Gα16 interacts with Class IA phosphatidylinositol 3-kinases and inhibits Akt signaling

Phosphatidylinositol 3-kinase (PI3K) mediates receptor tyrosine kinase and G protein coupled receptor (GPCR) signaling by phosphorylating phosphoinositides to elicit various biological responses. Gα_q has previously been shown to inhibit class IA PI3K by interacting with the p110α subunit. However, it is not known if PI3Ks can associate with other Gα_q family members such as Gα₁₆. Here, we demonstrated that class IA PI3Ks, p85/p110α and p85/p110β, could form stable complexes with wild type Gα₁₆ and its constitutively active mutant (Gα₁₆QL) in HEK293 cells. In contrast, no interaction between Gα₁₆ and class IB PI3K was observed. The Gα₁₆/p110α signaling complex could be detected in hematopoietic cells that endogenously express Gα₁₆. Overexpression of class I PI3Ks did not inhibit Gα₁₆QL-induced IP₃ production and, unlike p63RhoGEF, class IA PI3Ks did not attenuate the binding of PLCβ₂ to Gα₁₆QL. On the contrary, the function of class IA PI3Ks was suppressed by Gα₁₆QL as revealed by diminished production of PIP₃ as well as inhibition of EGF-induced Akt phosphorylation. Taken together, these results suggest that Gα₁₆ can bind to class IA PI3Ks and inhibit the PI3K signaling pathway.     

Genetic introgression between an introduced babbler, the Chinese hwamei Leucodioptron c. canorum, and the endemic Taiwan hwamei L. taewanus: a multiple marker systems analysis

Identification of interspecific hybrids is often a subject of primary concern in the development of conservation strategies. Here we performed a genetic analysis combining mitochondrial DNA (mtDNA), microsatellites and single nucleotide polymorphic sites (SNPs) to assay the level of hybridization and introgression between an introduced babbler, Chinese hwamei Leucodioptron canorus, and its close relative, the endemic Taiwan hwamei L. taewanus in Taiwan. Fifty‐five Chinese hwameis from the Asian mainland and 69 Taiwan hwameis, including nine morphological hybrids, were sampled and analyzed. Evidences of mitochondrial introgression were found in three hybrids and one Taiwan hwamei. Five unlinked interspecific SNPs were identified at nine anonymous nuclear loci with interspecific differentiation (total Fst=0.77) that was much higher than that at seven highly polymorphic microsatellite loci combined (total Fst=0.1). Bayesian cluster analysis based on five interspecific SNP loci and two highly differentiated microsatellite loci (Fst>0.08) suggested that twelve individuals sampled in Taiwan were likely F2 or backcross hybrids, among which eight were morphological intermediates. A total of 20.3% (14/69) individuals sampled in Taiwan were suggested to be hybrids, suggesting that fitness reduction in hybrids might be negligible. These results imply that without an effective management strategy, the entire Taiwan hwamei population could easily become an admixed with Chinese hwamei and loose its evolutionary integrity. To reduce introgressive hybridization, illegal trade of Chinese hwamei should be strictly regulated and only the expensive male Chinese hwameis should be legally imported to minimize the chance for Chinese hwameis being released into the field. In our study we also found interspecific SNP markers to outperform microsatellite loci in detecting hybridization and introgression between two closely related species, which may be ascribed to the lower level of homoplasy of SNP loci.     

The osmotic property and fluorescent tracer movement of developing orchid embryos of Phaius tankervilliae (Aiton) Bl

The suspensor plays an active role during the early embryo development of flowering plants. In orchids, the suspensor cells are highly vacuolated without structural specializations, and the possible mechanism(s) that enable the suspensor to serve as the nutrient uptake site is virtually unknown. Here, we used the fluorescent tracer CFDA to characterize the pathway for symplastic transport in the suspensor cells of developing embryos and to provide direct visual evidence that the orchid suspensor has unique physiological properties. The embryo proper uptakes the fluorescent dye through the suspensor. CF could first be detected throughout the suspensor cell and then subsequently in the embryo proper. A plasmolysis experiment clearly indicates that suspensor cells have a more negative osmotic potential than the adjoining testa cells. It is proposed that the preferential entry of CFDA into the suspensor cell of the Nun orchid is aided by the more negative osmotic potential of the suspensor than neighboring cells, providing a driving force for the uptake of water from the apoplast into the symplast.     

