The Symbiotic Foundation of Biocrust Microbiomes and its Application in Ecological Restoration

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Description
Biocrusts are microbial communities that inhabit arid soil surfaces, providing essential services to dryland ecosystems. A paradoxical filamentous cyanobacterium, Microcoleus vaginatus, resides within the biocrust. While is often pioneers the colonization of bare, nutrient-poor desert soils worldwide, it cannot fix

Biocrusts are microbial communities that inhabit arid soil surfaces, providing essential services to dryland ecosystems. A paradoxical filamentous cyanobacterium, Microcoleus vaginatus, resides within the biocrust. While is often pioneers the colonization of bare, nutrient-poor desert soils worldwide, it cannot fix dinitrogen. In nature, M. vaginatus coexists with a unique microbial community, a “cyanosphere”, that is characterized by a high abundance of diazotrophic heterotrophs. This suggests mutualistic relationships wherein nutrients are traded between phototrophs and heterotrophs. To explore these relationships, I performed targeted, pedigreed isolation of cyanosphere members and used co-cultivation to recreate the mutualism in culture. Results showed that, in the absence of fixed nitrogen, M. vaginatus grew well when co-cultured with cyanosphere diazotrophs, but only poorly or not at all when alone or with non-cyanosphere diazotrophs. In agreement with this, the experimental provision of nitrogen to natural populations resulted in a loss of diazotrophs from the cyanosphere compared to controls, but the addition of phosphorus did not. Additionally, the convergence of M. vaginatus trichomes into large bundles held by a common sheath was elicited in culture by the addition of cyanosphere diazotrophs, pointing to a role of cyanobacterial motility responses in the development of mutualistic interactions. I then demonstrated that the tendency of M. vaginatus to stay within bundles and close to the sheath-dwelling cyanosphere was dependent on the cyanosphere population size. This effect was likely mediated by glutamate that acted as a signaling molecule rather than as a N source and impacted the gliding speed and negative chemophobic responses on the cyanobacterium. Glutamate seems to be used as a cue to spatially optimize cyanobacterium-cyanosphere mutualistic exchanges. My findings have potential practical applications in restoration ecology, which I further pursued experimentally. Co-inoculation of soil with cyanosphere diazotrophs resulted in swifter development of biocrusts over inoculation with the cyanobacterium only. Further, their addition to disturbed native soils containing traces of cyanobacteria sufficed for the formation of cohesive biocrusts without cyanobacterial inoculation. The inclusion of such “biocrust probiotics” in biocrust restoration is recommended. Overall, this body of work elucidates the hitherto unknown role of beneficial heterotrophic bacteria in the initial formation and development of biocrusts.
Date Created
2021
Agent

Characterization of Tropical Agricultural Soil Microbiomes After Biochar Amendment

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Description
Modern agriculture faces multiple challenges: it must produce more food for a growing global population, adopt more efficient and sustainable management strategies, and adapt to climate change. One potential component of a sustainable management strategy is the application of biochar

Modern agriculture faces multiple challenges: it must produce more food for a growing global population, adopt more efficient and sustainable management strategies, and adapt to climate change. One potential component of a sustainable management strategy is the application of biochar to agricultural soils. Biochar is the carbon-rich product of biomass pyrolysis, which contains large proportions of aromatic compounds that influence its stability in soil. Concomitant with carbon sequestration, biochar has the potential to increase soil fertility through increasing soil pH, moisture and nutrient retention. Changes in the soil physical and chemical properties can result in shifts in the soil microbiome, which are the proximate drivers of soil processes. This dissertation aims to determine the compositional and functional changes in the soil microbial community in response to the addition of a low-volatile matter biochar. First, the impact of biochar on the bacterial community was investigated in two important agricultural soils (Oxisol and Mollisol) with contrasting fertility under two different cropping systems (conventional sweet corn and zero-tillage napiergrass) one month and one year after the initial addition. This study revealed that the effects of biochar on the bacterial community were most pronounced in the Oxisol under napiergrass cultivation, however soil type was the strongest determinant of the bacterial community. A follow-up study was conducted using shotgun metagenomics to probe the functional community of soil microcosms, which contained Oxisol soil under napiergrass two years after the initial addition of biochar. Biochar significantly increased total carbon in the soils but had little impact on other soil properties. Theses analyses showed that biochar-amended soil microcosms exhibited significant shifts in the functional community and key metabolic pathways related to carbon turnover and denitrification. Given the distinct alterations to the biochar-amended community, deoxyribose nucleic acid (DNA) stable isotope probing was used to target the active populations. These analyses revealed that biochar did not significantly shift the active community in soil microcosms. Overall, these results indicate that the impact of biochar on the active soil community is transient in nature. Yet, biochar may still be a promising strategy for long-term carbon sequestration in agricultural soils.
Date Created
2020
Agent

Genetics of Athletic Performance

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Description
Abstract
Purpose—Use a framework of genetic knowledge to investigate the association between the genotypes of various genes with phenotypes, specifically the traits of elite athletes, in order to establish a personal opinion on their relevance to athletic performance.
Methods—Assemble and

Abstract
Purpose—Use a framework of genetic knowledge to investigate the association between the genotypes of various genes with phenotypes, specifically the traits of elite athletes, in order to establish a personal opinion on their relevance to athletic performance.
Methods—Assemble and analyze selected published scientific studies on genotype and athletic performance and lastly to formulate a personal opinion on the value of genetic testing of athletes. ACTN3, ACE, MSTN, and apoE were the genes selected for analyses.
Results—Two genes, ACTN3 and ACE, showed a significant relationship of genotype to phenotypic traits related to athletic performance. ApoE did not demonstrate a phenotypic association with athletic performance, however it showed a correlation with injury susceptibility leading to traumatic brain injury (TBI). MSTN did not show a phenotypic association with athletic performance.
Conclusion—When considering the multifactorial nature of athletics, each sport must be investigated individually due to the different individual requirements. ACTN3 and ACE are the most widely studied genes, therefore, considerable data on their relevance to athletic performance was easily obtained and supported a relationship between genotype and athletic performance.
Date Created
2017-05
Agent