Salinity affects microbial composition and function in artificially induced biocrusts: Implications for cyanobacterial inoculation in saline soils

Cyanobacterial inoculation is a promising technology that can induce biocrust development, for stabilizing degraded soils in dryland environments. However, it is challenging to grow cyanobacteria in dry, saline soils, which limits the application of this technology. In this study, NaCl was added into field-collected induced biocrusts to investigate how salt affects the biocrust community. This fundamental knowledge improves our assessment of microbial salinity preference and adaptation, and can guide researchers to select the appropriate cyanobacterial inoculants for saline soil restoration. The results showed that the biocrusts induced by inoculating Microcoleus vaginatus and Scytonema javanicum could survive 1.0% salinity, although both salt and drought stresses significantly inhibited microbial biomass and metabolism (P < 0.05), and salinity led to an obvious shift in microbial community structure. Compared to salt stress, drought seems to provide a vital ecological protection for the biocrusts, allowing them to be active only under relative low salinity after hydration. In the induced biocrusts, cyanobacteria were always the dominant organisms (even 18 years since inoculation), whereas under elevated salinity, cyanobacterial communities with lower relative abundance had a higher survival percentage of M. steenstrupii and Phormidium sp. Altogether, our results showed that both prokaryotic and eukaryotic communities have obvious salinity preference in the cyanobacteria-induced biocrusts. These results suggest that cyanobacterial inoculation strategies can be adapted in response to the soil salinity conditions. Furthermore, a combined inoculation of M. steenstrupii and Phormidium sp. appears to be favorable approach that is expected to improve cyanobacterial inoculation technology in saline soils.