La restauración de biocostras: una herramienta clave para recuperar la funcionalidad de los ecosistemas áridos degradados

Canton, Yolanda; Roncero Ramos, Beatriz; Román, JR; Rodriguez-Caballero, E; Chamizo, S

doi:10.7818/ECOS.2236

Article (Scientific journals)

La restauración de biocostras: una herramienta clave para recuperar la funcionalidad de los ecosistemas áridos degradados

Canton, Yolanda; Roncero Ramos, Beatriz; Román, JR et al.

2021 • In Ecosistemas, 30

Peer reviewed

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https://hdl.handle.net/2268/267995

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10.7818/ECOS.2236

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Abstract :

[en] Biocrusts are autotroph and heterotroph communities that cover 12% of the Earth land’s surface, where they act as ecosystem engineers. They are very vulnerable to climate change and disturbance caused by different anthropic activities. In this work, we revise the impacts of both disturbance types, which negatively affect biogeochemical cycles and water and energy balances, accelerate erosion processes and dust emissions, and decrease biodiversity, reducing ecosystem ability to provide services. We also explore the ability of these communities to recover after disturbance, which in general requires long time periods for the most developed communities. Because of this, new biotechnologies have emerged to accelerate their restoration, based on the inoculation of biocrust-forming organisms. Results from two main strategies according to the origin of the biocrust propagules used are revised: a) translocation of biocrust fragments from a donor area to the degraded area. This strategy is recommended for planned activities in which the existing biocrust before disturbance is applied; b) large-scale cultivation of biocrust-forming organisms (cyanobacteria, lichens, mosses or the whole community) in laboratory or greenhouse conditions for their later inoculation in the degraded area. Finally, we identify future challenges to maximize restoration success and biocrust conservation.

Disciplines :

Environmental sciences & ecology

Author, co-author :

Canton, Yolanda

Roncero Ramos, Beatriz ; Université de Liège - ULiège > Département des sciences de la vie > Centre d'ingénierie des protéines

Román, JR

Rodriguez-Caballero, E

Chamizo, S

Language :

English

Title :

La restauración de biocostras: una herramienta clave para recuperar la funcionalidad de los ecosistemas áridos degradados

Alternative titles :

[en] Biocrust restoration: a key tool to recover degraded arid ecosystem functioning

Publication date :

24 December 2021

Journal title :

Ecosistemas

eISSN :

1697-2473

Publisher :

Asociacion Espanola de Ecologia Terrestre, Spain

Volume :

Peer reviewed :

Peer reviewed

Available on ORBi :

