Your search keyword '"Sneha P. Couvillion"' showing total 17 results

1. Fungal organic acid uptake of mineral-derived K is dependent on distance from carbon hotspot

Author

Arunima Bhattacharjee, Dusan Velickovic, Jocelyn A. Richardson, Sneha P. Couvillion, Gregory W. Vandergrift, Odeta Qafoku, Michael J. Taylor, Janet K. Jansson, Kirsten Hofmockel, and Christopher R. Anderton

Subjects

fungi, microbe-mineral interactions, weathering, organic acid, micromodels, Microbiology, QR1-502

Abstract

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.

Published

2023

2. Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry

Author

Katherine I. Naasko, Daniel Naylor, Emily B. Graham, Sneha P. Couvillion, Robert Danczak, Nikola Tolic, Carrie Nicora, Steven Fransen, Haiying Tao, Kirsten S. Hofmockel, and Janet K. Jansson

Subjects

soil depth, multi-omics, calcareous soil, carbon storage, metaphenome, soil microbiome, Microbiology, QR1-502

Abstract

ABSTRACT Climate change is causing an increase in drought in many soil ecosystems and a loss of soil organic carbon. Calcareous soils may partially mitigate these losses via carbon capture and storage. Here, we aimed to determine how irrigation-supplied soil moisture and perennial plants impact biotic and abiotic soil properties that underpin deep soil carbon chemistry in an unfertilized calcareous soil. Soil was sampled up to 1 m in depth from irrigated and planted field treatments and was analyzed using a suite of omics and chemical analyses. The soil microbial community composition was impacted more by irrigation and plant cover treatments than by soil depth. By contrast, metabolomes, lipidomes, and proteomes differed more with soil depth than treatments. Deep soil (>50 cm) had higher soil pH and calcium concentrations and higher levels of organic acids, bicarbonate, and triacylglycerides. By contrast, surface soil (0–5 cm) had higher concentrations of soil organic matter, organic carbon, oxidizable carbon, and total nitrogen. Surface soils also had higher amounts of sugars, sugar alcohols, phosphocholines, and proteins that reflect osmotic and oxidative stress responses. The lipidome was more responsive to perennial tall wheatgrass treatments compared to the metabolome or proteome, with a striking change in diacylglyceride composition. Permanganate oxidizable carbon was more consistently correlated to metabolites and proteins than soil organic and inorganic carbon and soil organic matter. This study reveals specific compounds that reflect differences in organic, inorganic, and oxidizable soil carbon fractions that are impacted by interactions between irrigation-supplied moisture and plant cover in calcareous soil profiles. IMPORTANCE Carbon is cycled through the air, plants, and belowground environment. Understanding soil carbon cycling in deep soil profiles will be important to mitigate climate change. Soil carbon cycling is impacted by water, plants, and soil microorganisms, in addition to soil mineralogy. Measuring biotic and abiotic soil properties provides a perspective of how soil microorganisms interact with the surrounding chemical environment. This study emphasizes the importance of considering biotic interactions with inorganic and oxidizable soil carbon in addition to total organic carbon in carbonate-containing soils for better informing soil carbon management decisions.

Published

2023

3. Interrogating the role of the milk microbiome in mastitis in the multi-omics era

Author

Sneha P. Couvillion, Katie E. Mostoller, Janet E. Williams, Ryan M. Pace, Izabel L. Stohel, Haley K. Peterson, Carrie D. Nicora, Ernesto S. Nakayasu, Bobbie-Jo M. Webb-Robertson, Mark A. McGuire, Michelle K. McGuire, and Thomas O. Metz

Subjects

milk, multi-omics, mastitis, metagenomics, metatranscriptomics, metaproteomics, Microbiology, QR1-502

Abstract

There is growing interest in a functional understanding of milk-associated microbiota as there is ample evidence that host-associated microbial communities play an active role in host health and phenotype. Mastitis, characterized by painful inflammation of the mammary gland, is prevalent among lactating humans and agricultural animals and is associated with significant clinical and economic consequences. The etiology of mastitis is complex and polymicrobial and correlative studies have indicated alterations in milk microbial community composition. Recent evidence is beginning to suggest that a causal relationship may exist between the milk microbiota and host phenotype in mastitis. Multi-omic approaches can be leveraged to gain a mechanistic, molecular level understanding of how the milk microbiome might modulate host physiology, thereby informing strategies to prevent and ameliorate mastitis. In this paper, we review existing studies that have utilized omics approaches to investigate the role of the milk microbiome in mastitis. We also summarize the strengths and challenges associated with the different omics techniques including metagenomics, metatranscriptomics, metaproteomics, metabolomics and lipidomics and provide perspective on the integration of multiple omics technologies for a better functional understanding of the milk microbiome.

