Investigating the distribution of a unique crustacean microendemic to tree hollows

Water-filled tree hollows constitute phytotelmata that harbor specialized organisms. One striking example of extreme adaptation to these microhabitats is the case of the microcrustacean Micromoina arboricola , which has been found inhabiting the hollow of a single tree individual in the Atlantic For...

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Bibliographic Details
Published in:Die Naturwissenschaften 2024-12, Vol.111 (6), p.54, Article 54
Main Authors: Raiary, Bruna, Ribeiro, Carolina, Lima, Débora, Afeitos, Arthur, Mendonça, Thais, Cárdenas, Valéria, Magalhães, André, de Azevedo, Cristiano Schetini, Cassino, Raquel, Antonini, Yasmine, Cardoso, João C. F.
Format: Article
Language:English
Subjects:
Animal Distribution
Animals
Biomedical and Life Sciences
Brazil
Crustacea - classification
Crustacea - physiology
Crustaceans
Dispersal
Ecological function
Ecology
Ecosystem
Environment
Environmental changes
Forest management
Forests
Geographical distribution
Habitats
Harbors
Life Sciences
Microenvironments
Microhabitats
Original Article
Pattern analysis
Population Density
Spatial analysis
Spatial distribution
Trees
Wildlife conservation
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Summary:Water-filled tree hollows constitute phytotelmata that harbor specialized organisms. One striking example of extreme adaptation to these microhabitats is the case of the microcrustacean Micromoina arboricola , which has been found inhabiting the hollow of a single tree individual in the Atlantic Forest. We investigated the spatial distribution and influence of microhabitat characteristics such as hollow volume and height from the ground in the occurrence of M. arboricola . We surveyed all the trunks present in ca. 5000 m 2 of an Atlantic old-growth forest area. We found M. arboricola individuals in 75% of the hollows, thus expanding the known distribution of the species. Spatial analysis suggested a clustered pattern of population densities across hollows, indicating that the dispersal capacity to new microhabitat patches may vary in space. Although we did not find an effect of hollow volume, population density was negatively related to hollow height. This suggests that more restrictive abiotic conditions at greater heights limit the occurrence of the species, emphasizing its vulnerability to environmental changes. Hollow-mediated ecosystem engineering depends on the occasional formation of cavities that require time and ancient trees. Preserving old forests with hollows under varying conditions tends to maintain ecosystem functionality and the conservation of this unique microendemic species.
ISSN:0028-1042
1432-1904
1432-1904
DOI:10.1007/s00114-024-01943-3