Rhizobiome dynamics in plant growth promotion and abiotic stress response

Abstract

Soil microorganisms play vital roles in global nutrient cycling. Understanding the complex relationships between plants and soil microbes and their implications is one of the greatest challenges facing microbial ecology today. Soil microbes can play beneficial roles in supporting plant growth by increasing access to nutrients, water, and decreasing plant stress signaling under abiotic stresses such as drought and heat. With increasing climate variability due to climate change, it is imperative to make scientifically informed management decisions to best support global biodiversity and plant productivity in natural and agroecosystsms. In this dissertation I summarize four separate investigations of plant-microbe interactions. The first is using nitrogen-fixing cyanobacterial biofertilizers to promote plant growth of perennial second generation bioenergy crops switchgrass (Panicum virgatum) and tall wheatgrass (Agropyrun elongatum). The second and third studies seek to better understand plant-microbe carbon exchange under drought stress in the native North American prairie grass blue grama (Bouteloua gracilis). The final study explores the potential microbial contribution to heat tolerance of panic grass (Dichanthelium lanuginosum) across a natural soil temperature gradient in Yellowstone National Park. Next-generation amplicon sequencing using the Illumina Miseq platform is the primary technique utilized across the three studies to investigate microbial community dynamics. The main results of the biofertilizer study were that tall wheatgrass is better suited to the SW Montana growing season than switchgrass, and similar plant yields were achieved with the cyanobacterial biofertilizer as with urea chemical fertilizer without negatively impacting the microbial community diversity. The first blue grama study found that severe and mild drought had distinct, phylogenetically linked responses within the blue grama rhizobiome with Planctomycetes, Thermoproteota (ammonia-oxidizing archaea), and Glomeromycetes (arbuscular mycorrhizal fungi) exhibiting notably altered relative abundances. The second blue grama study found that climate legacy plays an important role in shaping blue grama drought response. Finally, from the D. lanuginosum study in Yellowstone National Park we learned that pH and temperature both strongly influence community composition, and that D. lanuginosum selects for unique community members in its rhizosphere at higher temperatures. Collectively, these studies contribute to furthering our understanding of the dynamics of plant-associated microbiomes.