since 08 February 2022

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Bibliography

Acea, M.J., Diz, N., Prieto-Fernández, A. 2001. Microbial populations in heated soils inoculated with cyanobacteria. Biology and Fertility of Soils 33:118-125.
Acea, M.J., Prieto-Fernández, A., Diz-Cid, N. 2003. Cyanobacterial inoculation of heated soils: Effect on microorganisms of C and N cycles and on chemical composition in soil surface. Soil Biology and Biochemistry 35:513-524.
Antoninka, A., Bowker, M.A., Reed, S.C., Doherty, K. 2016. Production of greenhouse-grown biocrust mosses and associated cyanobacteria to rehabilitate dryland soil function. Restoration Ecology 24:324-335.
Antoninka, A., Bowker, M.A., Chuckran, P., Barger, N.N., Reed, S., Belnap, J. 2018. Maximizing establishment and survivorship of field-collected and greenhouse-cultivated biocrusts in a semi-cold desert. Plant Soil 429:213-225.
Antoninka, A., Bowker, M.A., Barger, N.N., Belnap, J., GiraldoSilva, A., Reed, S.C., et al. 2020a. Addressing barriers to improve biocrust colonization and establishment in dryland restoration. Restoration Ecology 28:S150-S159.
Antoninka, A., Faist, A., Rodriguez-Caballero, E., Young, K.E., Bala Chaudhary, V., Condon, L.A., Pyke, D.A. 2020b. Biological soil crusts in ecological restoration: emerging research and perspectives. Restoration Ecology 28 S2:S3–S8.
Ballesteros, M., Ayerbe, J., Casares, M., Cañadas, E.M., Lorite, J. 2017. Successful lichen translocation on disturbed gypsum areas: A test with adhesives to promote the recovery of biological soil crusts. Scientific Reports 7: 45606.
Belnap, J. 1993. Recovery rates of cryptobiotic crusts: inoculant use and assessment methods. Great Basin Nat 53:89-95.
Belnap, J., Eldridge, D. 2003. Disturbance and recovery of biological soil crusts. En: Belnap, J., Lange, O.L.(eds), Biological Soil Crusts: Structure, Function, and Management, pp. 363-383. Springer, Berlin, Alemania.
Belnap, J., Lange O.L. 2003. Biological soil crusts: structure, function and management. Ecological Studies 150, Springer, Berlin, Alemania.
Belnap, J., Warren, S.D. 2002. Patton’s tracks in the Mojave Desert, USA: an ecological legacy. Arid Land Research and Management 16:245–258.
Beraldi-Campesi, H. 2013. Early life on land and the first terrestrial ecosystems. Ecological Processes 2(1): 1.
Bethany, J., Giraldo-Silva, A., Nelson, C., Barger, N.N., Garcia-Pichel, F. 2019. Optimizing the Production of Nursery-Based Biological Soil Crusts for Restoration of Arid Land Soils. Applied and Environmental Microbiology 18;85(15):e00735-19.
Blankenship, W.D., Condon, L.A., Pyke, D.A. 2020. Hydroseeding tackifiers and dryland moss restoration potential. Restoration Ecology 28:S127-S138.
Bowker, M.A. 2007. Biological soil crust rehabilitation in theory and practice. Restoration Ecology 15:13–23.
Bowker, M.A., Belnap, J., Davidson, D.W. 2010. Microclimate and propagule availability are equally important for rehabilitation of dryland N-fixing lichens. Restoration Ecology 18:30-33
Bowker, M.A., Antoninka, A.J., Chuckran, P.F. 2019. Improving field success of biocrust rehabilitation materials: hardening the organisms or softening the environment? Restoration Ecology 28:177-186.
Bu, C., Zhang, K., Zhang, C., Wu, S. 2015. Key Factors Influencing Rapid Development of Potentially Dune- Stabilizing Moss-Dominated Crusts. PLOS One 10:e0134447.
Bu, C., Li, R., Wang, C., Bowker, M.A. 2018. Successful field cultivation of moss biocrusts on disturbed soil surfaces in the short term. Plant Soil 429:227-240.
Cantón, Y., Chamizo, S., Rodriguez-Caballero, E., Lázaro, R., Roncero-Ramos, B., Román, J.R., Solé-Benet, A. 2020. Water Regulation in Cyanobacterial Biocrusts from Drylands: Negative Impacts of Anthropogenic Disturbance. Water 2020 12 (3):720.
