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Effect of biodegradable poly-3-hydroxybutyrate amendment on the soil biochemical properties and fertility under varying sand loads

Chemical and Biological Technologies in Agriculture 2022 22 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 50 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Jakub Fojt, Jakub Fojt, Martin Brtnický Jakub Fojt, Martin Brtnický Jakub Fojt, Jiří Holátko, Jiří Holátko, Václav Pecina, Martin Brtnický Jiří Kučerík, Tereza Hammerschmiedt, Martin Brtnický Martin Brtnický Jiří Holátko, Jiří Kučerík, Jiří Holátko, Jiří Kučerík, Martin Brtnický Jiří Holátko, Jiří Kučerík, Jiří Kučerík, Tereza Hammerschmiedt, Jiří Holátko, Jiří Kučerík, Martin Brtnický Jiří Kučerík, Jiří Kučerík, Jiří Kučerík, Tereza Hammerschmiedt, Adnan Mustafa, Václav Pecina, Tivadar Baltazár, Antonín Kintl, Jiří Kučerík, Václav Pecina, Jiří Kučerík, Jakub Fojt, Jiří Kučerík, Adnan Mustafa, Jiří Kučerík, Jiří Kučerík, Jiří Kučerík, Antonín Kintl, Jakub Fojt, Jiří Kučerík, Antonín Kintl, Tivadar Baltazár, Martin Brtnický Václav Pecina, Jiří Kučerík, Jiří Kučerík, Jiří Kučerík, Jiří Kučerík, Martin Brtnický Martin Brtnický

Summary

Researchers added a biodegradable bacterial plastic called poly-3-hydroxybutyrate (P3HB) to nutrient-poor soils and found that while it boosted microbial activity, it significantly stunted lettuce growth by diverting nitrogen away from plants. This suggests that using P3HB as a soil amendment has unintended consequences — microbes consume it as a carbon source, depleting the nutrients that crops need to grow.

Abstract Background Poly-3-hydroxybutyrate (P3HB) is a bacterial intracellular carbon and energy storage polymer, used as a thermoplastic polyester in a wide array of industrial and agricultural applications. However, how the soil microbiome and fertility are altered by exogenously applied P3HB has been relatively unexplored. This study aimed to assess the effects of P3HB addition to nutrient restricted soil: its biological properties and lettuce ( Lactuca sativa L. var. capitata L.) biomass production. The experiment was designed to evaluate impacts of spatial arrangement of the relatively organic-rich (soil organic matter, P3HB particles) versus poor fractions of the matrix with confounding factors such as variable microbial biomass, inherent nutrient/energy status, different water relations (due to variable hydrophysical properties of soil augmented by sand at different ratios). Results The results revealed that P3HB in soils induced inconsistent to contradictory changes in the microbial abundance as well as in most enzymatic activities. The differences were conditioned by the sand content both under P3HB presence or absence. On the other hand, dehydrogenase, urease activities, basal and substrate-induced soil respirations were mostly enhanced by P3HB addition, directly with increasing sand content (several respiration types). Nevertheless, P3HB significantly inhibited lettuce biomass production. Conclusions P3HB introduction to soil boosts the microbial activity owing to the preferential utilization of P3HB as C source, which depletes soil N and strongly inhibits the plant growth. Enhanced microbial activity in P3HB-amended soils with high sand content (60–80%) suggested that in nutrient-impoverished soil P3HB can temporarily replace SOM as a C source for microbial communities due to the shift of their structure to preferentially P3HB-degrading microbiome. Graphical Abstract

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