Functional Evolution of the Feeding System in Rodents

Cox, Philip G.; Rayfield, Emily J.; Fagan, Michael J.; Herrel, Anthony; Pataky, Todd C.; Jeffery, Nathan

doi:10.1371/journal.pone.0036299

Cited by 171 publications

(254 citation statements)

References 48 publications

Supporting

Mentioning

238

Contrasting

Unclassified

Order By: Relevance

“…The adaptive diversity that characterizes the evolution of Ctenohystrica, and particularly the Caviomorpha, a group that dispersed from Africa to colonise South America (Poux et al, 2006;Rowe et al, 2010) and evolved on that continent during a period of splendid isolation in the Cenozoic, has been the subject of numerous morphofunctional and evolutionary studies (e.g. Verzi et al, 2010;Á lvarez et al, 2011a, b;Hautier et al, 2011Hautier et al, , 2012Cox et al, 2012;Geiger et al, 2013;.…”

Section: Introductionmentioning

confidence: 99%

Diversity and evolution of femoral variation in Ctenohystrica

Wilson

Geiger

Cox³

et al. 2015

Evolution of the Rodents

View full text Add to dashboard Cite

Despite possessing a rather generalised postcranial skeleton, rodents are on average capable of a wide variety of locomotory behaviours, such as swimming, digging and climbing (Nowak, 1999). Particularly, rodents belonging to Ctenohystrica (sensu Huchon et al., 2002, andFabre et al., 2012: Ctenodactylidae, Diatomyidae and Hystricognathi) display a diversity of locomotory styles and encompass a large range in body mass from approximately 50 g for the naked mole-rat Heterocephalus glaber to around 60 kg for the largest living rodent, the capybara Hydrochoerus hydrochaeris, consequently filling many different ecological niches (e.g. MacDonald, 2009; Sánchez-Villagra, 2009, 2010). Moreover, this diversity is greatly expanded by the inclusion of giant extinct members such as Phoberomys, Arazamys and Josephoartigasia that reached body masses at least seven or eight times that of the capybara (Sánchez-Villagra et al., 2003;Rinderknecht and Blanco, 2008;Rinderknecht and Bostelmann, 2011). The adaptive diversity that characterises the evolution of Ctenohystrica, and particularly the Caviomorpha, a group that dispersed from Africa to colonise South America (Poux et al., 2006;Rowe et al., 2010) and evolved on that continent during a period of splendid isolation in the Cenozoic, has been the subject of numerous morpho-functional and evolutionary studies (e.g. Verzi et al., 2010; Ál-varez et al., 2011a, b;Hautier et al., 2011Hautier et al., , 2012Cox et al., 2012;Geiger et al., 2013;. The interplay between form and function has been studied in the postcranial skeleton of a number of mammals (e.g. Kappelman, 19;Anemone, 1990;White, 1993;Vizcaíno and Milne, 2002;Kley and Kearney, 2007;Meachen-Samuels, 2010), and studies of Ctenohystrica have, for example, examined individual bones (e.g. Seckel and Janis, 2008;Morgan, 2009;Steiner-Souza et al., 2010;Elissamburu and De Santis, 2011), long bones (Biknevicius, 1993; Elissamburu and Vizcaino, 2004;Samuels and Van Valkenburgh, 2008; Morgan and Álvarez, 2013) and the autopodial skeleton (e.g. Weisbecker and Schmid, 2007;Morgan and Verzi, 2011). These studies have used morphological traits, described as ratios or quantified using biomechanical indices or geometric morphometric descriptors of shape, to identify functional specialisations and instances of adaptive convergence underpinned by shared function and/or ecology. The widespread use of mouse models in developmental, behavioural and genetic studies has sparked wider interest in rodent biology as a whole. This book brings together the latest research on rodents to better understand the evolution of both living and extinct members of this fascinating group.Topics analysed include the role of molecular techniques in the determination of robust phylogenetic framework; how geometric morphometric methods help quantify and analyse variation in shape; and the role of developmental biology in elucidating the origins of skeletal elements and the teeth. The editors unite these disciplines to present the current state of knowledg...

