Cytokine polymorphisms and histologic expression in autopsy studies: contribution of TNF-alpha and TGF-beta 1 to the pathogenesis of autoimmune-associated congenital heart block

Although Abs to SSA/Ro-SSB/La are necessary for the development of congenital heart block (CHB), the low frequency suggests that fetal factors are contributory. Because CHB involves a cascade from inflammation to scarring, polymorphisms of the TNF-alpha promoter region and codons 10 and 25 of the TGF-beta gene were evaluated in 88 children (40 CHB, 17 rash, 31 unaffected siblings) and 74 mothers from the Research Registry for Neonatal Lupus (NL). Cytokine expression was assessed in autopsy material from two fetuses with CHB. Significantly increased frequency of the -308A (high-producer) allele of TNF-alpha was observed in all NL groups compared with controls. In contrast, the TGF-beta polymorphism Leu(10) (associated with increased fibrosis) was significantly higher in CHB children (genotypic frequency 60%, allelic frequency 78%) than unaffected offspring (genotypic frequency 29%, p = 0.016; allelic frequency 56%, p = 0.011) and controls, while there were no significant differences between controls and other NL groups. For the TGF-beta polymorphism, Arg(25), there were no significant differences between NL groups and controls. In fetal CHB hearts, protein expression of TGF-beta, but not TNF-alpha, was demonstrated in septal regions, extracellularly in the fibrous matrix, and intracellularly in macrophage infiltrates. Age-matched fetal hearts from voluntary terminations expressed neither cytokine. TNF-alpha may be one of several factors that amplify susceptibility; however, the genetic studies, backed by the histological data, more convincingly link TGF-beta to the pathogenesis of CHB. This profibrosing cytokine and its secretion/activation circuitry may provide a novel direction for evaluating fetal factors in the development of a robust animal model of CHB as well as therapeutic strategies in humans.     

Role of astrocytes in trimethyltin neurotoxicity

Although the neurotoxicity of trimethyltin (TMT) is well known, mechanisms are still not clear. Glia have been proposed to mediate the toxic action of TMT on nerve cells. Accordingly, the effects of TMT were tested in primary neuronal cultures from rat cerebellum and compared to effects in astrocytes and mixed cultures. Neuronal damage observed following TMT exposure was less in the presence of astrocytes and astrocytes alone were resistant to TMT. Thus, astrocytes have a protective effect against TMT-induced neurotoxicity. TMT caused an oxidative stress in granule cell cultures involving a variety of oxidative species (O2)*-, H2O2, NO), but astrocytes were less sensitive to TMT-induced oxidative species generation. Antioxidants, glutathione and 7-nitroindazole attenuated neuronal cell death induced by TMT. It appears that oxidative stress mediates a large part of the destructive action of TMT in neuronal cultures. The presence of astrocytes appears to modulate TMT-induced oxidative stress so that TMT causes only a small increase in lipid peroxidation in mouse brain after systemic administration. Thus, TMT induces a pronounced oxidative stress in cultured neurons, but when astrocytes are present, oxidative species play a lesser role in the neurotoxic action of TMT.     

Effect of cardiac pacing on forearm vascular responses and nitric oxide function

We examined the hypothesis that changes in heart rate at rest influence bioactivity of nitric oxide (NO) in humans by examining forearm blood flow responses during cardiac pacing in six subjects. Peak forearm and mean forearm blood flows across the cardiac cycle were continuously recorded at baseline and during pacing, with the use of high-resolution brachial artery ultrasound and Doppler flow velocity measurement. The brachial artery was cannulated to allow continuous infusion of saline or N(G)-monomethyl-L-arginine (L-NMMA). As heart rate increased, no changes in pulse pressure and mean or peak blood flow were evident. L-NMMA had no effect on brachial artery diameter, velocity, or flows compared with saline infusion. These results contrast with our recent findings that exercise involving the lower body, associated with increases in heart rate and pulse pressure, also increased forearm blood flow, the latter response being diminished by L-NMMA. These data suggest that changes in blood pressure, rather than pulse frequency, may be the stimulus for shear stress-mediated NO release in vivo.     

