T wave alternans in an in vitro canine tissue model of Brugada syndrome

Macroscopic T wave alternans (TWA) associated with increased occurrence of ventricular arrhythmias has been reported in patients with Brugada syndrome. However, the mechanisms in this syndrome are still unclear. We evaluated the hypothesis that TWA in Brugada syndrome was caused by the dynamic instability and heterogeneity of action potentials (APs) in the right ventricle. Using an optical mapping system, we mapped APs on the epicardium or transmural surfaces of 28 isolated and arterially perfused canine right ventricular preparations having drug-induced Brugada syndrome (in micromol/l: 2.5-15 pinacidil, 5.0 terfenadine, and 5.0-13 pilsicainide). Bradycardia at cycle length (CL) of 2,632 +/- 496 ms (n = 19) induced alternating deep and shallow T waves in the transmural electrocardiogram. Compared with the shallow T waves, deep T waves were associated with epicardial APs having longer durations and larger domes. Adjacent regions having APs with alternating domes, with constant domes, and without domes coexisted simultaneously in the epicardium and caused TWA. In contrast to the alternating epicardial APs, midmyocardial and endocardial APs did not change during TWA. Alternans could be terminated by rapid (CL: 529 +/- 168 ms, n = 7) or very slow (CL: 3,000 ms, n = 7) pacing. The heterogeneic APs during TWA augmented the dispersion of repolarization both within the epicardium and from the epicardium to the endocardium and caused phase 2 reentry. In this drug-induced model of Brugada syndrome, heterogeneic AP contours and dynamic alternans in the dome of right ventricular epicardial, but not midmyocardial or endocardial, APs caused TWA and heightened arrhythmogenicity in part by increasing the dispersion of repolarization.     

Role for IL-4 nonproducing NKT cells in CC-chemokine ligand 2-induced Th2 cell generation

NKT cells from C57Bl/6 mice are known to be the initial cellular source of IL-4 that acts as a trigger for Th2 cell differentiation. CC-chemokine ligand 2 (CCL2) has been described as an initial stimulator of IL-4 production by these cells; however, IL-4 was not produced by NKT cells from BALB/c mice even when Th2 cell responses were established in these mice. In this study, we found a new pathway for CCL2-associated Th2 cell generation in BALB/c mice. Splenic T cells from BALB/c mice produced IL-4 in response to CCL2 stimulation. However, IL-4 production was not seen in cultures of splenic T cells from CD1-/- mice (BALB/c origin), whereas, in the presence of CCL2, splenic T cells from CD1-/- mice produced IL-4 when NKT cells from wild-type mice were added. CCL2 induced IL-4 in cultures of NKT cells cocultured with naive T cells, but IL-4 was not produced by these cells cultured separately with CCL2. Interestingly, IL-4 was produced by naive T cells cocultured with NKT cells that were previously treated with CCL2 (CCL2-NKT cells). In addition, IL-4 was produced by naive T cells supplemented with a culture supernatant of CCL2-NKT cells. These results indicate that, through the production of a soluble factor(s) other than IL-4, NKT cells play a role in the CCL2-associated generation of Th2 cells.     

T-type Ca2+ Channels Promote Oxygenation-induced Closure of the Rat Ductus Arteriosus Not Only by Vasoconstriction but Also by Neointima Formation