Published

2023

4. A Histoplasma capsulatum Lipid Metabolic Map Identifies Antifungal Targets

Author

Daniel Zamith-Miranda, Heino M. Heyman, Meagan C. Burnet, Sneha P. Couvillion, Xueyun Zheng, Nathalie Munoz, William C. Nelson, Jennifer E. Kyle, Erika M. Zink, Karl K. Weitz, Kent J. Bloodsworth, Geremy Clair, Jeremy D. Zucker, Jeremy R. Teuton, Samuel H. Payne, Young-Mo Kim, Morayma Reyes Gil, Erin S. Baker, Erin L. Bredeweg, Joshua D. Nosanchuk, and Ernesto S. Nakayasu

Subjects

Histoplasma capsulatum, drug targets, lipid metabolism, lipidomics, metabolic map, proteomics, Microbiology, QR1-502

Abstract

ABSTRACT Lipids play a fundamental role in fungal cell biology, being essential cell membrane components and major targets of antifungal drugs. A deeper knowledge of lipid metabolism is key for developing new drugs and a better understanding of fungal pathogenesis. Here, we built a comprehensive map of the Histoplasma capsulatum lipid metabolic pathway by incorporating proteomic and lipidomic analyses. We performed genetic complementation and overexpression of H. capsulatum genes in Saccharomyces cerevisiae to validate reactions identified in the map and to determine enzymes responsible for catalyzing orphan reactions. The map led to the identification of both the fatty acid desaturation and the sphingolipid biosynthesis pathways as targets for drug development. We found that the sphingolipid biosynthesis inhibitor myriocin, the fatty acid desaturase inhibitor thiocarlide, and the fatty acid analog 10-thiastearic acid inhibit H. capsulatum growth in nanomolar to low-micromolar concentrations. These compounds also reduced the intracellular infection in an alveolar macrophage cell line. Overall, this lipid metabolic map revealed pathways that can be targeted for drug development. IMPORTANCE It is estimated that 150 people die per hour due to the insufficient therapeutic treatments to combat fungal infections. A major hurdle to developing antifungal therapies is the scarce knowledge on the fungal metabolic pathways and mechanisms of virulence. In this context, fungal lipid metabolism is an excellent candidate for developing drugs due to its essential roles in cellular scaffolds, energy storage, and signaling transductors. Here, we provide a detailed map of Histoplasma capsulatum lipid metabolism. The map revealed points of this fungus lipid metabolism that can be targeted for developing antifungal drugs.

Published

2021

5. Comparative Molecular and Immunoregulatory Analysis of Extracellular Vesicles from Candida albicans and Candida auris

Author

Daniel Zamith-Miranda, Heino M. Heyman, Sneha P. Couvillion, Radames J. B. Cordero, Marcio L. Rodrigues, Leonardo Nimrichter, Arturo Casadevall, Rafaela F. Amatuzzi, Lysangela R. Alves, Ernesto S. Nakayasu, and Joshua D. Nosanchuk

Subjects

Candida auris, Candida albicans, extracellular vesicles, multi-omics, fungal pathogenesis, candidiasis, Microbiology, QR1-502

Abstract

ABSTRACT Candida auris is a recently described multidrug-resistant pathogenic fungus that is increasingly responsible for health care-associated outbreaks across the world. Bloodstream infections of this fungus cause death in up to 70% of cases. Aggravating this scenario, the disease-promoting mechanisms of C. auris are poorly understood. Fungi release extracellular vesicles (EVs) that carry a broad range of molecules, including proteins, lipids, carbohydrates, pigments, and RNA, many of which are virulence factors. Here, we carried out a comparative molecular characterization of C. auris and Candida albicans EVs and evaluated their capacity to modulate effector mechanisms of host immune defense. Using proteomics, lipidomics, and transcriptomics, we found that C. auris released EVs with payloads that were significantly different from those of EVs released by C. albicans. EVs released by C. auris potentiated the adhesion of this yeast to an epithelial cell monolayer, while EVs from C. albicans had no effect. C. albicans EVs primed macrophages for enhanced intracellular yeast killing, whereas C. auris EVs promoted survival of the fungal cells. Moreover, EVs from both C. auris and C. albicans induced the activation of bone marrow-derived dendritic cells. Together, our findings show distinct profiles and properties of EVs released by C. auris and by C. albicans and highlight the potential contribution of C. auris EVs to the pathogenesis of this emerging pathogen. IMPORTANCE Candida auris is a recently described multidrug-resistant pathogenic fungus that is responsible for outbreaks across the globe, particularly in the context of nosocomial infections. Its virulence factors and pathogenesis are poorly understood. Here, we tested the hypothesis that extracellular vesicles (EVs) released by C. auris are a disease-promoting factor. We describe the production of EVs by C. auris and compare their biological activities against those of the better-characterized EVs from C. albicans. C. auris EVs have immunoregulatory properties, of which some are opposite those of C. albicans EVs. We also explored the cargo and structural components of those vesicles and found that they are remarkably distinct compared to EVs from C. auris’s phylogenetic relative Candida albicans.