Chamizo, S., Cantón, Y., Lázaro, R., Solé-Benet, A., Domingo, F. 2012. Crust composition and disturbance drive infiltration through biological soil crusts in semiarid ecosystems. Ecosystems 15:148-161.
Chamizo, S., Cantón, Y., Rodríguez-Caballero, E. Domingo, F. 2016. Biocrusts positively affect the soil water balance in semiarid ecosystems. Ecohydrology 9(7):1208–1221.
Chamizo, S., Rodríguez-Caballero, E., Román, J.R., Cantón, Y. 2017. Effects of biocrust on soil erosion and organic carbon losses under natural rainfall. Catena 148:117-125.
Chamizo, S., Mugnai, G., Rossi, F., Certini, G., De Philippis, R. 2018. Cyanobacteria inoculation improves soil stability and fertility on different textured soils: Gaining insights for applicability in soil restoration. Frontiers in Environmental Science 6:49.
Chen, L., Xie, Z., Hu, C., Li, D., Wang, G., Liu, Y. 2006. Man-made desert algal crusts as affected by environmental factors in Inner Mongolia, China. Journal of Arid Environments 67:521-527.
Chiquoine, L.P., Abella, S.R., Bowker, M.A. 2016. Rapidly restoring biological soil crusts and ecosystem functions in a severely disturbed desert ecosystem. Ecological Applications 26:1260-1272.
Concostrina-Zubiri, L., Huber-Sannwald, E., Martínez, I., Flores Flores, J.L., Escudero, A. 2013. Biological soil crusts greatly contribute to small-scale soil heterogeneity along a grazing gradient. Soil Biology and Biochemistry 64:28-36.
Condon, L.A., Pyke, D.A. 2016. Filling the interspace-restoring arid land mosses: source populations, organic matter, and overwintering govern success. Ecology and Evolution 6:7623-7632.
Cruz de Carvalho, R., dos Santos, P., Branquinho, C. 2018. Production of moss-dominated biocrusts to enhance the stability and function of the margins of artificial water bodies. Restoration Ecology 26:419-421.
Da Rosa, A.P.C., Fernandes Carvalho, L., Goldbeck, L., Vieira Costa, J.A. 2011. Carbon dioxide fixation by microalgae cultivated in open bioreactors. Energy Convers 52 (8–9):3071-3073.
Davidson, D.W., Bowker, M., George, D., Phillips, S.L., Belnap, J. 2002. Treatment effects on performance of N-fixing lichens in disturbed soil crusts of the Colorado Plateau. Ecological Applications 12:1391-1405
Dojani, S., Büdel, B., Deutschewitz, K., Weber, B. 2011. Rapid succession of biological soil crusts after experimental disturbance in the Succulent Karoo, South Africa. Applied Soil Ecology 48:263–269.
Doherty, K.D., Antoninka, A.J., Bowker, M.A., Ayuso, S.V., Johnson, N.C. 2015. A novel approach to cultivate biocrusts for restoration and experimentation. Ecological Restoration 33:13-16.
Doherty, K.D., Bowker, M.A., Antoninka, A.J., Johnson, N.C., Wood, T.E. 2018. Biocrust moss populations differ in growth rates, stress response, and microbial associates. Plant Soil 429:187-198.
Doherty, K.D., Grover, H.S., Bowker, M.A., Durham, R.A., Antoninka, A.J., Ramsey, P.W. 2020. Producing moss-colonized burlap fabric in a fog chamber for restoration of biocrust. Ecological Engineering 158:106019.
Elbert, W., Weber, B., Burrows, S., Steinkamp, J., Büdel, B., Andreae, M.O., Poschl, U. 2012. Contribution of cryptogamic covers to the global cycles of carbon and nitrogen. Nature Geoscience 5:459-462.
Eldridge, D.J., Reed, S., Travers, S.K., Bowker, M.A., Maestre, F.T., Ding, J., et al. 2020. The pervasive and multifaceted influence of biocrusts on water in the world’s drylands. Global Change Biology 26: 6003 – 6014.
Faist, A.M., Antoninka, A.J., Belnap, J., Bowker, M.A., Duniway, M.C., Garcia-Pichel, F., et al. 2020. Inoculation and habitat amelioration efforts in biological soil crust recovery vary by desert and soil texture. Restoration Ecology 28:S96-S105.
