Evolution of limb bone loading and body size in varanid lizards

SUMMARY Geometric scaling predicts that stresses on limb bones and muscles should increase with body size. Mammals counter this size-related increase in stress partially through changes in bone geometry, but largely through changes in posture, with larger species having a more erect stance. However, the ability to counter size-related stresses in this fashion may be limited to those taxa that have a parasagittal gait (such as mammals), where legs are swung underneath the body. We examined locomotor kinematics for 11 species of varanid lizards (from 0.04 to 8 kg body mass) that have a sprawling gait, to determine how they moderate size-related stresses. Posture, as indicated by femur adduction and hip heights, did not change significantly with body size, beyond that expected from geometrical scaling. Instead, lizards mitigated size-related increases in stress by increasing duty factor and possibly reducing femur rotation. Incorporating these factors in biomechanical models predicted that both bending (∝M0.016, where M is mass) and torsional (∝M–0.049) stresses should be nearly independent of body size over the size range examined. However, increasing duty factor and reducing femur rotation probably have deleterious effects on speed, and this difference in kinematics with size may explain why speed scales lower for sprawling lizards than for parasagittal mammals (∝M0.17 and ∝M0.24, respectively). Further, paralleling conclusions for the synapsid lineage, these findings suggest that evolution from sprawling to upright posture did not occur in archosaurs as a response to larger size; rather, these archosaurs likely became upright first and larger later.

[1]  Stephen A. Wainwright,et al.  Mechanical Design in Organisms , 2020 .

[2]  R. McN. Alexander,et al.  Allometry of the limb bones of mammals from shrews (Sorex) to elephant (Loxodonta) , 2009 .

[3]  D. Brinkman The hind limb step cycle of Iguana and primitive reptiles , 2009 .

[4]  R. Alexander,et al.  Allometry of the legs of running birds , 2009 .

[5]  P. Withers,et al.  Evolutionary relationships of sprint speed in Australian varanid lizards , 2009 .

[6]  M. Butcher,et al.  In vivo strains in the femur of river cooter turtles (Pseudemys concinna) during terrestrial locomotion: tests of force-platform models of loading mechanics , 2008, Journal of Experimental Biology.

[7]  M. Benton,et al.  EVOLUTION OF HINDLIMB POSTURE IN ARCHOSAURS: LIMB STRESSES IN EXTINCT VERTEBRATES , 2007 .

[8]  John R. Hutchinson,et al.  The evolution of locomotion in archosaurs , 2006 .

[9]  A. Biewener Biomechanical consequences of scaling , 2005, Journal of Experimental Biology.

[10]  Stephen M Reilly,et al.  Motor control of locomotor hindlimb posture in the American alligator (Alligator mississippiensis) , 2003, Journal of Experimental Biology.

[11]  T. Garland,et al.  TESTING FOR PHYLOGENETIC SIGNAL IN COMPARATIVE DATA: BEHAVIORAL TRAITS ARE MORE LABILE , 2003, Evolution; international journal of organic evolution.

[12]  R. Blob Evolution of hindlimb posture in nonmammalian therapsids: biomechanical tests of paleontological hypotheses , 2001, Paleobiology.

[13]  Bieke Vanhooydonck,et al.  Origins of interspecific variation in lizard sprint capacity , 2001 .

[14]  A. Biewener,et al.  Mechanics of limb bone loading during terrestrial locomotion in the green iguana (Iguana iguana) and American alligator (Alligator mississippiensis). , 2001, The Journal of experimental biology.

[15]  R. Blob Interspecific scaling of the hindlimb skeleton in lizards, crocodilians, felids and canids: does limb bone shape correlate with limb posture? , 2000 .

[16]  A. Biewener,et al.  In vivo locomotor strain in the hindlimb bones of alligator mississippiensis and iguana iguana: implications for the evolution of limb bone safety factor and non-sprawling limb posture , 1999, The Journal of experimental biology.

