Evolution in caves: Darwin’s ‘wrecks of ancient life’ in the molecular era

Juan, Carlos; Guzik, Michelle T.; Jaume, Damià; Cooper, Steven J.

doi:10.1111/j.1365-294x.2010.04759.x

Cited by 186 publications

(171 citation statements)

References 139 publications

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“…These experts used their prior knowledge to assign likely species. (4) Molecular data have proven a major innovation in delineation of new species, both cryptic and otherwise (Juan et al 2010). Hence, in situations in which it was uncertain whether there were distinct species present, genetic methods were used to estimate 'known' but undescribed species from recent collections and molecular studies.…”

Section: Methodology For Estimating Subterranean Faunal Diversitymentioning

confidence: 99%

“…Colonisation of these habitats by multiple unrelated surface species has also contributed to the high levels of diversity (Leys et al 2003;Cooper et al 2008;Guzik et al 2008). Further, in situ speciation within aquifers is also considered a plausible source of species diversity, particularly in the Yilgarn (Guzik et al 2009;Juan et al 2010) and Pilbara (Finston et al 2009). Abiotic heterogeneity within habitats (i.e.…”

Section: The Predicted Origins Of This Diversitymentioning

confidence: 99%

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VIEWPOINT. Is the Australian subterranean fauna uniquely diverse?

Guzik

Austin

Cooper

et al. 2010

Invert. Systematics

Self Cite

107

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Abstract. Australia was historically considered a poor prospect for subterranean fauna but, in reality, the continent holds a great variety of subterranean habitats, with associated faunas, found both in karst and non-karst environments. This paper critically examines the diversity of subterranean fauna in several key regions for the mostly arid western half of Australia. We aimed to document levels of species richness for major taxon groups and examine the degree of uniqueness of the fauna. We also wanted to compare the composition of these ecosystems, and their origins, with other regions of subterranean diversity world-wide. Using information on the number of 'described' and 'known' invertebrate species (recognised based on morphological and/or molecular data), we predict that the total subterranean fauna for the western half of the continent is 4140 species, of which~10% is described and 9% is 'known' but not yet described. The stygofauna, water beetles, ostracods and copepods have the largest number of described species, while arachnids dominate the described troglofauna. Conversely, copepods, water beetles and isopods are the poorest known groups with less than 20% described species, while hexapods (comprising mostly Collembola, Coleoptera, Blattodea and Hemiptera) are the least known of the troglofauna. Compared with other regions of the world, we consider the Australian subterranean fauna to be unique in its diversity compared with the northern hemisphere for three key reasons: the range and diversity of subterranean habitats is both extensive and novel; direct faunal links to ancient Pangaea and Gondwana are evident, emphasising their early biogeographic history; and Miocene aridification, rather than Pleistocene post-ice age driven diversification events

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Section: Methodology For Estimating Subterranean Faunal Diversitymentioning

confidence: 99%

Section: The Predicted Origins Of This Diversitymentioning

confidence: 99%

VIEWPOINT. Is the Australian subterranean fauna uniquely diverse?

Guzik

Austin

Cooper

et al. 2010

Invert. Systematics

Self Cite

107

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“…In some caves of volcanic origin, hydrogen sulphide can reach concentrations of > 300 μM (Riesch et al 2010). These habitats host a unique fauna (Iliffe and Kornicker 2009;Juan et al 2010) and because they represent independent evolutionary trajectories of adaptations to similar conditions, similar to islands for the terrestrial environment, they are considered one of the most important habitats to study marine island biogeography (Dawson 2016).…”

Section: Submarine Cavesmentioning

confidence: 99%

Characteristics of meiofauna in extreme marine ecosystems: a review

et al. 2017

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Extreme marine environments cover more than 50% of the Earth's surface and offer many opportunities for investigating the biological responses and adaptations of organisms to stressful life conditions. Extreme marine environments are sometimes associated with ephemeral and unstable ecosystems, but can host abundant, often endemic and welladapted meiofaunal species. In this review, we present an integrated view of the biodiversity, ecology and physiological responses of marine meiofauna inhabiting several extreme marine environments (mangroves, submarine caves, Polar ecosystems, hypersaline areas, hypoxic/anoxic environments, hydrothermal vents, cold seeps, carcasses/sunken woods, deep-sea canyons, deep hypersaline anoxic basins [DHABs] and hadal zones). Foraminiferans, nematodes and copepods are abundant in almost all of these habitats and are dominant in deep-sea ecosystems. The presence and dominance of some other taxa that are normally less common may be typical of certain extreme conditions. Kinorhynchs are particularly well adapted to cold seeps and other environments that experience drastic changes in salinity, rotifers are well represented in polar ecosystems and loriciferans seem to be the only metazoan able to survive multiple stressors in DHABs. As well as natural processes, human activities may generate stressful conditions, including deoxygenation, acidification and rises in temperature. The behaviour and physiology of different meiofaunal taxa, such as some foraminiferans, nematode and copepod species, can provide vital information on how organisms may respond to these challenges and can provide a warning signal of anthropogenic impacts. From an evolutionary perspective, the discovery of new meiofauna taxa from extreme environments very often sheds light on phylogenetic relationships, while understanding how meiofaunal organisms are able to survive or even flourish in these conditions can explain evolutionary pathways. Finally, there are multiple potential economic benefits to be gained from ecological, biological, physiological and evolutionary studies of meiofauna in extreme environments. Despite all the advantages offered by meiofauna studies from extreme environments, there is still an urgent need to foster meiofauna research in terms of composition, ecology, biology and physiology focusing on extreme environments.

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“…It also has reduced eyes, and a less pigmented body than other Aphaenogaster species. Loss of wings, reduction of eyes, elongation of antennae and legs, and loss of pigmentation are commonly observed in troglobiotic arthropods (Vandel 1964, Christiansen 1965, Culver 1982, Marques & Gnaspini 2001Juan et al 2010). It is unclear whether A. gamagumayaa displays any wing loss/reduction in the queen and male, as during the course of the study only workers were found.…”

Section: Discussionmentioning

confidence: 86%

Aphaenogaster gamagumayaa sp. nov.: the first troglobiotic ant from Japan (Hymenoptera: Formicidae: Myrmicinae)

Naka

Maruyama

2018

Zootaxa

591

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Aphaenogaster gamagumayaa sp. nov., a new troglobiotic (true cave-dwelling) ant species, from a limestone cave on the island of Okinawa (Okinawa-jima), Ryukyu Archipelago, Japan is described. This is the first discovery of a troglobiotic ant in Japan and the second verified record worldwide. This species has only been found in a cave area with heavy guano deposits, and some worker ants were observed carrying guano. The evidence for categorizing this new species as troglobiont is discussed.

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Evolution in caves: Darwin’s ‘wrecks of ancient life’ in the molecular era

Cited by 186 publications

References 139 publications

VIEWPOINT. Is the Australian subterranean fauna uniquely diverse?

VIEWPOINT. Is the Australian subterranean fauna uniquely diverse?

Characteristics of meiofauna in extreme marine ecosystems: a review

Aphaenogaster gamagumayaa sp. nov.: the first troglobiotic ant from Japan (Hymenoptera: Formicidae: Myrmicinae)

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