Fernandes, V.M.C., Machado de Lima, N.M., Roush, D., Rudgers, J., Collins, S.L., Garcia-Pichel, F. 2018. Exposure to predicted precipitation patterns decreases population size and alters community structure of cyanobacteria in biological soil crusts from the Chihuahuan Desert. Environmental Microbiology 20:259-269.
Ferrenberg, S., Reed, S.C., Belnap, J., Schlesinger, W.H. 2015. Climate change and physical disturbance cause similar community shifts in biological soil crusts. PNAS 112 (39):12116-12121.
Fick, S.E., Barger, N., Tatarko, J., Duniway, M.C. 2020. Induced biological soil crust controls on wind erodibility and dust (PM10) emissions. Earth Surf. Process. Landforms 45: 224-236.
García-Pichel, F., Castenholz, R.W. 1991. Characterization and biological implications of scytonemin, a cynobacterial sheath pigment. Journal of Phycology 27:395-409.
García-Pichel, F., Pringault, O. 2001. Cyanobacteria track water in desert soils. Nature 413 (6854): 380-381.
García-Pichel, F., Loza, V., Marusenko, Y., Mateo, P., Potrafka, R.M. 2013. Temperature drives the continental-scale distribution of key microbes in topsoil communities. Science 340:1574-1577.
Giraldo-Silva, A., Nelson, C., Barger, N.N., Garcia-Pichel, F. 2019. Nursing biocrusts: isolation, cultivation, and fitness test of indigenous cyanobacteria. Restoration Ecology 27(4):793–803.
Giraldo-Silva, A., Nelson, C., Penfold, C., Barger, N.N., Garcia-Pichel, F. 2020. Effect of preconditioning to the soil environment on the performance of 20 cyanobacterial strains used as inoculum for biocrust restoration. Restoration Ecology 28(S2):187–193.
Gunde-Cimerman, N., Plemenita, A., Oren, A. 2018. Strategies of adaptation of microorganisms of the three domains of life to high salt concentrations. FEMS Microbiology Reviews 42:353–375.
Guo, Y., Zhao, Y., Downing, A.J. 2020. Effect of storage time on the physiological characteristics and vegetative regeneration of desiccation-tolerant mosses on the Loess Plateau, China. Restoration Ecology 28:S203–S211.
Havrilla, C.A., Chaudhary, V.B., Ferrenberg, S., et al. 2019. Towards a predictive framework for biocrust mediation of plant performance: A meta-analysis. Journal of Ecology 107:2789– 2807.
Hu, C., Liu, Y., Song, L., Zhang, D. 2002. Effect of desert soil algae on the stabilization of fine sands. Journal of Applied Phycology 14:281-292.
Jain, S., Prajapat, G., Abrar, M., Ledwani, L., Singh, A., Agrawal, A. 2017. Cyanobacteria as efficient producers of mycosporine-like amino acids. Journal of Basic Microbiology 57:715-727.
Kidron, G.J. 2016. Goat trampling affects plant establishment, runoff and sediment yields over crusted dunes. Hydrological Processes 30: 2237-2246.
Kidron, G.J. 2019. The enigmatic absence of cyanobacterial biocrusts from the Namib fog belt: Do dew and fog hold the key?. Flora 257: 151416.
Kidron, G.J., Xiao, B., Benenson, I. 2020. Data variability or paradigm shift? Slow versus fast recovery of biological soil crusts-a review. Science of The Total Environment 721: 137683.
Kubeckova, K., Johansen, J.R., Warren, S.D., Sparks, R. 2003. Development of immobilized cyanobacterial amendments for reclamation of microbiotic soil crusts. Algological Studies 109:341–362.
Ladrón de Guevara M., Gonzalo, B., Raggio, J., Lafuente, A., Prieto, M., Maestre, F.T. 2018. Warming reduces the cover, richness and evenness of lichen-dominated biocrusts but promotes moss growth: insights from an 8 yr experiment. New Phytologist 220:811–823.
Lan, S., Zhang, Q., Wu, L., Liu, Y., Zhang, D., Hu, C. 2014. Artificially accelerating the reversal of desertification: Cyanobacterial inoculation facilitates the succession of vegetation communities. Environmental Science and Technology 48:307-315.
Lalley, J.S., Viles, H.A. 2008. Recovery of lichen-dominated soil crusts in a hyper-arid desert. Biodiversity and Conservation 17:1-20.
