Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere

WANG, Lige; LV, Junping; JIAO, Xiaoyan; GUO, Jun; FENG, Jia; LIU, Shufang; XIE, Shulian; Liu, Qi

doi:10.3906/bot-1906-1

Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere

Junping LV, (Shanxi University)

Shufang LIU, (Shanxi University)

Jia FENG, (Shanxi University)

Qi LIU, (Shanxi University)

Jun GUO, (Institute of Agricultural Environment and Resource)

Lige WANG, (Institute of Agricultural Environment and Resource)

Xiaoyan JIAO, (Institute of Agricultural Environment and Resource)

Shulian XIE (Shanxi University)

Turkish Journal of Botany

2 0

Yıl: 2020 Cilt: 44 Sayı: 2 Sayfa Aralığı: 167 - 177 Metin Dili: İngilizce DOI: 10.3906/bot-1906-1 İndeks Tarihi: 04-05-2020

Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere

Öz:

In the present study, microalgal biomass (Anabeana circinalis and Scenedesmus quadricauda) was used as biofertilizer incucumber cultivation. The response of cucumber growth characters to microalgal biofertilizer was evaluated. Moreover, rhizospheremicrobial diversity and community composition of cucumber was analyzed through 16S rRNA high-throughput Illumina sequencingdata. The results showed that microalgal biomass as biofertilizer significantly promoted height, number of leaves and flower buds,and stem diameter of cucumber. The application of a high concentration of S. quadricauda to soil raised the diversity of rhizospherefungi of cucumber. The rhizosphere microbial community of cucumber also responded to microalgal biofertilizer. The most abundantbacterial phylum in all samples was Proteobacteria. Acidobacteria, Actinobacteria, and Gemmatimonadetes were also highly abundant inall samples. Ascomycota was the most predominant fungal phylum in all samples. Zygomycota was the dominant phylum in the control,whereas Basidiomycota was dominant in all treatments. At the genus level, both growth-promoting bacteria and fungi (Azotobacter,Bacillus, Pseudomonas, Cryptococcus, Fusarium, Penicillium, and Trichoderma) from the rhizosphere of cucumber were enhanced in alltreatments after the application of microalgae fertilizer. All results indica

Anahtar Kelime:

