Intra-species recognition

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Intra-species recognition is the recognition by a member of a species of a conspecific (another member of the same species). In many species, such recognition is necessary for procreation.

Different species may employ different methods, but all of them are based on one or more senses (after all, this is how the organism gathers information about the environment). The recognition may happen by chemical signature (smell), by having a distinctive shape or color (sight), by emitting certain sounds (hearing), or even by behaviour patterns. Often a combination of these is used.

Among human beings, the sense of sight is usually in charge of recognizing other members of the same species, with maybe the subconscious help of smell. In particular, the human brain has a disproportionate amount of processing power dedicated to finely analyze the features of a human face. This is why we are able to distinguish almost all human beings from each other (barring look-alikes), and a human being from a similar species like some anthropomorphic ape, with only a quick glance.

Intra-species recognition systems are often subtle. For example, ornithologists have great difficulty in distinguishing the chiffchaff from the willow warbler by eye, and there is no evidence that the birds themselves can do so other than by the different songs of the male. Sometimes, intra-species recognition is fallible: in many species of frog, the males are commonly seen copulating with females of the wrong species or even with inanimate objects.

Heliconius charithonia displays intra-species recognition by roosting with conspecifics. They do this with the help of UV rhodopsins in the eye that help them distinguish between ultraviolet yellow pigments and regular yellow pigments. [1] They have also been known to emit chemical cues in order to recognize members of their own species. [2]

See also

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References

  1. Bybee, Seth M., Furong Yuan, Monica D. Ramstetter, Jorge Llorente-Bousquets, Robert D. Reed, Daniel Osorio, and Adriana D. Briscoe. "UV Photoreceptors and UV- Yellow Wing Pigments in Heliconius Butterflies Allow a Color Signal to Serve Both Mimicry and Intraspecific Communication." The American Naturalist 179.1 (2012): 38–51. Web.
  2. Sacledo, Christian (2010). "Environmental Elements Involved in Communal Roosting in Heliconius Butterflies (Lepidoptera:Nymphalidae)." Entomological Society of America 39 (3): 907–11