How are microorganisms and nutrient cycling in saline soils affected by soil matric potential? Dryland agriculture is threatened by salinity and drought, and it is well-known that individually, both can decrease not only crop growth but also microbial activity and nutrient cycling which are critical for sustainability. As our climate becomes drier, it is necessary to understand how microbial activity and nutrient cycling in saline soils will be affected by drought and sporadic summer rainfall ev ....How are microorganisms and nutrient cycling in saline soils affected by soil matric potential? Dryland agriculture is threatened by salinity and drought, and it is well-known that individually, both can decrease not only crop growth but also microbial activity and nutrient cycling which are critical for sustainability. As our climate becomes drier, it is necessary to understand how microbial activity and nutrient cycling in saline soils will be affected by drought and sporadic summer rainfall events. As an international team of soil biologists, we will investigate the interactions between salinity and soil moisture on microbial activity and nutrient cycling. The results will provide insights into nutrient cycling in saline soils now and in the future and the benefit of amelioration strategies.Read moreRead less
Maintenance of Australia's soil resource - water, microbial diversity and function. Water availability is the major limitation to biological activity in semi-arid regions of Australia. We aim to quantify the dynamic relationships between organic matter cycling, microbial diversity and function in relation to seasonality, drought and land management. This will lead to a comprehensive understanding of how water mediates the diversity of soil organisms and their associated functions. This is of sp ....Maintenance of Australia's soil resource - water, microbial diversity and function. Water availability is the major limitation to biological activity in semi-arid regions of Australia. We aim to quantify the dynamic relationships between organic matter cycling, microbial diversity and function in relation to seasonality, drought and land management. This will lead to a comprehensive understanding of how water mediates the diversity of soil organisms and their associated functions. This is of specific relevance to maintaining biodiversity within the unique soil ecosystems that have developed under Australian climatic conditions.Read moreRead less
Quantifying the re-establishment of soil processes and the impact of fire management on rehabilitated bauxite mines in Western Australia. A major objective in the rehabilitation of bauxite mines in the jarrah forest of Western Australia is to return a self-sustaining ecosystem. Nutrient cycling and microbial diversity are key components of the functioning of the rehabilitated system; but little is know about the resilience of these processes in jarrah forests. We aim to quantify the dynamic rela ....Quantifying the re-establishment of soil processes and the impact of fire management on rehabilitated bauxite mines in Western Australia. A major objective in the rehabilitation of bauxite mines in the jarrah forest of Western Australia is to return a self-sustaining ecosystem. Nutrient cycling and microbial diversity are key components of the functioning of the rehabilitated system; but little is know about the resilience of these processes in jarrah forests. We aim to quantify the dynamic relationships between soil organic matter cycling, microbial diversity and function in relation to seasonality, rehabilitation age and fire. This is of specific relevance to restoring biodiversity within rehabilitated Jarrah forests and establishing a time frame for their return to state government management.Read moreRead less
Integrating microbiology and climatic drivers to determine triggers for nitrous oxide emissions from arable soils in semi-arid Western Australia. Increasing nitrous oxide emissions from soil to the atmosphere are a concern as they contribute to global warming and the destruction of the ozone layer. While 70-81% of this increase has been attributed globally to agricultural soils, the factors controlling emissions from arable soils in southern Australia are not well understood. We aim to charact ....Integrating microbiology and climatic drivers to determine triggers for nitrous oxide emissions from arable soils in semi-arid Western Australia. Increasing nitrous oxide emissions from soil to the atmosphere are a concern as they contribute to global warming and the destruction of the ozone layer. While 70-81% of this increase has been attributed globally to agricultural soils, the factors controlling emissions from arable soils in southern Australia are not well understood. We aim to characterise and model the relationship between the soil microbial community responsible for nitrous oxide emissions and soil water availability. Understanding the processes responsible for nitrous oxide emissions will enable us to change the way we manage our semi-arid soils so as to minimise nitrous oxide emissions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100271
Funder
Australian Research Council
Funding Amount
$452,005.00
Summary
Synthetic microbiome: improving crop nitrogen acquisition and productivity. Challenges to food security under conditions of global climate change are forcing us to increase crop production to feed the growing population. Focusing on the plant–microbe interactions, represent a promising area in the search for tools to address this challenge. This project aims to develop a three-step- framework that allows researchers to systematically and reproducibly investigate crop microbiomes to enable us to ....Synthetic microbiome: improving crop nitrogen acquisition and productivity. Challenges to food security under conditions of global climate change are forcing us to increase crop production to feed the growing population. Focusing on the plant–microbe interactions, represent a promising area in the search for tools to address this challenge. This project aims to develop a three-step- framework that allows researchers to systematically and reproducibly investigate crop microbiomes to enable us to design a ‘Beneficial Biome’, a biologically based solution for improving agricultural productivity and environmental sustainability under constrained conditions, where limited resources are available to fertilize.Read moreRead less
