Novel muscle and connective tissue design enables high extensibility and controls engulfment volume in lunge-feeding rorqual whales

SUMMARY Muscle serves a wide variety of mechanical functions during animal feeding and locomotion, but the performance of this tissue is limited by how far it can be extended. In rorqual whales, feeding and locomotion are integrated in a dynamic process called lunge feeding, where an enormous volume of prey-laden water is engulfed into a capacious ventral oropharyngeal cavity that is bounded superficially by skeletal muscle and ventral groove blubber (VGB). The great expansion of the cavity wall presents a mechanical challenge for the physiological limits of skeletal muscle, yet its role is considered fundamental in controlling the flux of water into the mouth. Our analyses of the functional properties and mechanical behaviour of VGB muscles revealed a crimped microstructure in an unstrained, non-feeding state that is arranged in parallel with dense and straight elastin fibres. This allows the muscles to accommodate large tissue deformations of the VGB yet still operate within the known strain limits of vertebrate skeletal muscle. VGB transverse strains in routine-feeding rorquals were substantially less than those observed in dead ones, where decomposition gas stretched the VGB to its elastic limit, evidence supporting the idea that eccentric muscle contraction modulates the rate of expansion and ultimate size of the ventral cavity during engulfment.

[1]  Lisa Schichtel Orton,et al.  Engulfing mechanics of fin whales , 1987 .

[2]  M. McKenna,et al.  Scaling of lunge‐feeding performance in rorqual whales: mass‐specific energy expenditure increases with body size and progressively limits diving capacity , 2012 .

[3]  A. Biewener,et al.  Dynamics of leg muscle function in tammar wallabies (M. eugenii) during level versus incline hopping , 2004, Journal of Experimental Biology.

[4]  R. Shadwick,et al.  Metabolic Expenditures of Lunge Feeding Rorquals Across Scale: Implications for the Evolution of Filter Feeding and the Limits to Maximum Body Size , 2012, PloS one.

[5]  M. Brooke,et al.  THREE "MYOSIN ADENOSINE TRIPHOSPHATASE" SYSTEMS: THE NATURE OF THEIR pH LABILITY AND SULFHYDRYL DEPENDENCE , 1970, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.

[6]  G H Pollack,et al.  The sarcomere length-tension relation in skeletal muscle , 1978, The Journal of General Physiology.

[7]  J A Goldbogen,et al.  Passive versus active engulfment: verdict from trajectory simulations of lunge-feeding fin whales Balaenoptera physalus , 2009, Journal of The Royal Society Interface.

[8]  R. Shadwick,et al.  Scaling of lunge feeding in rorqual whales: an integrated model of engulfment duration. , 2010, Journal of theoretical biology.

[9]  P. Best,et al.  Functional Polyovuly in the Sei Whale Balaenoptera borealis Lesson , 1963, Nature.

[10]  J. Goldbogen The Ultimate Mouthful: Lunge Feeding in Rorqual Whales , 2010 .

[11]  Robert E. Shadwick,et al.  Big gulps require high drag for fin whale lunge feeding , 2007 .

[12]  P. Arnold,et al.  Gulping behaviour in rorqual whales: underwater observations and functional interpretation , 2005 .

[13]  R. Shadwick,et al.  Skull and buccal cavity allometry increase mass-specific engulfment capacity in fin whales , 2010, Proceedings of the Royal Society B: Biological Sciences.

[14]  Richard H. Lambertsen,et al.  Internal Mechanism of Rorqual Feeding , 1983 .

[15]  John M. Gosline,et al.  Elastin as a random‐network elastomer: A mechanical and optical analysis of single elastin fibers , 1981 .

[16]  W Herzog,et al.  Residual force enhancement in myofibrils and sarcomeres , 2008, Proceedings of the Royal Society B: Biological Sciences.

[17]  John Calambokidis,et al.  Kinematics of foraging dives and lunge-feeding in fin whales , 2006, Journal of Experimental Biology.

[18]  K. Wang,et al.  Viscoelasticity of the sarcomere matrix of skeletal muscles. The titin-myosin composite filament is a dual-stage molecular spring. , 1993, Biophysical journal.

[19]  G. Gillis,et al.  How muscles accommodate movement in different physical environments: aquatic vs. terrestrial locomotion in vertebrates. , 2001, Comparative biochemistry and physiology. Part A, Molecular & integrative physiology.

[20]  A. Garrod Animal Locomotion , 1874, Nature.

[21]  D. Syme,et al.  Functional Properties of Skeletal Muscle , 2005 .

[22]  M.A. Lillie,et al.  Tensile Residual Strains on the Elastic Lamellae along the Porcine Thoracic Aorta , 2006, Journal of Vascular Research.

[23]  J. Dubbeldam,et al.  Histology of the grooved ventral pouch of the minke whale, Balaenoptera acutorostrata, with special reference to the occurrence of lamellated corpuscles , 1997 .

[24]  W. SOKOLOV,et al.  Some Similarities and Dissimilarities in the Structure of the Skin Among the Members of the Suborders Odontoceti and Mystacoceti (Cetacea) , 1960, Nature.

[25]  A. Biewener,et al.  Integration within and between muscles during terrestrial locomotion: effects of incline and speed , 2008, Journal of Experimental Biology.

[26]  A. Pivorunas,et al.  The fibrocartilage skeleton and related structures of the ventral pouch of Balaenopterid whales , 1977, Journal of morphology.

[27]  W Herzog,et al.  Myofilament lengths of cat skeletal muscle: theoretical considerations and functional implications. , 1992, Journal of biomechanics.

[28]  Peter T. Madsen,et al.  Keeping momentum with a mouthful of water: behavior and kinematics of humpback whale lunge feeding , 2012, Journal of Experimental Biology.

[29]  R. Shadwick,et al.  Discovery of a sensory organ that coordinates lunge feeding in rorqual whales , 2012, Nature.

[30]  Jon Lien,et al.  Propulsion of a fin whale ( Balenoptera physalus) : why the fin whale is a fast swimmer , 1989, Proceedings of the Royal Society of London. B. Biological Sciences.

[31]  C. I. Smith,et al.  MYOTOMAL MUSCLE FUNCTION AT DIFFERENT LOCATIONS IN THE BODY OF A SWIMMING FISH , 1993 .

[32]  C. Zuurbier,et al.  Mean sarcomere length-force relationship of rat muscle fibre bundles. , 1995, Journal of biomechanics.

[33]  Jonathan M. Borwein,et al.  Modular Equations and Approximations to π , 2000 .