The ductus arteriosus (DA), an essential vascular shunt for fetal circulation, begins to close immediately after birth. Although Ca²⁺ influx through several membrane Ca²⁺ channels is known to regulate vasoconstriction of the DA, the role of the T-type voltage-dependent Ca²⁺ channel (VDCC) in DA closure remains unclear. Here we found that the expression of α1G, a T-type isoform that is known to exhibit a tissue-restricted expression pattern in the rat neonatal DA, was significantly up-regulated in oxygenated rat DA tissues and smooth muscle cells (SMCs). Immunohistological analysis revealed that α1G was localized predominantly in the central core of neonatal DA at birth. DA SMC migration was significantly increased by α1G overexpression. Moreover, it was decreased by adding α1G-specific small interfering RNAs or using R(−)-efonidipine, a highly selective T-type VDCC blocker. Furthermore, an oxygenation-mediated increase in an intracellular Ca²⁺ concentration of DA SMCs was significantly decreased by adding α1G-specific siRNAs or using R(−)-efonidipine. Although a prostaglandin E receptor EP4 agonist potently promoted intimal thickening of the DA explants, R(−)-efonidipine (10⁻⁶ m) significantly inhibited EP4-promoted intimal thickening by 40% using DA tissues at preterm in organ culture. Moreover, R(−)-efonidipine (10⁻⁶ m) significantly attenuated oxygenation-induced vasoconstriction by ∼27% using a vascular ring of fetal DA at term. Finally, R(−)-efonidipine significantly delayed the closure of in vivo DA in neonatal rats. These results indicate that T-type VDCC, especially α1G, which is predominantly expressed in neonatal DA, plays a unique role in DA closure, implying that T-type VDCC is an alternative therapeutic target to regulate the patency of DA.The ductus arteriosus (DA)² is an essential vascular shunt between the aortic arch and the pulmonary trunk during a fetal period (1). After birth, the DA closes immediately in accordance with its smooth muscle contraction and vascular remodeling, whereas the connecting vessels such as the aorta and pulmonary arteries remain open. When the DA fails to close after birth, the condition is known as patent DA, which is a common form of congenital heart defect. Patent DA is also a frequent problem with significant morbidity and mortality in premature infants. Investigating the molecular mechanism of DA closure is important not only for vascular biology but also for clinical problems in pediatrics.Voltage-dependent Ca²⁺ channels (VDCCs) consist of multiple subtypes, named L-, N-, P/Q-, R-, and T-type. L-type VDCCs are known to play a primary role in regulating Ca²⁺ influx and thus vascular tone in the development of arterial smooth muscle including the DA (2–4). Our previous study demonstrated that all T-type VDCCs were expressed in the rat DA (5). α1G subunit, especially, was the most dominant isoform among T-type VDCCs. The abundant expression of α1G subunit suggests that it plays a role in the vasoconstriction and vascular remodeling of the DA. In this regard, Nakanishi et al. (6) demonstrated that 0.5 mm nickel, which blocks T-type VDCC, inhibited oxygen-induced vasoconstriction of the rabbit DA. On the other hand, Tristani-Firouzi et al. (7) demonstrated that T-type VDCCs exhibited little effect on oxygen-sensitive vasoconstriction of the rabbit DA. Thus, the role of T-type VDCCs in DA vasoconstriction has remained controversial.In addition to their role in determining the contractile state, a growing body of evidence has demonstrated that T-type VDCCs play an important role in regulating differentiation (8, 9), proliferation (10–12), migration (13, 14), and gene expression (15) in vascular smooth muscle cells (SMCs). Hollenbeck et al. (16) and Patel et al. (17) demonstrated that nickel inhibited platelet-derived growth factor-BB-induced SMC migration. Rodman et al. (18) demonstrated that α1G promoted SMC proliferation in the pulmonary artery. The DA dramatically changes its morphology during development. Intimal cushion formation, a characteristic feature of vascular remodeling of the DA (19–21), involves many cellular processes: an increase in SMC migration and proliferation, production of hyaluronic acid under the endothelial layer, impaired elastin fiber assembly, and so on (1, 19, 21–23). Although our previous study demonstrated that T-type VDCCs are involved in smooth muscle cell proliferation in the DA (5), the role of T-type VDCCs in vascular remodeling of the DA has remained poorly understood.In the present study, we hypothesized that T-type VDCCs, especially α1G subunit, associate with vascular remodeling and vasoconstriction in the DA. To test our hypothesis, we took full advantage of recent molecular and pharmacological developments. We chose the recently developed, highly selective T-type VDCC blocker R(−)-efonidipine instead of low dose nickel for our study. Selective inhibition or activation of α1G subunit was also obtained using small interfering RNA (siRNA) technology or by overexpression of the α1G subunit gene, respectively. We found that Ca²⁺ influx through T-type VDCCs promoted oxygenation-induced DA closure through SMC migration and vasoconstriction.     

