Your search keyword '"Balart-García P"' showing total 8 results

1. Parallel and convergent genomic changes underlie independent subterranean colonization across beetles

Author

Balart-García, Pau, Aristide, Leandro, Bradford, Tessa M., Beasley-Hall, Perry G., Polak, Slavko, Cooper, Steven J. B., and Fernández, Rosa

Published

2023

2. Loss of heat acclimation capacity could leave subterranean specialists highly sensitive to climate change

Author

Pallarés, S., primary, Colado, R., additional, Botella‐Cruz, M., additional, Montes, A., additional, Balart‐García, P., additional, Bilton, D. T., additional, Millán, A., additional, Ribera, I., additional, and Sánchez‐Fernández, D., additional

Published

2020

3. Loss of heat acclimation capacity could leave subterranean specialists highly sensitive to climate change.

Author

Pallarés, S., Colado, R., Botella‐Cruz, M., Montes, A., Balart‐García, P., Bilton, D. T., Millán, A., Ribera, I., and Sánchez‐Fernández, D.

Subjects

ACCLIMATIZATION, CLIMATE change, HEAT capacity, HEAT losses, THERMAL stresses, ECOLOGICAL niche

Abstract

Physiological traits are key in determining the vulnerability of narrow range, highly specialized animals to climate change. It is generally predicted that species from more stable environments possess lower thermal tolerance breadths and thermal plasticity than those from more variable habitats – the so‐called 'climatic variability hypothesis'. However, evolutionary trade‐offs between thermal breadth and its plasticity are also seen in some taxa, and the evolution of thermal physiology remains poorly understood. Subterranean environments are excellent systems for exploring these issues, being characterized by stable climatic conditions, with environmental variability increasing predictably from deep to shallow habitats. Acclimation capacity will be fundamental in determining the sensitivity of subterranean species to climate change, since they have poor dispersal capacity and limited possibility to exploit thermally different microhabitats in the uniform cave environment. We assessed critical thermal maximum (CTmax) and short‐term heat acclimation capacity in three related beetles (Leiodidae: Leptodirini) with differing degrees of specialization to the subterranean environment (deep, shallow and facultatively subterranean, respectively) and therefore exposed to contrasting thermal variability in nature. Only the facultative subterranean species showed any acclimatory capacity, also having the highest CTmax across the taxa studied. However, this species might experience the highest thermal stress in its habitat under climate change. The studied subterranean specialists will be poorly able to cope physiologically with temperature increase, but in contrast exposed to lower magnitude and rate of warming. Our results fit the climatic variability hypothesis, suggesting that adaptation to cave conditions has selected against the retention of acclimation mechanisms. We show that the pathways that determine vulnerability of subterranean species to climate change depend on their degree of specialization to deep subterranean environments. This information, combined with evaluation of exposure to climatic changes at their present locations, is fundamental in identifying species or populations at greatest risk. [ABSTRACT FROM AUTHOR]

Published

2021

4. A remarkable new genus of Iberian troglobitic Trechodina (Coleoptera: Carabidae: Trechinae: Trechini), with a revisited molecular phylogeny of the subtribe

Author

Faille, Arnaud, Balart-García, Pau, Fresneda, Javier, Bourdeau, Charles, and Ribera, Ignacio

Abstract

SummaryA new representative of the subtribe Trechodina, Iberotrechodes spinosusn. gen., n. sp., subterranean and known so far from a single cave system of the Cantabrian chain (NW Spain), is described. The external morphology of the new species is highly derived within Trechodina, in particular for the peculiar and unique shape of its elytra, and likely due in part to its subterranean habits. A phylogenetic analysis based on six nuclear and mitochondrial genes placed it unambiguously within the subtribe Trechodina of Trechinae, as sister to all extent species of Trechodesplus Sporades, distributed in Africa, Madagascar, Asia, New Caledonia and Australia. Using a Bayesian molecular clock approach we estimated the separation of Iberotrechodesn. gen. and its sister clade to have occurred in the early Paleocene, at ca. 61 Ma. The biogeographic implications of this discovery are discussed in the context of the unusual abundance of phylogenetically and geographically isolated species of subterranean Carabidae in the Iberian peninsula. Finally, new phylogenetic relationships are highlighted within Trechodina, such as the sister-group relationship between the genera Pachytrechodes(Tanzania) and Himalotrechodes(Nepal), and the African origin of the genus Amblystogenium(Crozet Islands).

