Michelle DaCosta

Research Advances in Mechanisms of Turfgrass Tolerance to Abiotic Stresses: From Physiology to Molecular Biology

Turgrfass used on landscapes, parks, sports fields, and golf courses has significant ecological, environmental, and economic impacts. The economic value of seed production of turfgrasses is second to hybrid corn. The land area cultivated with turfgrass is increasing due to rapid urban development. Turfgrass is often subjected to various abiotic stresses, which cause declines in aesthetic quality, functionality and seed yield. Among abiotic stresses, drought, salinity, heat, and low temperature are the most common detrimental factors for turfgrass growth in various regions. Thorough understanding of mechanisms of turfgrass stress responses is vital for the development of superior stress-tolerant germplasm through breeding and biotechnology. Significant progress has been made in turfgrass stress physiology and molecular biology in recent decades, but research for turfgrasses generally lags behind that of the major Poaceae crops, particularly at the molecular and genomic levels. This review focuses on research advances in turfgrass stress physiology and provides an overview of limited information on gene discovery, genetic transformation, and molecular marker development for improving stress tolerance, with emphasis on drought, salinity, heat, and low temperature stress. Major growth and physiological traits associated with these stresses, as well as metabolic and molecular factors regulating various traits for turfgrass tolerance to each stress are discussed. Future research at the systems biology level and through genomic sequencing is paramount for further insights on fundamental mechanisms of turfgrass stress tolerance and for improving turfgrass tolerance to various environmental stresses.

Projected Carbon Dioxide to Increase Grass Pollen and Allergen Exposure Despite Higher Ozone Levels

One expected effect of climate change on human health is increasing allergic and asthmatic symptoms through changes in pollen biology. Allergic diseases have a large impact on human health globally, with 10–30% of the population affected by allergic rhinitis and more than 300 million affected by asthma. Pollen from grass species, which are highly allergenic and occur worldwide, elicits allergic responses in 20% of the general population and 40% of atopic individuals. Here we examine the effects of elevated levels of two greenhouse gases, carbon dioxide (CO2), a growth and reproductive stimulator of plants, and ozone (O3), a repressor, on pollen and allergen production in Timothy grass (Phleum pratense L.). We conducted a fully factorial experiment in which plants were grown at ambient and/or elevated levels of O3 and CO2, to simulate present and projected levels of both gases and their potential interactive effects. We captured and counted pollen from flowers in each treatment and assayed for concentrations of the allergen protein, Phl p 5. We found that elevated levels of CO2 increased the amount of grass pollen produced by ∼50% per flower, regardless of O3 levels. Elevated O3 significantly reduced the Phl p 5 content of the pollen but the net effect of rising pollen numbers with elevated CO2 indicate increased allergen exposure under elevated levels of both greenhouse gases. Using quantitative estimates of increased pollen production and number of flowering plants per treatment, we estimated that airborne grass pollen concentrations will increase in the future up to ∼200%. Due to the widespread existence of grasses and the particular importance of P. pratense in eliciting allergic responses, our findings provide evidence for significant impacts on human health worldwide as a result of future climate change.

Biochar Application and Drought Stress Effects on Physiological Characteristics of Silybum marianum

ABSTRACT Soil amending with biochar has been viewed as a sustainable way to improve soil moisture holding capacity. The potential of biochar application to improve water status of crops under drought stress has not been extensively evaluated. In this study, we evaluated the impact of biochar application (0%, 1%, and 2% w/w soil) on some important physiological traits of milk thistle (Silybum marianum L. Gaertn) under moderate and severe drought stress conditions in a controlled environment. Although, the application of biochar at the higher rate slightly improved soil moisture holding capacity, the magnitude of its effect was not sufficient to influence plant performance under drought stress. To get the positive effects of biochar application on milk thistle performance under drought stress, application with higher rates is probably necessary.