Conservation of molecular interactions stabilizing bovine and mouse rhodopsin

Rhodopsin is the light receptor that initiates phototransduction in rod photoreceptor cells. The structure and function of rhodopsin are tightly linked to molecular interactions that stabilize and determine the receptor's functional state. Single-molecule force spectroscopy (SMFS) was used to localize and quantify molecular interactions that structurally stabilize bovine and mouse rhodopsin from native disk membranes of rod photoreceptor cells. The mechanical unfolding of bovine and mouse rhodopsin revealed nine major unfolding intermediates, each intermediate defining a structurally stable segment in the receptor. These stable structural segments had similar localization and occurrence in both bovine and mouse samples. For each structural segment, parameters describing their unfolding energy barrier were determined by dynamic SMFS. No major differences were observed between bovine and mouse rhodopsin, thereby implying that the structures of both rhodopsins are largely stabilized by similar molecular interactions.     

The AAA+ ATPase ATAD3A Controls Mitochondrial Dynamics at the Interface of the Inner and Outer Membranes

Dynamic interactions between components of the outer (OM) and inner (IM) membranes control a number of critical mitochondrial functions such as channeling of metabolites and coordinated fission and fusion. We identify here the mitochondrial AAA⁺ ATPase protein ATAD3A specific to multicellular eukaryotes as a participant in these interactions. The N-terminal domain interacts with the OM. A central transmembrane segment (TMS) anchors the protein in the IM and positions the C-terminal AAA⁺ ATPase domain in the matrix. Invalidation studies in Drosophila and in a human steroidogenic cell line showed that ATAD3A is required for normal cell growth and cholesterol channeling at contact sites. Using dominant-negative mutants, including a defective ATP-binding mutant and a truncated 50-amino-acid N-terminus mutant, we showed that ATAD3A regulates dynamic interactions between the mitochondrial OM and IM sensed by the cell fission machinery. The capacity of ATAD3A to impact essential mitochondrial functions and organization suggests that it possesses unique properties in regulating mitochondrial dynamics and cellular functions in multicellular organisms.Mitochondria not only supply cells with the bulk of their ATP but also contribute to the fine regulation of metabolism, calcium homeostasis, and apoptosis (27). Coordination of these functions is dependent on the dynamic nature of mitochondria (5). These organelles constantly fuse and divide to form small spheres, short rods, or long tubules and are actively transported to specific subcellular locations. These processes are essential for mammalian development, and defects can lead to degenerative diseases and cancers (9, 17). In eukaryotes, these organellar gymnastics are controlled by numerous pathways that preserve proper mitochondrial morphology and function (30, 45). The best-understood mitochondrial process is the fusion and fission pathways, which rely on conserved GTPases, and their binding partners to regulate organelle connectivity (10, 18, 45). There are also evidences that dynamic interactions between the outer membrane (OM) and inner membrane (IM) exist for coordinated fusion and fission, channeling of metabolites, and protein transport, but proteins playing a role in these interactions have yet to be identified (34). In the present study, we provide a detailed biochemical and functional characterization of the mitochondrial AAA⁺ ATPase ATAD3A protein that is present exclusively in multicellular eukaryotes and which participates in the control of mitochondrial dynamics at the interface between the IMs and OMs. Proteins related to the Atad3A genes have been previously identified in proteomic surveys of mouse brain mitochondria (28) and liver mitochondrial inner membrane (8), as mitochondrial DNA-binding proteins (4, 21, 44) and as nuclear mRNA-associated proteins (6). The Atad3A protein has also been identified as a cell surface antigen in some human tumors (16). Functional genomics identified the Drosophila Atad3A ortholog (bor) as a major gene positively regulated by the TOR (for target of rapamycin) signaling pathway involved in cell growth and division (19). In our laboratory, we identified ATAD3A as a specific target for the Ca²⁺/Zn²⁺-binding S100B protein (B. Gilquin et al., unpublished data). We here show that ATAD3A is anchored into the mitochondrial IM at contact sites with the OM. The N-terminal domain of ATAD3A interacts with the inner surface of the OM and its C-terminal AAA ATPase domain localizes in a specific matrix compartment. Thanks to its simultaneous interaction with two membranes, ATAD3A regulates mitochondrial dynamics at the interface between the IMs and OMs and controls diverse cell responses ranging from cell growth, channeling of cholesterol, and mitochondrial fission.     