Li, X., Xiao, H., Zhang, J., Wang, X. 2004. Long-term ecosystem effects of sand-binding vegetation in the Tengger Desert, Northern China. Restoration Ecology 12:376–390.
Li, Z., Chen, C., Gao, Y., Wang, B., Wang, D., Du, Y., et al. 2021. Synergistic effect of cyanobacteria and nano-sand-stabilizer on biocrust formation and sand fixation. 9:104887
López-Rodríguez M.D., Chamizo, S, Cantón Y, Rodríguez-Caballero, E. 2020. Identifying social–ecological gaps to promote biocrust conservation actions. Web Ecology 20:117–132
Maestre, F.T., Bowker, M.A., Cantón, Y., Castillo-Monroy, A.P., Cortina, J., Escolar, C., et al. 2011. Ecology and functional roles of biological soil crusts in semi-arid ecosystems of Spain. 75 (12):1282-1291.
Maestre, F.T., Escolar, C., de Guevara, M.L., Quero, J.L., Lázaro, R., Delgado-Baquerizo, M., et al. 2013. Changes in biocrust cover drive carbon cycle responses to climate change in drylands. Global Change Biology 19:3835-3847.
Maestre, F.T., Eldridge, D.J., Soliveres, S., Kéfi, S., Delgado-Baquerizo, M., Bowker, M.A., et al. 2016. Structure and Functioning of Dryland Ecosystems in a Changing World. Annual Review of Ecology, Evolution, and Systematics 47:215-237.
Mallen-Cooper, M., Bowker, M.A., Antoninka, A. J., Eldridge, D. J. 2020. A practical guide to measuring functional indicators and traits in biocrusts. Restoration Ecology 28: S56-S66.
Mugnai, G., Rossi, F., Felde, V.J.M.N.L., Colesie, C., Büdel, B., Peth, S., Kaplan, A., De Philippis, R. 2018. Development of the polysaccharidic matrix in biocrusts induced by a cyanobacterium inoculated in sand microcosms. Biology and Fertility of Soils 54:27-40.
Muñoz-Rojas, M., Román, J.R., Roncero-Ramos, B., Erickson, T.E., Merritt, D.J., Aguila-Carricondo, P., Cantón, Y. 2018. Cyanobacteria inoculation enhances carbon sequestration in soil substrates used in dryland restoration. Science of the Total Environment 636:1149-1154.
Nelson, C., Giraldo-Silva, A., Garcia-Pichel, F. 2020. A fog-irrigated soil substrate system unifies and optimizes cyanobacterial biocrust inoculum production, applied and environmental microbiology. Applied and Environmental Microbiology 86(13): e00624-20.
Nelson, C., Giraldo-Silva, A., Garcia-Pichel, F. 2021. A symbiotic nutrient exchange within the cyanosphere microbiome of the biocrust cyanobacterium, Microcoleus vaginatus. SME Journal 15(1): 282-292.
Peng, C., Zheng, J., Huang, S., Li, S., Li, D., Cheng, M., Liu, Y. 2017. Application of sodium alginate in induced biological soil crusts: enhancing the sand stabilization in the early stage. Journal of Applied Phycology 29:1421–1428.
Pointing, S., Belnap, J. 2012. Microbial colonization and controls in dryland systems. Nature Reviews Microbiology 10:551–562.
Rajeev, L., da Rocha, U., Klitgord, N. et al. 2013. Dynamic cyanobacterial response to hydration and dehydration in a desert biological soil crust. The ISME Journal 7:2178-2191.
Read, C.F., Elith, J., Vesk, P.A. 2016. Testing a model of biological soil crust succession. Journal of vegetation science 27(1): 176-186.
Rodríguez-Caballero, E., Belnap, J., Büdel, B., Crutzen, P.J., Andreae, M.O., Pöschl, U., Weber, B. 2018a. Dryland photoautotrophic soil surface communities endangered by global change. Nature Geoscience 11(3):185–189.
Rodríguez-Caballero, E., Castro, A.J., Chamizo, S., Quintas-Soriano, C., Garcia-Llorente, M., Cantón, Y., Weber, B. 2018b. Ecosystem services provided by biocrusts: From ecosystem functions to social values. Journal of Arid Environments 159:45–53.
Rodríguez-Caballero, E., Chamizo, S., Roncero-Ramos, B., Román, R., Cantón, Y. 2018c. Runoff from biocrust: A vital resource for vegetation performance on Mediterranean steppes. Ecohydrology 11 (6):e1977.
Román, J.R., Roncero-Ramos, B., Chamizo, S., Rodríguez-Caballero, E., Cantón, Y. 2018. Restoring soil functions by means of cyanobacteria inoculation: Importance of soil conditions and species selection. Land Degradation and Development 29:3184-3193.
