[1]	Abalos J, Pérez i de Lanuza G, Bartolomé A, Aubret F, Uller T, Font E (2022). Viability, behavior, and color expression in the offspring of matings between common wall lizard Podarcis muralis color morphs. Current Zoology 68, 41–55.

[2]	Abalos J, Pérez i de Lanuza G, Bartolomé A et al. (2020). No evidence for differential sociosexual behavior and space use in the color morphs of the European common wall lizard (Podarcis muralis). Ecology and Evolution 10, 10986–1005.

[3]	Abalos J, Pérez i de Lanuza G, Carazo P, Font E (2016). The role of male coloration in the outcome of staged contests in the European common wall lizard (Podarcis muralis). Behaviour 153, 607–31.

[4]	Andrade P, Pinho C, Pérez i de Lanuza G et al. (2019). Regulatory changes in pterin and carotenoid genes underlie balanced color polymorphisms in the wall lizard. PNAS 116, 5633–5642.

[5]	Angilletta MJ (2009). Thermal Adaptation: A Theoretical and Empirical Synthesis, 1st edn. Oxford University Press Inc., New York City.

[6]	Angilletta MJ, Niewiarowski PH, Navas CA (2002). The evolution of thermal physiology in ectotherms. Journal of Thermal Biology 27, 249–268.

[7]	Avery RA (1978). Activity patterns, thermoregulation and food consumption in two sympatric lizard species (Podarcis muralis and P. sicula) from Central Italy. Journal of Animal Ecology 47, 143–158.

[8]	Badillo-Saldaña LM, García-Rosales A, Ramírez-Bautista A (2022). Influence of microhabitat use on morphology traits of three species of the Anolis sericeus complex (Squamata: Dactyloidae) in Mexico. Zoology 152, 126003.

[9]	BeVier GT, Ayton C, Brock KM (2022). It ain't easy being orange: Lizard colour morphs occupying highly vegetated microhabitats suffer greater ectoparasitism. Amphibia-Reptilia 43, 287–297.

[10]	Black IRG, Berman JM, Cadena V, Tattersall GJ (2019). Behavioral thermoregulation in lizards: Strategies for achieving preferred temperature. In: Bels VL, Russell AP, eds. Behavior of Lizards: Evolutionary and Mechanistic Perspectives. CRC Press, Boca Raton, FL, pp. 13–46.

[11]	Blair TA, Cree A, Skeaff CM (2000). Plasma fatty acids, triacylglycerol and cholesterol of the tuatara (Sphenodon punctatus punctatus) from islands differing in the presence of rats and the abundance of seabirds. Journal of Zoology 252, 463–472.

[12]	Bodensteiner BL, Agudelo-Cantero GA, Arietta AZA et al. (2021a). Thermal adaptation revisited: How conserved are thermal traits of reptiles and amphibians? Journal of Experimental Zoology Part A: Ecological and Integrative Physiology 335, 173–194.

[13]	Bodensteiner BL, Gangloff EJ, Kouyoumdjian L, Muñoz MM, Aubret F (2021b). Thermal–metabolic phenotypes of the lizard Podarcis muralis differ across elevation, but converge in high-elevation hypoxia. Journal of Experimental Biology 224, jeb243660.

[14]	Bolton PE, Rollins LA, Griffith SC (2016). Colour polymorphism is likely to be disadvantageous to some populations and species due to genetic architecture and morph interactions. Molecular Ecology 25, 2713–2718.

[15]	Bonier F (2023). Future directions in urban endocrinology—The effects of endocrine plasticity on urban tolerance. Molecular and Cellular Endocrinology 565, 111886.

[16]	Braña F (1993). Shifts in body temperature and escape behaviour of female Podarcis muralis during pregnancy. Oikos 66, 216–222.

[17]	Brischoux F, Dupoué A, Lourdais O, Angelier F (2016). Effects of mild wintering conditions on body mass and corticosterone levels in a temperate reptile, the aspic viper (Vipera aspis). Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 192, 52–56.

[18]	Brock KM, Baeckens S, Donihue CM, Martín J, Pafilis P, Edwards DL (2020). Trait differences among discrete morphs of a color polymorphic lizard. Podarcis erhardii. PeerJ 8, e10284.