Konular: Biyoloji

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık

Abd EA, Abd-Allah ASE (2008). Effect of green alga cells extract as foliar spray on vegetative growth, yield and berries quality of superior grapevines. American-Eurasian Journal of Agricultural and Environmental Sciences 4: 427-433.
Ahemad M, Kibret M (2014). Mechanisms and applications of plant growth promoting rhizobacteria: current perspective. Journal of King Saud University, Science 26: 1-20.
Berendsen RL, Pieterse CM, Bakker PA (2012). The rhizosphere microbiome and plant health. Trends in Plant Science 17: 478- 486.
Bidyarani N, Prasanna R, Babu S, Hossain F, Saxena AK (2016). Enhancement of plant growth and yields in chickpea (Cicer arietinum L.) through novel cyanobacterial and biofilmed inoculants. Microbiological Research 188: 97-105.
Borowitzka MA (2013). High-value products from microalgae— their development and commercialisation. Journal of Applied Phycology 25: 743-756.
Chen G, Zhao L, Qi Y (2015). Enhancing the productivity of microalgae cultivated in wastewater toward biofuel production: a critical review. Applied Energy 137: 282-291.
Connell L, Redman R, Craig S, Scorzetti G, Iszard M et al. (2008). Diversity of soil yeasts isolated from South Victoria Land, Antarctica. Microbial Ecology 56: 448-459.
Dey SK, Chakrabarti B, Prasanna R, Pratap D, Singh SD et al. (2017). Elevated carbon dioxide level along with phosphorus application and cyanobacterial inoculation enhances nitrogen fixation and uptake in cowpea crop. Archives of Agronomy and Soil Science 63: 1-11.
El-Borollosy AM, Oraby MM (2012). Induced systemic resistance against Cucumber mosaic cucumovirus and promotion of cucumber growth by some plant growth-promoting rhizobacteria. Annals of Agricultural Sciences 57: 91-97.
Eifediyi EK, Remison SU (2009). The effects of inorganic fertilizer on the yield of two varieties of cucumber (Cucumis sativus L.). Report and Opinion 1: 74-80.
Eifediyi EK, Remison SU (2010). Growth and yield of cucumber (Cucumis sativus L.) as influenced by farmyard manure and inorganic fertilizer. Journal of Plant Breeding and Crop Science 2: 216-220.
Grzesik M, Romanowska-Duda Z, Kalaji HM (2017). Effectiveness of cyanobacteria and green algae in enhancing the photosynthetic performance and growth of willow (Salix viminalis L.) plants under limited synthetic fertilizers application. Photosynthetica 55: 510-521.
Gu Y, Van Nostrand JD, Wu L, He Z, Qin Y et al. (2017). Bacterial community and arsenic functional genes diversity in arsenic contaminated soils from different geographic locations. PloS One 12: e0176696.
Herman MAB, Nault BA, Smart CD (2008). Effects of plant growthpromoting rhizobacteria on bell pepper production and green peach aphid infestations in New York. Crop Protection 27: 996- 1002.
Islam S, Akanda AM, Prova A, Islam MT, Hossain MM (2016). Isolation and identification of plant growth promoting rhizobacteria from cucumber rhizosphere and their effect on plant growth promotion and disease suppression. Frontiers in Microbiology 6: 1360.
Khalid A, Arshad M, Zahir ZA (2004). Screening plant growthpromoting rhizobacteria for improving growth and yield of wheat. Journal of Applied Microbiology 96: 473-480.
Kong QX, Li L, Martinez B, Chen P, Ruan R (2010). Culture of microalgae Chlamydomonas reinhardtii in wastewater for biomass feedstock production. Applied Biochemistry and Biotechnology 160: 9-18.
Kozich JJ, Westcott SL, Baxter NT, Highlander SK, Schloss PD (2013). Development of a dual-index sequencing strategy and curation pipeline for analyzing amplicon sequence data on the MiSeq Illumina sequencing platform. Applied and Environmental Microbiology 79: 5112-5120.
Li X, Hu H, Gan K, Yang J (2010). Growth and nutrient removal properties of a freshwater microalga Scenedesmus sp. LX1 under different kinds of nitrogen sources. Ecological Engineering 36: 379-381.
Lim YW, Kim BK, Kim C, Jung HS, Kim BS et al. (2010). Assessment of soil fungal communities using pyrosequencing. Journal of Microbiology 48: 284-289.
Maity JP, Bundschuh J, Chen CY, Bhattacharya P (2014). Microalgae for third generation biofuel production, mitigation of greenhouse gas emissions and wastewater treatment: present and future perspectives—a mini review. Energy 78: 104-113.
McFadden D, Zaragoza O, Casadevall A (2006). The capsular dynamics of Cryptococcus neoformans. Trends in Microbiology 14: 497-505.
Meera MS, Shivanna MB, Kageyama K, Hyakumachi M (1994). Plant growth promoting fungi from zoysiagrass rhizosphere as potential inducers of systemic resistance in cucumbers. Phytopathology 84: 1399-1406.
Mulbry W, Westhead EK, Pizarro C, Sikora L (2005). Recycling of manure nutrients: use of algal biomass from dairy manure treatment as a slow release fertilizer. Bioresource Technology 96: 451-458.
Peiffer JA, Spor A, Koren O, Jin Z, Tringe SG et al. (2013). Diversity and heritability of the maize rhizosphere microbiome under field conditions. Proceedings of the National Academy of Sciences of the United States of America 110: 6548-6553.
Philippot L, Raaijmakers JM, Lemanceau P, van der Putten WH (2013). Going back to the roots: the microbial ecology of the rhizosphere. Nature Reviews Microbiology 11: 789-799.
Pii Y, Mimmo T, Tomasi N, Terzano R, Cesco S et al. (2015a). Microbial interactions in the rhizosphere: beneficial influences of plant growth-promoting rhizobacteria on nutrient acquisition process. A review. Biology and Fertility of Soils 51: 403-415.
Pii Y, Penn A, Terzano R, Crecchio C, Mimmo T et al. (2015b). Plantmicroorganism-soil interactions influence the Fe availability in the rhizosphere of cucumber plants. Plant Physiology and Biochemistry 87: 45-52.
Prasanna R, Joshi M, Rana A, Shivay YS, Nain L (2012). Influence of co-inoculation of bacteria-cyanobacteria on crop yield and C–N sequestration in soil under rice crop. World Journal of Microbiology and Biotechnology 28: 1223-1235.
Qiu M, Zhang R, Xue C, Zhang S, Li S et al. (2012). Application of bio-organic fertilizer can control Fusarium wilt of cucumber plants by regulating microbial community of rhizosphere soil. Biology and Fertility of Soils 48: 807-816.
Renuka N, Prasanna R, Sood A, Ahluwalia AS, Bansal R et al. (2016). Exploring the efficacy of wastewater-grown microalgal biomass as a biofertilizer for wheat. Environmental Science and Pollution Research 23: 6608-6620.
Tian Y, Gao L (2014). Bacterial diversity in the rhizosphere of cucumbers grown in soils covering a wide range of cucumber cropping histories and environmental conditions. Microbial Ecology 68: 794-806.
Tripathi RD, Dwivedi S, Shukla MK, Mishra S, Srivastava S et al. (2008). Role of blue green algae biofertilizer in ameliorating the nitrogen demand and fly-ash stress to the growth and yield of rice (Oryza sativa L.) plants. Chemosphere 70: 1919-1929.
Vessey JK (2003). Plant growth promoting rhizobacteria as biofertilizers. Plant and Soil 255: 571-586.
Viaud M, Pasquier A, Brygoo Y (2000). Diversity of soil fungi studied by PCR-RFLP of ITS. Mycological Research 104: 1027-1032.
Vishniac HS (2006). A multivariate analysis of soil yeasts isolated from a latitudinal gradient. Microbial Ecology 52: 90-103.
Wuang SC, Khin MC, Chua PQD, Luo YD (2016). Use of Spirulina biomass produced from treatment of aquaculture wastewater as agricultural fertilizers. Algal Research 15: 59-64.
Wuczkowski M, Prillinger H (2004). Molecular identification of yeasts from soils of the alluvial forest national park along the river Danube downstream of Vienna, Austria (Nationalpark Donau-Auen). Microbiological Research 159: 263-275.
Zhang W, Chen L, Zhang R, Lin K (2016). High throughput sequencing analysis of the joint effects of BDE209-Pb on soil bacterial community structure. Journal of Hazardous Materials 301: 1-7.
Zhou J, Lei T (2007). Review and prospects on methodology and affecting factors of soil microbial diversity. Biodiversity Science 15: 306-311 (in Chinese).
Zhou X, Zhang J, Pan D, Ge X, Jin X et al. (2018). p-Coumaric can alter the composition of cucumber rhizosphere microbial communities and induce negative plant-microbial interactions. Biology and Fertility of Soils 54: 363-372.