show abstract

Section: Introductionmentioning

confidence: 99%

Diversity and evolution of femoral variation in Ctenohystrica

Wilson

Geiger

Cox³

et al. 2015

Evolution of the Rodents

View full text Add to dashboard Cite

show abstract

“…Some studies have pointed out the existence of a close relationship between feeding habits and skulls or mandibles morphology using classical and geometric morphometric tools for quantification of shapes Renaud et al, 2007;Samuels, 2009;Cox et al, 2012;Hautier et al, 2012). As the masticatory behaviors are important in evaluating biomechanical properties, we predicted that aspects of mandibular shape, as revealed in the principal components analysis, would separate C. gambianus and T. swinderianus.…”

mentioning

confidence: 92%

Comparación de la morfología geométrica de la mandíbula de dos roedores africanos, Thryonomys swinderianus y Cricetomys gambianus (Rodentia: Thryonomyidae y Nesomyidae)

Samuel

Casanova

Olopade

2016

URJ

View full text Add to dashboard Cite

La rata gigante africana (Cricetomys gambianus) y la rata de caña africana (Thryonomys swinderianus) tienen conformación corporal similar y biomas similares. Este estudio tuvo como objetivo comparar los parámetros mandibulares en adultos de ambas especies. Para ello usamos 9 puntos de referencia mandibulares laterales en machos de T. swinderianus (n = 11) y C. gambianus (n = 12) analizándolos mediante morfometría geométrica. T. swinderianus presentó un coronoides equivalente al cóndilo y un proceso angular desplazado más caudal, mientras que los dientes de mejilla son menos prominentes y más cortos en C. gambianus. Este estudio puede ser útil para resolver ambigüedades filogenéticas, vigilancia de fauna y control con la edad de la población, formulación de raciones de especies en cautiverio, y eco- migración. Creemos que esta es la primera vez en que la comparación mandibular de estos roedores permite inferir preferencias ecológicas en la dieta con base en la forma de la mandíbula

show abstract

“…These specializations, plus a small number of cheek teeth used for chewing, are associated with a specialized musculature (Schumacher, 1961). To cope with the demands imposed by such an unusual dentition and propaliny (e.g., the mandible can be moved fore and aft) (Cox et al, 2012), the masticatory musculature of rodents has become highly specialized. The masseter is the dominant jaw-closing muscle, forming between 60% and 80% of the masticatory musculature (Sisson et al, 1982), and is divided into three layers in rodents: the musculus masseter (with a pars superficialis and a pars profunda) and the musculus zygomaticomandibularis (sometimes termed the medial masseter).…”

Section: Introductionmentioning

confidence: 99%

Mandibular allometry in Hydrochoerus hydrochaeris (Linnaeus, 1766) (Hydrocherinae, Caviidae)

Casanova

2017

Pap. Avulsos Zool.

View full text Add to dashboard Cite

The mammalian masticatory apparatus is a highly plastic region of the skull and thus subjected to singular ontogenetic trajectories. Here we present the first descriptive allometric pattern study of mandible among the capybara (Hydrochoerus hydrochaeris), based on the study of 37 specimens. Allometric changes in shape were analyzed using geometric morphometrics techniques and the pattern of allometry was visualized. A multivariate regression of the shape component on size, estimated by the logarithm of centroid size, appeared as highly significant. Therefore, a major component of shape variation in these mandibles is related to the attainment of adult size (i.e., growth).

show abstract

Functional Evolution of the Feeding System in Rodents

Cited by 171 publications

References 48 publications

Diversity and evolution of femoral variation in Ctenohystrica

Diversity and evolution of femoral variation in Ctenohystrica

Comparación de la morfología geométrica de la mandíbula de dos roedores africanos, Thryonomys swinderianus y Cricetomys gambianus (Rodentia: Thryonomyidae y Nesomyidae)

Mandibular allometry in Hydrochoerus hydrochaeris (Linnaeus, 1766) (Hydrocherinae, Caviidae)

Contact Info

Product

Resources

About