Uptake of jasmonic acid and related compounds by mesophyll protoplasts of the barley leaf

Jasmonic acid (JA) permeates the plasma membrane of mesophyll cells by diffusion as the lipophilic undissociated JAH molecule probably without the participation of a saturable uptake component. The mesophyll plasma membrane is nearly impermeable to the JA anion. The permeability coefficients of JA and several JA derivatives (its methyl ester (JAMe), 7-iso-cucurbic acid (7-iso-CA), 6-epi-7-iso-cucurbic acid (6-epi-7-iso-CA), and both stereoisomers of the JA leucine conjugate ((+)-JA-Leu and (-)-JA-Leu)) were determined and used in a simplified mathematical model to predict stressdependent JA redistribution between cytosol and apoplast in comparison with ABA. The redistribution of JA takes place similar to ABA; however, its velocity is much higher because of the high JA membrane permeability. When the permeability coefficients for the mesophyll plasma membrane are plotted double-logarithmically against the ratio of the distribution coefficient and the molecular ratio to the power of 1.5 (K_DM_r ^–1.5), two straight lines result for two different classes of compounds. The permeability coefficients of JA conjugates are lower than that of the free acid by approximately one order of magnitude, but they are still significantly higher than that of ABA.     

Long-term follow-up after bypass surgery or coronary stenting in elderly with multivessel disease

Background

We sought to compare long-term follow-up of coronary artery bypass grafting (CABG) with percutaneous coronary intervention (PCI) in elderly patients with left main or multivessel disease, hypothesising that completeness of revascularisation and severity of coronary artery disease are predictors of adverse outcomes.

Methods

Patients aged ≥75 years with multivessel disease or left main disease who underwent PCI or CABG between 2012–2016 were included in this retrospective cohort study. Baseline characteristics from the index procedure were collected. Severity of coronary artery disease and completeness of revascularisation were assessed. Primary outcome was all-cause mortality, in addition we captured major adverse cardiac and cerebral events, bleedings, recurrent angina and new onset atrial fibrillation.

Results

A total of 597 patients were included. Median follow-up was 4 years (interquartile range 2.8–5.3 years). At baseline, patients in the PCI group more often had a previous medical history of CABG and more frequently underwent an urgent procedure compared with patients in the CABG group. Mortality at 5‑year follow-up was significantly higher in patients who underwent PCI compared with CABG (39.9% vs 25.4%, p < 0.001). Furthermore, acute coronary syndrome (ACS), repeat revascularisation and recurrent angina occurred more frequently after PCI, while occurrence of bleedings and new onset atrial fibrillation were more frequent after CABG. Neither completeness of revascularisation nor severity of coronary artery disease was a predictor for any of the outcomes.

Conclusion

Long-term mortality was higher in elderly patients with multivessel disease undergoing PCI compared with CABG. In addition, patients undergoing PCI had a higher risk of ACS, repeat revascularisation and recurrent angina.

     

The permeability of the epidermal cell plasma membrane of barley leaves to abscisic acid

Uptake of ³H-labelled (±)-abscisic acid (ABA) into isolated barley (Hordeum vulgare L.) epidermal cell protoplasts (ECP) was followed over a range of pH values and ABA concentrations. The present results show that ABA uptake is not always linearly correlated with the external concentration of undissociated ABA (ABAH). At pH 7.25, ABA uptake exhibited saturation kinetics with an apparent K _m value of 75 mmol·m^–3 to tal ABA. This saturable transport component was inhibited by pretreating the protoplasts with 1 mol·m^–3 p-chloromercuribenzenesulfonic acid at pH 8.0, conditions that minimized the uptake of this acid sulfhydryl reagent. Moreover, the rate of (±)-[^3]HABA uptake was reduced by addition of 0.1 mol·m^–3 (±)-ABA to 41%, whereas the same concentration of (±)-ABA was approximately half as effective (46% of the inhibitory effect). Thus, it was concluded that only (±)-ABA competes for an ABA carrier that is located in the epidermal cell plasma membrane. The permeability of the epidermal cell plasma membrane was studied by performing a Collander analysis. At pH 6 the overall plasma-membrane permeability of epidermal cells was similar to that of guard cells but was about two times higher than that of mesophyll cells.Abbreviations ABA abscisic acid - ABA^– anion of ABA - ABAH undissociated ABA - 2,4-D 2,4-dichlorophenoxyacetic acid - DMO 5,5-dimethyloxazolidine-2,4-dione - ECP deepidermal cell protoplast - K_r partition coefficient - M_r relative molecular mass - NEM N-ethylmaleimide - PCMBS p-chloromercuriben zenesulfonic acid - P_s permeability coefficient We are grateful to Barbara Dierich for expert technical assistance, to Prof. H. Gimmler (Lehrstuhl für Botanik I, Universität Würzburg, FRG) for helpful discussions and to the Deutsche Forschungsgemeinschaft (SFB 251, TP 3) for financial support.     

Using real-world data to monitor and improve quality of care in coronary artery disease: results from the Netherlands Heart Registration

Netherlands Heart Journal - Worldwide, quality registries for cardiovascular diseases enable the use of real-world data to monitor and improve the quality of cardiac care. In the Netherlands Heart...     

REVIEW ARTICLE: Compartmental redistribution and long-distance transport of abscisic acid (ABA) in plants as influenced by environmental changes in the rhizosphere --a biomathematical model

Based on experimental data obtained in earlier studies on membranepermeabilities of abscisic acid (ABA) for cortex and stele cellsof roots and on measured com-partmental pH shifts after onsetor release of different types of soil-borne stresses, a biomathematicalmodel was developed which permits computer analysis of the dynamicsof compartmental ABA distribution within different root tissues(cortex, stele) and their compartments (apoplast, cytosol, vacuole),and in the xylem sap of the root stele. Metabolism and conjugationof ABA and its export from roots via the xylem and its importinto roots via phloem sap flow are also taken into consideration.We want to know which soil-borne stresses can biophysicallyprovoke a root-to-shoot signal of ABA. In this communicationwe describe the biomathematical structure of the root modeland present all necessary morphological (volumes, surfaces etc.)and physiological (pH, membrane conductances etc.) parametersof unstressed roots. This root model and an available leaf modelare integrated to a plant model (rosette plant). Simulationsreveal the fundamental role of the stele tissues, the rhizosphericABA concentration and the ABA synthesis in roots (root-to-shootcommunication). The shoot-to-root communication strongly dependson ABA synthesis in leaves, but hardly on ABA redistributioneffects after stress-induced compartmental pH-shifts in leaves. Key words: Abscisic acid, compartmental redistribution, computer model, pH shifts, root-to-shoot communication, shoot-to-root communication