Flehmen response

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Flehmen response in the Sumatran Tiger

The flehmen response (/ˈflmən/; German: [ˈfleːmən]), also called the flehmen position, flehmen reaction, flehming, or flehmening, is a behaviour whereby an animal curls back its upper lips exposing its front teeth, inhales with the nostrils usually closed and then often holds this position for several seconds. It may be performed over a site or substance of particular interest to the animal (e.g. urine or faeces) or may be performed with the neck stretched and the head held high in the air. Flehmen is performed by a wide range of mammals including ungulates and felids. The behaviour facilitates the transfer of pheromones and other scents into the vomeronasal organ located above the roof of the mouth via a duct which exits just behind the front teeth of the animal.

Etymology

The word originates from the German verb flehmen, to bare the upper teeth or the Upper Saxony flemmen, to look spiteful.[1]

Description

An animal investigating odours or tastes at sites of particular interest or perhaps more generally, may perform the flehmen response. This response is characterised by the animal curling back its top lips exposing the front teeth and gums, then inhaling and holding the posture for several seconds. The behaviour may be performed over particular locations, in which case the animal may also lick the site of interest, or it may be performed with the neck stretched and head held high in the air for a more general gustatory investigation. The flehmen response often gives the appearance that the animal is "grimacing", "smirking" or "laughing".

Function

Flehmen response in a horse

The main function of flehmen is to transfer air containing pheremones and other scents to the vomeronasal organ, a chemosensory organ located between the roof of the mouth and the palate. This provides chemical cues which animals use in a variety of ways.

Identifying reproductive status: Male individuals commonly use the flehmen response as an olfactory mechanism for identifying the reproductive state of females of the same species based on pheromones in the female's urine or genitals. This is exhibited in sheep; flehmen by rams, after sniffing the ewes’ external genital region, occurs most frequently on the day before estrus, when the ewes were sexually receptive.[2]

Reproductive synchrony: Flehmen behavior also plays a role in reproductive synchrony between females. In the sable antelope, the frequency of flehmen changed seasonally, with the highest levels just prior to conception. Female antelopes associated closely with other females in the same reproductive state. Flehmen rates between females anticipated birth synchrony. Additionally, the level of synchrony was predicted by the frequency of female urine sampling during the previous year. Flehmen is a mechanism used by female sable antelopes to manipulate the timing of both conception and birth of offspring.[3] In the American bison, flehmen behavior in females has also been shown to stimulate the onset of estrus and copulation synchronization.[4]

Inter-specific communication: The flehmen response is not limited to conspecific communication. Goats have been tested for their flehmen response to urine from 20 different species, including several non-mammalian species. This study suggests there is a common element in the urine of all animals, a pheromone, which elicits flehmen behavior. Specifically, chemical pheromone levels of a modified form of androgen, a sex hormone, were associated with the response in goats.[5]

Post-parturition: Mares commonly show a peak in flehmen response during the first few hours after giving birth. Smelling the newborn foal and the amniotic fluids associated with birth often produce the reaction.[6]

Immature animals: In young horses, both colts (males) and fillies (females) exhibit flehmen behavior towards other conspecifics with neither sex performing the behavior more than the other.[7] However, it has been reported that young colts flehmen up to five times more frequently than fillies, and fillies flehmen more frequently than mature mares.[6] Young elephants also have a flehmen response to stimulants. The VNO of newborn elephants displays a structural maturity similar to adults, which supports the conclusion that flehmen at only six weeks of age is used to deliver chemical pheromones to a functional vomeronasal organ.[8]

Physiology

The flemen response draws air into the vomeronasal organ (VNO) or Jacobson's organ, an auxiliary olfactory sense organ that is found in many animals. It was discovered by Frederik Ruysch and described later by Ludwig Jacobson in 1813.[9] This organ plays a role in the perception of certain scents and pheromones. It is named for its closeness to the vomer and nasal bones, and is particularly well developed in animals such as cats and horses. The VNO is found at the base of the nasal cavity. It is encompassed inside a bony or cartilaginous capsule which opens into the base of the nasal cavity.[10] Animals that exhibit flehmen have a pappila located behind the incisors and ducts which connect the oral cavity to the VNO; horses are an exception, they exhibit flehmen but do not have an incisive duct communication between the nasal and oral cavity because they do not breathe through their mouths, instead, the VNOs connect to the nasal passages by the nasopalatine duct.[11]

Chemical cues

The chemical cue obtained by an animal exhibiting the flehmen response is the presence of a non-volatile organic compound. In contrast to volatile organic compounds (VOCs), non-volatile organic compounds are those carbon compounds that do not participate in atmospheric photochemical reactions or evaporate under normal atmospheric conditions.[12] The vomeronasal organ detects non-VOCs, which must have direct contact with the odor source. Sources of non-VOCs relevant to the flehmen response include pheromones and hormones excreted from the genital regions or urine of animals.

Animals exhibiting flehmen

A wide range of mammals exhibit flehmen including both predatory and non-predatory species.

