The evolution of micro-cursoriality in mammals

Lovegrove, Barry G.; Mowoe, Metoboroghene Oluwaseyi

doi:10.1242/jeb.095737

Cited by 25 publications

(33 citation statements)

References 80 publications

(136 reference statements)

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“…Elephant shrews ( Elephantulus spp. , Macroscelidae) would provide the most informative comparison, as they are the only identified group of micro-cursorial quadrupedal mammals [48]. Evidence of thinner tendons than expected by geometric similarity in elephant shrew hindlimbs would suggest that animals of small size may not be constrained to have stiff tendons with low elastic energy storage.…”

Section: Discussionmentioning

confidence: 99%

Vertical leaping mechanics of the Lesser Egyptian Jerboa reveal specialization for maneuverability rather than elastic energy storage

2017

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BackgroundNumerous historical descriptions of the Lesser Egyptian jerboa, Jaculus jaculus, a small bipedal mammal with elongate hindlimbs, make special note of their extraordinary leaping ability. We observed jerboa locomotion in a laboratory setting and performed inverse dynamics analysis to understand how this small rodent generates such impressive leaps. We combined kinematic data from video, kinetic data from a force platform, and morphometric data from dissections to calculate the relative contributions of each hindlimb muscle and tendon to the total movement.ResultsJerboas leapt in excess of 10 times their hip height. At the maximum recorded leap height (not the maximum observed leap height), peak moments for metatarso-phalangeal, ankle, knee, and hip joints were 13.1, 58.4, 65.1, and 66.9 Nmm, respectively. Muscles acting at the ankle joint contributed the most work (mean 231.6 mJ / kg Body Mass) to produce the energy of vertical leaping, while muscles acting at the metatarso-phalangeal joint produced the most stress (peak 317.1 kPa). The plantaris, digital flexors, and gastrocnemius tendons encountered peak stresses of 25.6, 19.1, and 6.0 MPa, respectively, transmitting the forces of their corresponding muscles (peak force 3.3, 2.0, and 3.8 N, respectively). Notably, we found that the mean elastic energy recovered in the primary tendons of both hindlimbs comprised on average only 4.4% of the energy of the associated leap.ConclusionsThe limited use of tendon elastic energy storage in the jerboa parallels the morphologically similar heteromyid kangaroo rat, Dipodomys spectabilis. When compared to larger saltatory kangaroos and wallabies that sustain hopping over longer periods of time, these small saltatory rodents store and recover less elastic strain energy in their tendons. The large contribution of muscle work, rather than elastic strain energy, to the vertical leap suggests that the fitness benefit of rapid acceleration for predator avoidance dominated over the need to enhance locomotor economy in the evolutionary history of jerboas.Electronic supplementary materialThe online version of this article (doi:10.1186/s12983-017-0215-z) contains supplementary material, which is available to authorized users.

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Section: Discussionmentioning

confidence: 99%

Vertical leaping mechanics of the Lesser Egyptian Jerboa reveal specialization for maneuverability rather than elastic energy storage

2017

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“…Optimum body mass for speed is denoted by the peak of each curvilinear relationship. Original data reported in [40,46–51]. (B) Frequency distribution for the body masses of extant running mammals [52] ( n = 2,919; yellow bars) and extinct dinosaur species [1] ( n = 406; red bars) shown with the relationship of optimum mass for speed in nonfelid mammals.…”

Section: Speeds Get Slowermentioning

confidence: 99%

Where Have All the Giants Gone? How Animals Deal with the Problem of Size

Dick

Clemente

2017

PLoS Biol

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The survival of both the hunter and the hunted often comes down to speed. Yet how fast an animal can run is intricately linked to its size, such that the fastest animals are not the biggest nor the smallest. The ability to maintain high speeds is dependent on the body’s capacity to withstand the high stresses involved with locomotion. Yet even when standing still, scaling principles would suggest that the mechanical stress an animal feels will increase in greater demand than its body can support. So if big animals want to be fast, they must find solutions to overcome these high stresses. This article explores the ways in which extant animals mitigate size-related increases in musculoskeletal stress in an effort to help understand where all the giants have gone.

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“…We used instantaneous sampling of focal animals at 10-min intervals, where an individual is followed continuously to record the locations of sengis during our observation periods (Martin & Bateson, 2007). As the fast, cursorial movement of sengis allows them to move across their home range within minutes (Lovegrove & Mowoe, 2014), a 10-min interval between successive locations is adequate to avoid statistical autocorrelation (Otis & White, 1999;Schubert, Schradin, Rödel, Pillay, & Ribble, 2009). This was validated by conducting a 48-hr continuous observation of one male and one female during BS14.…”

Section: Radio Trackingmentioning

confidence: 99%

Space use and the evolution of social monogamy in eastern rock sengis

et al. 2019

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Limiting resources often differ between males and females. Reproductive success in females is constrained by resources such as food and shelter, while the availability of receptive females determines male reproductive success. In addition to limiting resources, low intra‐sexual tolerances among females can affect their spacing. High intolerances coinciding with low population densities have been suggested as a cause for the evolution of monogamy in mammals, but the evidence for female intolerance is limited. We investigated long‐term space use patterns (measured as home range sizes and centers of activity) in a wild population of eastern rock sengis (Elephantulus myurus) from Limpopo, South Africa. Between March 2012 and March 2016, we recorded capture locations for 93 sengis and home range size for 22 sengis and evaluated the contributions of study year, sex, and season on these measures. Sex had no significant effect on home range size, but ranges were significantly greater during the breeding compared to the non‐breeding season, consistent with the increased energetic demands during reproduction. We found corroborative support for the role of energetic demands on home range size fluctuations. The activity centers of female–female dyads were further apart than those of male–male or mixed‐sex dyads, suggesting lower female–female tolerances in the study species. Our results offer evidence that intolerances may affect female spacing behavior and may have contributed to the evolution of monogamy in sengis.

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The evolution of micro-cursoriality in mammals

Cited by 25 publications

References 80 publications

Vertical leaping mechanics of the Lesser Egyptian Jerboa reveal specialization for maneuverability rather than elastic energy storage

Vertical leaping mechanics of the Lesser Egyptian Jerboa reveal specialization for maneuverability rather than elastic energy storage

Where Have All the Giants Gone? How Animals Deal with the Problem of Size

Space use and the evolution of social monogamy in eastern rock sengis

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