Do Nitrogen and Phosphorus Additions Affect Nitrogen Fixation Associated with Tropical Mosses?

Overview

Journal Plants (Basel)

Date 2023 Apr 13

PMID 37050067

Authors

Lina Avila Clasen

Aya Permin

Aline B Horwath

Daniel B Metcalfe

Kathrin Rousk

Affiliations

Soon will be listed here.

Abstract

Tropical cloud forests are characterized by abundant and biodiverse mosses which grow epiphytically as well as on the ground. Nitrogen (N)-fixing cyanobacteria live in association with most mosses, and contribute greatly to the N pool via biological nitrogen fixation (BNF). However, the availability of nutrients, especially N and phosphorus (P), can influence BNF rates drastically. To evaluate the effects of increased N and P availability on BNF in mosses, we conducted a laboratory experiment where we added N and P, in isolation and combined, to three mosses ( sp., sp. and collected from a cloud forest in Peru. Our results show that N addition almost completely inhibited BNF within a day, whereas P addition caused variable results across moss species. Low N fixation rates were observed in sp. across the experiment. BNF in sp. was decreased by all nutrients, while P additions seemed to promote BNF in . Hence, each of the three mosses contributes distinctively to the ecosystem N pool depending on nutrient availability. Moreover, increased N input will likely significantly decrease BNF associated with mosses also in tropical cloud forests, thereby limiting N input to these ecosystems via the moss-cyanobacteria pathway.

Citing Articles

Rapid response of moss-associated nitrogen fixation to nutrient additions in tropical montane cloud forests with different successional stages.

Clasen L, Alvarenga D, Wang Y, Andersen R, Rousk K Biogeochemistry. 2025; 168(1):12.

PMID: 39764295 PMC: 11700064. DOI: 10.1007/s10533-024-01195-3.

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