[19]	Brock KM, Chelini M-C, Ayton C et al. (2022b). Colour morph predicts social behaviour and contest outcomes in a polymorphic lizard (Podarcis erhardii). Animal Behaviour 191, 91–103.

[20]	Brock KM, McTavish EJ, Edwards DL (2022a). Color polymorphism is a driver of diversification in the lizard family Lacertidae. Systematic Biology 71, 24–39.

[21]	Brodeur JC, Damonte MJ, Vera Candioti J, Poliserpi MB, D'Andrea MF, Bahl MF (2020). Frog body condition: Basic assumptions, comparison of methods and characterization of natural variability with field data from Leptodactylus latrans. Ecological Indicators 112, 106098.

[22]	Brown RM, Gist DH, Taylor DH (1995a). Home range ecology of an introduced population of the European wall lizard Podarcis muralis (Lacertilia; Lacertidae) in Cincinnati, Ohio. The American Midland Naturalist 133, 344–359.

[23]	Brown RM, Taylor DH, Gist DH (1995b). Effect of caudal autotomy on locomotor performance of wall lizards (Podarcis muralis). Journal of Herpetology 29, 98–105.

[24]	Calsbeek B, Hasselquist D, Clobert J (2010). Multivariate phenotypes and the potential for alternative phenotypic optima in wall lizard (Podarcis muralis) ventral colour morphs. Journal of Evolutionary Biology 23, 1138–1147.

[25]	Campbell-Staton SC, Winchell KM, Rochette NC et al. (2020). Parallel selection on thermal physiology facilitates repeated adaptation of city lizards to urban heat islands. Nature Ecology & Evolution 4, 652–658.

[26]	Chow WTL, Roth M (2006). Temporal dynamics of the urban heat island of Singapore. International Journal of Climatology 26, 2243–2260.

[27]	Coladonato AJ, Mangiacotti M, Scali S et al. (2020). Morph-specific seasonal variation of aggressive behaviour in a polymorphic lizard species. PeerJ 8, e10268.

[28]	Collyer M, Adams D (2019). RRPP: Linear model evaluation with randomized residuals in a permutation procedure. R package version 1.3.1. Available from URL: https://CRAN.R-project.org/package=RRPP

[29]	Collyer ML, Adams DC (2018). RRPP: An r package for fitting linear models to high-dimensional data using residual randomization. Methods in Ecology and Evolution 9, 1772–1779.

[30]	Comendant T, Sinervo B, Svensson EI, Wingfield J (2003). Social competition, corticosterone and survival in female lizard morphs. Journal of Evolutionary Biology 16, 948–955.

[31]	Davis JG, Ferner JW, Krusling PJ (2021). Common wall lizard, Podarcis muralis (Laurenti 1768). Ohio Biological Survey 317–334.

[32]	Deichsel G, Gist DH (2001). On the origin of the common wall lizards Podarcis muralis (Reptilia: Lacertidae) in Cincinnati, Ohio USA. Herpetological Review 32, 230–232.

[33]	Diamond SE, Chick L, Perez A, Strickler SA, Martin RA (2017). Rapid evolution of ant thermal tolerance across an urban-rural temperature cline. Biological Journal of the Linnean Society 121, 248–257.

[34]	Diamond SE, Chick LD, Perez A, Strickler SA, Zhao C (2018). Evolution of plasticity in the city: Urban acorn ants can better tolerate more rapid increases in environmental temperature. Conservation Physiology 6, coy030.

[35]	Donihue CM, Herrel A, Foufopoulos J, Pafilis P (2022). Body condition and jumping predict initial survival in a replicated island introduction experiment. Biological Journal of the Linnean Society 135, 490–498.

[36]	Flouris AD, Piantoni C (2015). Links between thermoregulation and aging in endotherms and ectotherms. Temperature 2, 73–85.

[37]	Forsman A (2000). Some like it hot: Intra-population variation in behavioral thermoregulation in color-polymorphic pygmy grasshoppers. Evolutionary Ecology 14, 25–38.

[38]	Forsman A (2016). Is colour polymorphism advantageous to populations and species? Molecular Ecology 25, 2693–2698.

