Your search keyword '"Guber, Andrey"' showing total 5 results

1. Composition and metabolism of microbial communities in soil pores.

Author

Li, Zheng, Kravchenko, Alexandra N., Cupples, Alison, Guber, Andrey K., Kuzyakov, Yakov, Philip Robertson, G., and Blagodatskaya, Evgenia

Abstract

Delineation of microbial habitats within the soil matrix and characterization of their environments and metabolic processes are crucial to understand soil functioning, yet their experimental identification remains persistently limited. We combined single- and triple-energy X-ray computed microtomography with pore specific allocation of 13C labeled glucose and subsequent stable isotope probing to demonstrate how long-term disparities in vegetation history modify spatial distribution patterns of soil pore and particulate organic matter drivers of microbial habitats, and to probe bacterial communities populating such habitats. Here we show striking differences between large (30-150 µm Ø) and small (4-10 µm Ø) soil pores in (i) microbial diversity, composition, and life-strategies, (ii) responses to added substrate, (iii) metabolic pathways, and (iv) the processing and fate of labile C. We propose a microbial habitat classification concept based on biogeochemical mechanisms and localization of soil processes and also suggests interventions to mitigate the environmental consequences of agricultural management.The work proposes the concept of distinct micro-habitats within an intact soil matrix and describes composition and metabolic pathways of their bacterial inhabitants, as a first step towards a generalizable C processing-focused classification of soil micro-environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Amino mapping: possibility to visualize amino-N compounds in the rhizosphere of Zea Mays L.

Author

Khosrozadeh, Sajedeh, Guber, Andrey, Nourbakhsh, Farshid, Khalili, Banafshe, and Blagodatskaya, Evgenia

Subjects

*CORN, *RHIZOSPHERE, *SOIL classification, *DIGITAL cameras, *PLANT species

Abstract

Understanding N uptake by plants, the N cycle, and their relationship to soil heterogeneity has generated a great deal of interest in the distribution of amino-N compounds in soil. Visualization of the spatial distribution of amino-N in soil can provide insights into the role of labile N in plant-microbial mechanisms of N acquisition and plant N uptake, but until now, it has remained technically challenging. Here, we describe a novel technique to visualize the amino-N distribution at the root-soil interface. The technique is based on time-lapse amino mapping (TLAM) using membranes saturated with the fluorogenic OPAME reagent (O-phthalaldehyde and β-mercaptoethanol). OPAME in the membrane reacts with organic compounds containing a NH2 functional group at the membrane-soil interface, generating a fluorescent product visible under UV light and detectable by a digital camera. The TLAM amino-mapping technique was applied to visualize and quantify the concentration of amino-N compounds in the rhizosphere of maize (Zea Mays L.). A ten times greater amino-N concentration was detected in the rhizosphere compared to non-rhizosphere soil. The high content of amino-N was mainly associated with the root tips and was 3 times larger than the average amino-N content at seminal roots. The amino-N rhizosphere was 2 times broader around the root tips than around other parts of the roots. We concluded that TLAM is a promising approach for monitoring the fate of labile N in soils. However, the technique needs to be standardized for different soil types, plant species, and climate conditions to allow wider application. [ABSTRACT FROM AUTHOR]

Published

2023

3. Pore architecture and particulate organic matter in soils under monoculture switchgrass and restored prairie in contrasting topography.

Author

Juyal, Archana, Guber, Andrey, Oerther, Maxwell, Quigley, Michelle, and Kravchenko, Alexandra

Subjects

*SWITCHGRASS, *TOPOGRAPHY, *X-ray computed microtomography, *PRAIRIES, *CLIMATE change mitigation, *ORGANIC compounds, *SOIL topography

