Bio


I am an Associate Scientist at SLAC National Accelerator Laboratory, where I explore the intersection of biology and the environment. My research delves into the biogeochemical processes that govern the cycling of essential elements like phosphorus (P), sulfur (S), and potassium (K). With expertise in X-ray Fluorescence (XRF) imaging and tender energy X-ray Absorption Spectroscopy (XAS), I apply these advanced techniques to a diverse range of systems. At SSRL, I contribute to enhancing outreach and engagement with the biological and environmental research communities, offering training and fostering collaboration with both new and experienced users of advanced X-ray methods.

Before joining SSRL, I earned my PhD from Washington University in St. Louis, where my research focused on the geochemical signatures of sulfur in Ordovician marine sediments, employing a combination of sedimentology, bulk geochemistry, and microanalytical techniques. I am originally from Scotland and obtained my BSc in Geology from the University of St. Andrews in Scotland.

All Publications


  • X-ray fluorescence and XANES spectroscopy revealed diverse potassium chemistries and colocalization with phosphorus in the ectomycorrhizal fungus Paxillus ammoniavirescens FUNGAL BIOLOGY Richardson, J. A., Rose, B. D., Garcia, K. 2024; 128 (6): 2054-2061

    Abstract

    Ectomycorrhizal (ECM) fungi play a major role in forest ecosystems and managed tree plantations. Particularly, they facilitate mineral weathering and nutrient transfer towards colonized roots. Among nutrients provided by these fungi, potassium (K) has been understudied compared to phosphorus (P) or nitrogen (N). The ECM fungus Paxillus ammoniavirescens is a generalist species that interacts with the root of many trees and can directly transfer K to them, including loblolly pine. However, the forms of K that ECM fungi can store is still unknown. Here, we used synchrotron potassium X-ray fluorescence (XRF) and K-edge X-ray Absorption Near Edge Structure (XANES) spectroscopy on P. ammoniavirescens growing in axenic conditions to investigate the K chemistries accumulating in the center and the edge of the mycelium. We observed that various K forms accumulated in different part of the mycelium, including K-nitrate (KNO3), K-C-O compounds (such as K-tartrate K2(C4H4O6) and K-oxalate (K2C2O4)), K-S and K-P compounds. Saprotrophic fungi have been shown to excrete carboxylic acids, which in turn play a role in soil mineral weathering. Our finding of several K counter-ions to carboxylic acids may suggest that, besides their direct transfer to colonized roots, K ions can also be involved in the production of compounds necessary for sourcing nutrients from their surrounding environment by ECM fungi. Additionally, this work reveals that XANES spectroscopy can be used to identify the various forms of K accumulating in biological systems.

    View details for DOI 10.1016/j.funbio.2024.08.004

    View details for Web of Science ID 001294580100001

    View details for PubMedID 39174240

  • Sulfur isotopes from the Paleoproterozoic Francevillian Basin record multigenerational pyrite formation, not depositional conditions COMMUNICATIONS EARTH & ENVIRONMENT Paiste, K., Fike, D. A., Mayika, K., Moussavou, M., Lepland, A., Prave, A. R., Sato, T., Ueno, Y., Sawaki, Y., Richardson, J. A., Wood, R. S., Jones, C., Webb, S. M., Kirsimae, K. 2024; 5 (1)
  • X-ray absorption spectroscopy and theoretical investigations of the effect of extended ligands in potassium organic matter interaction. The Journal of chemical physics Richardson, J. A., Kim, H., Kas, J. J., You, X., Andersen, A., Ginovska, B., Bhattacharjee, A., Sarangi, R. 2024; 160 (4)

    Abstract

    Potassium (K) is an essential nutrient for plant growth, and despite its abundance in soil, most of the K is structurally bound in minerals, limiting its bioavailability and making this soil K reservoir largely inaccessible to plants. Microbial biochemical weathering has been shown to be a promising pathway to sustainably increase plant available K. However, the mechanisms underpinning microbial K uptake, transformation, storage, and sharing are poorly resolved. To better understand the controls on microbial K transformations, we performed K K-edge x-ray absorption near-edge structure (XANES) spectroscopy on K-organic salts, including acetate, citrate, nitrate, oxalate, and tartrate, which are frequently observed as low molecular weight organic acids secreted by soil microbes, as well as humic acid, which acts as a proxy for higher molecular weight organic acids. The organic salts display feature-rich K XANES spectra, each demonstrating numerous unique features spanning 13eV range across the absorption edge. In contrast, the spectra for humic acid have one broad, wide feature across the same energy range. We used a combination of time-dependent density functional theory and the Bethe-Salpeter equation based approach within the OCEAN code to simulate the experimental spectra for K-nitrate (KNO3) and K-citrate [K3(C6H5O7)·H2O] to identify the electronic transitions that give rise to some of the outlying and unique spectral features in the organic salts. KNO3 has both the lowest and highest lying energy features, and K3(C6H5O7)·H2O is produced by several soil microbes and is effective at mineral weathering. Our results analyze the K-organic salt bonding in detail to elucidate why the spectral shapes differ and indicate that the K K-edge XANES spectra are associated with the entire ligand despite similar first-shell bonding environments around the K center. The improved understanding of K bonding environments with organic ligands and their use for interpretation of the K-XANES spectra provides an important toolkit to understand how K is transformed by microbial processes and made bioavailable for plant uptake.