[39]	Forsman A, Ahnesjö J, Caesar S, Karlsson M (2008). A model of ecological and evolutionary consequences of color polymorphism. Ecology 89, 34–40.

[40]	Forsman A, Wennersten L (2016). Inter-individual variation promotes ecological success of populations and species: Evidence from experimental and comparative studies. Ecography 39, 630–648.

[41]	Forsman A, Åberg V (2008). Associations of variable coloration with niche breadth and conservation status among Australian reptiles. Ecology 89, 1201–1207.

[42]	French SS, Webb AC, Hudson SB, Virgin EE (2018). Town and country reptiles: A review of reptilian responses to urbanization. Integrative and Comparative Biology 58, 948–966.

[43]	Galeotti P, Pellitteri-Rosa D, Sacchi R et al. (2010). Sex-, morph- and size-specific susceptibility to stress measured by haematological variables in captive common wall lizard Podarcis muralis. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 157, 354–363.

[44]	Galeotti P, Sacchi R, Pellitteri-Rosa D et al. (2013). Colour polymorphism and alternative breeding strategies: Effects of parent's colour morph on fitness traits in the common wall lizard. Evolutionary Biology 40, 385–394.

[45]	Gangloff EJ, Greenberg N (2023). Biology of stress. In: Warwick C, Arena PC, Burghardt GM, eds. Health and Welfare of Captive Reptiles. Springer International Publishing, Cham, Switzerland, pp. 93–142.

[46]	Gangloff EJ, Sorlin M, Cordero GA, Souchet J, Aubret F (2019). Lizards at the peak: Physiological plasticity does not maintain performance in lizards transplanted to high altitude. Physiological and Biochemical Zoology 92, 189–200.

[47]	Hall JM, Warner DA (2018). Thermal spikes from the urban heat island increase mortality and alter physiology of lizard embryos. Journal of Experimental Biology 221, jeb181552.

[48]	Hedeen S (1984). The establishment of Podarcis muralis in Cincinnati, Ohio. Herpetological Review 15, 70–77.

[49]	Hertz PE, Huey RB, Stevenson RD (1993). Evaluating temperature regulation by field-active ectotherms: The fallacy of the inappropriate question. The American Naturalist 142, 796–818.

[50]	Heym A, Deichsel G, Hochkirch A, Veith M, Schulte U (2013). Do introduced wall lizards (Podarcis muralis) cause niche shifts in a native sand lizard (Lacerta agilis) population? A case study from south-western Germany. Salamandra 49, 97–104.

[51]	Holden KG, Gangloff EJ, Miller DAW et al. (2022). Over a decade of field physiology reveals life-history specific strategies to drought in garter snakes (Thamnophis elegans). Proceedings of the Royal Society B: Biological Sciences 289, 20212187.

[52]	Homan CM (2013). Bottlenecks and microhabitat preference in invasive wall lizard. Podarcis muralis (Master's thesis). University of Cincinnati, Cincinnati, USA.

[53]	Huey RB, Kearney MR, Krockenberger A, Holtum JAM, Jess M, Williams SE (2012). Predicting organismal vulnerability to climate warming: Roles of behaviour, physiology and adaptation. Philosophical Transactions of the Royal Society B: Biological Sciences 367, 1665–1679.

[54]	Huey RB, Stevenson RD (1979). Integrating thermal physiology and ecology of ectotherms: A discussion of approaches. American Zoologist 19, 357–366.

[55]	Huyghe K, Husak JF, Herrel A et al. (2009). Relationships between hormones, physiological performance and immunocompetence in a color-polymorphic lizard species, Podarcis melisellensis. Hormones and Behavior 55, 488–494.

[56]	Huyghe K, Small M, Vanhooydonck B et al. (2010). Genetic divergence among sympatric colour morphs of the Dalmatian wall lizard (Podarcis melisellensis). Genetica 138, 387–393.

[57]	Huyghe K, Vanhooydonck B, Herrel A, Tadić Z, Van Damme R (2007). Morphology, performance, behavior and ecology of three color morphs in males of the lizard Podarcis melisellensis. Integrative and Comparative Biology 47, 211–220.

[58]	Isaksson C (2020). Urban ecophysiology: Beyond costs, stress and biomarkers. Journal of Experimental Biology 223, jeb203794.

