Are basidiomycete laccase gene abundance and composition related to reduced lignolytic activity under elevated atmospheric NO3 − deposition in a northern hardwood forest?

• John E. Hassett ^[1] ; Donald R. Zak ^[1] ; Christopher B. Blackwood ^[2] ; Kurt S. Pregitzer ^[3]
  1. [1] University of Michigan–Ann Arbor

     University of Michigan–Ann Arbor

     City of Ann Arbor, Estados Unidos

     
  2. [2] Kent State University

     Kent State University

     City of Kent, Estados Unidos

     
  3. [3] University of Nevada, Estados Unidos

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• Localización: Microbial ecology, ISSN-e 1432-184X, ISSN 0095-3628, Vol. 57, Nº. 4, 2009, págs. 728-739
• Idioma: inglés
• Texto completo no disponible (Saber más ...)
• Resumen

  • Anthropogenic release of biologically available N has increased atmospheric N deposition in forest ecosystems, which may slow decomposition by reducing the lignolytic activity of white-rot fungi. We investigated the potential for atmospheric N deposition to reduce the abundance and alter the composition of lignolytic basidiomycetes in a regional network of four northern hardwood forest stands receiving experimental NO3 − deposition (30 kg NO3 −−N ha−1 year−1) for a decade. To estimate the abundance of basidiomycetes with lignolytic potential, we used PCR primers targeting laccase (polyphenol oxidase) and quantitative fluorescence PCR to estimate gene copy number. Natural variation in laccase gene size permitted use of length heterogeneity PCR to profile basidiomycete community composition across two sampling dates in forest floor and mineral soil. Although past work has identified significant and consistent negative effects of NO3 − deposition on lignolytic enzyme activity, microbial biomass, soil respiration, and decomposition rate, we found no consistent effect of NO3 − deposition on basidiomycete laccase gene abundance or community profile. Rather, laccase abundance under NO3 − deposition was lower (−52%), higher (+223%), or unchanged, depending on stand. Only a single stand exhibited a significant change in basidiomycete laccase gene profile. Basidiomycete laccase genes occurring in mineral soil were a subset of the genes observed in the forest floor. Moreover, significant effects on laccase abundance were confined to the forest floor, suggesting that species composition plays some role in determining how lignolytic basidiomycetes are affected by N deposition. Community profiles differed between July and October sampling dates, and basidiomycete communities sampled in October had lower laccase gene abundance in the forest floor, but higher laccase abundance in mineral soil. Although experimental N deposition significantly suppresses lignolytic activity in these forests, this change is not related to the abundance or community composition of basidiomycete fungi with laccase genes. Understanding the expression of laccases and other lignolytic enzymes by basidiomycete fungi and other lignin-decaying organisms appears to hold promise for explaining the consistent decline in lignolytic activity elicited by experimental N deposition.