Whole genome expression array profiling highlights differences in mucosal defense genes in Barrett's esophagus and esophageal adenocarcinoma

Esophageal adenocarcinoma (EAC) has become a major concern in Western countries due to rapid rises in incidence coupled with very poor survival rates. One of the key risk factors for the development of this cancer is the presence of Barrett's esophagus (BE), which is believed to form in response to repeated gastro-esophageal reflux. In this study we performed comparative, genome-wide expression profiling (using Illumina whole-genome Beadarrays) on total RNA extracted from esophageal biopsy tissues from individuals with EAC, BE (in the absence of EAC) and those with normal squamous epithelium. We combined these data with publically accessible raw data from three similar studies to investigate key gene and ontology differences between these three tissue states. The results support the deduction that BE is a tissue with enhanced glycoprotein synthesis machinery (DPP4, ATP2A3, AGR2) designed to provide strong mucosal defenses aimed at resisting gastro-esophageal reflux. EAC exhibits the enhanced extracellular matrix remodeling (collagens, IGFBP7, PLAU) effects expected in an aggressive form of cancer, as well as evidence of reduced expression of genes associated with mucosal (MUC6, CA2, TFF1) and xenobiotic (AKR1C2, AKR1B10) defenses. When our results are compared to previous whole-genome expression profiling studies keratin, mucin, annexin and trefoil factor gene groups are the most frequently represented differentially expressed gene families. Eleven genes identified here are also represented in at least 3 other profiling studies. We used these genes to discriminate between squamous epithelium, BE and EAC within the two largest cohorts using a support vector machine leave one out cross validation (LOOCV) analysis. While this method was satisfactory for discriminating squamous epithelium and BE, it demonstrates the need for more detailed investigations into profiling changes between BE and EAC.     

Seasonal changes in leaf antioxidant systems and xanthophyll cycle characteristics in Taxus x media growing in sun and shade environments

We examined differences between summer and winter in xanthophyll cycle-dependent energy dissipation and leaf antioxidant systems in needles of the overwintering evergreen Taxus x media cv. Tauntonii (Taunton yew) growing in both sun and shade environments in Saint Paul, Minnesota. During the winter, both sun and shade plants exhibited increases in the capacity for, and utilization of, xanthophyll cycle-dependent thermal energy dissipation. Winter needles showed decreases (sun needles) or no change (shade needles) in superoxide dismutase activity (EC 1.15.1.1), no change in ascorbate peroxidase activity (EC 1.11.1.11) and no change (sun needles) or increases (shade needles) in reduced ascorbate levels. Both sun and shade needles showed large increases in glutathione reductase activity (EC 1.6.4.2) and total glutathione levels during the winter, in addition to increases in levels of α-tocopherol. These results suggest an important photoprotective role during the winter for xanthophyll cycle-dependent energy dissipation and for the antioxidants glutathione and α-tocopherol. They suggest a less important photoprotective function of the enzyme-based water–water cycle in winter acclimation in the seasonally very cold environment of Minnesota.     

Multimodality imaging of anomalous pulmonary veins

Partial anomalous pulmonary venous connection (PAPVC) is an extremely rare congenital condition where one or more of the pulmonary veins are connected to the venous circulation. Although initially suspected with unexplained right ventricular enlargement on transthoracic echocardiography (TTE), cardiac MRI is able to delineate the anatomical variant. We present a case of a 65-year-old male diagnosed with left sided PAPVC using multimodality cardiac imaging.     

Lack of tyrosine nitration by hypochlorous acid in the presence of physiological concentrations of nitrite. Implications for the role of nitryl chloride in tyrosine nitration in vivo

Elevated levels of reactive nitrogen species (RNS) such as peroxynitrite have been implicated in over 50 diverse human diseases as measured by the formation of the RNS biomarker 3-nitrotyrosine. Recently, an additional RNS was postulated to contribute to 3-nitrotyrosine formation in vivo; nitryl chloride formed from the reaction of nitrite and neutrophil myeloperoxidase-derived hypochlorous acid (HOCl). Whether nitryl chloride nitrates intracellular protein is unknown. Therefore, we exposed intact human HepG2 and SW1353 cells or cell lysates to HOCl and nitrite and examined each for 3-nitrotyrosine formation by: 1) Western blotting, 2) using a commercial 3-nitrotyrosine enzyme-linked immunosorbent assay kit, 3) flow cytometric analysis, and 4) confocal microscopic analysis. With each approach, no significant 3-nitrotyrosine formation was observed in either whole cells or cell lysates. However, substantial 3-nitrotyrosine was observed when peroxynitrite (100 microm) was added to cells or cell lysates. These data suggest that nitryl chloride formed from the reaction of nitrite with HOCl does not contribute to the elevated levels of 3-nitrotyrosine observed in human diseases.     

