A review of recent advances in the study of geographical distribution and ecological functions of soil fauna diversity

doi:10.17520/biods.2022435

Abstract

Abstract:

Aims: Understanding the distribution and drivers of soil fauna diversity as well as their ecological functions have become areas of cutting-edge research in modern geoscience and ecology. Here, we briefly introduce the latest progress in this field, discuss present research limitations and uncertainties, and offer promising research directions in future studies of soil fauna.
Progresses: Many studies have described the global distribution of representative soil fauna taxa diversity and abundance, such as that of earthworms. Research on soil fauna distribution and ecological function in China has also flourished with many large scale, intensive sampling studies in the past 10 years (especially for earthworms and nematodes). Based on a literature review, we observed that there were two main distribution patterns of soil fauna diversity across latitudes. Diversity was found to be highest either at low-latitude tropical zones or at mid-latitude temperate zones; while changes in soil fauna abundance and diversity can be consistent, non-related, totally different, and even opposite. Precipitation, plant productivity and soil organic matter were the critical drivers of soil fauna distribution, but their influences varied with soil faunal taxon. The major ecological functions of soil fauna include improving soil physical structure, facilitating nutrient cycling and organic carbon stabilization, and enhancing plant health. The concept of multifunctionality of soil fauna has been proposed by soil ecologist to fully measure these multi-dimensional ecological functions, but it still faces many challenges.
Prospect: The drivers of soil fauna distribution are not simply predicted from the variation pattern of soil faunal community characteristics across latitudes, longitudes or altitudes. Rather, we suggest that drivers of the soil fauna distribution should be explored within a multi-dimensional spatial-temporal framework based on a combination of geological and ecological history as well as “latitude & longitude-altitude-distance to coast”. The distribution pattern of soil fauna may critically influence their potential ecological functions; however, the prediction and simulation of soil fauna distribution mainly relied on data-driven empirical models, and the results were not conclusive. Thus, the application of theories such as metabolic ecology deserves more attention. Research on the relationship between soil fauna diversity and function is in the preliminary stages; focusing on functional diversity and exploring the redundancy mechanism of taxonomic diversity could link soil fauna diversity and function. We propose to understand soil fauna diversity and function under specific condition of space and time, as well as the context of the whole soil food web and its connection with plants. There are two promising directions for further research: (1) illustrating the large uncertainties that human activity and climate change may bring to soil fauna studies; (2) developing precision manipulation approaches of soil fauna community to ultimately link soil fauna multifunctionality with human well-being.

Key words: soil fauna diversity, multifunctionality, human activity, global change, ecosystem service

Shenglei Fu, Manqiang Liu, Weixin Zhang, Yuanhu Shao. A review of recent advances in the study of geographical distribution and ecological functions of soil fauna diversity[J]. Biodiv Sci, 2022, 30(10): 22435.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2022435

https://www.biodiversity-science.net/EN/Y2022/V30/I10/22435

Figures/Tables 4

Fig. 1 The distribution of species richness of representative soil fauna along latitudes in northern hemisphere. Species richness in panels a-f refers to the mean value of species richness within a specific latitude range for a given group of soil fauna; data for collembola within 10°-20° N was shown, instead of that within 20°-30° N since the data was not available; data for termite within 40°-50° N, instead of that within 50°-60° N, was shown since almost no termite was reported in further northern regions with higher latitude. Data sources: earthworm (Phillips et al, 2019), termite (Deca?ns, 2010), oribatid mite (Maraun et al, 2007; Deca?ns, 2010), collembola (Potapov et al, 2022a) and nematode (Boag & Yeates, 1998).

Fig. 2 The changes in sampling sites of soil fauna community in China. The legend of “sampling sites during 2010-2020” refers to the new sampling sites during 2010-2020 based on literature analysis from CNKI; while the “sampling sites before 2010” refers to the sampling sites during 1980-2008 in studies represented by Yin et al, and the main data sources are from monographs edited by Yin, 1992, 2000; Zhao & Xie, 1996; Yin, 2001; Zhang, 2006; Liao & Li, 2009.

Fig. 3 Conceptual diagram of pathways for the effects of soil fauna on soil multifunctionality. Soil fauna have different effects on soils, litters and plant roots, among which, macrofauna (e.g. earthworm), mesofauna (e.g. springtail) and microfauna (e.g. nematode) potentially show the strong impact on soils, litters and plant roots, respectively. These changes can directly affect soil properties, as well as indirectly affect soil microbial properties such as microbial biomass, diversity and activity via modifying soil abiotic properties, e.g., pH, soil organic matter (SOM), nutrient and aggregate. Finally, these changes could also positively or negatively affect soil multifunctionality, such as the improvement of soil structure, the transformation of soil organic matter and the maintaining of plant health. The arrow width is proportional to the strength of the relationship. Solid and dashed arrows indicate direct and indirect effects, respectively.

Fig. 4 A schematic diagram showing energetic structure of soil micro-food webs and their relation to ecosystem multifunctionality. The C refers to the flux of energy through a given taxa of consumption, i.e., CH, CF, CB indicates flux of energy through herbivores, fungivores and bacterivores, respectively. The flux of energy through microbivores (CF and CB) has been shown to be related to litter decomposition and nutrient cycling, while the flux of energy through herbivores is typically related to plant productivity, and the flux of energy through predators is related to top-down controls on ecosystem drivers. The flow uniformity of energy in the soil micro-food web indicates the energy distribution of different channels, which determines the functional stability of food webs. Resources exert strong effects on the energetic structure of food webs by shifting the diversity and composition of soil micro-food webs. These shifts in soil biodiversity and composition could optimize the energetic structure of soil micro-food webs to support ecosystem services.

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