Disialogangliosides and TNFα Alter Gene Expression for Cytokines and Chemokines in Primary Brain Cell Cultures

Gangliosides have long been implicated in multiple pathologies affecting the central nervous system. Empirical studies have suggested the possibility that gangliosides, particularly GD3, work in tandem with pro-inflammatory cytokines, especially tumor necrosis factor alpha (TNFα), to initiate or facilitate cell death in the CNS. As a step toward unraveling the metabolic pathways activated in the pathogenesis of brain cell death, we have surveyed gene expression for a host of cytokines and chemokines in primary brain cell cultures exposed to GD3, GD1b, and TNFα for 24 h. An initial screen of 98 genes on a focused mini-array revealed the expression of at least 28 genes related to cell growth, death, or inflammation in our system of mixed cells cultured from neonatal rat brains. Clear evidence of a differential response to the gangliosides or TNFα was seen in 12 genes. Quantitative PCR was used to validate the response of six of these genes. We found that both GD3 and GD1b, but not TNFα, up-regulated expression of macrophage inflammatory protein 3 (MIP3A) and interleukin-1 receptor 1 (IL1R1), but down-regulated fibroblast growth factor 13 (FGF13). The expression of FGF receptor activating protein 1 (FRAG1) and interleukin-3 receptor alpha (IL3RA) was down-regulated by GD3. Exposure to TNFα resulted in a dramatic up-regulation of IL3RA and chemokine ligand 2 (CCL2), both of which have been implicated in multiple sclerosis. Our results provide strong evidence that the expression of these genes might be critical links in the metabolic cascades leading to cell degeneration and death in the brain.     

Inflammation and Programmed Cell Death in Alzheimer’s Disease: Comparison of the Central Nervous System and Peripheral Blood

Although the central nervous system (CNS) has been defined as a privileged site in Alzheimer’s disease (AD), periphery can be more than simply witness of events leading to neurodegeneration. The CNS and peripheral blood can mutually communicate through cells and factors trafficking from the circulation into the brain and vice versa. A number of articles have reviewed inflammatory profiles and programmed cell death (PCD) in AD, separately in the CNS and at the peripheral level. This review does not provide an exhaustive account of what has been published on inflammation and PCD in AD. Rather, the aim of this review is to focus on possible linkages between the central and the peripheral compartments during AD progression, by critically analyzing, in a comparative manner, phenomena occurring in the CNS as well as the peripheral blood. In fact, growing evidence suggests that CNS and peripheral inflammation might present common features in the disease. Microarrays and metabolomics revealed that dysfunction of the glycolytic and oxidative pathways is similar in the brain and in the periphery. Moreover, dysregulated autophagosome/lysosomal molecular machinery, both at the CNS and the peripheral level, in AD-related cell damage, has been observed. Possible implications of these observations have been discussed.     

Hypothalamo–Pituitary System Controls the Development of Humoral Immune Response during Prenatal Ontogenesis in Rats

We studied the influence of the neuroendocrine system on the development of humoral immune response to sheep erythrocytes in rat fetuses. The removal of brain in utero by decapitation of 18-day fetuses induced a fourfold increase in the number of antibody-forming cells in the liver, as compared to the unoperated fetuses. After the removal of the forebrain, including hypothalamus (encephalectomy), the number of antibody-forming cells was comparable to that in unoperated fetuses. The observed increase in the number of antibody-forming cells in the liver was not due to a disturbed migration of precursors of B-lymphocytes in the spleen, since their content in the spleen was also four times that in the encephalectomized and unoperated fetuses. The increased number of antibody-forming cells in decapitated fetuses could be due to an enhanced proliferative activity of the lymphocytes in the liver of these fetuses. It has been proposed that humoral immunity is controlled by the hypothalamo–pituitary–adrenal system already during prenatal development; the adrenocorticotropic hormone and glucocorticoids appear to be involved in this regulation.     