Published

2021

6. MetFish: a Metabolomics Pipeline for Studying Microbial Communities in Chemically Extreme Environments

Author

Chengdong Xu, Sneha P. Couvillion, Ryan L. Sontag, Nancy G. Isern, Yukari Maezato, Stephen R. Lindemann, Taniya Roy Chowdhury, Rui Zhao, Beau R. Morton, Rosalie K. Chu, Ronald J. Moore, Janet K. Jansson, Vanessa L. Bailey, Paula J. Mouser, Margaret F. Romine, James F. Fredrickson, and Thomas O. Metz

Subjects

Microbiology, QR1-502

Abstract

The identification and accurate quantification of metabolites using electrospray ionization-mass spectrometry (ESI-MS) in hypersaline samples is a challenge due to matrix effects. Clean-up and desalting strategies that typically work well for samples with lower salt concentrations are often ineffective in hypersaline samples.

Published

2021

7. Who Is Metabolizing What? Discovering Novel Biomolecules in the Microbiome and the Organisms Who Make Them

Author

Sneha P. Couvillion, Neha Agrawal, Sean M. Colby, Kristoffer R. Brandvold, and Thomas O. Metz

Subjects

microbiome, function, standards-free metabolomics, ABPP, human health, Microbiology, QR1-502

Abstract

Even as the field of microbiome research has made huge strides in mapping microbial community composition in a variety of environments and organisms, explaining the phenotypic influences on the host by microbial taxa—both known and unknown—and their specific functions still remain major challenges. A pressing need is the ability to assign specific functions in terms of enzymes and small molecules to specific taxa or groups of taxa in the community. This knowledge will be crucial for advancing personalized therapies based on the targeted modulation of microbes or metabolites that have predictable outcomes to benefit the human host. This perspective article advocates for the combined use of standards-free metabolomics and activity-based protein profiling strategies to address this gap in functional knowledge in microbiome research via the identification of novel biomolecules and the attribution of their production to specific microbial taxa.

Published

2020

8. Multi-omics Signature of Candida auris, an Emerging and Multidrug-Resistant Pathogen

Author

Daniel Zamith-Miranda, Heino M. Heyman, Levi G. Cleare, Sneha P. Couvillion, Geremy C. Clair, Erin L. Bredeweg, Attila Gacser, Leonardo Nimrichter, Ernesto S. Nakayasu, and Joshua D. Nosanchuk

Subjects

Candida auris, antifungal resistance, fluconazole, multi-omics, Microbiology, QR1-502

Abstract

ABSTRACT Candida auris is a recently described pathogenic fungus that is causing invasive outbreaks on all continents. The fungus is of high concern given the numbers of multidrug-resistant strains that have been isolated in distinct sites across the globe. The fact that its diagnosis is still problematic suggests that the spreading of the pathogen remains underestimated. Notably, the molecular mechanisms of virulence and antifungal resistance employed by this new species are largely unknown. In the present work, we compared two clinical isolates of C. auris with distinct drug susceptibility profiles and a Candida albicans reference strain using a multi-omics approach. Our results show that, despite the distinct drug resistance profile, both C. auris isolates appear to be very similar, albeit with a few notable differences. However, compared to C. albicans both C. auris isolates have major differences regarding their carbon utilization and downstream lipid and protein content, suggesting a multifactorial mechanism of drug resistance. The molecular profile displayed by C. auris helps to explain the antifungal resistance and virulence phenotypes of this new emerging pathogen. IMPORTANCE Candida auris was first described in Japan in 2009 and has now been the cause of significant outbreaks across the globe. The high number of isolates that are resistant to one or more antifungals, as well as the high mortality rates from patients with bloodstream infections, has attracted the attention of the medical mycology, infectious disease, and public health communities to this pathogenic fungus. In the current work, we performed a broad multi-omics approach on two clinical isolates isolated in New York, the most affected area in the United States and found that the omic profile of C. auris differs significantly from C. albicans. In addition to our insights into C. auris carbon utilization and lipid and protein content, we believe that the availability of these data will enhance our ability to combat this rapidly emerging pathogenic yeast.