Spatial variation of phosphorus fractions in bottom sediments and the potential contributions to eutrophication in shallow lakes

Spatial variation of phosphorus fractions in bottom sediment, pore water and overlying water in three shallow eutrophic lakes, Nishiura, Kitaura and Sotonasakaura, Japan, and the contributions of the fractional P to mobilization of phosphorus from sediment were examined in this study. The vertical distributions of dissolved inorganic phosphorus (DIP) concentrations in overlying and pore water differed with lake and sampling site. In particular, DIP was high in pore water in the surface layer of the sediment for the middle to downlake areas of Lake Kitaura. DIP release flux calculated from a gradient of the concentrations at the sediment–water interface was high compared with other sites. The distribution of fractional P content in sediments was highly variable. The citrate–dithionite–bicarbonate–non-reactive phosphorus (CDB–NRP) fraction, in particular, differed greatly among the three lakes. According to correlation in the ratios between CDB–NRP and loss on ignition, sediments of these lakes were classified in three clusters. The CDB–NRP fraction was suggested to play a role in DIP release from sediment. The possibility of nitrate concentration playing a role in the control of DIP release was considered.     

TRANCE, a TNF family member, activates Akt/PKB through a signaling complex involving TRAF6 and c-Src

TRANCE, a TNF family member, and its receptor, TRANCE-R, are critical regulators of dendritic cell and osteoclast function. Here, we demonstrate that TRANCE activates the antiapoptotic serine/threonine kinase Akt/PKB through a signaling complex involving c-Src and TRAF6. A deficiency in c-Src or addition of Src family kinase inhibitors blocks TRANCE-mediated PKB activation in osteoclasts. c-Src and TRAF6 interact with each other and with TRANCE-R upon receptor engagement. TRAF6, in turn, enhances the kinase activity of c-Src leading to tyrosine phosphorylation of downstream signaling molecules such as c-Cbl. These results define a mechanism by which TRANCE activates Src family kinases and PKB and provide evidence of cross-talk between TRAF proteins and Src family kinases.     

Membrane translocation mechanism of the antimicrobial peptide buforin 2

The antimicrobial peptide magainin 2 isolated from the skin of the African clawed frog Xenopus laevis crosses lipid bilayers by transiently forming a peptide-lipid supramolecular complex pore inducing membrane permeabilization and flip-flop of membrane lipids [Matsuzaki, K., Murase, O., Fujii, N., and Miyajima, K. (1996) Biochemistry 35, 11361-11368]. In contrast, the antimicrobial peptide buforin 2 discovered in the stomach tissue of the Asian toad Bufo bufo gargarizans efficiently crosses lipid bilayers without inducing severe membrane permeabilization or lipid flip-flop, and the Pro(11) residue plays a key role in this unique property [Kobayashi, S, Takeshima, K., Park, C. B., Kim, S. C., and Matsuzaki, K. (2000) Biochemistry 39, 8648-8654]. To elucidate the translocation mechanism, the secondary structure and the orientation of the peptide in lipid bilayers as well as the effects of the peptide concentration, the lipid composition, and the cis-trans isomerization of the Pro peptide bond on translocation efficiency were investigated. The translocation efficiencies of F10W-buforin 2 (BF2), P11A-BF2, and F5W-magainin 2 (MG2) across egg yolk L-alpha-phosphatidyl-DL-glycerol (EYPG)/egg yolk L-alpha-phosphatidylcholine (1/1) bilayers were dependent supralinearly on the peptide concentration, suggesting that the translocation mechanisms of these peptides are similar. The incorporation of the negative curvature-inducing lipid egg yolk L-alpha -phosphatidylethanolamine completely suppressed the translocation of BF2, indicating the induction of the positive curvature by BF2 on the membrane is related to the translocation process, similarly to MG2. In pure EYPG, where the repulsion between polycationic BF2 molecules is reduced, membrane permeabilization and coupling lipid flip-flop were clearly observed. Structural studies by use of Fourier transform infrared-polarized attenuated total reflection spectroscopy indicated that BF2 assumed distorted helical structures in EYPG/EYPC bilayers. A BF2 analogue with an alpha-methylproline, which fixed the peptide bond to the trans configuration, translocated similarly to the parent peptide, suggesting the cis-trans isomerization of the Pro peptide bond is not involved in the translocation process. These results indicate that BF2 crosses lipid bilayers via a mechanism similar to that of MG2. The presence of Pro(11) distorts the helix, concentrating basic amino acid residues in a limited amphipathic region, thus destabilizing the pore by enhanced electrostatic repulsion, enabling efficient translocation.