[59]	Johanson W, Tse-Leon J (2023). Common wall lizards Podarcis muralis at a new site in England registered by a citizen science reporting tool. The Herpetological Bulletin 163, 39–40.

[60]	Kearney M, Shine R, Porter WP (2009). The potential for behavioral thermoregulation to buffer “cold-blooded” animals against climate warming. PNAS 106, 3835–3840.

[61]	Kolbe JJ, Lavin BR, Burke RL, Rugiero L, Capula M, Luiselli L (2013). The desire for variety: Italian wall lizard (Podarcis siculus) populations introduced to the United States via the pet trade are derived from multiple native-range sources. Biological Invasions 15, 775–783.

[62]	Kwiat G, Gist D (1987). Annual reproductive cycle of an introduced population of European wall lizards (Podarcis muralis) in Ohio. Journal of Herpetology 21, 205.

[63]	Lailvaux SP (2007). Interactive effects of sex and temperature on locomotion in reptiles. Integrative and Comparative Biology 47, 189–199.

[64]	Landys MM, Ramenofsky M, Wingfield JC (2006). Actions of glucocorticoids at a seasonal baseline as compared to stress-related levels in the regulation of periodic life processes. General and Comparative Endocrinology 148, 132–149.

[65]	Lattanzio MS, Miles DB (2014). Ecological divergence among colour morphs mediated by changes in spatial network structure associated with disturbance. Journal of Animal Ecology 83, 1490–1500.

[66]	Lazić MM, Carretero MA, Živković U, Crnobrnja-Isailović J (2017). City life has fitness costs: Reduced body condition and increased parasite load in urban common wall lizards, Podarcis muralis. Salamandra 53, 10–17.

[67]	Le Galliard J-F, Clobert J, Ferrière R (2004). Physical performance and Darwinian fitness in lizards. Nature 432, 502–505.

[68]	Lenth RV, Bolker B, Buerkner P et al. (2023). emmeans: Estimated marginal means, aka least-squares means. R package version 1.8.5. Available from URL: https://CRAN.R-project.org/package=emmeans

[69]	Lescano NV (2010). Population bottlenecks and range expansion in Podarcis muralis, a wall lizard introduced from Italy (Master's thesis). University of Cincinnati, Cincinnati, USA.

[70]	Litmer AR, Murray CM (2019). Critical thermal tolerance of invasion: Comparative niche breadth of two invasive lizards. Journal of Thermal Biology 86, 102432.

[71]	Liu Z, He C, Wu J (2016). The relationship between habitat loss and fragmentation during urbanization: An empirical evaluation from 16 world cities. PLoS ONE 11, e0154613.

[72]	Ljubisavljević K, Urošević A, Aleksić I, Ivanović A (2010). Sexual dimorphism of skull shape in a lacertid lizard species (Podarcis spp., Dalmatolacerta sp., Dinarolacerta sp.) revealed by geometric morphometrics. Zoology 113, 168–174.

[73]	MacDougall-Shackleton SA, Bonier F, Romero LM, Moore IT (2019). Glucocorticoids and “stress” are not synonymous. Integrative Organismal Biology 1, obz017.

[74]	MacLean GS, Lee AK, Wilson KJ (1973). A Simple method of obtaining blood from lizards. Copeia 1973, 338–339.

[75]	Matthews G, Farquhar JE, White CR, Chapple DG (2023). Does thermal biology differ between two colour pattern morphs of a widespread Australian lizard? Journal of Thermal Biology 114, 103579.

[76]	McEwen BS, Wingfield JC (2003). The concept of allostasis in biology and biomedicine. Hormones and Behavior 43, 2–15.

[77]	Megía-Palma R, Arregui L, Pozo I et al. (2020). Geographic patterns of stress in insular lizards reveal anthropogenic and climatic signatures. Science of The Total Environment 749, 141655.

[78]	Michaelides SN, While GM, Zajac N, Uller T (2015). Widespread primary, but geographically restricted secondary, human introductions of wall lizards, Podarcis muralis. Molecular Ecology 24, 2702–2714.

