Your search keyword '"Fabre, Pierre‐Henri"' showing total 6 results

1. Unilocus delimitation methods reveal the underestimated species diversity of Thomasomys (Rodentia, Cricetidae).

Author

Ruelas, Dennisse, Pacheco, Víctor, Pérez, José, Diaz‐Nieto, Juan, and Fabre, Pierre‐Henri

Subjects

CYTOCHROME b, SPECIES diversity, CRICETIDAE, PHYLOGENY, RODENTS, MOLECULAR phylogeny, PHYLOGEOGRAPHY

Abstract

Thomasomys is the most diverse genus of the Sigmodontinae subfamily, comprising at least 51 species. Despite recent systematic advances, the monophyly of this genus, the proposed species groups and their content, and the species limits are not yet firmly established. Using a well‐sampled mitochondrial dataset, we aim to test the monophyly of the genus, infer phylogenetic relationships among species and species groups and test the limits between valid species and candidate species. For this, we used a large matrix of 272 partial non‐redundant sequences of the cytochrome b mitochondrial gene from 40 valid and 20 candidate species. Using probabilistic approaches on this dataset, we inferred Thomasomys phylogenetic relationships and explored species boundaries using four unilocus species delimitation methods (ABGD, ASAP, bPTP and GMYC). Thomasomys sensu stricto was recovered monophyletic and well‐supported, excluding a Peruvian lineage misidentified as part of the genus. Analyses consistently recovered 10 well‐supported major clades and several paraphyletic or polyphyletic species. Delimitation methods and genetic divergences estimated that Thomasomys comprises between 81 and 93 putative species, thus potentially doubling the species diversity of Thomasomys. Such a result clearly calls for an urgent taxonomic revision of this genus and the use of further molecular loci within an integrative taxonomic approach to describe its diversity and understand its evolutionary history. [ABSTRACT FROM AUTHOR]

Published

2024

2. Of flippers and wings: The locomotor environment as a driver of the evolution of forelimb morphological diversity in mammals.

Author

Rothier, Priscila S., Fabre, Anne‐Claire, Benson, Roger B. J., Martinez, Quentin, Fabre, Pierre‐Henri, Hedrick, Brandon P., and Herrel, Anthony

Subjects

BODY fluids, MAMMAL diversity, WATER-pipes, FORELIMB, WATER use

Abstract

The early diversification of tetrapods into terrestrial environments involved adaptations of their locomotor apparatus that allowed for weight support and propulsion on heterogeneous surfaces. Many lineages subsequently returned to the water, while others conquered the aerial environment, further diversifying under the physical constraints of locomoting through continuous fluid media. While many studies have explored the relationship between locomotion in continuous fluids and body mass, none have focused on how continuous fluid media have impacted the macroevolutionary patterns of limb shape diversity.We investigated whether mammals that left terrestrial environments to use air and water as their main locomotor environment experienced constraints on the morphological evolution of their forelimb, assessing their degree of morphological disparity and convergence. We gathered a comprehensive sample of more than 800 species that cover the extant family‐level diversity of mammals, using linear measurements of the forelimb skeleton to determine its shape and size.Among mammals, fully aquatic groups have the most disparate forelimb shapes, possibly due to the many different functional roles performed by flippers or the relaxation of constraints on within‐flipper bone proportions. Air‐based locomotion, in contrast, is linked to restricted forelimb shape diversity. Bats and gliding mammals exhibit similar morphological patterns that have resulted in partial phenotypic convergence, mostly involving the elongation of the proximal forelimb segments.Thus, whereas aquatic locomotion drives forelimb shape diversification, aerial locomotion constrains forelimb diversity. These results demonstrate that locomotion in continuous fluid media can either facilitate or limit morphological diversity and more broadly that locomotor environments have fostered the morphological and functional evolution of mammalian forelimbs. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2024

3. A replacement name for the endemic Rattus (Muridae, Mammalia) of the island of Obi, Indonesia

Author

Fabre, Pierre-Henri, primary, Portela Miguez, Roberto, additional, Holden, Mary Ellen, additional, Fitriana, Yuli S., additional, Semiadi, Gono, additional, Musser, Guy G., additional, and Helgen, Kristofer M., additional

Published

2024

4. Springhares, flying and flightless scaly‐tailed squirrels (Anomaluromorpha, Rodentia) are the squirrely mouse: comparative anatomy of the masticatory musculature and its implications on the evolution of hystricomorphy in rodents.

