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Cursorial

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Horses can be considered cursorial grazers.

A cursorial organism is one that is adapted specifically to run. An animal can be considered cursorial if it has the ability to run fast (e.g. cheetah) or if it can keep a constant speed for a long distance (high endurance). "Cursorial" is often used to categorize a certain locomotor mode, which is helpful for biologists who examine behaviors of different animals and the way they move in their environment. Cursorial adaptations can be identified by morphological characteristics (e.g. loss of lateral digits as in ungulate species), physiological characteristics, maximum speed, and how often running is used in life. There is much debate over how to define a cursorial animal specifically.[1][2] The most accepted definitions include that a cursorial organism could be considered adapted to long-distance running at high speeds or has the ability to accelerate quickly over short distances. Among vertebrates, animals under 1 kg of mass are rarely considered cursorial, and cursorial behaviors and morphology is thought to only occur at relatively large body masses in mammals.[3] There are a few mammals that have been termed "micro-cursors" that are less than 1 kg in mass and have the ability to run faster than other small animals of similar sizes.[4]

Some species of spiders are also considered cursorial, as they walk much of the day, looking for prey.

Cursorial adaptations

Terrestrial vertebrates

Adaptations for cursorial locomotion in terrestrial vertebrates include:

  • Increased stride length by:
    • Increased limb bone length
    • Adoption of digitigrade or unguligrade stance
    • Loss of clavicle in mammals, which allows the scapula to move forwards and backwards with the limb and thereby increase stride length.
    • Increased spinal flexion during galloping
  • Decreased distal limb weight (in order to minimize moment of inertia):
    • Increase in mass of proximal muscles with decrease in mass of distal muscles
    • Increase in length of distal limb bones (the manus and pes) rather than proximal ones (the brachium or thigh).
    • Longer tendons in distal limb
  • Decreased ability to move limbs outside of the sagittal plane, which increases stability.
  • Reduction or loss of digits.
  • Loss of ability to pronate and supinate the forearm (more specialized cursors)
  • Hooves, hoof-like claws, or blunt claws for traction (as opposed to sharp claws for prey-capture or climbing)

Typically, cursors will have long, slender limbs mostly due to the elongation of distal limb proportions (metatarsals/metacarpals) and loss or reduction of lateral digits with a digitigrade or unguligrade foot posture.[1][2][5] These characters are understood to decrease weight in the distal portions of the limb which allows the individual to swing the limb faster (minimizing the moment of inertia).[6][7][8][9][10] This gives the individual the ability to move their legs fast and is assumed to contribute to the ability to produce higher speeds. A larger concentration of muscles at the pectoral and pelvic girdles, with less muscle and more tendons as you move distally down the limb, is the typical configuration for quadrupedal cursors (e.g. cheetah, greyhound, horse). All ungulates are considered cursorial based on these criteria, but in fact there are some ungulates that do not habitually run.[11] Elongation of the limbs does increase stride length, which has been suggested to be more correlated with larger home ranges and foraging patterns in ungulates.[12] Stride length can also be lengthened by the mobility of the shoulder girdle. Some cursorial mammals have a reduced or absent clavicle, which allows the scapula to slide forward across the ribcage.[8][13][14]

Cursorial animals tend to have increased elastic storage in their epaxial muscles, which allows them to store elastic energy while the spine flexes and extends in the dorso-ventral plane.[15] Furthermore, limbs in cursorially adapted mammals will tend to stay in the dorso-ventral (or sagittal) plane to increase stability when moving forward at high speeds, but this hinders the amount of lateral flexibility that limbs can have. Some felids are special in that they can pronate and supinate their forearms and run fast, but this is not the case in most other quadrupedal cursors.[8] Ungulates and canids have restricted motion in their limbs and therefore could be considered more specialized for cursorial locomotion. Several rodents are also considered cursorial (e.g. the mara, capybara, and agouti) and have similar characters to other cursorial mammals such as reduced digits, more muscles in the proximal portion than distal portion of the limb, and straight, sagittally oriented limbs.[16] Some rodents are bipedal and can hop quickly to move around, which is called ricochetal or saltatorial instead of cursorial.

