Diplura in caves: diversity, ecology, evolution and biogeography

Sendra, Alberto; Palero, Ferran; Jiménez‐Valverde, Alberto; Reboleira, Ana Sofía P.S.

doi:10.1093/zoolinnean/zlaa116

Cited by 15 publications

(14 citation statements)

References 49 publications

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“…We showed that the distribution ranges of both soil and cave Eukoenenia species are very narrow even when compared to other subterranean species, and that range size does not significantly differ between the two guilds here considered. This suggests a limited dispersal potential for most species, as also empirically observed for other small‐sized soil‐ and cave‐dwelling specialists, such as proturans (Galli & Rellini, 2020) and diplurans (Sendra et al, 2020). An anecdotal example of this low dispersal ability can be found in the case of Eukoenenia maquinensis and E. sagarana , two cave‐adapted palpigrades from Brazil.…”

Section: Discussionsupporting

confidence: 60%

“…This suggests a limited dispersal potential for most species, as also empirically observed for other small-sized soil-and cave-dwelling specialists, such as proturans (Galli & Rellini, 2020) and diplurans (Sendra et al, 2020). An anecdotal example of this low dispersal ability can be found in the case of Eukoenenia maquinensis and E. sagarana, two caveadapted palpigrades from Brazil.…”

Section: Distribution Patterns and Ecologymentioning

confidence: 52%

See 1 more Smart Citation

Global distribution of microwhip scorpions (Arachnida: Palpigradi)

Mammola

Souza

Isaia

et al. 2021

Journal of Biogeography

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Section: Discussionsupporting

confidence: 60%

Section: Distribution Patterns and Ecologymentioning

confidence: 52%

Global distribution of microwhip scorpions (Arachnida: Palpigradi)

Mammola

Souza

Isaia

et al. 2021

Journal of Biogeography

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“…This impediment (also known as 'Linnean shortfall'; Hortal et al, 2015) is especially problematic in studies focusing on community structure and functioning. It is particularly severe for tropical areas, whose subterranean fauna were largely unknown until very recently (e.g., Alvarenga et al, 2021;Trajano & Bichuette, 2010;Trajano et al, 2016), as well as for certain small-sized animal groups which have been traditionally neglected despite being relatively abundant in subterranean habitats, such as diplurans (Sendra, Antić, et al, 2020;Sendra, Palero, et al, 2020), proturans (Galli et al, 2021), palpigrades (Mammola et al, 2021), nematodes (Du Preez et al, 2017), gastrotrichs (Kolicka et al, 2017), and other meiofaunal lineages (Martínez et al, 2019;Sánchez & Martínez, 2019). The lack of taxonomists for many groups surely hampers the conduction of more concise studies on cave communities in many regions; a situation that is further aggravated by the existence of often high cryptic diversity within most subterranean taxa (Delić et al, 2017;Eme et al, 2018;Esposito et al, 2015;Fišer et al, 2018;Gonzalez et al, 2017;Niemiller et al, 2012).…”

Section: Biological Impedimentmentioning

confidence: 99%

Collecting eco‐evolutionary data in the dark: Impediments to subterranean research and how to overcome them

Mammola

Lunghi

Bilandžija

et al. 2021

Ecology and Evolution

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Caves and other subterranean habitats fulfill the requirements of experimental model systems to address general questions in ecology and evolution. Yet, the harsh working conditions of these environments and the uniqueness of the subterranean organisms have challenged most attempts to pursuit standardized research. Two main obstacles have synergistically hampered previous attempts. First, there is a habitat impediment related to the objective difficulties of exploring subterranean habitats and our inability to access the network of fissures that represents the elective habitat for the so‐called “cave species.” Second, there is a biological impediment illustrated by the rarity of most subterranean species and their low physiological tolerance, often limiting sample size and complicating laboratory experiments. We explore the advantages and disadvantages of four general experimental setups ( in situ , quasi in situ , ex situ , and in silico ) in the light of habitat and biological impediments. We also discuss the potential of indirect approaches to research. Furthermore, using bibliometric data, we provide a quantitative overview of the model organisms that scientists have exploited in the study of subterranean life. Our over‐arching goal is to promote caves as model systems where one can perform standardized scientific research. This is important not only to achieve an in‐depth understanding of the functioning of subterranean ecosystems but also to fully exploit their long‐discussed potential in addressing general scientific questions with implications beyond the boundaries of this discipline.

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“…In caves, diplurans from the families Campodeidae and Japygidae are found in karst and in volcanic formations all around the world, except in extreme cold or dry regions or areas that experienced these extreme conditions in the past (Sendra et al ., 2020b).…”

Section: Ecologymentioning

confidence: 99%

“…All diplurans inhabit soil and subsurface terrestrial habitats, extending from non-consolidated debris in soils to network of voids in the bedrock, including caves (Condé, 1956;Sendra et al, 2020b) (Fig. 3).…”

Section: Ecologymentioning

confidence: 99%

Diversity, ecology, distribution and biogeography of Diplura

Sendra

Jiménez‐Valverde

Selfa

et al. 2021

Insect Conserv Diversity

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Diplura is the sister group to insects and one of the three basal hexapod groups with unique entognathan mouthparts. The order is divided into 10 families, which include 1008 species in 141 genera, with a high proportion of monotypic genera. They are ubiquitous in soils and subsurface terrestrial habitats, as well as have an important role in overall biogeochemical cycles. We present the first comprehensive review of the global biodiversity and ecology of Diplura. We highlight four aspects of this basal hexapod group: diversity in morphological body plans and sizes; ecology in terrestrial environments from soil to caves; food preference and trophic levels, and their biogeographical and paleobiogeographical significance. Diplura depends on high humidity and moderate temperatures. They are presumably very sensitive to anthropogenic pressures and climate change, and therefore are a suitable model for ecophysiological studies and evident priority targets for conservation. We conclude that the future efforts should focus on establishing a molecular phylogeny to clarify the relationships between and within families, as well as to reveal global biogeographical patterns. This will require an increase in sampling effort in several regions of the globe, especially in tropical regions.

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Diplura in caves: diversity, ecology, evolution and biogeography

Cited by 15 publications

References 49 publications

Global distribution of microwhip scorpions (Arachnida: Palpigradi)

Global distribution of microwhip scorpions (Arachnida: Palpigradi)

Collecting eco‐evolutionary data in the dark: Impediments to subterranean research and how to overcome them

Diversity, ecology, distribution and biogeography of Diplura

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