[79]	Mills SC, Hazard L, Lancaster L et al. (2008). Gonadotropin hormone modulation of testosterone, immune function, performance, and behavioral trade-offs among male morphs of the lizard Uta stansburiana. The American Naturalist 171, 339–357.

[80]	Moeller KT, Demare G, Davies S, DeNardo DF (2017). Dehydration enhances multiple physiological defense mechanisms in a desert lizard, Heloderma suspectum. Journal of Experimental Biology 220, 2166–2174.

[81]	Mohan M, Pathan SK, Narendrareddy K, Kandya A, Pandey S (2011). Dynamics of urbanization and its impact on land-use/land-cover: A case study of megacity Delhi. Journal of Environmental Protection 02, 1274.

[82]	Navas CA, Bevier CR (2001). Thermal dependency of calling performance in the eurythermic frog Colostethus subpunctatus. Herpetologica 57, 384–395.

[83]	Neuman-Lee LA, Bobby Fokidis H, Spence AR et al. (2015). Food restriction and chronic stress alter energy use and affect immunity in an infrequent feeder. Functional Ecology 29, 1453–1462.

[84]	Nowakowski AJ, Watling JI, Thompson ME et al. (2018). Thermal biology mediates responses of amphibians and reptiles to habitat modification. Ecology Letters 21, 345–355.

[85]	Ortega Z, Mencía A, Pérez-Mellado V (2016). The peak of thermoregulation effectiveness: Thermal biology of the Pyrenean rock lizard, Iberolacerta bonnali (Squamata, Lacertidae). Journal of Thermal Biology 56, 77–83.

[86]	Palacios MG, Sparkman AM, Bronikowski AM (2012). Corticosterone and pace of life in two life-history ecotypes of the garter snake Thamnophis elegans. General and Comparative Endocrinology 175, 443–448.

[87]	Peig J, Green AJ (2009). New perspectives for estimating body condition from mass/length data: The scaled mass index as an alternative method. Oikos 118, 1883–1891.

[88]	Pellitteri-Rosa D (2010). Mechanisms of regulation and maintenance of color polymorphism in the common wall lizard (Podarcis muralis). Scientifica Acta 4, 3–12.

[89]	Pellitteri-Rosa D, Martín J, López P et al. (2014). Chemical polymorphism in male femoral gland secretions matches polymorphic coloration in common wall lizards (Podarcis muralis). Chemoecology 24, 67–78.

[90]	Peterson CC (2002). Temporal, population, and sexual variation in hematocrit of free-living desert tortoises: Correlational tests of causal hypotheses. Canadian Journal of Zoology 80, 461–470.

[91]	Pizzatto L, Dubey S (2012). Colour-polymorphic snake species are older. Biological Journal of the Linnean Society 107, 210–218.

[92]	Podnar M, Mayer W, Tvrtković N (2005). Phylogeography of the Italian wall lizard, Podarcis sicula, as revealed by mitochondrial DNA sequences. Molecular Ecology 14, 575–588.

[93]	Price ER (2017). The physiology of lipid storage and use in reptiles. Biological Reviews 92, 1406–1426.

[94]	Puerta M, Abelenda M, Salvador A, Martín J, López P, Veiga JP (1996). Haematology and plasma chemistry of male lizards, Psammodromus algirus. Effects of testosterone treatment. Comparative Haematology International 6, 102–106.

[95]	Putman BJ, Pauly GB, Blumstein DT (2020). Urban invaders are not bold risk-takers: A study of 3 invasive lizards in Southern California. Current Zoology 66, 657–665.

[96]	Putman BJ, Tippie ZA (2020). Big city living: A global meta-analysis reveals positive impact of urbanization on body size in lizards. Frontiers in Ecology and Evolution 8, 580745.

[97]	Pérez i de Lanuza G, Abalos J, Bartolomé A, Font E (2018a). Through the eyes of a lizard: Hue discrimination in a lizard with ventral polymorphic coloration. Journal of Experimental Biology 221, jeb169565.

[98]	Pérez i de Lanuza G, Carretero MA (2018). Partial divergence in microhabitat use suggests environmental-dependent selection on a colour polymorphic lizard. Behavioral Ecology and Sociobiology 72, 138.