Román, J.R., Chilton, A.M., Cantón, Y., Muñoz-Rojas, M. 2020. Assessing the viability of cyanobacteria pellets for application in arid land restoration. Journal of Environmental Management 270:110795.
Román, JR; Chamizo, S; Roncero-Ramos, B; Adessi, A; De Philippis, R; Cantón, Y. 2021a. Overcoming field barriers to restore dryland soils by cyanobacteria inoculation. Soil and tillage research 207:104799.
Román, J.R., Roncero-Ramos, B., Rodríguez-Caballero, E., Chamizo, S., Cantón, Y. 2021b. Effect of water availability on induced cyanobacterial biocrust development. Catena 197:104988.
Roncero-Ramos, B., Muñoz-Martín, M.A., Chamizo, S., Fernández-Valbuena, L., Mendoza, D., Perona, E., et al. 2019a. Polyphasic evaluation of key cyanobacteria in biocrusts from the most arid region in Europe. PeerJ 7:e6169.
Roncero-Ramos, B., Román, J.R., Gómez-Serrano, C., Cantón, Y., Acién, F.G. 2019b. Production of a biocrust-cyanobacteria strain (Nostoc commune) for large-scale restoration of dryland soils. Journal of Applied Phycology. 31:2217-2230.
Roncero-Ramos, B., Román, J.R., Rodríguez-Caballero, E., Chamizo, S., Águila-Carricondo, P., Mateo, P., Cantón, Y. 2019c. Assessing the influence of soil abiotic and biotic factors on Nostoc commune inoculation success. Plant Soil 444:57-70.
Roncero-Ramos, B., Muñoz-Martín, M.A., Cantón, Y., Chamizo, S., Rodríguez-Caballero, E., Mateo, P. 2020. Land degradation effects on composition of pioneering soil communities: An alternative successional sequence for dryland cyanobacterial biocrusts. Soil Biology and Biochemistry 146:107824.
Rosentreter, R. 2020. Biocrust lichen and moss species most suitable for restoration projects. Restoration Ecology 28:S67-S74.
Rossi, F., De Philippis, R. 2015. Role of cyanobacterial exopolysaccharides in phototrophic biofilms and in complex microbial mats. Life 5:1218-1238.
Rossi, F., Li, H., Liu, Y., De Philippis, R. 2017. Cyanobacterial inoculation (cyanobacterisation): Perspectives for the development of a standardized multifunctional technology for soil fertilization and desertification reversal. Earth-Science Reviews 171:28-43.
Rutherford, W.A., Painter, T.H., Ferrenberg, S., Belnap, J., Okin, G.S., Flagg, C., Reed, S.C. 2017. Albedo feedbacks to future climate via climate change impacts on dryland biocrusts. 7:44188.
Sadeghi, S.H., Kheirfam, H., Homaee, M., Darki, B.Z., Vafakhah, M. 2017. Improving runoff behavior resulting from direct inoculation of soil microorganisms. Soil and Tillage Research 171:35-41.
Sadeghi, S.H., Satri, M.S., Kheirfam, H., Darki, B.Z. 2020. Controlling runoff generation and soil loss from field experimental plots through inoculating cyanobacteria. Journal of Hydrology 585:124814.
Slate, M.L., Durham, R.A., Pearson, D.E. 2020. Strategies for restoring the structure and function of lichen-moss biocrust communities. Restoration Ecology 28 (S2):S160-S167.
Tian, G., Bai, X., Xu, J., Wang, X. 2006. Experimental studies on the natural restoration and the artificial culture of the moss crusts on fixed dunes in the Tengger Desert, China. Frontiers of Biology in China 1:13-17.
Velasco-Ayuso, S.V., Giraldo Silva, A., Nelson, C., Barger, N.N., García-Pichel, F. 2017. Microbial Nursery Production of High-Quality Biological Soil Crust Biomass for Restoration of Degraded Dryland Soils. Applied Environmental Microbiology 83 (3):e02179-16.
Velasco-Ayuso, S., Giraldo-Silva, A., Barger, N.N., García-Pichel, F. 2020. Microbial inoculum production for biocrust restoration: testing the effects of a common substrate versus native soils on yield and community composition. Restoration Ecology 28(S2):194–202.