The interaction of light irradiance with ethylene in regulating growth of Helianthus annuus shoot tissues

Shade light found in ecological niches where plants are growing under a canopy or in proximity of taller neighbouring vegetation consist mainly of two separate light signals: low red to far-red ratio and low photosynthetically active radiation (PAR). The effect of the latter on the growth of 7-day old sunflower shoots was examined by assessing hypocotyl, cotyledon and leaf tissue growth under three varying PAR levels: near-normal of 1,000 μmol m^?2 s^?1, low of 100 μmol m^?2 s^?1 and very low of 10 μmol m^?2 s^?1. Then, the possible interaction between PAR signaling and ethylene in regulating growth of these sunflower tissues was investigated. The results showed that gradual decrease in PAR level increases hypocotyl elongation and decreases ethylene evolution. However, gradual decrease in PAR level decreases cotyledon and leaf growth and increases ethylene evolution. Thus it seems possible that PAR regulation of shoot growth is mediated by changes in ethylene evolution in tissue specific manner. This hypothesis was supported by experiments with the ethylene releasing factor, ethephon, and the ethylene biosynthesis inhibitor, AVG, as well as by transfer experiments where sunflower seedlings were transferred from one PAR regime to another with subsequent growth and ethylene measurements.     

Biochemical Characterization of the Cell-Biomaterial Interface by Quantitative Proteomics

Surface topography and texture of cell culture substrata can affect the differentiation and growth of adherent cells. The biochemical basis of the transduction of the physical and mechanical signals to cellular responses is not well understood. The lack of a systematic characterization of cell-biomaterial interaction is the major bottleneck. This study demonstrated the use of a novel subcellular fractionation method combined with quantitative MS-based proteomics to enable the robust and high-throughput analysis of proteins at the adherence interface of Madin-Darby canine kidney cells. This method revealed the enrichment of extracellular matrix proteins and membrane and stress fibers proteins at the adherence surface, whereas it shows depletion of extracellular matrix belonging to the cytoplasmic, nucleus, and lateral and apical membranes. The asymmetric distribution of proteins between apical and adherence sides was also profiled. Apart from classical proteins with clear involvement in cell-material interactions, proteins previously not known to be involved in cell attachment were also discovered.The growth and differentiation of cells in multicellular organisms are regulated by the complex interplay of biochemical and mechanical signals. In the past decades, a plethora of data on the roles of mechanical and structural cues in modulating cellular behaviors has emerged (1–5). It is increasingly evident that cell fates can be changed by engineering the physical properties of the microenvironment to which the cells are exposed (6–8). These observations have inspired the development of functionalized biomaterials that can directly and specifically interact with tissue components, and support or even direct the appropriate cellular activities (9, 10). Although promising progress has been observed in the past few years, several gaps in knowledge in this field have hindered the development of such ”intelligent” biomaterials. In particular, the understanding of the mechanism in which the cell orchestrates physiological and morphological changes by translating mechanical and structural information into biochemical signals is still very limited.As a standard experimental model, cell lines cultured in vitro as a monolayer over solid substrata are usually used to study the effects of biomaterial surfaces on cellular phenotypes. With this simple model system, ingenious experiments have shown that physical forces applied through the extracellular matrix (ECM)1 can induce changes in cell adhesion molecules and stress-induced ion channels, which then lead to changes in the cytoskeleton and gene expressions (11–13). We term the biochemical structure present at the interface between the substratum and the cellular interior the adherence surface (AS), which is composed of the basal plasma membrane with associated structures such as the ECM on one side and the focal adherence complexes on the other. In monolayer cell culture systems, the AS is the only part of the cells in direct contact with the substratum, and is therefore responsible for the first line of communication between the cells and the biomaterial. It is likely that the AS is the organelle that mediates the communication of mechanical and tectonic signals from the substratum to biochemical transducers in the cells. Given the complexity of this process, it is clear that the understanding of this phenomenon cannot be achieved merely by studying individual biological parts in isolation. It is necessary, therefore, to systematically characterize the biochemical factors that mediate the interactions between cells and materials to yield insights into intracellular signaling processes that are responsible for such cellular responses. Toward this goal, we seek to investigate the biochemical basis of how different biomaterials may impose changes in the composition of the AS of adherent cells.MS-based proteomics have recently emerged as a standard technique in modern cell biology. Various techniques based on the chemical conjugation of isotopically labeled reporters to proteins or peptides, such as the isobaric tag for relative and absolute quantitation (iTRAQ) and the isotope-coded affinity tags, enable MS-based proteomics to quantify and compare proteome changes between biological samples. As an attractive alternative, stable isotope labeling with amino acids in cell culture (SILAC) is a metabolic labeling technique that enables isotopically encoded cells to be mixed before lysis and fractionation, thus eliminating inherent quantification biases in these steps, and also enables a simpler procedure and more accurate quantitation (14). SILAC MS-based proteomics have recently contributed to organellar proteomes (15, 16), accurate measurement of protein-protein interactions (17), and the characterization of proteome dynamics during cell differentiation (18). The use of MS-based proteomics has enabled the systematic evaluation of proteome changes on the adhesion of cells to substrata of interest. Kantawong et al. (19) applied DIGE and LC-MS/MS to identify proteome changes in cells on surface with nanotopography. Xu et al. (20) investigated proteome differences of human osteoblasts on various nano-sized hydroxyapatite powders with different shapes and chemical compositions using iTRAQ-based two-dimensional LC-MS/MS.One advantage of proteomics is that it can effectively be combined with subcellular fractionation and allow the comprehensive characterization of the proteins enriched in targeted cellular structures. To yield new insight in molecular interactions in cell-biomaterial interfaces, we aimed to develop a robust protocol for the proteomic characterization of the AS of adherent cells on a biomaterial surface and use it for discovering new cell-biomaterial interface specific biomarkers. Our approach was to develop an isolation technique for AS with high yields and purity for proteomic analysis. The isolated AS on substratum was analyzed by confocal microscopy and Western blotting. SILAC was then used to characterize the fold-enrichment of proteins in the purified AS compared with whole cells and to discover new biomolecules in the cell-biomaterial interface. This study introduces a novel cell-biomaterial interface proteomic procedure, which can be used to identify the AS specific proteome in a high throughput manner and provide a simple and robust method to systematically analyze cell-biomaterial interactions at a molecular level.     