Published

2019

9. Rapid remodeling of the soil lipidome in response to a drying-rewetting event

Author

Sneha P. Couvillion, Robert E. Danczak, Dan Naylor, Montana L. Smith, Kelly G. Stratton, Vanessa L. Paurus, Kent J. Bloodsworth, Yuliya Farris, Darren J. Schmidt, Rachel E. Richardson, Lisa M. Bramer, Sarah J. Fansler, Ernesto S. Nakayasu, Jason E. McDermott, Thomas O. Metz, Mary S. Lipton, Janet K. Jansson, and Kirsten S. Hofmockel

Subjects

Microbiology (medical), Microbiology

Abstract

Background Microbiomes contribute to multiple ecosystem services by transforming organic matter in the soil. Extreme shifts in the environment, such as drying-rewetting cycles during drought, can impact the microbial metabolism of organic matter by altering microbial physiology and function. These physiological responses are mediated in part by lipids that are responsible for regulating interactions between cells and the environment. Despite this critical role in regulating the microbial response to stress, little is known about microbial lipids and metabolites in the soil or how they influence phenotypes that are expressed under drying-rewetting cycles. To address this knowledge gap, we conducted a soil incubation experiment to simulate soil drying during a summer drought of an arid grassland, then measured the response of the soil lipidome and metabolome during the first 3 h after wet-up. Results Reduced nutrient access during soil drying incurred a replacement of membrane phospholipids, resulting in a diminished abundance of multiple phosphorus-rich membrane lipids. The hot and dry conditions increased the prevalence of sphingolipids and lipids containing long-chain polyunsaturated fatty acids, both of which are associated with heat and osmotic stress-mitigating properties in fungi. This novel finding suggests that lipids commonly present in eukaryotes such as fungi may play a significant role in supporting community resilience displayed by arid land soil microbiomes during drought. As early as 10 min after rewetting dry soil, distinct changes were observed in several lipids that had bacterial signatures including a rapid increase in the abundance of glycerophospholipids with saturated and short fatty acid chains, prototypical of bacterial membrane lipids. Polar metabolites including disaccharides, nucleic acids, organic acids, inositols, and amino acids also increased in abundance upon rewetting. This rapid metabolic reactivation and growth after rewetting coincided with an increase in the relative abundance of firmicutes, suggesting that members of this phylum were positively impacted by rewetting. Conclusions Our study revealed specific changes in lipids and metabolites that are indicative of stress adaptation, substrate use, and cellular recovery during soil drying and subsequent rewetting. The drought-induced nutrient limitation was reflected in the lipidome and polar metabolome, both of which rapidly shifted (within hours) upon rewet. Reduced nutrient access in dry soil caused the replacement of glycerophospholipids with phosphorus-free lipids and impeded resource-expensive osmolyte accumulation. Elevated levels of ceramides and lipids with long-chain polyunsaturated fatty acids in dry soil suggest that lipids likely play an important role in the drought tolerance of microbial taxa capable of synthesizing these lipids. An increasing abundance of bacterial glycerophospholipids and triacylglycerols with fatty acids typical of bacteria and polar metabolites suggest a metabolic recovery in representative bacteria once the environmental conditions are conducive for growth. These results underscore the importance of the soil lipidome as a robust indicator of microbial community responses, especially at the short time scales of cell-environment reactions.

Published

2023

10. Comparative metabolomic analysis reveals shared and unique chemical interactions in sponge holobionts

Author

Shan Zhang, Weizhi Song, Louis-Félix Nothias, Sneha P. Couvillion, Nicole Webster, and Torsten Thomas

Subjects

Microbial ecology, Microbiology (medical), Sponge, Tandem Mass Spectrometry, Research, QR100-130, Antagonist, Metabolomics, Symbionts, Microbiology, Antioxidants, Chromatography, Liquid

