacokinetic model describing the activity-time course of pegylated (PEG)-asparaginase for all dose levels. Patients received 500, 750, 1000 or 2500 U/m² PEG-asparaginase on up to nine occasions. Serum samples were analysed for asparaginase activity and data analysis was done using nonlinear mixed effects modelling (NONMEM Vers. VI, Globomax, Hanouet, MD, USA). Different linear and nonlinear models were tested. The best model applicable to all dosing groups was a one-compartmental model with clearance (Cl) increasing with time according to the formula: Cl=Cl_i * e ^{(0·0793 * t )} where Cl_i = initial clearance and t  = time after dose. The parameters found were: volume of distribution ( V ) 1·02 ± 26% l/m², Cl_i 59·9 ± 59% ml/d per m² (mean ± interindividual variability). Interoccasion variability was substantial with 0·183 l/m² for V and 44·7 ml/d per m² for Cl, respectively. A subgroup of the patients showed a high clearance, probably due to the development of inactivating antibodies. This is the first model able to predict the activity-time course of PEG-asparaginase at different dosing levels and can therefore be used for developing new dosing regimens.     

Distant Relatives of Severe Acute Respiratory Syndrome Coronavirus and Close Relatives of Human Coronavirus 229E in Bats, Ghana

We tested 12 bat species in Ghana for coronavirus (CoV) RNA. The virus prevalence in insectivorous bats (n = 123) was 9.76%. CoV was not detected in 212 fecal samples from Eidolon helvum fruit bats. Leaf-nosed bats pertaining to Hipposideros ruber by morphology had group 1 and group 2 CoVs. Virus concentrations were <45,000 copies/100 mg of bat feces. The diversified group 1 CoV shared a common ancestor with the human common cold virus hCoV-229E but not with hCoV-NL63, disputing hypotheses of common human descent. The most recent common ancestor of hCoV-229E and GhanaBt-CoVGrp1 existed in ≈1686–1800 ad. The GhanaBt-CoVGrp2 shared an old ancestor (≈2,400 years) with the severe acute respiratory syndrome–like group of CoV.     

The emerging role of T cell Ig mucin 1 in alloimmune responses in an experimental mouse transplant model

T cell Ig mucin 1 (TIM-1) plays an important role in regulating immune responses in autoimmune and asthma models, and it is expressed on both Th1 and Th2 cells. Using an antagonistic TIM-1-specific antibody, we studied the role of TIM-1 in alloimmunity. A short course of TIM-1-specific antibody monotherapy prolonged survival of fully MHC-mismatched vascularized mouse cardiac allografts. This prolongation was associated with inhibition of alloreactive Th1 responses and preservation of Th2 responses. TIM-1-specific antibody treatment was more effective in Th1-type cytokine-deficient Stat4(-/-) recipients as compared with Th2-type cytokine-deficient Stat6(-/-) recipients. Subtherapeutic doses of rapamycin plus TIM-1-specific antibody resulted in allograft acceptance and prevented the development of chronic allograft vasculopathy. Allograft survival via this treatment was accompanied by a Th1- to Th2-type cytokine switch. Depletion of natural Tregs abrogated the graft-protecting effect of the TIM-1-specific antibody. Importantly, CD4(+)CD25(+) Tregs obtained from long-term survivors had enhanced regulatory activity as compared with naive CD4(+)CD25(+) Tregs. Consistent with this, TIM-1-specific antibody treatment both preserved Tregs and prevented the expansion of alloreactive effector Th1 cells in an alloreactive TCR transgenic adoptive transfer model. These studies define previously unknown functions of TIM-1 in regulating alloimmune responses in vivo and may provide a novel approach to promoting transplantation tolerance.