Stimulation of production of tumor necrosis factor by murine macrophages when exposed in vio and in vitro to weak electromagnetic waves in the centimeter range

Whole-body microwave sinusoidal irradiation of male NMRI mice, exposure of macrophages in vitro, and preliminary irradiation of culture medium with 8.15-18 GHz (1 Hz within) at a power density of 1 microW/cm2 caused a significant enhancement of tumor necrosis factor production in peritoneal macrophages. The role of microwaves as a factor interfering with the process of cell immunity is discussed.     

Response to András Szilágyi's Commentary

In a commentary to our article on protein domain size, András Szilágyi suggests our findings are a mathematical artifact. In examining his concerns, we believe they are possibly a result of misunderstandings, errors of fact, and philosophical approach. Proteins 2008. © 2008 Wiley‐Liss, Inc.     

SREBP‐1c,Pdx‐1, and GLP‐1R involved in palmitate–EPA regulated glucose‐stimulated insulin secretion in INS‐1 cells

Impairment of glucose‐stimulated insulin secretion (GSIS) caused by glucolipotoxicity is an essential feature in type 2 diabetes mellitus (T2DM). Palmitate and eicosapentaenoate (EPA), because of their lipotoxicity and protection effect, were found to impair or restore the GSIS in beta cells. Furthermore, palmitate was found to up‐regulate the expression level of sterol regulatory element‐binding protein (SREBP)‐1c and down‐regulate the levels of pancreatic and duodenal homeobox (Pdx)‐1 and glucagon‐like peptide (GLP)‐1 receptor (GLP‐1R) in INS‐1 cells. To investigate the underlying mechanism, the lentiviral system was used to knock‐down or over‐express SREBP‐1c and Pdx‐1, respectively. It was found that palmitate failed to suppress the expression of Pdx‐1 and GLP‐1R in SREBP‐1c‐deficient INS‐1 cells. Moreover, down‐regulation of Pdx‐1 could cause the low expression of GLP‐1R with/without palmitate treatment. Additionally, either SREBP‐1c down‐regulation or Pdx‐1 over‐expression could partially alleviate palmitate‐induced GSIS impairment. These results suggested that sequent SREBP‐1c‐Pdx‐1‐GLP‐1R signal pathway was involved in the palmitate‐caused GSIS impairment in beta cells. J. Cell. Biochem. 111: 634–642, 2010. © 2010 Wiley‐Liss, Inc.     

AP-1 Membrane–Cytoplasm Recycling Regulated by μ1A-Adaptin

The adaptor protein complex AP-1 mediates vesicular protein sorting between the trans Golgi network and endosomes. AP-1 recycles between membranes and the cytoplasm together with clathrin during transport vesicle formation and vesicle uncoating. AP-1 recycles independent of clathrin, indicating binding to unproductive membrane domains and premature termination of vesicle budding. Membrane recruitment requires ADP ribosylation factor-1-GTP, a transmembrane protein containing an AP-1-binding motif and phosphatidyl-inositol phosphate (PI-4-P). Little is known about the regulation of AP-1 membrane–cytoplasm recycling. We identified the N-terminal domain of μ1A-adaptin as being involved in the regulation of AP-1 membrane–cytoplasm recycling by constructing chimeras of μ1A and its homologue μ2. The AP-1* complex containing this μ2–μ1A chimera had slowed down recycling kinetics, resulting in missorting of mannose 6-phosphate receptors. The N-terminal domain is only accessible from the cytoplasmic AP-1 surface. None of the proteins known to influence AP-1 membrane recycling bound to this μ1A domain, indicating the regulation of AP-1 membrane–cytoplasm recycling by an yet unidentified cytoplasmic protein.     

α1 adrenoceptor activation by norepinephrine inhibits LPS‐induced cardiomyocyte TNF‐α production via modulating ERK1/2 and NF‐κB pathway

Cardiomyocyte tumour necrosis factor α (TNF‐α) production contributes to myocardial depression during sepsis. This study was designed to observe the effect of norepinephrine (NE) on lipopolysaccharide (LPS)‐induced cardiomyocyte TNF‐α expression and to further investigate the underlying mechanisms in neonatal rat cardiomyocytes and endotoxaemic mice. In cultured neonatal rat cardiomyocytes, NE inhibited LPS‐induced TNF‐α production in a dose‐dependent manner. α₁‐ adrenoceptor (AR) antagonist (prazosin), but neither β₁‐ nor β₂‐AR antagonist, abrogated the inhibitory effect of NE on LPS‐stimulated TNF‐α production. Furthermore, phenylephrine (PE), an α₁‐AR agonist, also suppressed LPS‐induced TNF‐α production. NE inhibited p38 phosphorylation and NF‐κB activation, but enhanced extracellular signal‐regulated kinase 1/2 (ERK1/2) phosphorylation and c‐Fos expression in LPS‐treated cardiomyocytes, all of which were reversed by prazosin pre‐treatment. To determine whether ERK1/2 regulates c‐Fos expression, p38 phosphorylation, NF‐κB activation and TNF‐α production, cardiomyocytes were also treated with U0126, a selective ERK1/2 inhibitor. Treatment with U0126 reversed the effects of NE on c‐Fos expression, p38 mitogen‐activated protein kinase (MAPK) phosphorylation and TNF‐α production, but not NF‐κB activation in LPS‐challenged cardiomyocytes. In addition, pre‐treatment with SB202190, a p38 MAPK inhibitor, partly inhibited LPS‐induced TNF‐α production in cardiomyocytes. In endotoxaemic mice, PE promoted myocardial ERK1/2 phosphorylation and c‐Fos expression, inhibited p38 phosphorylation and IκBα degradation, reduced myocardial TNF‐α production and prevented LPS‐provoked cardiac dysfunction. Altogether, these findings indicate that activation of α₁‐AR by NE suppresses LPS‐induced cardiomyocyte TNF‐α expression and improves cardiac dysfunction during endotoxaemia via promoting myocardial ERK phosphorylation and suppressing NF‐κB activation.