Gene Expression of the EGF System—a Prognostic Model in Non–Small Cell Lung Cancer Patients Without Activating EGFR Mutations

OBJECTIVES: Contradicting results have been demonstrated for the expression of the epidermal growth factor receptor (EGFR) as a prognostic marker in non–small cell lung cancer (NSCLC). The complexity of the EGF system with four interacting receptors and more than a dozen activating ligands is a likely explanation. The aim of this study is to demonstrate that the combined network of receptors and ligands from the EGF system is a prognostic marker. MATERIAL AND METHODS: Gene expression of the receptors EGFR, HER2, HER3, HER4, and the ligands AREG, HB-EGF, EPI, TGF-α, and EGF was measured by quantitative polymerase chain reaction in tumor samples from 100 NSCLC patients without EGFR activating mutations. Results were dichotomized into high or low levels of target expression. Coexpression of the ligands and receptors was observed, and a score was developed based on the summed effect of receptors and ligands. Akaike’s information criteria selected the optimal score. Results were correlated with age, sex, stage, histology, performance status, and overall survival. RESULTS: Patients were randomly split 1:1 to create test and validation cohorts. In multivariate analyses, the only individual prognostic marker was EPI (hazard ratio [HR] 0.38 [0.20-0.72], P = .003). The optimal score in the test cohort was validated as a marker of inferior survival in the validation cohort and by bootstrapping. Multivariate analysis confirmed the combined score as a prognostic marker of inferior survival (HR 3.75 [2.17-6.47], P < .00001). CONCLUSION: Our study has developed a model that takes the complexity of the EGF system into account and shows that this model is a strong prognostic marker in NSCLC patients.Despite advances in the treatment, non–small cell lung cancer (NSCLC) remains the leading cause of cancer-related death in the world [1]. In particular, the overall prognosis is poor for the metastatic stages, with a median overall survival (OS) of only 8 to 10 months. Even in the early nonmetastatic stages, the 5-year survival rate is as low as 50% [2], [3]. Prognostic markers are needed to stratify patients with different risk outcome. Several biomarkers have been evaluated in NSCLC, but only a few have proven to be clinically relevant. An activating mutation in the epidermal growth factor receptor (EGFR) is both a well-described predictive marker of benefit of EGFR-targeted tyrosine kinase inhibitors but also a debated prognostic marker of better OS [4], [5], [6], [7], [8], [9]. As EGFR expression has been associated with OS in head and neck, colorectal, and esophagus cancer [10], [11], [12], attention has been directed toward the use of EGFR expression as a prognostic marker in NSCLC, but contradicting results have been demonstrated [13], [14], [15], [16]. The EGF system is complex, and the effect of ligand-receptor interaction depends on a variety of different factors, which provides a plausible explanation for the divergence observed between studies that only evaluate EGFR expression in general. EGFR is one out of four related receptors from the EGF system and is capable of forming homodimers or heterodimers with one of the three other receptors when activated by a ligand. Several ligands from the EGF system such as amphiregulin (AREG), epidermal growth factor (EGF), and transforming growth factor–α (TGF-α) only activate EGFR, whereas some have the ability to activate several combinations of the four EGF receptors like heparin-binding epidermal growth factor (HB-EGF), epiregulin (EPI), and betacellulin (BCL). Most knowledge on the role of the ligands in NSCLC is from in vitro studies or from smaller clinical studies. In vitro studies have suggested that the biological effect of EGFR activation is dependent on the specific activating ligand as well as the dimerization partner [17]. Yet, no clinical studies have evaluated the effect of the network of receptors and ligands influencing EGFR in NSCLC. Furthermore, the majority of the clinical studies exploring EGFR expression are based on immunohistochemistry which is a semiquantitative method with a great risk of interobserver variability. Quantitative gene expression analyses provide a more accurate measure and are therefore more suitable for studies comparing expression levels. Prospectively, we have collected fresh tumor samples from patients suspected of lung cancer. Accordingly, the aim of this study is to evaluate the gene expression of the network of receptors and ligands of the EGF system affecting EGFR as a prognostic markers in NSCLC.     