Published

2021

5. Highly dynamic evolution of the chemosensory system driven by gene gain and loss across subterranean beetles.

Author

Balart-García P, Bradford TM, Beasley-Hall PG, Polak S, Cooper SJB, and Fernández R

Subjects

Animals, Phylogeny, Ecosystem, Insecta, Caves, Coleoptera genetics

Abstract

Chemical cues in subterranean habitats differ highly from those on the surface due to the contrasting environmental conditions, such as absolute darkness, high humidity or food scarcity. Subterranean animals underwent changes to their sensory systems to facilitate the perception of essential stimuli for underground lifestyles. Despite representing unique systems to understand biological adaptation, the genomic basis of chemosensation across cave-dwelling species remains unexplored from a macroevolutionary perspective. Here, we explore the evolution of chemoreception in three beetle tribes that underwent at least six independent transitions to the underground, through a phylogenomics spyglass. Our findings suggest that the chemosensory gene repertoire varies dramatically between species. Overall, no parallel changes in the net rate of evolution of chemosensory gene families were detected prior, during, or after the habitat shift among subterranean lineages. Contrarily, we found evidence of lineage-specific changes within surface and subterranean lineages. However, our results reveal key duplications and losses shared between some of the lineages transitioning to the underground, including the loss of sugar receptors and gene duplications of the highly conserved ionotropic receptors IR25a and IR8a, involved in thermal and humidity sensing among other olfactory roles in insects. These duplications were detected both in independent subterranean lineages and their surface relatives, suggesting parallel evolution of these genes across lineages giving rise to cave-dwelling species. Overall, our results shed light on the genomic basis of chemoreception in subterranean beetles and contribute to our understanding of the genomic underpinnings of adaptation to the subterranean lifestyle at a macroevolutionary scale., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

6. Parallel duplication and loss of aquaporin-coding genes during the "out of the sea" transition as potential key drivers of animal terrestrialization.

Author

Martínez-Redondo GI, Simón Guerrero C, Aristide L, Balart-García P, Tonzo V, and Fernández R

Subjects

Animals, Phylogeny, Ecosystem, Water, Biological Evolution, Aquaporins genetics, Arthropods

Abstract

One of the most important physiological challenges animals had to overcome during terrestrialization (i.e., the transition from sea to land) was water loss, which alters their osmotic and hydric homeostasis. Aquaporins are a superfamily of membrane water transporters heavily involved in osmoregulatory processes. Their diversity and evolutionary dynamics in most animal lineages remain unknown, hampering our understanding of their role in marine-terrestrial transitions. Here, we interrogated aquaporin gene repertoire evolution across the main terrestrial animal lineages. We annotated aquaporin-coding genes in genomic data from 458 species from seven animal phyla where terrestrialization episodes occurred. We then explored aquaporin gene evolutionary dynamics to assess differences between terrestrial and aquatic species through phylogenomics and phylogenetic comparative methods. Our results revealed parallel aquaporin-coding gene duplications during the ecological transition from marine to nonmarine environments (e.g., brackish, freshwater and terrestrial), rather than from aquatic to terrestrial ones, with some notable duplications in ancient lineages. In contrast, we also recovered a significantly lower number of superaquaporin genes in terrestrial arthropods, suggesting that more efficient oxygen homeostasis in land arthropods might be linked to a reduction in this type of aquaporin. Our results thus indicate that aquaporin-coding gene duplication and loss might have been one of the key steps towards the evolution of osmoregulation across animals, facilitating the "out of the sea" transition and ultimately the colonization of land., (© 2023 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2023