Hydrogen sulfide effects on stomatal apertures

Hydrogen sulfide (H₂S) has recently been reported to be a signaling molecule in plants. It has been well established that is has such roles in animals and it has been suggested that it is included into the group of gasotransmitters. We have recently shown that hydrogen sulfide causes stomatal opening in the model plant Arabidopsis thaliana. H₂S can be supplied to the plant tissues from donors such as sodium hydrosulfide (NaSH) or more recently from slow release H₂S donor molecules such as GYY4137. Both give similar effects, that is, they cause stomatal opening. Furthermore both H₂S donors reduced the accumulation of nitric oxide (NO) induced by abscisic acid (ABA) treatment of leaf tissues. Here similar work has been repeated in a crop plant, Capsicum anuum, and similar data has been obtained, suggesting that such effects of hydrogen sulfide on plants is not confined to model species.Key words: abscisic acid, GYY4137, hydrogen sulfide, nitric oxide, stomatal apertureThe effects of hydrogen sulfide on plants have been studied for many years, but it is only recently that it has been suggested that this gas is acting as a signaling molecule. In animals this has been well established^1,2 and it has been suggested that H₂S be grouped together with other gasotransmitters.^2,3 This group will also contain nitric oxide (NO) which as well as having established roles in animals is also known to cause stomatal closure in plants.^4,5 With this in mind, we previously investigated whether H₂S may also have an effect on stomatal closure, using a model organism Arabidopsis thaliana.⁶ The study used two different H₂S donors, sodium hydrosulfide (NaSH) and morpholin-4-ium 4 methoxyphenyl(morpholino) phosphinodithionate (GYY4137). The former will release H₂S in an instant burst which soon dissipates, which questions the wisdom of its use. GYY4137 on the other hand will release H₂S much more slowly and in a manner which is more likely to reflect physiological generation of H₂S.^7,8 Both donors caused stomatal that had previously been exposed to light to open even further. If leaf tissues were not light treated H₂S compounds once again caused stomata to open. Furthermore, H₂S treatment prevented stomatal closure caused by dark treatment. To investigate the possible mechanism of this effect, tissues were treated with the plant hormone abscisic acid (ABA) to initiate NO generation and then NO accumulation was measured in the absence and presence of H₂S donors using fluorescent probes and confocal microscopy.⁹ Both NaSH and GYY4137 caused a reduction in the accumulation of NO. This suggests that H₂S may be acting by a disruption of NO signaling, which results in the alteration of guard cell physiology.Others have reported different effects of H₂S on stomatal movements. Garcia-Mata and Lamattina¹⁰ found that both H₂S donors NaSH and GY4137 caused stomatal closure in different plant species including Vicia faba, Arabidopsis thaliana and Impatiens walleriana. Use of glibenclamide, which is an ABC transport inhibitor, reduced the effect. Cystathione γ lyase and L-Cys desulfhydrase are enzymes which may be responsible for H₂S synthesis and stomatal movements were also reduced by propargylglycine, an inhibitor of these enzymes. It was suggested therefore that H₂S helps to mediate ABA signaling pathway in guard cells. This paper was further discussed following its publication by Desikan.¹¹ However, this seems to be in conflict with the work we reported. This would not be the first time that there has been contradictory data when it comes to reporting stomatal movements, as ethylene has been shown to mediate auxin-induced opening¹² and to cause stomatal closure.¹³More recently it has been reported that stomatal conductance was increased by carbonyl sulfide (COS).¹⁴ The authors went on to suggest that this effect was mediated by H₂S which was produced from COS hydrolysis. This seems to support our original data. Therefore, here we report on the effects of both NaSH and GYY4137 on a different plant species and one which has relevance as an important crop, that is Capsicum anuum. GYY4137 was supplied as in our previous paper in reference ⁶ and ⁷. As can be seen in Figure 1A NaSH caused stomata to open further, even though the leaf tissue had been exposed to the light. Stomata were able to close, as ABA treatment demonstrated, therefore showing that the stomata were not defective. When the experiments were repeated with GYY4137 (Fig. 1B) and smaller but similar effect of the addition of the H₂S donor was seen. This would be expected as the release of H₂S from GYY4137 would be slower and more prolonged than from NaSH.