Wang, W.B., Liu, Y.D., Li, D.H., Hu, C.X., Rao, B.Q. 2009. Feasibility of cyanobacterial inoculation for biological soil crusts formation in desert area. Soil Biology and Biochemistry 41(5):926–929.
Weber, B., Büde,l B., Belnap, J. 2016. Biological Soil Crusts: An Organizing Principle in Drylands. Springer, Suiza.
Wu, Y., Rao, B., Wu, P., Liu, Y., Li, G., Li, D. 2013. Development of artificially induced biological soil crusts in fields and their effects on top soil. Plant Soil 370:115-124
Wu, L., Zhu, Q., Yang, L., Li, B., Hu, C., Lan, S. 2018. Nutrient transferring from wastewater to desert through artificial cultivation of desert cyanobacteria. 247:947-953.
Xiao, B., Zhao, Y., Wang, Q., Li, C. 2015. Development of artificial moss-dominated biological soil crusts and their effects on runoff and soil water content in a semi-arid environment. Journal of Arid Environments 117:75-83.
Xiao, B., Hu, K., Veste, M., Kidron, G.J. 2019. Natural recovery rates of moss biocrusts after severe disturbance in a semiarid climate of the Chinese loess plateau. 337:402–412.
Zaady, E., Arbel, S., Barkai, D., Sarig, S. 2013. Long-term impact of agricultural practices on biological soil crusts and their hydrological processes in a semiarid landscape. Journal of Arid Environments 90:5–11.
Zaady, E., Eldridge, D.J., Bowker, M.A. 2016. Effects of local-scale disturbance on biocrusts En: Weber, W., Büdel B., Belnap J. (eds.), Biological Soil Crusts: an Organizing Principle in Drylands, pp. 3-13. Ecological Studies 226, Springer, Suiza.
Zhao, Y., Wang, N., Zhang, Z., Pan, Y., Jia, R. 2019. Accelerating the development of artificial biocrusts using covers for restoration of degraded land in dryland ecosystems. Land Degradation and Development 32:285–295.
Zhou, X., Zhao, Y., Belnap, J., Zhang, B., Bu, C., Zhang, Y. 2020. Practices of biological soil crust rehabilitation in China: experiences and challenges. Restoration Ecology 28:S45–S55.
Antoninka, A., Bowker, M.A., Chuckran, P., Barger, N.N., Reed, S., Belnap, J. 2018. Maximizing establishment and survivorship of field-collected and greenhouse-cultivated biocrusts in a semi-cold desert. Plant Soil 429:213-225.
Antoninka, A., Bowker, M.A., Barger, N.N., Belnap, J., Giraldo-Silva, A., Reed, S.C., et al. 2020. Addressing barriers to improve biocrust colonization and establishment in dryland restoration. Restoration Ecology 28: S150-S159
Ballesteros, M., Ayerbe, J., Casares, M., Cañadas, E.M., Lorite, J. 2017. Successful lichen translocation on disturbed gypsum areas: A test with adhesives to promote the recovery of biological soil crusts. Scientific Reports 7: 45606.
Bowker, M.A., Belnap, J., Davidson, D.W. 2010. Microclimate and propagule availability are equally important for rehabilitation of dryland N-fixing lichens. Restoration Ecology 18:30-33.
Bowker, M.A., Antoninka, A.J., Chuckran, P.F. 2020. Improving field success of biocrust rehabilitation materials: hardening the organisms or softening the environment? Restoration Ecology 28: S177-S1869.
Bu, C., Li, R., Wang, C., Bowker, M.A. 2018. Successful field cultivation of moss biocrusts on disturbed soil surfaces in the short term. Plant Soil 429:227-240.
Chen, L., Xie, Z., Hu, C., Li, D., Wang, G., Liu, Y. 2006. Man-made desert algal crusts as affected by environmental factors in Inner Mongolia, China. Journal of Arid Environments 67:521-527.
Condon, L.A., Pyke, D.A. 2016. Filling the interspace-restoring arid land mosses: source populations, organic matter, and overwintering govern success. Ecology and Evolution 6:7623-7632.
Davidson, D.W., Bowker, M., George, D., Phillips, S.L., Belnap, J. 2002. Treatment effects on performance of N-fixing lichens in disturbed soil crusts of the Colorado Plateau. Ecological Applications 12:1391-1405