Author

Da Cunha, Léa, Fabre, Pierre‐Henri, and Hautier, Lionel

Subjects

*COMPARATIVE anatomy, *RODENTS, *JAWS, *MICE, *SQUIRRELS

Abstract

Anomaluromorpha is a particularly puzzling suborder of Rodentia. Endemic to Africa, this clade includes the extant genera Idiurus, Anomalurus, Zenkerella, and Pedetes. These rodents present an hystricomorphous condition of the skull, characterized by a large infraorbital foramen, which evolved independently within the mouse‐related clade over a span of approximately 57 million years. They exhibit a high disparity in craniomandibular and dental morphology that has kept their phylogenetic affinities disputed for a long time. Given the past significance of masticatory morphotypes in establishing the classification of Rodentia, we propose to explore variations in the masticatory apparatus of Anomaluromorpha in order to evaluate whether its related features can offer additional data for systematics and contribute to our understanding of the complexity of hystricomorphy. In order to do so, we used traditional dissection and diffusible iodine‐based contrast‐enhanced computed tomography (diceCT) to accurately describe and compare the anatomy of the specimens. We found that the muscle morphology displays clear differentiation among each anomaluromorph taxonomic unit. Specifically, the masseteric complex of Anomaluromorpha exhibits distinctive synapomorphies such as the infraorbital part of the zygomaticomandibularis muscle being separated into a rostral and orbital part and an absence of a posterior part of the zygomaticomandibularis. Additionally, the orbital portion of the infraorbital part originates from a well‐marked ridge and fossa at the level of its area of origin on the anteromedial wall of the orbital cavity, a feature that is absent in other members of the mouse‐related clade. This evident bony feature, among others, is strongly associated with muscular anatomy and can contribute to ascertaining the taxonomic status of extinct representatives of the clade. Finally, we showed that the hystricomorphy of Anomaluromorpha largely differs from those of Ctenohystrica and Dipodoidea and that the definition of this morphotype is complex and cannot be reduced simply to the size of the opening of the infraorbital foramen. [ABSTRACT FROM AUTHOR]

Published

2024

5. Turbinal bones are still one of the last frontiers of the tetrapod skull: hypotheses, challenges and perspectives.

Author

Martinez, Quentin, Amson, Eli, Ruf, Irina, Smith, Timothy D., Pirot, Nelly, Broyon, Morgane, Lebrun, Renaud, Captier, Guillaume, Gascó Martín, Cristina, Ferreira, Gabriel, and Fabre, Pierre‐Henri

Subjects

*COMPARATIVE anatomy, *NASAL cavity, *SMELL, *TETRAPODS, *PHYSIOLOGY

Abstract

ABSTRACT Turbinals are bony or cartilaginous structures that are present in the nasal cavity of most tetrapods. They are involved in key functions such as olfaction, heat, and moisture conservation, as well as protection of the respiratory tract. Despite recent studies that challenged long‐standing hypotheses about their physiological and genomic correlation, turbinals remain largely unexplored, particularly for non‐mammalian species. Herein, we review and synthesise the current knowledge of turbinals using an integrative approach that includes comparative anatomy, physiology, histology and genomics. In addition, we provide synonyms and correspondences of tetrapod turbinals from about 80 publications. This work represents a first step towards drawing hypotheses of homology for the whole clade, and provides a strong basis to develop new research avenues. [ABSTRACT FROM AUTHOR]

Published

2024

6. Disparity of turbinal bones in placental mammals.

Author

Martinez Q, Wright M, Dubourguier B, Ito K, van de Kamp T, Hamann E, Zuber M, Ferreira G, Blanc R, Fabre PH, Hautier L, and Amson E

Abstract

Turbinals are key bony elements of the mammalian nasal cavity, involved in heat and moisture conservation as well as olfaction. While turbinals are well known in some groups, their diversity is poorly understood at the scale of placental mammals, which span 21 orders. Here, we investigated the turbinal bones and associated lamellae for one representative of each extant order of placental mammals. We segmented and isolated each independent turbinal and lamella and found an important diversity of variation in the number of turbinals, as well as their size, and shape. We found that the turbinal count varies widely, from zero in the La Plata dolphin, (Pontoporia blainvillei) to about 110 in the African bush elephant (Loxodonta africana). Multiple turbinal losses and additional gains took place along the phylogeny of placental mammals. Some changes are clearly attributed to ecological adaptation, while others are probably related to phylogenetic inertia. In addition, this work highlights the problem of turbinal nomenclature in some placental orders with numerous and highly complex turbinals, for which homologies are extremely difficult to resolve. Therefore, this work underscores the importance of developmental studies to better clarify turbinal homology and nomenclature and provides a standardized comparative framework for further research., (© 2024 The Author(s). The Anatomical Record published by Wiley Periodicals LLC on behalf of American Association for Anatomy.)

Published

2024