APA	LV J, LIU S, FENG J, Liu Q, GUO J, WANG L, JIAO X, XIE S (2020). Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. , 167 - 177. 10.3906/bot-1906-1
Chicago	LV Junping,LIU Shufang,FENG Jia,Liu Qi,GUO Jun,WANG Lige,JIAO Xiaoyan,XIE Shulian Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. (2020): 167 - 177. 10.3906/bot-1906-1
MLA	LV Junping,LIU Shufang,FENG Jia,Liu Qi,GUO Jun,WANG Lige,JIAO Xiaoyan,XIE Shulian Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. , 2020, ss.167 - 177. 10.3906/bot-1906-1
AMA	LV J,LIU S,FENG J,Liu Q,GUO J,WANG L,JIAO X,XIE S Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. . 2020; 167 - 177. 10.3906/bot-1906-1
Vancouver	LV J,LIU S,FENG J,Liu Q,GUO J,WANG L,JIAO X,XIE S Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. . 2020; 167 - 177. 10.3906/bot-1906-1
IEEE	LV J,LIU S,FENG J,Liu Q,GUO J,WANG L,JIAO X,XIE S "Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere." , ss.167 - 177, 2020. 10.3906/bot-1906-1
ISNAD	LV, Junping vd. "Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere". (2020), 167-177. https://doi.org/10.3906/bot-1906-1

APA	LV J, LIU S, FENG J, Liu Q, GUO J, WANG L, JIAO X, XIE S (2020). Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. Turkish Journal of Botany, 44(2), 167 - 177. 10.3906/bot-1906-1
Chicago	LV Junping,LIU Shufang,FENG Jia,Liu Qi,GUO Jun,WANG Lige,JIAO Xiaoyan,XIE Shulian Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. Turkish Journal of Botany 44, no.2 (2020): 167 - 177. 10.3906/bot-1906-1
MLA	LV Junping,LIU Shufang,FENG Jia,Liu Qi,GUO Jun,WANG Lige,JIAO Xiaoyan,XIE Shulian Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. Turkish Journal of Botany, vol.44, no.2, 2020, ss.167 - 177. 10.3906/bot-1906-1
AMA	LV J,LIU S,FENG J,Liu Q,GUO J,WANG L,JIAO X,XIE S Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. Turkish Journal of Botany. 2020; 44(2): 167 - 177. 10.3906/bot-1906-1
Vancouver	LV J,LIU S,FENG J,Liu Q,GUO J,WANG L,JIAO X,XIE S Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere. Turkish Journal of Botany. 2020; 44(2): 167 - 177. 10.3906/bot-1906-1
IEEE	LV J,LIU S,FENG J,Liu Q,GUO J,WANG L,JIAO X,XIE S "Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere." Turkish Journal of Botany, 44, ss.167 - 177, 2020. 10.3906/bot-1906-1
ISNAD	LV, Junping vd. "Effects of microalgal biomass as biofertilizer on the growth of cucumber and microbial communities in the cucumber rhizosphere". Turkish Journal of Botany 44/2 (2020), 167-177. https://doi.org/10.3906/bot-1906-1