Spatial dynamics of yeast community and its relationship to environmental factors in Lake Fuxian, Yunnan Province

Abstract Upland rice has the characteristics of strong drought tolerance and wide adaptability. Cultivating upland rice with high yield and high quality can solve the contradiction between food shortage, water shortage, and population increase in countries all over the world, and is of great significance to the sustainable development of agriculture. In this study, high-throughput sequencing technology based on the Illumina Miseq platform was used to investigate the structure and diversity of endophytic bacterial communities using 12 upland rice variety seeds from different areas in Yunnan Province of China as materials. This study aims to reveal the "core microbiota" of the endophytic bacteria in upland rice seeds in the Yunnan Province of China by examining their diversity and community structures. The results showed that 39 endophytic OTUs were found to coexist in all samples. At the phylum level, the first dominant phyla in the 12 seed samples were Proteobacteria (66.92-99.98%). At the genus level, Pantoea (9.75-99.24%), Pseudomonas (0.11-37.24%), Curtobacterium (0.01-19.90%), Microbacterium (0.01-14.95%), Methylobacterium (0.40-5.86%), Agrobacterium (0.01-4.53%), Sphingomonas (0.04-1.56%), Aurantimonas (0.01-1.45%) and Rhodococcus (0.11-1.09%) served as the dominant genera that coexisted in all the upland rice seeds tested and represent the core microbiota in upland rice seeds. Through the correlation analysis with upland rice habitat environmental factors, the effects of climate and altitude on the structure and diversity of endophytic bacterial community in upland rice seeds were further revealed. The results showed that environmental factors such as temperature, precipitation and altitude have great influences on the structure of endophytic bacterial community in upland rice seeds. This study is of great significance to explore the relationship between upland rice and its endophytic bacteria and to tap the resources of drought-tolerant bacteria to improve the yield of local upland rice.

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Composition and Diversity of Endophytic Bacterial Community in Seeds of Upland Rice Resources from Different Origin Habitats in Yunnan Province of China

10.21203/rs.3.rs-373041/v1 ◽

2021 ◽

Author(s):

Zhishan Wang ◽

Yongqiang Zhu ◽

Ni Li ◽

Biqi Sun ◽

Hai Liu ◽

...

Keyword(s):

Environmental Factors ◽

Bacterial Community ◽

Endophytic Bacteria ◽

Yunnan Province ◽

Upland Rice ◽

Population Increase ◽

Core Microbiota ◽

The Core ◽

Endophytic Bacterial Community ◽

Rice Seeds

Abstract Upland rice has the characteristics of strong drought tolerance and wide adaptability. Cultivating upland rice with high yield and high quality can solve the contradiction between food shortage, water shortage, and population increase in countries all over the world, and is of great significance to the sustainable development of agriculture. This study aims to reveal the "core microbiota" of the endophytic bacteria in upland rice seeds in the Yunnan Province of China by examining their diversity and community structures. Through the correlation analysis with upland rice habitat environmental factors, the effects of climate and altitude on the structure and diversity of endophytic bacterial community in upland rice seeds were further revealed. In this study, high-throughput sequencing technology based on the Illumina Miseq platform was used to investigate the structure and diversity of endophytic bacterial communities using 12 upland rice variety seeds from different areas in Yunnan Province of China as materials. Here, 39 endophytic OTUs (0.68%) were found to coexist in all samples. At the phylum level, the first dominant phyla in the 12 seed samples were Proteobacteria (66.92–99.98%). At the genus level, Pantoea (9.75–99.24%), Pseudomonas (0.11–37.24%), Curtobacterium (0.01–19.90%), Microbacterium (0.01–14.95%), Methylobacterium (0.40–5.86%), Agrobacterium (0.01–4.53%), Sphingomonas (0.04–1.56%), Aurantimonas (0.01–1.45%) and Rhodococcus (0.11–1.09%), which represent the core microbiota in upland rice seeds, served as the dominant genera that coexisted in all the upland rice seeds tested. Environmental factors such as temperature, precipitation and altitude have great influences on the structure of endophytic bacterial community in upland rice seeds. This study is of great significance to explore the relationship between upland rice and its endophytic bacteria and to tap the resources of drought-tolerant bacteria to improve the yield of local upland rice.

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Linking tagging technology and molecular genetics to gain insight in the spatial dynamics of two stocks of cod in Northeast Atlantic waters

ICES Journal of Marine Science ◽

10.1093/icesjms/fsu083 ◽

2014 ◽

Vol 71 (6) ◽

pp. 1417-1432 ◽

Cited By ~ 15

Author(s):

Kathrine Michalsen ◽

Torild Johansen ◽

Sam Subbey ◽

Alexander Beck

Keyword(s):

Environmental Factors ◽

Molecular Genetics ◽

Data Storage ◽

Large Scale ◽

Gadus Morhua ◽

Atlantic Cod ◽

Spatial Dynamics ◽

Scientific Basis ◽

The North ◽

Shortest Distance

The Northeast Arctic cod (Gadus morhua L.: NEAC) remains the most abundant cod stock in the North Atlantic, while the catches of the partially co-occurring Norwegian coastal cod (NCC) stocks have dramatically decreased in recent years. To ensure effective management of the two stocks, it is necessary to know if the population genetic structure is associated with any pattern in the spatial dynamics or whether it is affected by any distinct environmental factors. By combining information from electronic data storage tags (DST) and molecular genetics methods with statistical tools, we have been able to associate spatial dynamics and distinct environmental factors to the two cod stocks. In general, adult NEAC migrate between deep, warm overwintering grounds and shallow summer feeding grounds where water temperatures maybe low. In contrast, NCC do not undertake large-scale seasonal migrations, show little seasonal variation in depth distribution, and experience the opposite seasonal change in temperature compared with NEAC. However, within the NCC group, some individuals did conduct longer horizontal movements than others. Even though the distances calculated in this study represent the shortest distance between release and recapture positions, they are far higher than previously reported by NCC. Distinctive depth profiles indicate that this migrant NCC have moved out of the area, passing the deep trenches outside Lofoten while more stationary NCC occupies shallower depths throughout the year. The temperature profiles also indicate that migrant and stationary NCC has occupied different areas during the year. We demonstrate that the combination of information from DSTs and molecular genetics offers a deeper understanding of individual cod behaviour, provides an insight in the spatial dynamics of the species, and ultimately, improves the scientific basis for management of a complex mixed fishery of Atlantic cod.

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