I. Cellular and molecular biology of sodium channel beta-subunits: therapeutic implications for pain? I. Cellular and molecular biology of sodium channel beta-subunits: therapeutic implications for pain?

Voltage-gated sodium channel alpha-subunits have been shown to be key mediators of the pathophysiology of pain. The present review considers the role of sodium channel auxiliary beta-subunits in channel modulation, channel protein expression levels, and interactions with extracellular matrix and cytoskeletal signaling molecules. Although beta-subunits have not yet been directly implicated in pain mechanisms, their intimate association with and ability to regulate alpha-subunits predicts that they may be a viable target for therapeutic intervention in the future. It is proposed that multifunctional sodium channel beta-subunits provide a critical link between extracellular and intracellular signaling molecules and thus have the ability to fine tune channel activity and electrical excitability.     

Cloning, localization, and functional expression of sodium channel beta1A subunits

Auxiliary beta1 subunits of voltage-gated sodium channels have been shown to be cell adhesion molecules of the Ig superfamily. Co-expression of alpha and beta1 subunits modulates channel gating as well as plasma membrane expression levels. We have cloned, sequenced, and expressed a splice variant of beta1, termed beta1A, that results from an apparent intron retention event. beta1 and beta1A are structurally homologous proteins with type I membrane topology; however, they contain little to no amino acid homology beyond the shared Ig loop region. beta1A mRNA expression is developmentally regulated in rat brain such that it is complementary to beta1. beta1A mRNA is expressed during embryonic development, and then its expression becomes undetectable after birth, concomitant with the onset of beta1 expression. In contrast, beta1A mRNA is expressed in adult adrenal gland and heart. Western blot analysis revealed beta1A protein expression in heart, skeletal muscle, and adrenal gland but not in adult brain or spinal cord. Immunocytochemical analysis of beta1A expression revealed selective expression in brain and spinal cord neurons, with high expression in heart and all dorsal root ganglia neurons. Co-expression of alphaIIA and beta1A subunits in Chinese hamster lung 1610 cells results in a 2.5-fold increase in sodium current density compared with cells expressing alphaIIA alone. This increase in current density reflected two effects of beta1A: 1) an increase in the proportion of cells expressing detectable sodium currents and 2) an increase in the level of functional sodium channels in expressing cells. [(3)H]Saxitoxin binding analysis revealed a 4-fold increase in B(max) with no change in K(D) in cells coexpressing alphaIIA and beta1A compared with cells expressing alphaIIA alone. beta1A-expressing cell lines also revealed subtle differences in sodium channel activation and inactivation. These effects of beta1A subunits on sodium channel function may be physiologically important events in the development of excitable cells.     

Sodium channel beta subunits mediate homophilic cell adhesion and recruit ankyrin to points of cell-cell contact

Sodium channels isolated from mammalian brain are composed of alpha, beta1, and beta2 subunits. The auxiliary beta subunits do not form the ion conducting pore, yet play important roles in channel modulation and plasma membrane expression. beta1 and beta2 are transmembrane proteins with one extracellular V-set immunoglobulin (Ig) protein domain. It has been shown recently that beta1 and beta2 interact with the extracellular matrix proteins tenascin-C and tenascin-R. In the present study we show that rat brain beta1 and beta2, but not alphaIIA, subunits interact in a trans-homophilic fashion, resulting in recruitment of the cytoskeletal protein ankyrin to sites of cell-cell contact in transfected Drosophila S2 cells. Whereas alphaIIA subunits expressed alone do not cause cellular aggregation, beta subunits co-expressed with alphaIIA retain the ability to adhere and recruit ankyrin. Truncated beta subunits lacking cytoplasmic domains interact homophilically to produce cell aggregation but do not recruit ankyrin. Thus, the cytoplasmic domains of beta1 and beta2 are required for cytoskeletal interactions. It is hypothesized that sodium channel beta subunits serve as a critical communication link between the extracellular and intracellular environments of the neuron and may play a role in sodium channel placement at nodes of Ranvier.     