Morphological and physiological responses of canola (Brassica napus) siliquas and seeds to UVB and CO2 under controlled environment conditions

Combined effects of UVB radiation and CO₂ concentration on plant reproductive parts have received little attention. We studied morphological and physiological responses of siliquas and seeds of canola (Brassica napus L. cv. 46A65) to UVB and CO₂ under four controlled experimental conditions: UVB radiation (4.2 kJ m⁻² d⁻¹) with ambient level of CO₂ (370 μmol mol⁻¹) (control); UVB radiation (4.2 kJ m⁻² d⁻¹) with elevated level of CO₂ (740 μmol mol⁻¹); no UVB radiation (0 kJ m⁻² d⁻¹) with ambient level of CO₂ (370 μmol mol⁻¹); and no UVB radiation (0 kJ m⁻² d⁻¹) with elevated level of CO₂ (740 μmol mol⁻¹). UVB radiation affected the outer appearance of siliquas, such as colour, as well as their anatomical structures. At both CO₂ levels, the UVB radiation of 4.2 kJ m⁻² d⁻¹ reduced the size of seeds, which had different surface patterns than those from no UVB radiation. At both CO₂ levels, 4.2 kJ m⁻² d⁻¹ of UVB decreased net CO₂ assimilation (A_N) and water use efficiency (WUE), but had no effect on transpiration (E). Elevated CO₂ increased A_N and WUE, but decreased E, under both UVB conditions. At both CO₂ levels, the UVB radiation of 4.2 kJ m⁻² d⁻¹ decreased chlorophyll fluorescence, total chlorophyll (Chl), Chl a and Chl b, but had no effect on the ratio of Chl a/b and the concentration of UV-screening pigments. Elevated CO₂ increased total Chl and the concentration of UV-screening pigments under 4.2 kJ m⁻² d⁻¹ of UVB radiation. Neither UVB nor CO₂ affected wax content of siliqua surface. Many significant relationships were found between the above-mentioned parameters. This study revealed that UVB radiation exerts an adverse effect on canola siliquas and seeds, and some of the detrimental effects of UVB on these reproductive parts can partially be mitigated by CO₂.     

