Anatomy and histochemistry of spread‐wing posture in birds. 2. Gliding flight in the California Gull, Larus californicus: A paradox of fast fibers and posture

Gliding flight is a postural activity which requires the wings to be held in a horizontal position to support the weight of the body. Postural behaviors typically utilize isometric contractions in which no change in length takes place. Due to longer actin‐myosin interactions, slow contracting muscle fibers represent an economical means for this type of contraction. In specialized soaring birds, such as vultures and pelicans, a deep layer of the pectoralis muscle, composed entirely of slow fibers, is believed to perform this function. Muscles involved in gliding posture were examined in California gulls (Larus californicus) and tested for the presence of slow fibers using myosin ATPase histochemistry and antibodies. Surprisingly small numbers of slow fibers were found in the M. extensor metacarpi radialis, M. coracobrachialis cranialis, and M. coracobrachialis caudalis, which function in wrist extension, wing protraction, and body support, respectively. The low number of slow fibers in these muscles and the absence of slow fibers in muscles associated with wing extension and primary body support suggest that gulls do not require slow fibers for their postural behaviors. Gulls also lack the deep belly to the pectoralis found in other gliding birds. Since bird muscle is highly oxidative, we hypothesize that fast muscle fibers may function to maintain wing position during gliding flight in California gulls. J. Morphol. 233:237–247, 1997. © 1997 Wiley‐Liss, Inc.

[1]  J. V. Berge A Comparative Study of the Appendicular Mus- culature of the Order Ciconiiformes , 1970 .

[2]  H. I. Fisher,et al.  Bony Mechanism of Automatic Flexion and Extension in the Pigeon's Wing , 1957 .

[3]  A. Maier Differences in muscle spindle structure between pigeon muscles used in aerial and terrestrial locomotion. , 1983, The American journal of anatomy.

[4]  E. Bandman,et al.  Muscle Fiber Types in the Pectoralis of the White Pelican, a Soaring Bird , 1994 .

[5]  Burt L. Monroe,et al.  A Supplement To Distribution And Taxonomy Of Birds Of The World , 1952 .

[6]  R. A. Meyers,et al.  Gliding flight in the American Kestrel (Falco sparverius): An electromyographic study , 1993, Journal of morphology.

[7]  Tobalske,et al.  NEUROMUSCULAR CONTROL AND KINEMATICS OF INTERMITTENT FLIGHT IN BUDGERIGARS (MELOPSITTACUS UNDULATUS) , 1994, The Journal of experimental biology.

[8]  A. Novikoff,et al.  MITOCHONDRIAL LOCALIZATION OF OXIDATIVE ENZYMES: STAINING RESULTS WITH TWO TETRAZOLIUM SALTS , 1961, The Journal of biophysical and biochemical cytology.

[9]  G. E. Goslow,et al.  Neuromuscular organization of the pectoralis (pars thoracicus) of the pigeon (Columba livia): Implications for motor control , 1989, The Anatomical record.

[10]  R. A. Meyers Anatomy and histochemistry of spread‐wing posture in birds. I. Wing drying posture in the double‐crested cormorant, Phalacrocorax auritus , 1997, Journal of morphology.

[11]  N. Kuroda,et al.  A Note on the Pectoral Muscles of Birds , 1961 .

[12]  M. Greaser,et al.  Contractile properties and protein isoforms of single fibres from the chicken pectoralis red strip muscle. , 1996, The Journal of physiology.

[13]  C. Pennycuick The Flight of Petrels and Albatrosses (Procellariiformes), Observed in South Georgia and its Vicinity , 1982 .

[14]  V. Tucker Metabolism during flight in the laughing gull, Larus atricilla. , 1972, The American journal of physiology.

[15]  R. Furness,et al.  A histochemical comparison of fibre types in the M. pectoralis and M. supracoracoideus of the great skua Catharacta skua and the herring gull Larus argentatus with reference to kleptoparasitic capabilities , 1993 .

[16]  R. A. Meyers,et al.  The morphological basis of folded‐wing posture in the American Kesrel, Falco sparverius , 1992, The Anatomical record.

[17]  J. Baumel,et al.  Handbook of avian anatomy : nomina anatomica avium , 1993 .

[18]  J. C. George,et al.  An exceptionally high density of muscle spindles in a slow‐tonic pigeon muscle , 1985, The Anatomical record.

[19]  T. Gordon,et al.  Innervation ratio is an important determinant of force in normal and reinnervated rat tibialis anterior muscles. , 1992, Journal of neurophysiology.

[20]  Adaptations for locomotion and feeding in the anhinga and the double-crested cormorant , 1967 .

[21]  A. C. Bent Life histories of North American gulls and terns , 1921 .

[22]  K. Schmidt-Nielsen,et al.  Energy cost of gliding flight in herring gulls , 1974, Nature.

[23]  B. Livezey Flightlessness in the Galápagos cormorant (Compsohalieus [Nannopterum] harrisi): heterochrony, giantism and specialization , 1992 .

[24]  Benjamin W. C. Rosser,et al.  The avian pectoralis : histochemical characterization and distribution of muscle fiber types , 1986 .

[25]  R. S. Hikida Quantitative ultrastructure of histochemically identified avian skeletal muscle fiber types , 1987, The Anatomical record.

[26]  J. Hermanson,et al.  Four forearm flexor muscles of the horse, Equus caballus: Anatomy and histochemistry , 1992, Journal of morphology.

[27]  J. C. George,et al.  Slow muscle fibres in the pectoralis of the turkey vulture (Cathartes aura): an adaptation for soaring flight , 1986 .

[28]  G. E. Goslow,et al.  Neuromuscular Organization for “Wing” Control in a Mollusc (Clione limacina) and a Bird (Columba livia): Parallels in Design , 1991 .

[29]  H. I. Fisher Adaptations and Comparative Anatomy of the Locomotor Apparatus of New World Vultures , 1946 .