Abstract

Background Sponges are ancient sessile metazoans, which form with their associated microbial symbionts a complex functional unit called a holobiont. Sponges are a rich source of chemical diversity; however, there is limited knowledge of which holobiont members produce certain metabolites and how they may contribute to chemical interactions. To address this issue, we applied non-targeted liquid chromatography tandem mass spectrometry (LC-MS/MS) and gas chromatography mass spectrometry (GC-MS) to either whole sponge tissue or fractionated microbial cells from six different, co-occurring sponge species. Results Several metabolites were commonly found or enriched in whole sponge tissue, supporting the notion that sponge cells produce them. These include 2-methylbutyryl-carnitine, hexanoyl-carnitine and various carbohydrates, which may be potential food sources for microorganisms, as well as the antagonistic compounds hymenialdisine and eicosatrienoic acid methyl ester. Metabolites that were mostly observed or enriched in microbial cells include the antioxidant didodecyl 3,3′-thiodipropionate, the antagonistic compounds docosatetraenoic acid, and immune-suppressor phenylethylamide. This suggests that these compounds are mainly produced by the microbial members in the sponge holobiont, and are potentially either involved in inter-microbial competitions or in defenses against intruding organisms. Conclusions This study shows how different chemical functionality is compartmentalized between sponge hosts and their microbial symbionts and provides new insights into how chemical interactions underpin the function of sponge holobionts.

Published

2022

11. A Histoplasma capsulatum Lipid Metabolic Map Identifies Antifungal Targets

Author

Jeremy Teuton, Daniel Zamith-Miranda, Morayma Reyes Gil, Joshua D. Nosanchuk, Jeremy Zucker, Karl K. Weitz, Samuel H. Payne, Meagan C. Burnet, Jennifer E. Kyle, Ernesto S. Nakayasu, Young-Mo Kim, William C. Nelson, Nathalie Munoz, Erika M. Zink, Sneha P. Couvillion, Geremy Clair, Erin S. Baker, Erin L. Bredeweg, Xueyun Zheng, Heino M. Heyman, and Kent J. Bloodsworth

Subjects

Proteomics, Histoplasma, Context (language use), Microbiology, Fungal Proteins, chemistry.chemical_compound, Virology, Myriocin, drug targets, Humans, Histoplasmosis, chemistry.chemical_classification, Sphingolipids, biology, Fatty Acids, Lipid metabolism, Lipid Metabolism, QR1-502, Histoplasma capsulatum, Metabolic pathway, Fatty acid desaturase, Enzyme, chemistry, Biochemistry, Fatty acid analog, Lipidomics, biology.protein, metabolic map, Research Article

Abstract

Lipids play a fundamental role in fungal cell biology, being essential cell membrane components and major targets of antifungal drugs. A deeper knowledge of lipid metabolism is key for developing new drugs and a better understanding of fungal pathogenesis. Here, we built a comprehensive map of the Histoplasma capsulatum lipid metabolic pathway by incorporating proteomic and lipidomic analyses. We performed genetic complementation and overexpression of H. capsulatum genes in Saccharomyces cerevisiae to validate reactions identified in the map and to determine enzymes responsible for catalyzing orphan reactions. The map led to the identification of both the fatty acid desaturation and the sphingolipid biosynthesis pathways as targets for drug development. We found that the sphingolipid biosynthesis inhibitor myriocin, the fatty acid desaturase inhibitor thiocarlide, and the fatty acid analog 10-thiastearic acid inhibit H. capsulatum growth in nanomolar to low-micromolar concentrations. These compounds also reduced the intracellular infection in an alveolar macrophage cell line. Overall, this lipid metabolic map revealed pathways that can be targeted for drug development. IMPORTANCE It is estimated that 150 people die per hour due to the insufficient therapeutic treatments to combat fungal infections. A major hurdle to developing antifungal therapies is the scarce knowledge on the fungal metabolic pathways and mechanisms of virulence. In this context, fungal lipid metabolism is an excellent candidate for developing drugs due to its essential roles in cellular scaffolds, energy storage, and signaling transductors. Here, we provide a detailed map of Histoplasma capsulatum lipid metabolism. The map revealed points of this fungus lipid metabolism that can be targeted for developing antifungal drugs.

Published

2021

12. Comparative Molecular and Immunoregulatory Analysis of Extracellular Vesicles from Candida albicans and Candida auris

Author

Rafaela F. Amatuzzi, Daniel Zamith-Miranda, Radames J. B. Cordero, Heino M. Heyman, Marcio L. Rodrigues, Joshua D. Nosanchuk, Leonardo Nimrichter, Lysangela R. Alves, Ernesto S. Nakayasu, Sneha P. Couvillion, and Arturo Casadevall

Subjects

Physiology, Virulence, Context (language use), Proteomics, Biochemistry, Microbiology, Transcriptome, Candida albicans, Genetics, Molecular Biology, Ecology, Evolution, Behavior and Systematics, biology, fungal pathogenesis, Effector, Pathogenic fungus, Candida auris, multi-omics, biology.organism_classification, candidiasis, Corpus albicans, QR1-502, Computer Science Applications, Modeling and Simulation, extracellular vesicles, Intracellular, Research Article