7. Smelling in the dark: Phylogenomic insights into the chemosensory system of a subterranean beetle.

Author

Balart-García P, Cieslak A, Escuer P, Rozas J, Ribera I, and Fernández R

Subjects

Animals, Caves, Gene Expression Profiling, Genomics, Insect Proteins genetics, Insect Proteins metabolism, Phylogeny, Transcriptome, Coleoptera genetics, Receptors, Odorant genetics

Abstract

The chemosensory system has experienced relevant changes in subterranean animals, facilitating the perception of specific chemical signals critical to survival in their particular environment. However, the genomic basis of chemoreception in cave-dwelling fauna has been largely unexplored. We generated de novo transcriptomes for antennae and body samples of the troglobitic beetle Speonomus longicornis (whose characters suggest an extreme adaptation to a deep subterranean environment) in order to investigate the evolutionary origin and diversification of the chemosensory gene repertoire across coleopterans through a phylogenomic approach. Our results suggested a diminished diversity of odourant and gustatory gene repertoires compared to polyphagous beetles that inhabit surface habitats. Moreover, S. longicornis showed a large diversity of odourant-binding proteins, suggesting an important role of these proteins in capturing airborne chemical cues. We identified a gene duplication of the ionotropic coreceptor IR25a, a highly conserved single-copy gene in protostomes involved in thermal and humidity sensing. In addition, no homologous genes to sugar receptors or the ionotropic receptor IR41a were detected. Our findings suggest that the chemosensory gene repertoire of this cave beetle may result from adaptation to the highly specific ecological niche it occupies, and that gene duplication and loss may have played an important role in the evolution of gene families involved in chemoreception. Altogether, our results shed light on the genomic basis of chemoreception in a cave-dwelling invertebrate and pave the road towards understanding the genomic underpinnings of adaptation to the subterranean lifestyle at a deeper level., (© 2021 John Wiley & Sons Ltd.)

Published

2021

8. Beyond survival experiments: using biomarkers of oxidative stress and neurotoxicity to assess vulnerability of subterranean fauna to climate change.

Author

Pallarés S, Sanchez-Hernandez JC, Colado R, Balart-García P, Comas J, and Sánchez-Fernández D

Abstract

Accurate assessments of species vulnerability to climate change need to consider the physiological capacity of organisms to deal with temperature changes and identify early signs of thermally induced stress. Oxidative stress biomarkers and acetylcholinesterase activity are useful proxies of stress at the cellular and nervous system level. Such responses are especially relevant for poor dispersal organisms with limited capacity for behavioural thermoregulation, like deep subterranean species. We combined experimental measurements of upper lethal thermal limits, acclimation capacity and biomarkers of oxidative stress and neurotoxicity to assess the impact of heat stress (20°C) at different exposure times (2 and 7 days) on the Iberian endemic subterranean beetle Parvospeonomus canyellesi . Survival response (7 days of exposure) was similar to that reported for other subterranean specialist beetles (high survival up to 20°C but no above 23°C). However, a low physiological plasticity (i.e. incapacity to increase heat tolerance via acclimation) and signs of impairment at the cellular and nervous system level were observed after 7 days of exposure at 20°C. Such sublethal effects were identified by significant differences in total antioxidant capacity, glutathione S-transferase activity, the ratio of reduced to oxidized forms of glutathione and acetylcholinesterase activity between the control (cave temperature) and 20°C treatment. At 2 days of exposure, most biomarker values indicated some degree of oxidative stress in both the control and high-temperature treatment, likely reflecting an initial altered physiological status associated to factors other than temperature. Considering these integrated responses and the predicted increase in temperature in its unique locality, P. canyellesi would have a narrower thermal safety margin to face climate change than that obtained considering only survival experiments. Our results highlight the importance of exploring thermally sensitive processes at different levels of biological organization to obtain more accurate estimates of the species capacity to face climate change., (© The Author(s) 2020. Published by Oxford University Press and the Society for Experimental Biology.)

Published

2020