[99]	Pérez i de Lanuza G, Font E, Carazo P (2013). Color-assortative mating in a color-polymorphic lacertid lizard. Behavioral Ecology 24, 273–279.

[100]

Pérez i de Lanuza G, Font E, Carretero MA (2016). Colour assortative mating in a colour polymorphic lizard is independent of population morph diversity. Science of Nature 103, 82.

[101]

Pérez i de Lanuza G, Sillero N, Carretero MÁ (2018b). Climate suggests environment-dependent selection on lizard colour morphs. Journal of Biogeography 45, 2791–2802.

[102]

R Core Team (2023). R: A language and environment for statistical computing. R Foundation for Statistical Computing, Version 4.0.3. Vienna, Austria.

[103]

Remage-Healey L, Romero LM (2001). Corticosterone and insulin interact to regulate glucose and triglyceride levels during stress in a bird. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology 281, R994–R1003.

[104]

Ribeiro R, Sá-Sousa P (2018). Where to live in Lisbon: Urban habitat used by the introduced Italian wall lizard (Podarcis siculus). Basic and Applied Herpetology 32, 57–70.

[105]

Romero LM, Beattie UK (2022). Common myths of glucocorticoid function in ecology and conservation. Journal of Experimental Zoology Part A: Ecological and Integrative Physiology 337, 7–14.

[106]

Rubolini D, Pupin F, Sacchi R et al. (2006). Sexual dimorphism in digit length ratios in two lizard species. The Anatomical Record Part A: Discoveries in Molecular, Cellular, and Evolutionary Biology 288A, 491–497.

[107]

Sacchi R, Coladonato AJ, Ghitti M et al. (2018). Morph-specific assortative mating in common wall lizard females. Current Zoology 64, 449–453.

[108]

Sacchi R, Ghitti M, Scali S et al. (2015a). Common wall lizard females (Podarcis muralis) do not actively choose males based on their colour morph. Ethology 121, 1145–1153.

[109]

Sacchi R, Mangiacotti M, Scali S et al. (2015b). Context-dependent expression of sexual dimorphism in island populations of the common wall lizard (Podarcis muralis). Biological Journal of the Linnean Society 114, 552–565.

[110]

Sacchi R, Pellitteri-Rosa D, Bellati A et al. (2013). Colour variation in the polymorphic common wall lizard (Podarcis muralis): An analysis using the RGB colour system. Zoologischer Anzeiger 252, 431–439.

[111]

Sacchi R, Rubolini D, Gentilli A et al. (2007b). Morph-specific immunity in male Podarcis muralis. Amphibia-Reptilia 28, 408–412.

[112]

Sacchi R, Scali S, Mangiacotti M et al. (2017). Seasonal variations of plasma testosterone among colour-morph common wall lizards (Podarcis muralis). General and Comparative Endocrinology 240, 114–120.

[113]

Sacchi R, Scali S, Pupin F, Gentilli A, Galeotti P, Fasola M (2007a). Microgeographic variation of colour morph frequency and biometry of common wall lizards. Journal of Zoology 273, 389–396.

[114]

Sapolsky RM, Romero LM, Munck AU (2000). How do glucocorticoids influence stress responses? Integrating permissive, suppressive, stimulatory, and preparative actions. Endocrine Reviews 21, 55–89.

[115]

Schielzeth H, Dingemanse NJ, Nakagawa S et al. (2020). Robustness of linear mixed-effects models to violations of distributional assumptions. Methods in Ecology and Evolution 11, 1141–1152.

[116]

Silva-Rocha I, Salvi D, Harris DJ et al. (2014). Molecular assessment of Podarcis sicula populations in Britain, Greece and Turkey reinforces a multiple-origin invasion pattern in this species. Acta Herpetologica 9, 253–258.

[117]

Sinervo B, Lively CM (1996). The rock–paper–scissors game and the evolution of alternative male strategies. Nature 380, 240–243.

[118]

Sparkman A, Howe S, Hynes S, Hobbs B, Handal K (2018). Parallel behavioral and morphological divergence in fence lizards on two college campuses. PLoS ONE 13, e0191800.

[119]

Spears S, Pettit C, Berkowitz S et al. (2023). Lizards in the wind: The impact of wind on the thermoregulation of the common wall lizard. (In revision.)