The connectivity of pore theory - does it influence microbial community composition and function? Climate change scenarios indicate that Australia will be directly affected by an increase in greenhouse gas emissions. Soil microbial activity is responsible for a large proportion of such emissions; therefore it is important that we understand how such changing climate patterns are likely to influence key microbial populations in soil, particularly those involved in the production of greenhouse ga ....The connectivity of pore theory - does it influence microbial community composition and function? Climate change scenarios indicate that Australia will be directly affected by an increase in greenhouse gas emissions. Soil microbial activity is responsible for a large proportion of such emissions; therefore it is important that we understand how such changing climate patterns are likely to influence key microbial populations in soil, particularly those involved in the production of greenhouse gases. This research interfaces two disciplines, earth and biological sciences, and will establish a new international collaboration that will ensure Australia is at the forefront of a rapidly developing research field.Read moreRead less
Unraveling the spread of antibiotic resistance genes across soil food webs. The emerging spread of antibiotic resistance genes (ARGs) in the environment is a major threat to public health and food security. This project aims to develop new knowledge about the key transmission routes of ARGs across multiple trophic levels in soil food webs, and how the interactions of plant, soil and fauna contribute to the profiles of environmental ARGs. Expected outcomes include an improved understanding of the ....Unraveling the spread of antibiotic resistance genes across soil food webs. The emerging spread of antibiotic resistance genes (ARGs) in the environment is a major threat to public health and food security. This project aims to develop new knowledge about the key transmission routes of ARGs across multiple trophic levels in soil food webs, and how the interactions of plant, soil and fauna contribute to the profiles of environmental ARGs. Expected outcomes include an improved understanding of the role of fauna in regulating ARGs in the soil environment and the spreading mechanisms of antibiotic resistance in soil food webs. This project will contribute to the development of evidence-based interventions to tackle environmental antibiotic resistance, which has benefits for the environment and public health.
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Contribution of comammox bacteria to soil nitrification. This project aims to understand the diversity, activity and environmental relevance of comammox bacteria, the newly-discovered complete nitrifiers, in Australian soils, and to evaluate their relative contributions to nitrification processes compared to other canonical nitrifying prokaryotes. Nitrogen transformations are pivotal microbial processes, with nitrification largely responsible for nitrogen losses through nitrous oxide emissions a ....Contribution of comammox bacteria to soil nitrification. This project aims to understand the diversity, activity and environmental relevance of comammox bacteria, the newly-discovered complete nitrifiers, in Australian soils, and to evaluate their relative contributions to nitrification processes compared to other canonical nitrifying prokaryotes. Nitrogen transformations are pivotal microbial processes, with nitrification largely responsible for nitrogen losses through nitrous oxide emissions and nitrate leaching in the terrestrial ecosystems. The expected outcomes will develop new knowledge on the comammox bacteria and provide novel insights into refined strategies to manipulate nitrification processes for improved nitrogen use efficiency and sustainable agricultural management.Read moreRead less
Alleviating herbicide damage to crops by using fulvate and manganese. Glyphosate is a widely used herbicide, but its drift can cause growth depression in sensitive plants such as wheat by reducing uptake of metallic micronutrients, particularly manganese. In pot and field trials, this project aims to assess the alleviating potential of fulvate and manganese on growth and micronutrient uptake by wheat exposed to glyphosate drift. The influence of land management on the effect of these treatments ....Alleviating herbicide damage to crops by using fulvate and manganese. Glyphosate is a widely used herbicide, but its drift can cause growth depression in sensitive plants such as wheat by reducing uptake of metallic micronutrients, particularly manganese. In pot and field trials, this project aims to assess the alleviating potential of fulvate and manganese on growth and micronutrient uptake by wheat exposed to glyphosate drift. The influence of land management on the effect of these treatments will also be assessed. The underlying mechanisms will be characterised, eg. by determining metal speciation in soil and assessing soil microbial community composition. The outcome of this project will contribute to sustainable agriculture by giving land managers options to reduce glyphosate damage in sensitive crops.Read moreRead less
Characterisation of soil microbial interactions for increased efficacy of herbicides using novel fertiliser management practices. Soil microbes are essential for nutrient cycling and plant root growth. This project aims to investigate whether herbicides influence soil biological processes when different types of fertilisers are used. It is expected that complex interactions between fertiliser practice and herbicides will alter herbicide efficacy in weed control. This project aims to compare nove ....Characterisation of soil microbial interactions for increased efficacy of herbicides using novel fertiliser management practices. Soil microbes are essential for nutrient cycling and plant root growth. This project aims to investigate whether herbicides influence soil biological processes when different types of fertilisers are used. It is expected that complex interactions between fertiliser practice and herbicides will alter herbicide efficacy in weed control. This project aims to compare novel fertiliser practices claimed to maximise benefits from soil microbial processes with traditional fertiliser practices which can override biological processes, including beneficial plant-microbial symbioses. This will enable a rigorous evaluation of fertiliser-herbicide interactions to clarify whether soil microbial benefits can be included as part of weed control programs.Read moreRead less