Abstract

Candida auris is a recently described multidrug-resistant pathogenic fungus that is increasingly responsible for health care-associated outbreaks across the world. Bloodstream infections of this fungus cause death in up to 70% of cases. Aggravating this scenario, the disease-promoting mechanisms of C. auris are poorly understood. Fungi release extracellular vesicles (EVs) that carry a broad range of molecules, including proteins, lipids, carbohydrates, pigments, and RNA, many of which are virulence factors. Here, we carried out a comparative molecular characterization of C. auris and Candida albicans EVs and evaluated their capacity to modulate effector mechanisms of host immune defense. Using proteomics, lipidomics, and transcriptomics, we found that C. auris released EVs with payloads that were significantly different from those of EVs released by C. albicans. EVs released by C. auris potentiated the adhesion of this yeast to an epithelial cell monolayer, while EVs from C. albicans had no effect. C. albicans EVs primed macrophages for enhanced intracellular yeast killing, whereas C. auris EVs promoted survival of the fungal cells. Moreover, EVs from both C. auris and C. albicans induced the activation of bone marrow-derived dendritic cells. Together, our findings show distinct profiles and properties of EVs released by C. auris and by C. albicans and highlight the potential contribution of C. auris EVs to the pathogenesis of this emerging pathogen. IMPORTANCECandida auris is a recently described multidrug-resistant pathogenic fungus that is responsible for outbreaks across the globe, particularly in the context of nosocomial infections. Its virulence factors and pathogenesis are poorly understood. Here, we tested the hypothesis that extracellular vesicles (EVs) released by C. auris are a disease-promoting factor. We describe the production of EVs by C. auris and compare their biological activities against those of the better-characterized EVs from C. albicans. C. auris EVs have immunoregulatory properties, of which some are opposite those of C. albicans EVs. We also explored the cargo and structural components of those vesicles and found that they are remarkably distinct compared to EVs from C. auris’s phylogenetic relative Candida albicans.

Published

2021

13. MetFish: a Metabolomics Pipeline for Studying Microbial Communities in Chemically Extreme Environments

Author

James F. Fredrickson, Margaret F. Romine, Janet K. Jansson, Vanessa L. Bailey, Rui Zhao, Stephen R. Lindemann, Paula J. Mouser, Thomas O. Metz, Sneha P. Couvillion, Ronald J. Moore, Taniya Roy Chowdhury, Chengdong Xu, Ryan L. Sontag, Beau R. Morton, Nancy G. Isern, Rosalie K. Chu, and Yukari Maezato

Subjects

Electrospray, Physiology, Carboxylic acid, microbial communities, Salt (chemistry), extreme environments, Mass spectrometry, Biochemistry, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Metabolomics, Genetics, Extreme environment, Derivatization, Molecular Biology, Ecology, Evolution, Behavior and Systematics, mass spectrometry, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Chromatography, 030306 microbiology, Extraction (chemistry), exometabolomics, hypersaline, 6. Clean water, QR1-502, Computer Science Applications, chemistry, Modeling and Simulation, Research Article

Abstract

Metabolites have essential roles in microbial communities, including as mediators of nutrient and energy exchange, cell-to-cell communication, and antibiosis. However, detecting and quantifying metabolites and other chemicals in samples having extremes in salt or mineral content using liquid chromatography-mass spectrometry (LC-MS)-based methods remains a significant challenge. Here, we report a facile method based on in situ chemical derivatization followed by extraction for analysis of metabolites and other chemicals in hypersaline samples, enabling for the first time direct LC-MS-based exometabolomics analysis in sample matrices containing up to 2 M total dissolved salts. The method, MetFish, is applicable to molecules containing amine, carboxylic acid, carbonyl, or hydroxyl functional groups, and it can be integrated into either targeted or untargeted analysis pipelines. In targeted analyses, MetFish provided limits of quantification as low as 1 nM, broad linear dynamic ranges (up to 5 to 6 orders of magnitude) with excellent linearity, and low median interday reproducibility (e.g., 2.6%). MetFish was successfully applied in targeted and untargeted exometabolomics analyses of microbial consortia, quantifying amino acid dynamics in the exometabolome during community succession; in situ in a native prairie soil, whose exometabolome was isolated using a hypersaline extraction; and in input and produced fluids from a hydraulically fractured well, identifying dramatic changes in the exometabolome over time in the well. IMPORTANCE The identification and accurate quantification of metabolites using electrospray ionization-mass spectrometry (ESI-MS) in hypersaline samples is a challenge due to matrix effects. Clean-up and desalting strategies that typically work well for samples with lower salt concentrations are often ineffective in hypersaline samples. To address this gap, we developed and demonstrated a simple yet sensitive and accurate method—MetFish—using chemical derivatization to enable mass spectrometry-based metabolomics in a variety of hypersaline samples from varied ecosystems and containing up to 2 M dissolved salts.