[120]

Speybroeck J, Beukema W, Bok B, Van Der Voort J (2016). Field Guide to the Reptiles and Amphibians of Britain and Europe, 1st edn. Bloomsbury Publishing Plc, London, UK.

[121]

Stevenson RD, Woods WA Jr (2006). Condition indices for conservation: New uses for evolving tools. Integrative and Comparative Biology 46, 1169–1190.

[122]

Stroud JT, Colom M, Ferrer P et al. (2019). Behavioral shifts with urbanization may facilitate biological invasion of a widespread lizard. Urban Ecosystems 22, 425–434.

[123]

Stuart-Fox D, Aulsebrook A, Rankin KJ, Dong CM, McLean CA (2021). Convergence and divergence in lizard colour polymorphisms. Biological Reviews 96, 289–309.

[124]

Svensson EI (2017). Back to basics: Using colour polymorphisms to study evolutionary processes. Molecular Ecology 26, 2204–2211.

[125]

Sykes KL, Klukowski M (2009). Effects of acute temperature change, confinement and housing on plasma corticosterone in water snakes, Nerodia sipedon (Colubridae: Natricinae). Journal of Experimental Zoology Part A: Ecological Genetics and Physiology 311A, 172–181.

[126]

Sándor K, Liker A, Sinkovics C, Péter Á, Seress G (2021). Urban nestlings have reduced number of feathers in Great Tits (Parus major). Ibis 163, 1369–1378.

[127]

Telemeco RS, Gangloff EJ (2020). Analyzing stress as a multivariate phenotype. Integrative and Comparative Biology 60, 70–78.

[128]

Telemeco RS, Gangloff EJ, Cordero GA, Rodgers EM, Aubret F (2022). From performance curves to performance surfaces: Interactive effects of temperature and oxygen availability on aerobic and anaerobic performance in the common wall lizard. Functional Ecology 36, 2544–2557.

[129]

Thompson A, Kapsanaki V, Liwanag HEM, Pafilis P, Wang IJ, Brock KM (2023). Some like it hotter: Differential thermal preferences among lizard color morphs. Journal of Thermal Biology 113, 103532.

[130]

Tylan C, Camacho K, French S et al. (2020). Obtaining plasma to measure baseline corticosterone concentrations in reptiles: How quick is quick enough? General and Comparative Endocrinology 287, 113324.

[131]

Van Valen L (1965). Morphological Variation and width of ecological niche. The American Naturalist 99, 377–390.

[132]

Vaughn PL, Mcqueen W, Gangloff EJ (2021). Moving to the city: Testing the implications of morphological shifts on locomotor performance in introduced urban lizards. Biological Journal of the Linnean Society 134, 141–153.

[133]

Warner DA, Johnson MS, Nagy TR (2016). Validation of body condition indices and quantitative magnetic resonance in estimating body composition in a small lizard. Journal of Experimental Zoology Part A: Ecological Genetics and Physiology 325, 588–597.

[134]

Weatherhead PJ, Brown GP (1996). Measurement versus estimation of condition in snakes. Canadian Journal of Zoology 74, 1617–1621.

[135]

Wickham H, Chang W, Henry L et al. (2023). ggplot2: Create Elegant Data Visualisations Using the Grammar of Graphics. R package version 3.4.1. Springer-Verlag, New York City.

[136]

Winchell KM, Maayan I, Fredette JR, Revell LJ (2018). Linking locomotor performance to morphological shifts in urban lizards. Proceedings of the Royal Society B: Biological Sciences 285, 20180229.

[137]

Wingfield JC, Maney DL, Breuner CW et al. (1998). Ecological bases of hormone—Behavior interactions: The “emergency life history stage”. American Zoologist 38, 191–206.

[138]

Yewers MSC, Pryke S, Stuart-Fox D (2016). Behavioural differences across contexts may indicate morph-specific strategies in the lizard Ctenophorus decresii. Animal Behaviour 111, 329–339.

[139]

Zajitschek SRK, Zajitschek F, Miles DB, Clobert J (2012). The effect of coloration and temperature on sprint performance in male and female wall lizards. Biological Journal of the Linnean Society 107, 573–582.