Integrating quantitative morphological and qualitative molecular methods to analyse soil nematode community responses to plant range expansion

Geisen, Stefan; Snoek, L. Basten; Hooven, Freddy C. ten; Duyts, Henk; Kostenko, Olga; Bloem, J.; Martens, Henk; Quist, Casper W.; Helder, J.; Putten, Wim H. van der

doi:10.1111/2041-210x.12999

Cited by 86 publications

(77 citation statements)

References 76 publications

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“…One factor hampering the study of management effects across multiple study sites is that traditional microscopy is the most common method to study nematodes, which is time‐consuming, requires specialists and is expensive (Ritz, Black, Campbell, Harris, & Wood, ). Molecular methods to assess nematode absolute abundances (qPCR) and diversity (high‐throughput amplicon sequencing, DGGE, T‐RFLP) are faster, cheaper, and allow higher throughput than visual methods (Ahmed, Sapp, Prior, Karssen, & Back, ; Geisen et al, ). Amplicon sequencing may allow identification of taxa that cannot be distinguished morphologically.…”

Section: Introductionmentioning

confidence: 99%

Reduced tillage, but not organic matter input, increased nematode diversity and food web stability in European long‐term field experiments

et al. 2019

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Soil nematode communities and food web indices can inform about the complexity, nutrient flows and decomposition pathways of soil food webs, reflecting soil quality. Relative abundance of nematode feeding and life‐history groups are used for calculating food web indices, i.e., maturity index (MI), enrichment index (EI), structure index (SI) and channel index (CI). Molecular methods to study nematode communities potentially offer advantages compared to traditional methods in terms of resolution, throughput, cost and time. In spite of such advantages, molecular data have not often been adopted so far to assess the effects of soil management on nematode communities and to calculate these food web indices. Here, we used high‐throughput amplicon sequencing to investigate the effects of tillage (conventional vs. reduced) and organic matter addition (low vs. high) on nematode communities and food web indices in 10 European long‐term field experiments and we assessed the relationship between nematode communities and soil parameters. We found that nematode communities were more strongly affected by tillage than by organic matter addition. Compared to conventional tillage, reduced tillage increased nematode diversity (23% higher Shannon diversity index), nematode community stability (12% higher MI), structure (24% higher SI), and the fungal decomposition channel (59% higher CI), and also the number of herbivorous nematodes (70% higher). Total and labile organic carbon, available K and microbial parameters explained nematode community structure. Our findings show that nematode communities are sensitive indicators of soil quality and that molecular profiling of nematode communities has the potential to reveal the effects of soil management on soil quality.

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Section: Introductionmentioning

confidence: 99%

Reduced tillage, but not organic matter input, increased nematode diversity and food web stability in European long‐term field experiments

et al. 2019

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“…These studies have yielded important insights on how our well-being is closely related to healthy soils with high biodiversity Orgiazzi et al, 2016). In addition, recent methodological advances such as high-throughput sequencing have enabled investigations of soil biodiversity with greater precision and have promoted insights on patterns of soil biodiversity at varying spatial scales (Bahram et al, 2018;Geisen et al, 2018;Ramirez et al, 2018;Potapov, Tiunov, & Scheu, 2019). Yet, only a few studies have tested contemporary biodiversity theories using patterns of soil biodiversity.…”

Section: Self-organizationmentioning

confidence: 99%

Towards an integrative understanding of soil biodiversity

et al. 2019

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Soil is one of the most biodiverse terrestrial habitats. Yet, we lack an integrative conceptual framework for understanding the patterns and mechanisms driving soil biodiversity. One of the underlying reasons for our poor understanding of soil biodiversity patterns relates to whether key biodiversity theories (historically developed for aboveground and aquatic organisms) are applicable to patterns of soil biodiversity. Here, we present a systematic literature review to investigate whether and how key biodiversity theories (species–energy relationship, theory of island biogeography, metacommunity theory, niche theory and neutral theory) can explain observed patterns of soil biodiversity. We then discuss two spatial compartments nested within soil at which biodiversity theories can be applied to acknowledge the scale‐dependent nature of soil biodiversity.

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“…Bacterivores were more abundant in nitrogen-enriched plots [42] . Geisen used morphological and molecular (qPCR and HTS) methods to analyze soil nematode communities and the results show that HTS afforded the highest taxonomic resolution and sample throughput [47] , although the various methods yielded similar outcomes.…”

Section: Frontier Methods Of Soil Nematode Community and Diversity Idmentioning

confidence: 99%

“…When sample numbers are large, HTS is optimal. HTS does not require expertise in morphological identification, and is therefore more feasible for scientists with little knowledge of morphological identification [47] . Both the morphological and molecular methods can effectively identify and analyze nematode community structure, and this has a critical role in evaluating soil health using the soil nematode community structure.…”

Section: Frontier Methods Of Soil Nematode Community and Diversity Idmentioning

confidence: 99%

A review of soil nematodes as biological indicators for the assessment of soil health

Liu

Wang

et al. 2020

Front. Agr. Sci. Eng.

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Healthy soils are essential for sustainable agricultural development and soil health requires careful assessment with increasing societal concern over environmentally friendly agricultural development. Soil health is the capacity of soil to function within ecological boundaries to sustain productivity, maintain environmental quality, and promote plant and animal health. Physical, chemical and biological indicators are used to evaluate soil health; the biological indicators include microbes, protozoa and metazoa. Nematodes are the most abundant metazoa and they vary in their sensitivity to pollutants and environmental disturbance. Soil nematode communities are useful biological indicators of soil health, with community characteristics such as abundance, diversity, community structure and metabolic footprint all closely correlated with the soil environment. The community size, complexity and structure reflect the condition of the soil. Both free-living and plant-parasitic nematodes are effective ecological indicators, contributing to nutrient cycling and having important roles as primary, secondary and tertiary consumers in food webs. Tillage inversion, cropping patterns and nutrient management may have strong effects on soil nematodes, with changes in soil nematode communities reflecting soil disturbance. Some free-living nematodes serve as biological models to test soil condition in the laboratory and because of these advantages soil nematodes are increasingly being used as biological indicators of soil health.

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Integrating quantitative morphological and qualitative molecular methods to analyse soil nematode community responses to plant range expansion

Cited by 86 publications

References 76 publications

Reduced tillage, but not organic matter input, increased nematode diversity and food web stability in European long‐term field experiments

Reduced tillage, but not organic matter input, increased nematode diversity and food web stability in European long‐term field experiments

Towards an integrative understanding of soil biodiversity

A review of soil nematodes as biological indicators for the assessment of soil health

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