Published

2021

14. Who Is Metabolizing What? Discovering Novel Biomolecules in the Microbiome and the Organisms Who Make Them

Author

Sean M. Colby, Kristoffer R. Brandvold, Sneha P. Couvillion, Neha Agrawal, and Thomas O. Metz

Subjects

0301 basic medicine, Microbiology (medical), 030106 microbiology, Combined use, Immunology, lcsh:QR1-502, microbiome, Computational biology, Biology, human health, Microbiology, lcsh:Microbiology, 03 medical and health sciences, Human health, Metabolomics, Cellular and Infection Microbiology, Humans, Microbiome, ABPP, function, standards-free metabolomics, Microbiota, Protein profiling, 030104 developmental biology, Infectious Diseases, Perspective, Identification (biology), Function (biology)

Abstract

Even as the field of microbiome research has made huge strides in mapping microbial community composition in a variety of environments and organisms, explaining the phenotypic influences on the host by microbial taxa – both known and unknown – and their specific functions still remain major challenges. A pressing need is the ability to assign specific functions in terms of enzymes and small molecules to specific taxa or groups of taxa in the community. This knowledge will be crucial for advancing personalized therapies based on the targeted modulation of microbes or metabolites that have predictable outcomes to benefit the human host. This perspective article advocates for the combined use of standards-free metabolomics and activity-based protein profiling strategies to address this gap in functional knowledge in microbiome research via the identification of novel biomolecules and the attribution of their production to specific microbial taxa.

Published

2020

15. Media matters! Alterations in the loading and release of Histoplasma capsulatum extracellular vesicles in response to different nutritional milieus

Author

Daniel Zamith, Ernesto S. Nakayasu, Levi G. Cleare, Sneha P. Couvillion, Marcio L. Rodrigues, Leonardo Nimrichter, Heino M. Heyman, and Joshua D. Nosanchuk

Subjects

Immunology, Histoplasma, Virulence, chemical and pharmacologic phenomena, Biology, Proteomics, Microbiology, Histoplasma capsulatum, complex mixtures, Histoplasmosis, Article, Fungal Proteins, 03 medical and health sciences, Extracellular Vesicles, fluids and secretions, Virology, parasitic diseases, medicine, Secretion, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, 030306 microbiology, Nutrients, biology.organism_classification, medicine.disease, bacterial infections and mycoses, Culture Media, Enzyme, chemistry, Pneumonia (non-human), Dimorphic fungus

Abstract

Histoplasma capsulatum is a dimorphic fungus that most frequently causes pneumonia, but can also disseminate and proliferate in diverse tissues. Histoplasma capsulatum has a complex secretion system that mediates the release of macromolecule-degrading enzymes and virulence factors. The formation and release of extracellular vesicles (EVs) are an important mechanism for non-conventional secretion in both ascomycetes and basidiomycetes. Histoplasma capsulatum EVs contain diverse proteins associated with virulence and are immunologically active. Despite the growing knowledge of EVs from H. capsulatum and other pathogenic fungi, the extent that changes in the environment impact the sorting of organic molecules in EVs has not been investigated. In this study, we cultivated H. capsulatum with distinct culture media to investigate the potential plasticity in EV loading in response to differences in nutrition. Our findings reveal that nutrition plays an important role in EV loading and formation, which may translate into differences in biological activities of these fungi in various fluids and tissues.

Published

2019

16. Multi-omics Signature of Candida auris, an Emerging and Multidrug-Resistant Pathogen

Author

Levi G. Cleare, Ernesto S. Nakayasu, Attila Gácser, Erin L. Bredeweg, Sneha P. Couvillion, Leonardo Nimrichter, Joshua D. Nosanchuk, Daniel Zamith-Miranda, Geremy Clair, and Heino M. Heyman

Subjects

0301 basic medicine, Molecular Biology and Physiology, Physiology, 030106 microbiology, Virulence, Drug resistance, Biochemistry, Microbiology, Carbon utilization, 03 medical and health sciences, fluconazole, Genetics, Candida albicans, Molecular Biology, Pathogen, Ecology, Evolution, Behavior and Systematics, biology, Pathogenic fungus, Candida auris, antifungal resistance, multi-omics, biology.organism_classification, Corpus albicans, QR1-502, 3. Good health, Computer Science Applications, 030104 developmental biology, Modeling and Simulation, Research Article

