Resistance of Tobacco to Thielaviopsis basicola under Tissue Culture Conditions and Increased Susceptibility after Transformation with Agrobacterium tumefaciens T-DNA

Tobacco callus cultures from a Thielaviopsis basicola (Berk. et Br.) Ferraris resistant cultivar were less severely colonized than callus cultures from susceptible cultivars by the pathogen at all concentrations of kinetin and α-indoleacetic acid tested. However, at concentrations where these substances influenced the morphology of the callus cultures they also influenced the degree of colonization by the fungus. Incorporation of T-DNA of Agrobacterium tumefaciens induced susceptibility in tissue culture of the resistant cultivar but did not significantly modify the reaction of the susceptible cultivar tested.     

Expression of the Arabidopsis vacuolar H+‐pyrophosphatase gene (AVP1) improves the shoot biomass of transgenic barley and increases grain yield in a saline field

Cereal varieties with improved salinity tolerance are needed to achieve profitable grain yields in saline soils. The expression of AVP1, an Arabidopsis gene encoding a vacuolar proton pumping pyrophosphatase (H⁺‐PPase), has been shown to improve the salinity tolerance of transgenic plants in greenhouse conditions. However, the potential for this gene to improve the grain yield of cereal crops in a saline field has yet to be evaluated. Recent advances in high‐throughput nondestructive phenotyping technologies also offer an opportunity to quantitatively evaluate the growth of transgenic plants under abiotic stress through time. In this study, the growth of transgenic barley expressing AVP1 was evaluated under saline conditions in a pot experiment using nondestructive plant imaging and in a saline field trial. Greenhouse‐grown transgenic barley expressing AVP1 produced a larger shoot biomass compared to null segregants, as determined by an increase in projected shoot area, when grown in soil with 150 mm NaCl. This increase in shoot biomass of transgenic AVP1 barley occurred from an early growth stage and also in nonsaline conditions. In a saline field, the transgenic barley expressing AVP1 also showed an increase in shoot biomass and, importantly, produced a greater grain yield per plant compared to wild‐type plants. Interestingly, the expression of AVP1 did not alter barley leaf sodium concentrations in either greenhouse‐ or field‐grown plants. This study validates our greenhouse‐based experiments and indicates that transgenic barley expressing AVP1 is a promising option for increasing cereal crop productivity in saline fields.     

Effect of NO synthase inhibition on myocardial metabolism during moderate ischemia

Nitric oxide (NO) is involved in the control of myocardial metabolism. In normoperfused myocardium, NO synthase inhibition shifts myocardial metabolism from free fatty acid (FFA) toward carbohydrate utilization. Ischemic myocardium is characterized by a similar shift toward preferential carbohydrate utilization, although NO synthesis is increased. The importance of NO for myocardial metabolism during ischemia has not been analyzed in detail. We therefore assessed the influence of NO synthase inhibition with N(G)-nitro-l-arginine (l-NNA) on myocardial metabolism during moderate ischemia in anesthetized pigs. In control animals, the increase in left ventricular pressure with l-NNA was mimicked by aortic constriction. Before ischemia, l-NNA decreased myocardial FFA consumption (MV(FFA); P < 0.05), while consumption of carbohydrate and O(2) (MVo(2)) remained constant. ATP equivalents [calculated with the assumption of complete oxidative substrate decomposition (ATP(eq))] decreased with l-NNA (P < 0.05), associated with a decrease of regional myocardial function (P < 0.05). In contrast, aortic constriction had no effect on MV(FFA), while MVo(2) increased (P < 0.05) and ATP(eq) and regional myocardial function remained constant. During ischemia, alterations in myocardial metabolism were similar in control and l-NNA-treated animals: MV(FFA) decreased (P < 0.05) and net lactate consumption was reversed to net lactate production (P < 0.05). Regional myocardial function was decreased (P < 0.05), although more markedly in animals receiving l-NNA (P < 0.05). We conclude that the efficiency of oxidative metabolism was impaired by l-NNA per se, paralleled by impaired regional myocardial function. During ischemia, l-NNA had no effect on myocardial substrate consumption, indicating that NO synthases were no longer effectively involved in the control of myocardial metabolism.     

Lessons from the eradication of smallpox: an interview with D. A. Henderson

It has been more than 35 years since the last naturally occurring case of smallpox. Sufficient time has passed to allow an objective overview of what were the key factors in the success of the eradication effort and what lessons smallpox can offer to other campaigns. Professor D. A. Henderson headed the international effort to eradicate smallpox. Here, we present a summary of D. A. Henderson''s perspectives on the eradication of smallpox. This text is based upon the Unither Baruch Blumberg Lecture, delivered by D. A. Henderson at the University of Oxford in November 2012 and upon conversations and correspondence with Professor Henderson.     

Measuring fractional forest canopy element cover and openness – definitions and methodologies revisited

Canopy structural parameters are often used to give adequate representation of vegetated ecosystems for various purposes including primary productivity, climate system, water and carbon gas exchanges, and radiation extinction. Canopy structural parameters are usually described using several pseudo‐synonymous terms, often measuring different components of vegetation canopies. Standardization in the definitions has fallen short, leading to confusion of terms even in standard text books making the comparison of historic measures futile. Here we clarify concepts that have been used for fractional canopy element cover and openness measures. The fractional canopy element cover and openness concepts considered are canopy closure, canopy cover, canopy openness, crown closure, crown completeness, crown cover, crown porosity, site openness and tilt openness. New methodologies are presented to obtain large scale fractional canopy element cover and openness measures using hemispherical photography. The new methodologies and variations in definitions of fractional canopy element cover and openness concepts are demonstrated using photographic measurements in complex topography. The results indicate that both fractional canopy element cover and openness parameters can be estimated with a few point‐based measurements using hemispherical photography. Hemispherical photography is therefore less time, labour and resource intensive, as compared to point based measuring techniques of canopy element cover and openness. Most of the commonly and interchangeably used concepts of fractional canopy element cover and openness measures represent physically different structural properties of a vegetated ecosystem.