Gene Expression Profile of Peripheral Blood Lymphocytes from Renal Cell Carcinoma Patients Treated with IL-2, Interferon-�� and Dendritic Cell Vaccine

Lymphocytes are a key component of the immune system and their differentiation and function are directly influenced by cancer. We examined peripheral blood lymphocyte (PBL) gene expression as a biomarker of illness and treatment effect using the Affymetrix Human Gene ST1 platform in patients with metastatic renal cell carcinoma (mRCC) who received combined treatment with IL-2, interferon-?-2a and dendritic cell vaccine. We examined gene expression, cytokine levels in patient serum and lymphocyte subsets as determined by flow cytometry (FCM). Pre-treatment PBLs from patients with mRCC exhibit a gene expression profile and serum cytokine profile consistent with inflammation and proliferation not found in healthy donors (HD). PBL gene expression from patients with mRCC showed increased mRNA of genes involved with T-cell and T_REG-cell activation pathways, which was also reflected in lymphocyte subset distribution. Overall, PBL gene expression post-treatment (POST) was not significantly different than pre-treatment (PRE). Nevertheless, treatment related changes in gene expression (post-treatment minus pre-treatment) revealed an increased expression of T-cell and B-cell receptor signaling pathways in responding (R) patients compared to non-responding (NR) patients. In addition, we observed down-regulation of T_REG-cell pathways post-treatment in R vs. NR patients. While exploratory in nature, this study supports the hypothesis that enhanced inflammatory cytotoxic pathways coupled with blunting of the regulatory pathways is necessary for effective anti-cancer activity associated with immune therapy. This type of analysis can potentially identify additional immune therapeutic targets in patients with mRCC.     

Changes in Expression of GABAA α4 Subunit mRNA in the Brain under Anesthesia Induced by Volatile and Intravenous Anesthetics

We investigated changes in levels of GABA_A receptor α4 subunit mRNA in the mouse brain after administration of volatile or i.v. anesthetic, by performing quantitative RT-PCR. We also performed immunohistochemical assays for c-fos-like protein. During deep anesthesia (which was estimated by loss of righting reflex) after administration of propofol, levels of GABA_A receptor α4 subunit mRNA in the hippocampus, striatum and diencephalons were significantly greater than those observed after administration of pentobarbital, midazolam or GOI (5.0% isoflurane and 70% nitrous oxide in oxygen). Under incomplete anesthesia, levels of GABA_A receptor α4 subunit mRNA were significantly increased by midazolam in all brain regions, and were significantly increased by pentobarbital in the posterior cortex and striatum. Expression of GABA_A receptor α4 subunit mRNA closely correlated with expression of c-fos-like protein. These results indicate that the GABA_A receptor α4 subunit plays an important role in regulating the anesthetic stage of i.v. anesthetics.     

Comparison of Neuronal Death,Blood–Brain Barrier Leakage and Inflammatory Cytokine Expression in the Hippocampal CA1 Region Following Mild and Severe Transient Forebrain Ischemia in Gerbils

Neurochemical Research - Transient ischemia in the brain causes blood–brain barrier (BBB) breakdown and dysfunction, which is related to ischemia-induced neuronal damage. Leakage of plasma...     

Dexamethasone Attenuates VEGF Expression and Inflammation but Not Barrier Dysfunction in a Murine Model of Ventilator–Induced Lung Injury

Background

Ventilator–induced lung injury (VILI) is characterized by vascular leakage and inflammatory responses eventually leading to pulmonary dysfunction. Vascular endothelial growth factor (VEGF) has been proposed to be involved in the pathogenesis of VILI. This study examines the inhibitory effect of dexamethasone on VEGF expression, inflammation and alveolar–capillary barrier dysfunction in an established murine model of VILI.

Methods

Healthy male C57Bl/6 mice were anesthetized, tracheotomized and mechanically ventilated for 5 hours with an inspiratory pressure of 10 cmH₂O (“lower” tidal volumes of ∼7.5 ml/kg; LV_T) or 18 cmH₂O (“higher” tidal volumes of ∼15 ml/kg; HV_T). Dexamethasone was intravenously administered at the initiation of HV_T–ventilation. Non–ventilated mice served as controls. Study endpoints included VEGF and inflammatory mediator expression in lung tissue, neutrophil and protein levels in bronchoalveolar lavage fluid, PaO₂ to FiO₂ ratios and lung wet to dry ratios.