    View details for DOI 10.1063/5.0183603

    View details for PubMedID 38284657

  • Fungal organic acid uptake of mineral-derived K is dependent on distance from carbon hotspot. mBio Bhattacharjee, A., Velickovic, D., Richardson, J. A., Couvillion, S. P., Vandergrift, G. W., Qafoku, O., Taylor, M. J., Jansson, J. K., Hofmockel, K., Anderton, C. R. 2023: e0095623

    Abstract

    Fungal mineral weathering regulates the bioavailability of inorganic nutrients from mineral surfaces to organic matter and increase the bioavailable fraction of nutrients. Such weathering strategies are classified as biomechanical or biochemical. In the case of fungal uptake of mineral nutrients through biochemical weathering, it is widely hypothesized that uptake of inorganic nutrients occurs through organic acid chelation, but such processes have not been directly visualized. This is in part due to challenges in probing the complex and heterogeneous soil environment. Here, using an epoxy-based, mineral-doped soil micromodel platform, which emulates soil mineralogy and porosity, we visualize the molecular mechanisms of mineral weathering. Mass spectrometry imaging revealed differences in the distribution of fungal exudates, citric acid, and tartaric acid on the soil micromodels in presence of minerals. Citric acid was detected closer to the nutrient-rich inoculation point, whereas tartaric acid was highly abundant away from inoculation point. This suggested that the organic acid exuded by the fungi depended on the proximity from the carbon-rich organic substrate at the point of inoculation. Using a combination of X-ray fluorescence and X-ray near edge structure analysis, we identified citric acid- and tartaric acid-bound K within fungal hyphae networks grown in the presence of minerals. Combined, our results provide direct evidence that fungi uptake and transport mineral derived nutrient organic acid chelation. The results of this study provided unprecedented visualization of fungal uptake and transport of K+, while resolving the indirect weathering mechanism of fungal K uptake from mineral interfaces. IMPORTANCE Fungal species are foundational members of soil ecosystems with vital contributions that support interspecies resource translocation. The minute details of these biogeochemical processes are poorly investigated. Here, we addressed this knowledge gap by probing fungal growth in a novel mineral-doped soil micromodel platform using spatially-resolved imaging methodologies. We found that fungi uptake K from K-rich minerals using organic acids exuded in a distance-dependent manner from a carbon-rich hotspot. While identification of specific mechanisms within soil remains challenging, our findings demonstrate the significance of reduced complexity platforms such as the mineral-doped micromodel in probing biogeochemical processes. These findings provide visualization into hyphal uptake and transport of mineral-derived nutrients in a resource-limited environment.

    View details for DOI 10.1128/mbio.00956-23

    View details for PubMedID 37655873

  • Saprotrophic Fungus Induces Microscale Mineral Weathering to Source Potassium in a Carbon-Limited Environment MINERALS Richardson, J. A., Anderton, C. R., Bhattacharjee, A. 2023; 13 (5)
  • Tonian Carbonates Record Phosphate-Rich Shallow Seas GEOCHEMISTRY GEOPHYSICS GEOSYSTEMS Roest-Ellis, S., Richardson, J. A., Phillips, B. L., Mehra, A., Webb, S. M., Cohen, P. A., Strauss, J. V., Tosca, N. J. 2023; 24 (5)
  • A Mineral-Doped Micromodel Platform Demonstrates Fungal Bridging of Carbon Hot Spots and Hyphal Transport of Mineral-Derived Nutrients. mSystems Bhattacharjee, A., Qafoku, O., Richardson, J. A., Anderson, L. N., Schwarz, K., Bramer, L. M., Lomas, G. X., Orton, D. J., Zhu, Z., Engelhard, M. H., Bowden, M. E., Nelson, W. C., Jumpponen, A., Jansson, J. K., Hofmockel, K. S., Anderton, C. R. 2022: e0091322