Abstract

Bioenergy cropping systems can substantially contribute to climate change mitigation. However, limited information is available on how they affect soil characteristics, including pores and particulate organic matter (POM), both essential components of the soil C cycle. The objective of this study was to determine effects of bioenergy systems and field topography on soil pore characteristics, POM, and POM decomposition under new plant growth. We collected intact soil cores from two systems: monoculture switchgrass (Panicum virgatum L.) and native prairie, at two contrasting topographical positions (depressions and slopes), planting half of the cores with switchgrass. Pore and POM characteristics were obtained using X-ray computed micro-tomography (μCT) (18.2 µm resolution) before and after new switchgrass growth. Diverse prairie vegetation led to higher soil C than switchgrass, with concomitantly higher volumes of 30–90 μm radius pores and greater solid-pore interface. Yet, that effect was present only in the coarse-textured soils on slopes and coincided with higher root biomass of prairie vegetation. Surprisingly, new switchgrass growth did not intensify decomposition of POM, but even somewhat decreased it in monoculture switchgrass as compared to non-planted controls. Our results suggest that topography can play a substantial role in regulating factors driving C sequestration in bioenergy systems. [ABSTRACT FROM AUTHOR]

Published

2021

4. Dynamics of N2O in vicinity of plant residues: a microsensor approach.

Author

Kim, Kyungmin, Kutlu, Turgut, Kravchenko, Alexandra, and Guber, Andrey

Subjects

PLANT residues, NITROUS oxide, CROP residues, SWITCHGRASS, PERFORMANCE technology, PLANT-soil relationships, MICROSENSORS

Abstract

Aims: Plant residues decomposing within the soil matrix are known to serve as hotspots of N2O production. However, the lack of technical tools for microscale in-situ N2O measurements limits understanding of hotspot functioning. Our aim was to assess performance of microsensor technology for evaluating the temporal patterns of N2O production in immediate vicinity to decomposing plant residues. Methods: We incorporated intact switchgrass leaves and roots into soil matrix and monitored O2 depletion and N2O production using electrochemical microsensors along with N2O emission from the soil. We also measured residue's water absorption and b-glucosidase activity on the surface of the residue - the characteristics related to microenvironmental conditions and biological activity near the residue. Results: N2O production in the vicinity of switchgrass residues began within 0–12 h after the wetting, reached peak at ~0.6 day and decreased by day 2. N2O was higher near leaf than near root residues due to greater leaf N contents and water absorption by the leaves. However, N2O production near the roots started sooner than near the leaves, in part due to high initial enzyme levels on root surfaces. Conclusion: Electrochemical microsensor is a useful tool for in-situ micro-scale N2O monitoring in immediate vicinity of soil incorporated plant residues. Monitoring provided valuable information on N2O production near leaves and roots, its temporal dynamic, and the factors affecting it. The N2O production from residues measured by microsensors was consistent with the N2O emission from the whole soil, demonstrating the validity of the microsensors for N2O hotspot studies. [ABSTRACT FROM AUTHOR]

Published

2021

5. Protection of soil carbon within macro-aggregates depends on intra-aggregate pore characteristics.

Author

Kravchenko, Alexandra N., Negassa, Wakene C., Guber, Andrey K., and Rivers, Mark L.

Subjects

SOIL protection, CARBON, HUMUS, ORGANIC compounds, ENVIRONMENTAL protection

Abstract

Soil contains almost twice as much carbon (C) as the atmosphere and 5-15% of soil C is stored in a form of particulate organic matter (POM). Particulate organic matter C is regarded as one of the most labile components of the soil C, such that can be easily lost under right environmental settings. Conceptually, micro-environmental conditions are understood to be responsible for protection of soil C. However, quantitative knowledge of the specific mechanisms driving micro-environmental effects is still lacking. Here we combined CO2 respiration measurements of intact soil samples with X-ray computed micro-tomography imaging and investigated how micro-environmental conditions, represented by soil pores, influence decomposition of POM. We found that atmosphere-connected soil pores influenced soil C's, and especially POM's, decomposition. In presence of such pores losses in POM were 3-15 times higher than in their absence. Moreover, we demonstrated the presence of a feed-forward relationship between soil C decomposition and pore connections that enhance it. Since soil hydrology and soil pores are likely to be affected by future climate changes, our findings indicate that not-accounting for the influence of soil pores can add another sizable source of uncertainty to estimates of future soil C losses. [ABSTRACT FROM AUTHOR]

Published

2015