Mate choice experiments revealed female preference towards larger

Mate choice experiments revealed female preference towards larger/older males in L. monticola (Lopez et al., 2003). The fact that high ectoparasite (tick) load was connected with low total brightness suggests LDK378 ic50 that brightness can also be an honest signal of high parasite resistance. Of course, our study is correlative; hence, we cannot exclude the possibility that ectoparasites cause a loss of brightness directly. However, throat brightness can still honestly signal actual health status

in the latter case. Numerous studies have demonstrated endo- and ectoparasites being costly for the host (Klukowski & Nelson, 2001; Bouma et al., 2007). Ticks have been demonstrated to act as vectors of lizard NVP-AUY922 clinical trial blood parasites, Haemolivia stellate (Haemogregarinidae) (Lainson, De Souza & Franco, 2007) and to decrease their hosts’ body condition (Dunlap, 1993), while parasite resistance was also shown to be costly (Olsson et al., 2005) and in trade-off with male

reproductive success (Uller & Olsson, 2003). Thus, an individual with the ability to avoid such detrimental effects is possibly of better quality. The Hamilton & Zuk (1982) hypothesis assumes that males may develop bright colours fully only if they possess resistance genes to parasites, and thus females should mate with brightly coloured males to associate their genes with ‘good genes’, giving their offspring the best chance of survival. One intraspecific prediction of this

hypothesis is that males with brighter colours are less parasitized, and our data support this prediction. We found no connection between blue chroma and the measured individual traits, which suggests that blue chroma does not play a role in signalling any characteristics, at least not in this studied population. We note that blue colour is not necessarily a pure structural colour. In some cases, blue colour is a by-product of the melanin layer beneath the MCE structural layer, which absorbs all non-blue radiation (Quinn & Hews, 2003). If such mechanism was present in L. viridis, blue colour might be a melanin-based signal, signalling aspects of individual quality we did not grasp with our morphological traits. Unfortunately, structure of skin layers has not yet been examined in our species yet. All three studied throat colour components (UV chroma, blue chroma and total brightness) varied significantly between years. Considering that male throat nuptial colouration is developing after hibernation and before the onset of the mating season in our species, the significant year effect is suggestive of a strong environmental component in colour development. Indeed, our manipulative experiment showing the importance of ambient temperature in colour development in L. viridis (Bajer et al.

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