Mechanisms of the vasorelaxant effect of 1-hydroxy-2, 3, 5-trimethoxy-xanthone, isolated from a Tibetan herb, Halenia elliptica, on rat coronary artery

1-Hydroxy-2, 3, 5-trimethoxyxanthone (HM-1) is a xanthone isolated from Halenia elliptica, a Tibetan medicinal herb. HM-1 (0.33-42.1 microM) produced a concentration-dependent relaxation in rat coronary artery rings pre-contracted with 1 microM 5-hydroxytryptamine (5-HT), with an EC(50) of 1.67+/-0.27 microM. Removal of the endothelium significantly affected the vasodilator potency of HM-1, resulting in 46% decrease in E(max) value. The endothelium-dependent effects of HM-1 was confirmed when its vasorelaxant effect was inhibited after addition of nitric oxide synthase (NOS) inhibitor N(omega)-nitro-l-arginine methyl ester (100 microM) or the soluble guanylate cyclase inhibitor 1H-[1, 2, 4] oxadiazolo [4,3-alpha] quinoxalin-1-one (ODQ, 10 microM). Atropine (100 nM), flurbiprofen (10 microM), propranolol (100 microM), pyrilamine (10 microM), cimetidine (10 microM) and SQ22536 (100 microM) had no effect on the vasorelaxant activity of HM-1 indicated the non-involvement of other receptor/enzyme systems. In endothelium-denuded coronary artery rings, the vasorelaxant effect of HM-1 was unaffected by potassium channel blockers such as tetraethylammonium (10 mM), iberiotoxin (100 nM), barium chloride (100 microM) and 4-aminopyridine (1 mM). The involvement of Ca(2+) channel in 5-HT-primed artery ring preparations incubated with Ca(2+)-free buffer was confirmed when HM-1 (9.93 microM) partially abolished the CaCl(2)-induced vasoconstriction (87% inhibition in intact-endothelium artery rings; 50% inhibition in endothelium-denuded rings). In the KCl-primed preparations incubated with Ca(2+)-free buffer, HM-1 (9.93 microM) produced a 27.3% inhibition in endothelium-denuded rings. HM-1 (3.31-33.1 microM) had minimal relaxant effects (14.4%-20.3%) on the contractile response generated by 10 microM phorbol 12,13-diacetate (PDA) in Ca(2+)-free solutions, suggesting minimal effects on intracellular Ca(2+) mechanisms. These findings suggest the vasodilator action of HM-1 involved both an endothelium-dependent mechanism involving NO and an endothelium-independent mechanism by inhibiting Ca(2+) influx through L-type voltage-operated Ca(2+) channels; a minor contribution to the effects of HM-1 may be related to inhibition of the protein kinase C-mediated release of intracellular Ca(2+) stores.     

Pharmacological and biophysical isolation of K+ currents encoded by ether-à-go-go-related genes in murine hepatic portal vein smooth muscle cells

The functional properties of the Saccharomyces cerevisiae bicarbonate transporter homolog Bor1p (YNL275wp) were characterized by measuring boron (H₃BO₃), Na⁺, and Cl^– fluxes. Neither Na⁺ nor Cl^– appears to be a transported substrate for Bor1p. Uphill efflux of boron mediated by Bor1p was demonstrated directly by loading cells with boron and resuspending in a low-boron medium. Cells with intact BOR1, but not the deletant strain, transport boron outward until the intracellular concentration is sevenfold lower than that in the medium. Boron efflux through Bor1p is a saturable function of intracellular boron (apparent K_m 1–2 mM). The extracellular pH dependences of boron distribution and efflux indicate that uphill efflux is driven by the inward H⁺ gradient. Addition of 30 mM HCO₃^– does not affect boron extrusion by Bor1p, indicating that HCO₃^– does not participate in Bor1p function. Functional Bor1p is present in cells grown in medium with no added boron, and overnight growth in 10 mM H₃BO₃ causes only a small increase in the levels of functional Bor1p and in BOR1 mRNA. The fact that Bor1p is expressed when there is no need for boron extrusion and is not strongly induced in the presence of growth-inhibitory boron concentrations is surprising if the main physiological function of yeast Bor1p is boron efflux. A possible role in vacuolar dynamics for Bor1p was recently reported by Decker and Wickner (10). Under the conditions used presently, there appears to be mildly abnormal vacuolar morphology in the deletant strain. boron; SLC4; YNL275w