Biochemical,biophysical, and genetic changes of porcine trophoblast‐derived stem‐like cells during differentiation as evaluated using Raman microspectroscopy,Atomic force microscopy,and quantitative polymerase chain reaction

Porcine trophoblast‐derived stem‐like cells grown into serum medium start to differentiate and become senescent within 30 days. However, trophoblast‐derived cells, cultured in vitro in a defined and non‐serum medium, have the regenerative properties, such as indefinite passage and foreign DNA receptivity, similar to stem cells. To evaluate the biochemical, biophysical, and genetic changes of the terminal differentiation of trophoblast derived cells, Raman microspectroscopy, atomic force microscopy, and qPCR were applied. It was found that Raman spectral intensities of characteristic peaks, cell morphology, and Young's modulus can be used to distinguish differentiated and undifferentiated trophoblast cells. In addition, 17 cytoskeleton and extracellular matrix‐related genes were significantly impacted by medium type (non‐serum versus serum). Our findings suggest that Raman microspectroscopy and atomic force microscopy—both considered as label‐free, non‐invasive techniques—can be applied to distinguish differentiated trophoblast cells, and cellular biochemical information and biophysical properties can be indicative of cellular differences during cell differentiation. In addition, most of cytoskeleton‐related genes exhibit similar pattern to that of Young's modulus during trophoblast cell differentiation, indicating the potential connection between cytoskeleton‐related genes and cellular stiffness. genesis 53:749–761, 2015. © 2015 Wiley Periodicals, Inc.     

BMPER Promotes Epithelial-Mesenchymal Transition in the Developing Cardiac Cushions

Formation of the cardiac valves is an essential component of cardiovascular development. Consistent with the role of the bone morphogenetic protein (BMP) signaling pathway in cardiac valve formation, embryos that are deficient for the BMP regulator BMPER (BMP-binding endothelial regulator) display the cardiac valve anomaly mitral valve prolapse. However, how BMPER deficiency leads to this defect is unknown. Based on its expression pattern in the developing cardiac cushions, we hypothesized that BMPER regulates BMP2-mediated signaling, leading to fine-tuned epithelial-mesenchymal transition (EMT) and extracellular matrix deposition. In the BMPER^-/- embryo, EMT is dysregulated in the atrioventricular and outflow tract cushions compared with their wild-type counterparts, as indicated by a significant increase of Sox9-positive cells during cushion formation. However, proliferation is not impaired in the developing BMPER^-/- valves. In vitro data show that BMPER directly binds BMP2. In cultured endothelial cells, BMPER blocks BMP2-induced Smad activation in a dose-dependent manner. In addition, BMP2 increases the Sox9 protein level, and this increase is inhibited by co-treatment with BMPER. Consistently, in the BMPER^-/- embryos, semi-quantitative analysis of Smad activation shows that the canonical BMP pathway is significantly more active in the atrioventricular cushions during EMT. These results indicate that BMPER negatively regulates BMP-induced Smad and Sox9 activity during valve development. Together, these results identify BMPER as a regulator of BMP2-induced cardiac valve development and will contribute to our understanding of valvular defects.     

Dibutyltin activates MAP kinases in human natural killer cells,in vitro

Previous studies have shown that dibutyltin (DBT) interferes with the function of human natural killer (NK) cells, diminishing their capacity to destroy tumor cells, in vitro. DBT is a widespread environmental contaminant and has been found in human blood. As NK cells are our primary immune defense against tumor cells, it is important to understand the mechanism by which DBT interferes with their function. The current study examines the effects of DBT exposures on key enzymes in the signaling pathway that regulates NK responsiveness to tumor cells. These include several protein tyrosine kinases (PTKs), mitogen-activated protein kinases (MAPKs), and mitogen-activated protein kinase kinases (MAP2Ks). The results showed that in vitro exposures of NK cells to DBT had no effect on PTKs. However, exposures to DBT for as little as 10 min were able to increase the phosphorylation (activation) of the MAPKs. The DBT-induced activations of these MAPKs appear to be due to DBT-induced activations of the immediate upstream activators of the MAPKs, MAP2Ks. The results suggest that DBT-interference with the MAPK signaling pathway is a consequence of DBT exposures, which could account for DBT-induced decreases in NK function.