    Abstract

    Soil fungi facilitate the translocation of inorganic nutrients from soil minerals to other microorganisms and plants. This ability is particularly advantageous in impoverished soils because fungal mycelial networks can bridge otherwise spatially disconnected and inaccessible nutrient hot spots. However, the molecular mechanisms underlying fungal mineral weathering and transport through soil remains poorly understood primarily due to the lack of a platform for spatially resolved analysis of biotic-driven mineral weathering. Here, we addressed this knowledge gap by demonstrating a mineral-doped soil micromodel platform where mineral weathering mechanisms can be studied. We directly visualize acquisition and transport of inorganic nutrients from minerals through fungal hyphae in the micromodel using a multimodal imaging approach. We found that Fusarium sp. strain DS 682, a representative of common saprotrophic soil fungus, exhibited a mechanosensory response (thigmotropism) around obstacles and through pore spaces (~12mum) in the presence of minerals. The fungus incorporated and translocated potassium (K) from K-rich mineral interfaces, as evidenced by visualization of mineral-derived nutrient transport and unique K chemical moieties following fungus-induced mineral weathering. Specific membrane transport proteins were expressed in the fungus in the presence of minerals, including those involved in oxidative phosphorylation pathways and the transmembrane transport of small-molecular-weight organic acids. This study establishes the significance of a spatial visualization platform for investigating microbial induced mineral weathering at microbially relevant scales. Moreover, we demonstrate the importance of fungal biology and nutrient translocation in maintaining fungal growth under water and carbon limitations in a reduced-complexity soil-like microenvironment. IMPORTANCE Fungal species are foundational members of soil microbiomes, where their contributions in accessing and transporting vital nutrients is key for community resilience. To date, the molecular mechanisms underlying fungal mineral weathering and nutrient translocation in low-nutrient environments remain poorly resolved due to the lack of a platform for spatial analysis of biotic weathering processes. Here, we addressed this knowledge gap by developing a mineral-doped soil micromodel platform. We demonstrate the function of this platform by directly probing fungal growth using spatially resolved optical and chemical imaging methodologies. We found the presence of minerals was required for fungal thigmotropism around obstacles and through soil-like pore spaces, and this was related to fungal transport of potassium (K) and corresponding K speciation from K-rich minerals. These findings provide new evidence and visualization into hyphal transport of mineral-derived nutrients under nutrient and water stresses.

    View details for DOI 10.1128/msystems.00913-22

    View details for PubMedID 36394319

  • Distribution of Mn Oxidation States in Grassland Soils and Their Relationships with Soil Pores ENVIRONMENTAL SCIENCE & TECHNOLOGY Kravchenko, A. N., Richardson, J. A., Lee, J., Guber, A. K. 2022; 56 (22): 16462-16472
  • Distribution of Mn Oxidation States in Grassland Soils and Their Relationships with Soil Pores. Environmental science & technology Kravchenko, A. N., Richardson, J. A., Lee, J. H., Guber, A. K. 2022

    Abstract

    Manganese (Mn) is known to be an active contributor to processing and cycling of soil organic carbon (C), yet the exact mechanisms behind its interactions with C are poorly understood. Plant diversity in terrestrial ecosystems drives feedback links between plant C inputs and soil pores, where the latter, in turn, impact the redox environment and Mn. This study examined associations between soil pores (>36 mum O) and Mn within intact soils from two grassland ecosystems, after their >6-year implementation in a replicated field experiment. We used mu-XRF imaging and XANES spectroscopy to explore spatial distribution patterns of Mn oxidation states, combined with X-ray computed microtomography and 2D zymography. A high plant diversity system (restored prairie) increased soil C and modified spatial distribution patterns of soil pores as compared to a single species system (monoculture switchgrass). In switchgrass, the abundance of oxidized and reduced Mn oxidation states varied with distance from pores consistently with anticipated O2 diffusion, while in the soil from restored prairie, the spatial patterns suggested that biological activity played a greater role in influencing Mn distributions. Based on the findings, we propose a hypothesis that Mn transformations promote C gains in soils of high plant diversity grasslands.

    View details for DOI 10.1021/acs.est.2c05403

    View details for PubMedID 36268932

  • Characterization and Geological Implications of Precambrian Calcite-Hosted Phosphate GEOPHYSICAL RESEARCH LETTERS Richardson, J. A., Roest-Ellis, S., Phillips, B. L., Strauss, J., Webb, S. M., Tosca, N. J. 2022; 49 (17)
  • The source of sulfate in brachiopod calcite: Insights from mu-XRF imaging and XANES spectroscopy CHEMICAL GEOLOGY Richardson, J. A., Newville, M., Lanzirotti, A., Webb, S. M., Rose, C., Catalano, J. G., Fike, D. A. 2019; 529
  • Depositional and diagenetic constraints on the abundance and spatial variability of carbonate-associated sulfate CHEMICAL GEOLOGY Richardson, J. A., Newville, M., Lanzirotti, A., Webb, S. M., Rose, C., Catalano, J. G., Fike, D. A. 2019; 523: 59–72
  • Insights into past ocean proxies from micron-scale mapping of sulfur species in carbonates GEOLOGY Rose, C., Webb, S. M., Newville, M., Lanzirotti, A., Richardson, J. A., Tosca, N. J., Catalano, J. G., Bradley, A. S., Fike, D. A. 2019; 47 (9): 833–37

    View details for DOI 10.1130/G46228.1

    View details for Web of Science ID 000483606500011