There are also bipedal cursors. Humans are bipedal and considered to be built for endurance running. Several species of birds are also cursorial, mainly those that have attained larger body sizes (ostrich, greater rhea, emu). Most of the stride length in birds comes from movements below the knee joint, because the femur is situated horizontally and the knee joint sits more towards the front of the body, placing the feet below the center of mass.[17] Different birds will increase their speed in one of two ways: by increasing the frequency of footfalls or increasing the stride length.[18][19] Several studies have also found that many theropod dinosaurs (specifically coelurosaurs) were also cursorial to an extent.[2][5]

Spiders

Spiders maintain balance when walking, so that legs 1 and 3 on one side and 2 and 4 on the other side are moving, while the other four legs are on the surface. To run faster, spiders increase their stride frequency.[20]

Cursorial taxa

Several notable taxa are cursorial, including some mammals (such as wolverines and wolves, ungulates, agoutis, and kangaroos) and birds (such as the ostrich), as well as some dinosaurs (such as theropods, and Heterodontosauridae). Several extinct archosaurs were also cursorial, including the crocodylomorphs Pristichampsus, Hesperosuchus, and several genera within Notosuchia.

Jumping spiders and other non-web based spiders generally walk throughout the day, so that they maximize their chances of a catch,[21] and web-based spiders run away if threatened.[22]

In evolutionary theory

The presumed cursorial nature of theropod dinosaurs is an important part of the ground-up theory of the evolution of bird flight (also called the Cursorial theory), a theory that contrasts with the idea that birds' pre-flight ancestors were arboreal species and puts forth that the flight apparatus may have been adapted to improve hunting by lengthening leaps and improving maneuverability.[citation needed]

