Microbial community structure and function respond more strongly to temporal progression than to the application of slurry in an Irish grassland

Aaron Fox, Israel Ikoyi, Rachel Creamer, Gary Lanigan, Achim Schmalenberger

Research output: Contribution to journalArticlepeer-review

Abstract

The application of slurry to grassland for fertilization purposes is common practice, but its effect on the soil microbiota is mostly overlooked. This study investigated the short term response of the functionality and composition of the soil microbiome to slurry application. A 180 m2 field was divided into 36 plots. Slurry was splash-plate applied at a rate of 30 t ha−1. Sampling was conducted 5, 30 and 65 days after application. The functionality of the soil microbial community was examined using assays on 8 carbon cycling enzymes as well as basal respiration analysis. Microbial community structure was analysed via bacterial 16S rRNA gene and fungal internal transcribed spacer region terminal restriction fragment length polymorphism. Bacterial and fungal abundance was determined via quantitative PCR aiming at the same genetic targets. Furthermore, microbial biomass carbon and nitrogen were quantified. A significant increase in enzymatic activity with slurry treatment was reported on days 5 and 65, indicating a sequential response of the microbiota to slurry-derived carbon with the utilization of labile carbon on day 5 and the more stable carbon on day 65. This activity seemingly resulted from the microbial demand for N. In contrast, T-RFLP revealed that only bacterial community structures on day 5 were significantly affected by slurry application, all other bacterial and all fungal communities were not significantly altered by slurry. However, bacterial and fungal community structures, microbial biomass carbon and basal respiration significantly responded to temporal progression (day 5, 30 and 65). These findings suggest that soil microbial communities are responding to slurry applications via enhanced microbial activity but their structure remains largely unchanged with temporal progression having a greater impact.

Original languageEnglish
Pages (from-to)97-104
Number of pages8
JournalApplied Soil Ecology
Volume120
DOIs
Publication statusPublished - Nov 2017

Keywords

  • Bacteria
  • Carbon
  • Fungi
  • qPCR
  • Soil enzymatic activity
  • T-RFLP

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