Results

Particularly HV_T–ventilation led to alveolar–capillary barrier dysfunction as reflected by reduced PaO₂ to FiO₂ ratios, elevated alveolar protein levels and increased lung wet to dry ratios. Moreover, VILI was associated with enhanced VEGF production, inflammatory mediator expression and neutrophil infiltration. Dexamethasone treatment inhibited VEGF and pro–inflammatory response in lungs of HV_T–ventilated mice, without improving alveolar–capillary permeability, gas exchange and pulmonary edema formation.

Conclusions

Dexamethasone treatment completely abolishes ventilator–induced VEGF expression and inflammation. However, dexamethasone does not protect against alveolar–capillary barrier dysfunction in an established murine model of VILI.     

The Effect of Butylphthalide on the Brain Edema,Blood–Brain Barrier of Rats After Focal Cerebral Infarction and the Expression of Rho A

The aim of this study was to explore the effect of butylphthalide on the brain edema, blood–brain barrier of rats of rats after focal cerebral infarction and the expression of Rho A. A total of 195 sprague–dawley male rats were randomly divided into control group, model group, and butylphthalide group (40 mg/kg, once a day, by gavage). The model was made by photochemical method. After surgery 3, 12, 24, 72, and 144 h, brain water content was done to see the effect of butylphthalide for the cerebral edema. Evans blue extravasation method was done to see the changes in blood–brain barrier immunohistochemistry, and Western blot was done to see the expression of Rho A around the infarction. Compared with the control group, the brain water content of model group and butylphthalide group rats was increased, the permeability of blood–brain barrier of model group and butylphthalide group rats was increased, and the Rho A protein of model group and butylphthalide group rats was increased. Compared with the model group, the brain water content of butylphthalide group rats was induced (73.67 ± 0.67 vs 74.14 ± 0.46; 74.89 ± 0.57 vs 75.61 ± 0.52; 77.49 ± 0.34 vs 79.33 ± 0.49; 76.31 ± 0.56 vs 78.01 ± 0.48; 72.36 ± 0.44 vs 73.12 ± 0.73; P < 0.05), the permeability of blood–brain barrier of butylphthalide group rats was induced (319.20 ± 8.11 vs 394.60 ± 6.19; 210.40 ± 9.56 vs 266.40 ± 7.99; 188.00 ± 9.22 vs 232.40 ± 7.89; 288.40 ± 7.86 vs 336.00 ± 6.71; 166.60 ± 6.23 vs 213.60 ± 13.79; P < 0.05), and the Rho A protein of butylphthalide group rats was decreased (western blot result: 1.2230 ± 0.0254 vs 1.3970 ± 0.0276; 1.5985 ± 0.0206 vs 2.0368 ± 0.0179; 1.4229 ± 0.0167 vs 1.7930 ± 0.0158;1.3126 ± 0.0236 vs 1.5471 ± 0.0158; P < 0.05). The butylphthalide could reduce the brain edema, protect the blood–brain barrier, and decrease the expression of Rho A around the infarction.     

Analysis of the N-Acetyltransferase 2 Gene Polymorphism in the Patients with Chronic Obstructive Pulmonary Disease and in Populations of the Volga–Ural Region

Restriction fragment-length polymorphism of the gene coding for N-acetyltransferase 2 (NAT2) was typed in populations of the Volga–Ural region (Bashkirs, Tatars, Chuvashes, Udmurts, and Russians) as well as in patients with chronic obstructive pulmonary disease (COPD) and in healthy individuals. Rapid and slow acetylator phenotypes were determined based on the presence or absence of the KpnI, TaqI, and BamHI restriction endonuclease recognition sites. The proportion of slow acetylators in the populations examined varied from 40.00% in Bashkirs to 64.15% in Chuvashes with statistically significant difference between these two ethnic groups (² = 5.7; P = 0.02). Overall, in the Volga–Ural populations slow acetylators represented 56.25% of the subjects examined. This value was similar to those presented in other studies of Caucasoid populations. In the COPD patients a statistically significant decrease of the slow acetylator frequency to 48.28% compared to healthy individuals (62.18%) was observed (² = 4.60; P = 0.036). The data obtained suggest a possible association between the drug resistance in the COPD patients with the rapid acetylator phenotype, which can lead to the development of the chronic form of the disease.