^7,8 To investigate if NO accumulation is also effected in Capsicum when treated with H₂S donors, leaf tissue was treated with ABA to initiate NO generation and NO measured by the use of DAF2-DA as previously reported in references ⁶ and ⁹. Once again the presence of H₂S donors dramatically reduced the amount of NO that was measured following ABA treatment (Fig. 2). This once again suggests that H₂S is having an effect on NO metabolism which may account for the stomata aperture measurements. It has been suggested in animal systems that H₂S and NO react, resulting in the formation of nitrosothiols/nitrothiol-like species¹⁵ which could have signaling effects in their own right. NO in plants has been reported to lead to increased cGMP and/or increased nitrosylation of proteins,⁵ but if H₂S was removing the bioavailability of NO both mechanisms are likely to be reduced.Open in a separate windowFigure 1H₂S donors cause stomatal opening in Capsicum anuum. The leaves of analyzed from Capsicum anuum plants which were between 6 and 7 weeks old. Stomatal bioassays were performed as described previously by Desikan et al.⁹ Epidermal peels were incubated in MES-KCl buffer [10 mM 2-morpholino ethane sulfonic acid (MES), 5 mM KCl, 50 µM CaCl₂, pH 6.15] for 2.5 h exposed to the direct lightning (in 60–100 IE m⁻² s⁻¹) before the addition of various compounds. (A) Samples were sheltered from direct lighting and treated with ABA or NaHS for 2.5 h and left under the day light conditions before stomata apertures were analyzed. (B) Samples were sheltered from direct lighting and treated with ABA or GYY 4137 for next 2 h and left under the day light conditions before stomata apertures were analyzed. Apertures were measured using a light microscope and imaging camera with LEICA QWIN image processing and analysis software (Leica Microsystems and Imaging Solutions, Cambridge, UK). n = 40 stomatal apertures, ±SE. GYY4137 was synthesis as previously described in reference ⁷.Open in a separate windowFigure 2H₂S donors reduce NO accumulation in Capsicum anuum. Nitric oxide accumulation was estimated using the specific NO dye DAF2-DA (Calbiochem, Nottingham, UK), using the method described previously by Desikan et al.⁹ Epidermal fragments in MES-KCl buffer (10 mM MES, 5 mM KCl, 50 µM CaCl₂, pH 6.15) were exposed to the direct lightning for 2 h. After 2 h samples were loaded with 30 µM DAF2-DA for 15 min before washing with MES-KCl buffer; three times for 10 min. Fragments were subsequently incubated for a further 30 min in the presence of various compounds (as indicated below) before images were visualized using CLSM (excitation 488 nm, emission 515 nm; Nikon PCM2000, Kingston-upon-Thames, UK). Images acquired were analyzed using SCION IMAGE software (Scion, Frederick, MD, USA). (A) Control with no treatment; (B) ABA (50) treatment; (C) NaHS (100 µm) treatment alone; (D) ABA treatment in the presence of NaHS; (E) GYY4137 (100 µm) treatment alone; (F) ABA treatment in the presence of NaHS.NO metabolism is involved in a wide range of plant functions, including seed germination,¹⁶ floral development,¹⁷ root gravitropism¹⁸ and gene expression¹⁹ as well as controlling stomatal function.⁴ H₂S on the other hand may be present in or around plants for a variety to reasons. H₂S can be produced endogenously by for example by plastid located cysteine desulfhydrases,²⁰ or H₂S may come from the environment,²¹ including the soil and waters.²² This is further discussed in a recent review in reference ²³. Therefore future work should be focused on the interplay between H₂S from a variety of sources on the NO metabolism of a range of plant tissues. Not all affects of H₂S will be mediated by NO, with alterations of glutathione on H₂S treatment being reported for example.²⁴ But the full extent of the modulation of NO accumulation and signal by both exogenous and endogenous H₂S needs to be explored so the role of these gasotransmitters^2,3 in mediating hormone and stress responses in plants can be fully understood.     

