AUTHOR=Kim Nakian , Riggins Chance W. , Zabaloy María C. , Rodriguez-Zas Sandra L. , Villamil María B. 

TITLE=Limited Impacts of Cover Cropping on Soil N-Cycling Microbial Communities of Long-Term Corn Monocultures

JOURNAL=Frontiers in Microbiology

VOLUME=13

YEAR=2022

URL=https://www.frontiersin.org/journals/microbiology/articles/10.3389/fmicb.2022.926592

DOI=10.3389/fmicb.2022.926592

ISSN=1664-302X

ABSTRACT=<p>Cover cropping (CC) is a promising in-field practice to mitigate soil health degradation and nitrogen (N) losses from excessive N fertilization. Soil N-cycling microbial communities are the fundamental drivers of these processes, but how they respond to CC under field conditions is poorly documented for typical agricultural systems. Our objective was to investigate this relationship for a long-term (36 years) corn [<italic>Zea mays</italic> L.] monocultures under three N fertilizer rates (N0, N202, and N269; kg N/ha), where a mixture of cereal rye [<italic>Secale cereale</italic> L.] and hairy vetch [<italic>Vicia villosa</italic> Roth.] was introduced for two consecutive years, using winter fallows as controls (BF). A 3 × 2 split-plot arrangement of N rates and CC treatments in a randomized complete block design with three replications was deployed. Soil chemical and physical properties and potential nitrification (PNR) and denitrification (PDR) rates were measured along with functional genes, including <italic>nifH</italic>, archaeal and bacterial <italic>amoA</italic>, <italic>nirK</italic>, <italic>nirS</italic>, and <italic>nosZ-I</italic>, sequenced in Illumina MiSeq system and quantified in high-throughput quantitative polymerase chain reaction (qPCR). The abundances of <italic>nifH</italic>, archaeal <italic>amoA</italic>, and <italic>nirS</italic> decreased with N fertilization (by 7.9, 4.8, and 38.9 times, respectively), and correlated positively with soil pH. Bacterial <italic>amoA</italic> increased by 2.4 times with CC within N269 and correlated positively with soil nitrate. CC increased the abundance of <italic>nirK</italic> by 1.5 times when fertilized. For both bacterial <italic>amoA</italic> and <italic>nirK</italic>, N202 and N269 did not differ from N0 within BF. Treatments had no significant effects on <italic>nosZ-I</italic>. The reported changes did not translate into differences in functionality as PNR and PDR did not respond to treatments. These results suggested that N fertilization disrupts the soil N-cycling communities of this system primarily through soil acidification and high nutrient availability. Two years of CC may not be enough to change the N-cycling communities that adapted to decades of disruption from N fertilization in corn monoculture. This is valuable primary information to understand the potentials and limitations of CC when introduced into long-term agricultural systems.</p>