Global Deep-Sea Biodiversity Research Trends Highlighted by Science Mapping Approach

Costa, Corrado; Fanelli, Emanuela; Marini, Simone; Danovaro, Roberto; Aguzzi, Jacopo

doi:10.3389/fmars.2020.00384

Cited by 34 publications

(28 citation statements)

References 97 publications

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“…The science mapping approach allows for a spatial representation of how disciplines, documents, countries, and authors are integrated. This approach has been successfully applied to several research fields to date [39][40][41][42][43][44][45][46]. To the best of our knowledge, the science mapping approach has never been applied to analyze soil microbial inoculant application.…”

Section: Introductionmentioning

confidence: 99%

Trends in Soil Microbial Inoculants Research: A Science Mapping Approach to Unravel Strengths and Weaknesses of Their Application

et al. 2021

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Microbial inoculants are widely accepted as potential alternatives or complements to chemical fertilizers and pesticides in agriculture. However, there remains a lack of knowledge regarding their application and effects under field conditions. Thus, a quantitative description of the scientific literature related to soil microbial inoculants was conducted, adopting a science mapping approach to observe trends, strengths, and weaknesses of their application during the period of 2000–2020 and providing useful insights for future research. Overall, the study retrieved 682 publications with an increasing number during the 2015–2020 period, confirming China, India, and the U.S. as leading countries in microbial inoculants research. Over the last decade, the research field emphasized the use of microbial consortia rather than single strains, with increasing attention paid to sustainability and environmental purposes by means of multidisciplinary approaches. Among the emerging topics, terms such as “persistence” indicate the actual need for detecting and monitoring the persistence and fate of soil microbial inoculants. On the other hand, the low occurrence of terms related to failed studies as well as formulation processes may have limited the overall comprehension of the real potential of microbial inoculants to date. In conclusion, successful application of soil microbial inoculants in agriculture requires filling the fundamental knowledge gaps related to the processes that govern dynamics and interactions of the inoculants with soil and its native microbiota.

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Section: Introductionmentioning

confidence: 99%

Trends in Soil Microbial Inoculants Research: A Science Mapping Approach to Unravel Strengths and Weaknesses of Their Application

et al. 2021

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“…In addition, oil and gas reserves have also been quantified in this area (Bird et al, 2008). It has been made clear that the onset of such multiple pressures in deep sea habitats results in an urgent need for biodiversity and trait-based characterization of deep-sea fauna (Costa et al, 2020), a need we directly address in the present study. Our trait-based evaluation of CBL epifauna points to potentially high sensitivity of benthic community function to disturbances especially at mid-depths as indicated by high FD and low FR.…”

Section: Perspective and Outlookmentioning

confidence: 97%

Functional Pattern of Benthic Epifauna in the Chukchi Borderland, Arctic Deep Sea

et al. 2021

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Assessment of Arctic deep-sea ecosystem functioning is currently an urgent task considering that ongoing sea-ice reduction opens opportunities for resource exploitation of yet understudied deep-sea regions. We used Biological Trait Analysis to evaluate ecosystem functioning and test if common paradigms for deep-sea fauna apply to benthic epifauna of the deep-sea Arctic Chukchi Borderland (CBL). We also investigated the influence of environmental factors on the functional structure of the epifauna. The analysis was performed for 106 taxa collected with a beam trawl and a Remotely Operated Vehicle from 486 to 2610 m depth. The most common trait modalities were small-medium size, mobile, benthic direct and lecithotrophic larval development, and predatory feeding, which mostly supports the current view of epifauna in the global deep sea. Functional composition of epifauna differed between two depth strata (486–1059 m and 1882–2610 m), with depth and sediment carbon content explaining most of the functional variability. Proportional abundances of the modalities free-living, swimming, suspension feeders, opportunists/scavengers, internal fertilization and globulose were higher at deep stations. Functional redundancy (FR) was also higher there compared to the mid-depth stations, suggesting adaptation of fauna to the more homogeneous deep environment by fewer and shared traits. Mid-depth stations represented higher functional variability in terms of both trait modality composition and functional diversity, indicating more variable resource use in the more heterogeneous habitat. Food input correlated positively with the proportional abundance of the modalities tube-dwelling, sessile and deposit feeding. Areas with drop stones were associated with higher proportional abundance of the modalities attached, upright, and predators. Comparatively low FR may render the heterogeneous mid-depth area of the CBL vulnerable to disturbance through the risk of loss of functions. Across the study area, high occurrence of taxa with low dispersal ability among adult and larval life stages may prevent rapid adaptation to changes, reduce ability to recolonize and escape perturbation.

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“…Benefiting from recent technological advances in different fields, from maritime engineering to genomics, we now have access to increasingly large biological and environmental data sets from the oceans, including areas or habitats that were previously inaccessible such as the deep sea (Costa et al., 2020). This offers an unprecedented opportunity to characterize the main reproductive barriers and evolutionary mechanisms underlying speciation of marine life forms across multiple ecosystems and taxa, and to provide a more complete view of speciation across a diverse range of marine environments.…”

Section: Introductionmentioning

confidence: 99%

Speciation in marine environments: Diving under the surface

Faria

Johannesson

Stankowski

2021

J of Evolutionary Biology

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Marine ecosystems harbour an important component of Earth's biodiversity. This is particularly well illustrated at high taxonomic levels, where 16 phyla are unique to the marine realm, whereas only one phylum is unique to terrestrial and none to freshwater environments (Jezkova & Wiens, 2017). Investigating the main processes underlying diversification in marine environments is thus crucial for a more general understanding of the origins and distribution of biodiversity. The study of how reproductive barriers between marine organisms accumulate resulting in new species in a broadly connected environment is also vital for the long-standing evolutionary debate concerning the importance of isolation by physical barriers in speciation. During most of the last century, our knowledge about the origin of species in the marine realm was very limited, with the exception of a few taxonomic groups (e.g. sea urchins; Mayr, 1954;

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Global Deep-Sea Biodiversity Research Trends Highlighted by Science Mapping Approach

Cited by 34 publications

References 97 publications

Trends in Soil Microbial Inoculants Research: A Science Mapping Approach to Unravel Strengths and Weaknesses of Their Application

Trends in Soil Microbial Inoculants Research: A Science Mapping Approach to Unravel Strengths and Weaknesses of Their Application

Functional Pattern of Benthic Epifauna in the Chukchi Borderland, Arctic Deep Sea

Speciation in marine environments: Diving under the surface

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