The Coenzyme Q10 analog decylubiquinone inhibits the redox-activated mitochondrial permeability transition: role of mitcohondrial [correction mitochondrial] complex III

The mitochondrial permeability transition (MPT) is a key event in apoptotic and necrotic cell death and is controlled by the cellular redox state. To further investigate the mechanism(s) involved in regulation of the MPT, we used diethylmaleate to deplete GSH in HL60 cells and increase mitochondrial reactive oxygen species (ROS) production. The site of mitochondrial ROS production was determined to be mitochondrial respiratory complex III (cytochrome bc1), because 1). stigmatellin, a Qo site inhibitor, blocked ROS production and prevented the MPT and cell death and 2). cytochrome bc1 activity was abolished in cells protected from the redox-dependent MPT by stigmatellin. We next investigated the effect of pretreating cells with coenzyme Q10 analogs decylubiquinone (dUb) and ubiquinone 0 (Ub0) on the redox-dependent MPT. Pretreatment of HL60 cells with dUb blocked ROS production induced by GSH depletion and prevented activation of the MPT and cell death, whereas Ub0 did not. Since we also found that dUb did not inhibit cytochrome bc1 activity, the mechanism of protection against redox-dependent MPT by dUb may depend on its ability to scavenge ROS generated by cytochrome bc1. These results indicate that dUb, like the clinically used ubiquinone analog idebenone, may serve as a candidate antioxidant compound for the development of pharmacological agents to treat diseases where there is an oxidative stress component.     

Leptin-Induced Endothelium-Dependent Vasorelaxation of Peripheral Arteries in Lean and Obese Rats: Role of Nitric Oxide and Hydrogen Sulfide

Adipose tissue hormone leptin induces endothelium-dependent vasorelaxation mediated by nitric oxide (NO) and endothelium-derived hyperpolarizing factors (EDHF). Previously it has been demonstrated that in short-term obesity the NO-dependent and the EDHF-dependent components of vascular effect of leptin are impaired and up-regulated, respectively. Herein we examined the mechanism of the EDHF-dependent vasodilatory effect of leptin and tested the hypothesis that alterations of acute vascular effects of leptin in obesity are accounted for by chronic hyperleptinemia. The study was performed in 5 groups of rats: (1) control, (2) treated with exogenous leptin for 1 week to induce hyperleptinemia, (3) obese, fed highly-palatable diet for 4 weeks, (4) obese treated with pegylated superactive rat leptin receptor antagonist (PEG-SRLA) for 1 week, (5) fed standard chow and treated with PEG-SRLA. Acute effect of leptin on isometric tension of mesenteric artery segments was measured ex vivo. Leptin relaxed phenylephrine-preconstricted vascular segments in NO- and EDHF-dependent manner. The NO-dependent component was impaired and the EDHF-dependent component was increased in the leptin-treated and obese groups and in the latter group both these effects were abolished by PEG-SRLA. The EDHF-dependent vasodilatory effect of leptin was blocked by either the inhibitor of cystathionine γ-lyase, propargylglycine, or a hydrogen sulfide (H₂S) scavenger, bismuth (III) subsalicylate. The results indicate that NO deficiency is compensated by the up-regulation of EDHF in obese rats and both effects are accounted for by chronic hyperleptinemia. The EDHF-dependent component of leptin-induced vasorelaxation is mediated, at least partially, by H₂S.     

Improve protective efficacy of a TB DNA-HSP65 vaccine by BCG priming

Vaccines are considered by many to be one of the most successful medical interventions against infectious diseases. But many significant obstacles remain, such as optimizing DNA vaccines for use in humans or large animals. The amount of doses, route and easiness of administration are also important points to consider in the design of new DNA vaccines. Heterologous prime-boost regimens probably represent the best hope for an improved DNA vaccine strategy. In this study, we have shown that heterologous prime-boost vaccination against tuberculosis (TB) using intranasal BCG priming/DNA-HSP65 boosting (BCGin/DNA) provided significantly greater protection than that afforded by a single subcutaneous or intranasal dose of BCG. In addition, BCGin/DNA immunization was also more efficient in controlling bacterial loads than were the other prime-boost schedules evaluated or three doses of DNA-HSP65 as a naked DNA. The single dose of DNA-HSP65 booster enhanced the immunogenicity of a single subcutaneous BCG vaccination, as evidenced by the significantly higher serum levels of anti-Hsp65 IgG2a Th1-induced antibodies, as well as by the significantly greater production of IFN-γ by antigen-specific spleen cells. The BCG prime/DNA-HSP65 booster was also associated with better preservation of lung parenchyma. The improvement of the protective effect of BCG vaccine mediated by a DNA-HSP65 booster suggests that our strategy may hold promise as a safe and effective vaccine against TB.