[17]  S. Reilly,et al.  Locomotion in alligator mississippiensis: kinematic effects of speed and posture and their relevance to the sprawling-to-erect paradigm , 1998, The Journal of experimental biology.

[18]  S. Gatesy,et al.  An electromyographic analysis of hindlimb function in Alligator during terrestrial locomotion , 1997, Journal of morphology.

[19]  P. Withers,et al.  Comparative morphology of Western Australian varanid lizards (Squamata: Varanidae) , 1997, Journal of morphology.

[20]  S. Reilly,et al.  Sprawling locomotion in the lizard Sceloporus clarkii: quantitative kinematics of a walking trot , 1997, The Journal of experimental biology.

[21]  E. Pianka Evolution of Body Size: Varanid Lizards as a Model System , 1995, The American Naturalist.

[22]  T. Garland,et al.  Procedures for the Analysis of Comparative Data Using Phylogenetically Independent Contrasts , 1992 .

[23]  P. Sereno Basal Archosaurs: Phylogenetic Relationships and Functional Implications , 1991 .

[24]  S. Gatesy Hind limb movements of the American alligator (Alligator mississippiensis) and postural grades , 1991 .

[25]  S. Gatesy,et al.  Bipedal locomotion: effects of speed, size and limb posture in birds and humans , 1991 .

[26]  A. Biewener Biomechanics of mammalian terrestrial locomotion. , 1990, Science.

[27]  A. Biewener Scaling body support in mammals: limb posture and muscle mechanics. , 1989, Science.

[28]  R. Blickhan,et al.  Muscle forces during locomotion in kangaroo rats: force platform and tendon buckle measurements compared. , 1988, The Journal of experimental biology.

[29]  J. Parrish The origin of crocodilian locomotion , 1987, Paleobiology.

[30]  C. R. Taylor,et al.  Bone strain: a determinant of gait and speed? , 1986, The Journal of experimental biology.

[31]  J. Felsenstein Phylogenies and the Comparative Method , 1985, The American Naturalist.

[32]  J. Bonaparte Locomotion in rauisuchid thecodonts , 1984 .

[33]  A. Biewener Allometry of quadrupedal locomotion: the scaling of duty factor, bone curvature and limb orientation to body size. , 1983, The Journal of experimental biology.

[34]  S. C. Rewcastle,et al.  Fundamental Adaptations in the Lacertilian Hind Limb: A Partial Analysis of the Sprawling Limb Posture and Gait , 1983 .

[35]  A. Biewener Locomotory stresses in the limb bones of two small mammals: the ground squirrel and chipmunk. , 1983, The Journal of experimental biology.

[36]  L. Lanyon,et al.  Limb mechanics as a function of speed and gait: a study of functional strains in the radius and tibia of horse and dog. , 1982, The Journal of experimental biology.

[37]  A A Biewener,et al.  Bone strength in small mammals and bipedal birds: do safety factors change with body size? , 1982, The Journal of experimental biology.

[38]  J. Murray,et al.  Scale Effects in Animal Locomotion. , 1978 .

[39]  R. Alexander,et al.  Mechanics and scaling of terrestrial locomotion 93-110, illust , 1977 .

[40]  R. Snyder,et al.  The anatomy and function of the pelvic girdle and hindlimb in lizard locomotion. , 1954, The American journal of anatomy.

[41]  P. Withers,et al.  Is body shape of varanid lizards linked with retreat choice , 2008 .

[42]  A. Biewener Safety factors in bone strength , 2005, Calcified Tissue International.

[43]  Alexander Rm,et al.  Factors of safety in the structure of animals. , 1981 .

[44]  R. M. Alexander Factors of safety in the structure of animals. , 1981, Science progress.

[45]  R. Close Dynamic properties of mammalian skeletal muscles. , 1972, Physiological reviews.

[46]  S. Reilly Quantitative electromyography and muscle function of the hind limb during quadrupedal running in the lizard Sceloporus clarki , 2022 .