Abstract

Candida auris was first described in Japan in 2009 and has now been the cause of significant outbreaks across the globe. The high number of isolates that are resistant to one or more antifungals, as well as the high mortality rates from patients with bloodstream infections, has attracted the attention of the medical mycology, infectious disease, and public health communities to this pathogenic fungus. In the current work, we performed a broad multi-omics approach on two clinical isolates isolated in New York, the most affected area in the United States and found that the omic profile of C. auris differs significantly from C. albicans. In addition to our insights into C. auris carbon utilization and lipid and protein content, we believe that the availability of these data will enhance our ability to combat this rapidly emerging pathogenic yeast., Candida auris is a recently described pathogenic fungus that is causing invasive outbreaks on all continents. The fungus is of high concern given the numbers of multidrug-resistant strains that have been isolated in distinct sites across the globe. The fact that its diagnosis is still problematic suggests that the spreading of the pathogen remains underestimated. Notably, the molecular mechanisms of virulence and antifungal resistance employed by this new species are largely unknown. In the present work, we compared two clinical isolates of C. auris with distinct drug susceptibility profiles and a Candida albicans reference strain using a multi-omics approach. Our results show that, despite the distinct drug resistance profile, both C. auris isolates appear to be very similar, albeit with a few notable differences. However, compared to C. albicans both C. auris isolates have major differences regarding their carbon utilization and downstream lipid and protein content, suggesting a multifactorial mechanism of drug resistance. The molecular profile displayed by C. auris helps to explain the antifungal resistance and virulence phenotypes of this new emerging pathogen. IMPORTANCE Candida auris was first described in Japan in 2009 and has now been the cause of significant outbreaks across the globe. The high number of isolates that are resistant to one or more antifungals, as well as the high mortality rates from patients with bloodstream infections, has attracted the attention of the medical mycology, infectious disease, and public health communities to this pathogenic fungus. In the current work, we performed a broad multi-omics approach on two clinical isolates isolated in New York, the most affected area in the United States and found that the omic profile of C. auris differs significantly from C. albicans. In addition to our insights into C. auris carbon utilization and lipid and protein content, we believe that the availability of these data will enhance our ability to combat this rapidly emerging pathogenic yeast.

Published

2019

17. Candida auris: multi-omics signature of an emerging and multidrug-resistant pathogen

Author

Attila Gácser, Leonardo Nimrichter, Geremy Clair, Levi G. Cleare, Heino M. Heyman, Joshua D. Nosanchuk, Daniel Zamith-Miranda, Ernesto S. Nakayasu, Erin L. Bredeweg, and Sneha P. Couvillion

Subjects

0303 health sciences, biology, 030306 microbiology, Virulence, Drug resistance, Pathogenic fungus, biology.organism_classification, Corpus albicans, 3. Good health, Carbon utilization, Microbiology, 03 medical and health sciences, Candida auris, Candida albicans, Pathogen, 030304 developmental biology

Abstract

Candida aurisis a recently described pathogenic fungus that is causing invasive outbreaks on all continents. The fungus is of high concern given the numbers of multidrug-resistant strains that have been isolated in distinct sites across the globe. The fact that its diagnosis is still problematic suggests that the spreading of the pathogen remains underestimated. Notably, the molecular mechanisms of virulence and antifungal resistance employed by this new species are largely unknown. In the present work, we compared two clinical isolates ofC. auriswith distinct drug susceptibility profiles and aCandida albicansreference strain using a multi-omics approach. Our results show that, despite the distinct drug-resistance profile, bothC. aurisstrains appear to be very similar, albeit with a few notable differences. However, when compared toC. albicansbothC. aurisstrains have major differences regarding their carbon utilization and downstream lipid and protein content, suggesting a multi-factorial mechanism of drug resistance. The molecular profile displayed byC. aurishelps to explain the antifungal resistance and virulence phenotypes of this new emerging pathogen.ImportanceCandida auriswas firstly described in Japan in 2009 and has now been the cause of significant outbreaks across the globe. The high number of isolates that are resistant to one or more antifungals, as well as the high mortality rates from patients with bloodstream infections, has caught the attention of the medical mycology, infectious disease and public health communities to this pathogenic fungus. In the current work, we performed a broad multi-omics approach on two clinical isolates isolated in New York, the most affected area in the USA and found that the omic profile ofC. aurisdiffers significantly fromC. albicans. Besides our insights intoC. auriscarbon utilization and lipid and protein content, we believe that the availability of these data will enhance our ability to combat this rapidly emerging pathogenic yeast.

Published

2019