See also

References

  1. ^ a b Stein, B. R.; Casinos, A. (1997). "What is a cursorial mammal?". Journal of Zoology. 242 (1): 185–192. doi:10.1111/j.1469-7998.1997.tb02939.x. ISSN 1469-7998.
  2. ^ a b c Carrano, M. T. (1999). "What, if anything, is a cursor? Categories versus continua for determining locomotor habit in mammals and dinosaurs". Journal of Zoology. 247 (1): 29–42. doi:10.1111/j.1469-7998.1999.tb00190.x. ISSN 1469-7998.
  3. ^ Steudel, Karen; Beattie, Jeanne (1993). "Scaling of cursoriality in mammals". Journal of Morphology. 217 (1): 55–63. doi:10.1002/jmor.1052170105. ISSN 1097-4687.
  4. ^ Lovegrove, Barry G.; Mowoe, Metobor O. (2014-04-15). "The evolution of micro-cursoriality in mammals". Journal of Experimental Biology. 217 (8): 1316–1325. doi:10.1242/jeb.095737. ISSN 0022-0949. PMID 24436375.
  5. ^ a b Coombs, Walter P. (1978). "Theoretical Aspects of Cursorial Adaptations in Dinosaurs". The Quarterly Review of Biology. 53 (4): 393–418. doi:10.1086/410790. ISSN 0033-5770. JSTOR 2826581.
  6. ^ Payne, R. C.; Hutchinson, J. R.; Robilliard, J. J.; Smith, N. C.; Wilson, A. M. (2005). "Functional specialisation of pelvic limb anatomy in horses (Equus caballus)". Journal of Anatomy. 206 (6): 557–574. doi:10.1111/j.1469-7580.2005.00420.x. ISSN 1469-7580. PMC 1571521. PMID 15960766.
  7. ^ Payne, R. C.; Veenman, P.; Wilson, A. M. (2005). "The role of the extrinsic thoracic limb muscles in equine locomotion". Journal of Anatomy. 206 (2): 193–204. doi:10.1111/j.1469-7580.2005.00353.x. ISSN 1469-7580. PMC 1571467. PMID 15730484.
  8. ^ a b c Hudson, Penny E.; Corr, Sandra A.; Payne‐Davis, Rachel C.; Clancy, Sinead N.; Lane, Emily; Wilson, Alan M. (2011). "Functional anatomy of the cheetah (Acinonyx jubatus) forelimb". Journal of Anatomy. 218 (4): 375–385. doi:10.1111/j.1469-7580.2011.01344.x. ISSN 1469-7580. PMC 3077521. PMID 21332715.
  9. ^ Hudson, Penny E.; Corr, Sandra A.; Payne‐Davis, Rachel C.; Clancy, Sinead N.; Lane, Emily; Wilson, Alan M. (2011). "Functional anatomy of the cheetah (Acinonyx jubatus) hindlimb". Journal of Anatomy. 218 (4): 363–374. doi:10.1111/j.1469-7580.2010.01310.x. ISSN 1469-7580. PMC 3077520. PMID 21062282.
  10. ^ Hudson, Penny E.; Corr, Sandra A.; Wilson, Alan M. (2012-07-15). "High speed galloping in the cheetah (Acinonyx jubatus) and the racing greyhound (Canis familiaris): spatio-temporal and kinetic characteristics". Journal of Experimental Biology. 215 (14): 2425–2434. doi:10.1242/jeb.066720. ISSN 0022-0949. PMID 22723482.
  11. ^ Barr, W. Andrew (2014). "Functional morphology of the bovid astragalus in relation to habitat: Controlling phylogenetic signal in ecomorphology". Journal of Morphology. 275 (11): 1201–1216. doi:10.1002/jmor.20279. ISSN 1097-4687. PMID 25042704.
  12. ^ Janis, Christine M.; Wilhelm, Patricia Brady (1993-06-01). "Were there mammalian pursuit predators in the tertiary? Dances with wolf avatars". Journal of Mammalian Evolution. 1 (2): 103–125. doi:10.1007/BF01041590. ISSN 1573-7055.
  13. ^ Hildebrand, Milton (1960). "HOW ANIMALS RUN". Scientific American. 202 (5): 148–160. doi:10.1038/scientificamerican0560-148. ISSN 0036-8733. JSTOR 24940484. PMID 13852321.
  14. ^ Seckel, Lauren; Janis, Christine (2008-05-30). "Convergences in Scapula Morphology among Small Cursorial Mammals: An Osteological Correlate for Locomotory Specialization". Journal of Mammalian Evolution. 15 (4): 261. doi:10.1007/s10914-008-9085-7. ISSN 1573-7055.
  15. ^ Galis, Frietson; Carrier, David R.; Alphen, Joris van; Mije, Steven D. van der; Dooren, Tom J. M. Van; Metz, Johan A. J.; Broek, Clara M. A. ten (2014-08-05). "Fast running restricts evolutionary change of the vertebral column in mammals". Proceedings of the National Academy of Sciences. 111 (31): 11401–11406. doi:10.1073/pnas.1401392111. ISSN 0027-8424. PMC 4128151. PMID 25024205.
  16. ^ Elissamburu, A.; Vizcaíno, S. F. (2004). "Limb proportions and adaptations in caviomorph rodents (Rodentia: Caviomorpha)". Journal of Zoology. 262 (2): 145–159. doi:10.1017/S0952836903004485. ISSN 1469-7998.
  17. ^ Jones, Terry D.; Farlow, James O.; Ruben, John A.; Henderson, Donald M.; Hillenius, Willem J. (August 2000). "Cursoriality in bipedal archosaurs". Nature. 406 (6797): 716–718. doi:10.1038/35021041. ISSN 1476-4687. PMID 10963594.
  18. ^ Abourachid, Anick; Renous, Sabine (2000). "Bipedal locomotion in ratites (Paleognatiform): examples of cursorial birds". Ibis. 142 (4): 538–549. doi:10.1111/j.1474-919X.2000.tb04455.x. ISSN 1474-919X.
  19. ^ Abourachid, Anick (2000-11-01). "Bipedal locomotion in birds: the importance of functional parameters in terrestrial adaptation in Anatidae". Canadian Journal of Zoology. 78 (11): 1994–1998. doi:10.1139/z00-112. ISSN 0008-4301.
  20. ^ Anderson, D. T. (1998). "The Chelicerata". In D. T. Anderson (ed.). Invertebrate Zoology (1 ed.). Oxford University Press Australia. p. 328. ISBN 0-19-553941-9.
  21. ^ Forster, Lyn M. (Nov 1977). "Some factors affecting feeding behaviour in young Trite auricoma spiderlings (Araneae: Salticidae)". New Zealand Journal of Zoology. 4 (4). The Royal Society of New Zealand: 435–442. doi:10.1080/03014223.1977.9517967. Retrieved 24 April 2011.
  22. ^ Wilcox, R. Stimson; Jackson, Robert R. (1998). "Cognitive Abilities of Araneophagic Jumping Spiders". In Balda, Russell P.; Pepperberg, Irene Maxine; Kamil, Alan C. (eds.). Animal cognition in nature: the convergence of psychology and biology in laboratory and field. Academic Press. p. 418. ISBN 978-0-12-077030-4. Retrieved 23 May 2011.