The response is perhaps most easily observed in domestic cats or horses; both exhibit a strong flehmen response to odors.[13] [14] Stallions usually smell the urine of mares in estrus whereas the male giraffe's flehmen response includes actually tasting the female's urine.[15] Elephants perform a flehmen response but also transfer chemosensory stimuli to the vomeronasal opening in the roof of their mouths using the prehensile structure, sometimes called a "finger", at the tips of their trunks.[16]

Other animals which exhibit the flehmen response include buffalo,[17] tigers,[18] tapirs,[19] lions,[20] giraffes,[15] goats,[21] llamas,[22] kobs,[23] hedgehogs,[24] rhinoceros and giant pandas.[25]

  • Flehmen response in a Tapir

  • Flehmen response in an elk

  • Flehmen response in a goat

  • Flehmen response in a zebra

Similar responses

A grimace similar to the flehmen response may also be seen in association with pain.[26] In horses, it is often associated with low-grade abdominal pain.

References

  1. "flehmen". Dictionary.com. Retrieved May 28, 2013. 
  2. Bland, K. P.; Jubilan, B. M. "Correlation of flehmen by male sheep with female behavior and oestrus". 1987. Animal Behaviour 35(3): 735–8
  3. Thompson, K. V. "Flehmen and birth synchrony among female sable antelope, Hippotragus-niger". 1995. Animal Behaviour 50: 475–84.
  4. Wolff, J. O. Breeding strategies, mate choice, and reproductive success in American bison". 1998. Oikos 83(3): 529–44.
  5. Sasada, H.; Kanomata, K.; Fukuoka, T. "Flehmen induction with goats by the urine of twenty animal species". 1988. 11th International Congress on Animal Reproduction and Artificial Insemination, University College Dublin, Irelend, June 26–30, 1988. Volume 4. Brief Communications.
  6. 6.0 6.1 "Flehmen: 'What's My Horse Doing with His Lip?'". Kentucky Equine Research, Inc. Retrieved May 29, 2013. 
  7. Weeks, J. W.; Cromwell-Davis, S. L.; Heusner, G. "Preliminary study of the development of the Flehmen response in Equus caballus. 2002. Applied Animal Behaviour Science 78(2): 329–35.
  8. Johnson, E. W.; Rasmussen, L. "Morphological characteristics of the vomeronasal organ of the newborn Asian elephant (Elephas maximus)". 2002. Anatomical Record 267(3): 252–9.
  9. Jacobson, L. (1813). "Anatomisk Beskrivelse over et nyt Organ i Huusdyrenes Næse". Veterinær=Selskapets Skrifter [in Danish] 2,209–246.
  10. http://www.neuro.fsu.edu/~mmered/vomer/
  11. Briggs, Karen (2013-12-11). "Equine Sense of Smell". The Horse. Retrieved 2013-12-15. 
  12. Volatile Organic Compounds (VOCs): Technical Overview. United States Environmental Protection Agency. http://www.epa.gov/iaq/voc2.html#2. Updated April 10, 2012. Accessed May 9, 2012.
  13. "Flehmening in cats". Catsguru.com. 2011-04-09. Retrieved 2012-05-23. 
  14. "Flehmening". ASPCA. Retrieved 2012-05-23. 
  15. 15.0 15.1 "Introduction to the social system of giraffe (Giraffa camelopardalis)". 2011-08-17. Archived from the original on August 17, 2011. Retrieved 2013-01-17. 
  16. Verne A. Simon, "Adaptations in the Animal Kingdom", Xlibris Corp. (2010), p. 31.
  17. "Plains Bison Flehmen". Alaskan Alpine Treks.com. Retrieved 2008-06-04. 
  18. "Enrichment - SCENT". Minnesota Zoo. Archived from the original on 2008-01-12. Retrieved 2008-06-04. 
  19. "Here's "flehmen" at you!". The Tapir Preservation Fund. Retrieved 2008-06-04. 
  20. "Lion Flehmen Display". Retrieved 2011-11-29. 
  21. "Caring for pygmy goats". Henry and Joey: Pet Pygmy Goats. Retrieved 2011-04-12. 
  22. "Llama body language". The Llama Question and Answer Page. Retrieved 2008-06-04. 
  23. "Sudan White-Eared Kob Animal Profile". Great Migrations - National Geographic Channel. Archived from the original on October 31, 2010. Retrieved 2010-11-15. 
  24. "Anointing and the flehmen response". Peerless Pinto Hedgehogs. 2010. Retrieved May 30, 2013. 
  25. Swaisgood, R. R., Lindburg, D. G., White, A. M., Hemin, Z. and Xiaoping, Z. "Chemical Communication in Giant Pandas". Retrieved June 4, 2013. 
  26. "Facial Expression". The Royal (Dick) School of Veterinary Studies at The University of Edinburgh. Retrieved 2008-06-04. 

Further reading

  • Swaisgood, R. R., D. G. Lindburg, X. Zhou, and M. A. Owen. 2000. "The effects of sex, reproductive condition and context on discrimination of conspecific odours by giant pandas". Anim. Behav. 60; 227–237.

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