Doherty, K.D., Grover, H.S., Bowker, M.A., Durham, R.A., Antoninka, A.J., Ramsey, P.W. 2020. Producing moss-colonized burlap fabric in a fog chamber for restoration of biocrust. Ecological Engineering 158:106019.
Faist, A.M., Antoninka, A.J., Belnap, J., Bowker, M.A., Duniway, M.C., Garcia-Pichel, F., et al. 2020. Inoculation and habitat amelioration efforts in biological soil crust recovery vary by desert and soil texture. Restoration Ecology 28:S96-S105.
Giraldo-Silva, A., Nelson, C., Barger, N.N., Garcia-Pichel, F. 2019. Nursing biocrusts: isolation, cultivation, and fitness test of indigenous cyanobacteria. Restoration Ecology 27(4):793–803.
Giraldo-Silva, A., Nelson, C., Penfold, C., Barger, N.N., Garcia-Pichel, F. 2020. Effect of preconditioning to the soil environment on the performance of 20 cyanobacterial strains used as inoculum for biocrust restoration. Restoration Ecology 28(S2):187–193.
Hu, C., Liu, Y., Song, L., Zhang, D. 2002. Effect of desert soil algae on the stabilization of fine sands. Journal of Applied Phycology 14:281-292.
Kheirfam, H., Roohi, M. 2020. Accelerating the formation of biological soil crusts in the newly dried-up lakebeds using the inoculation-based technique. Science of The Total Environment 706: 136036.
Kubeckova, K., Johansen, J.R., Warren, S.D., Sparks, R. 2003. Development of immobilized cyanobacterial amendments for reclamation of microbiotic soil crusts. Algological Studies 109:341–362.
Lan, S., Zhang, Q., Wu, L., Liu, Y., Zhang, D., Hu, C. 2014. Artificially accelerating the reversal of desertification: Cyanobacterial inoculation facilitates the succession of vegetation communities. Environmental Science and Technology 48:307-315.
Li, Z., Chen, C., Gao, Y., Wang, B., Wang, D., Du, Y., et al. 2021. Synergistic effect of cyanobacteria and nano-sand-stabilizer on biocrust formation and sand fixation. 9:104887
Liu, Y., Cockell, C.S., Wang, G., Hu, C., Chen, L., De Philippis, R. 2008. Control of lunar and martian dust—experimental insights from artificial and natural cyanobacterial and algal crusts in the desert of inner Mongolia, China. Astrobiology 8(1): 75-86.
Park, C.H., Li, X.R., Zhao, Y., Jia, R.L., Hur, J.S., 2017. Rapid development of cyanobacterial crust in the field for combating desertification. PLoS ONE 12.
Román, J.R., Chamizo, S., Roncero-Ramos, B., Adessi, A., De Philippis, R., Cantón, Y. 2021. Overcoming field barriers to restore dryland soils by cyanobacteria inoculation. Soil and tillage research 207:104799.
Sadeghi, S.H., Kheirfam, H., Homaee, M., Darki, B.Z., Vafakhah, M. 2017. Improving runoff behavior resulting from direct inoculation of soil micro-organisms. Soil and Tillage Research 171:35-41.
Sadeghi, S.H., Satri, M.S., Kheirfam, H., Darki, B.Z. 2020. Controlling runoff generation and soil loss from field experimental plots through inoculating cyanobacteria. Journal of Hydrology 585:124814.
Slate, M.L., Durham, R.A., Pearson, D.E. 2020. Strategies for restoring the structure and function of lichen-moss biocrust communities. Restoration Ecology 28 (S2):S160-S167.
Wang, W.B., Liu, Y.D., Li, D.H., Hu, C.X., Rao, B.Q. 2009. Feasibility of cyanobacterial inoculation for biological soil crusts formation in desert area. Soil Biology and Biochemistry 41(5):926–929.
Wu, Y., Rao, B., Wu, P., Liu, Y., Li, G., Li, D. 2013. Development of artificially induced biological soil crusts in fields and their effects on top soil. Plant Soil 370:115-124.
Xiao, B., Zhao, Y., Wang, Q., Li,C. 2015. Development of artificial moss-dominated biological soil crusts and their effects on runoff and soil water content in a semi-arid environment. Journal of Arid Environments 117:75-83.
Zhao, Y., Wang, N., Zhang, Z., Pan, Y., Jia, R. 2019. Accelerating the development of artificial biocrusts using covers for restoration of degraded land in dryland ecosystems. Land Degrad Dev 32:285–295.