taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
03C28793703D5B1EFCF1F9FC1938F9C4.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703D5B1EFCF1F9FC1938F9C4.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703D5B1EFCF1F9FC1938F9C4.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703D5B1EFCF1F9FC1938F9C4.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703D5B1EFCF1F9FC1938F9C4.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703D5B1EFCF1F9FC1938F9C4.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703B5B18FC72FA29192BF9B8.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703B5B18FC72FA29192BF9B8.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703B5B18FC72FA29192BF9B8.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703B5B18FC72FA29192BF9B8.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406498/files/figure.png	https://doi.org/10.5281/zenodo.5406498	Figure 4. Discriminant analyses for males and females previously called T. darwini. The total contribution of each of the two Canonical Discriminant Functions (CDF1 and CDF2) to explain the total morphological variation is also given. See Material and methods for details.	Figure 4. Discriminant analyses for males and females previously called T. darwini. The total contribution of each of the two Canonical Discriminant Functions (CDF1 and CDF2) to explain the total morphological variation is also given. See Material and methods for details.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703B5B18FC72FA29192BF9B8.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703B5B18FC72FA29192BF9B8.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793703B5B18FC72FA29192BF9B8.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370275B04FC63F9051928F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370275B04FC63F9051928F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370275B04FC63F9051928F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370275B04FC63F9051928F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406498/files/figure.png	https://doi.org/10.5281/zenodo.5406498	Figure 4. Discriminant analyses for males and females previously called T. darwini. The total contribution of each of the two Canonical Discriminant Functions (CDF1 and CDF2) to explain the total morphological variation is also given. See Material and methods for details.	Figure 4. Discriminant analyses for males and females previously called T. darwini. The total contribution of each of the two Canonical Discriminant Functions (CDF1 and CDF2) to explain the total morphological variation is also given. See Material and methods for details.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370275B04FC63F9051928F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370275B04FC63F9051928F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370275B04FC63F9051928F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FCFEF9051904F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FCFEF9051904F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FCFEF9051904F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FCFEF9051904F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FCFEF9051904F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FCFEF9051904F8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FF5FFF0E1E6EFF52.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FF5FFF0E1E6EFF52.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FF5FFF0E1E6EFF52.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FF5FFF0E1E6EFF52.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FF5FFF0E1E6EFF52.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370245B07FF5FFF0E1E6EFF52.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370215B03FC55FE051E33FD83.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370215B03FC55FE051E33FD83.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370215B03FC55FE051E33FD83.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370215B03FC55FE051E33FD83.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370215B03FC55FE051E33FD83.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370215B03FC55FE051E33FD83.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B03FF06FDA91E93FD39.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B03FF06FDA91E93FD39.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B03FF06FDA91E93FD39.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B03FF06FDA91E93FD39.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B03FF06FDA91E93FD39.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B03FF06FDA91E93FD39.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B0CFCF8FCF51EE8FC9F.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B0CFCF8FCF51EE8FC9F.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B0CFCF8FCF51EE8FC9F.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B0CFCF8FCF51EE8FC9F.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B0CFCF8FCF51EE8FC9F.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C2879370205B0CFCF8FCF51EE8FC9F.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702F5B0CFF7DFCA21E87FC0E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702F5B0CFF7DFCA21E87FC0E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702F5B0CFF7DFCA21E87FC0E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702F5B0CFF7DFCA21E87FC0E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702F5B0CFF7DFCA21E87FC0E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702F5B0CFF7DFCA21E87FC0E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702E5B0DFF11FCEA197DFAFD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702E5B0DFF11FCEA197DFAFD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406498/files/figure.png	https://doi.org/10.5281/zenodo.5406498	Figure 4. Discriminant analyses for males and females previously called T. darwini. The total contribution of each of the two Canonical Discriminant Functions (CDF1 and CDF2) to explain the total morphological variation is also given. See Material and methods for details.	Figure 4. Discriminant analyses for males and females previously called T. darwini. The total contribution of each of the two Canonical Discriminant Functions (CDF1 and CDF2) to explain the total morphological variation is also given. See Material and methods for details.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702E5B0DFF11FCEA197DFAFD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702E5B0DFF11FCEA197DFAFD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702E5B0DFF11FCEA197DFAFD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702E5B0DFF11FCEA197DFAFD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702D5B0EFCF0F905193DF8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406492/files/figure.png	https://doi.org/10.5281/zenodo.5406492	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	Figure 1. Map of the Cape Verde Islands showing the geographical location (latitudes and longitudes) and altitudes of the islands and the origins of the new Tarentola samples included in the genetic (circles) and morphological (diamonds) analyses (Geographic Coordinate System, Datum WGS 84). Island and taxa colours match the colours used on the network analyses. No specimens were found on Sal.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702D5B0EFCF0F905193DF8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406494/files/figure.png	https://doi.org/10.5281/zenodo.5406494	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	Figure 2. Phylogenetic relationships of endemic Cape Verde Tarentola taxa and their relatives from the Canary Islands modified from Vasconcelos et al. (2010) based on cytochrome b and 12S rRNA genes. The tree was inferred using maximum likelihood (ML) and GTR+I+G model of sequence evolution (log likelihood = -6468.896) and was rooted using Tarentola americana. Bootstrap support values above 60% for the ML analysis are shown below nodes. Posterior probability (PP) values higher than 95% for the Bayesian analysis are represented by an asterisk (*) and are shown above nodes. Names in bold follow the new taxonomic proposal and non-bold ones the taxonomy accepted in previous recent papers (Carranza et al., 2000; Jesus et al., 2002; Vasconcelos et al., 2010). For further details see Vasconcelos et al. (2010). Characters immediately to the right of island names correspond to the 15 evolutionarily significant units (ESUs) of A, B, C, and D clades recognized in the present work and represented in split green bars. Lines of evidence (in grey): 1, mitochondrial DNA (independent cyt b parsimony networks with a connection limit of 95%; see Appendix 3); 2, nuclear DNA (absence of shared haplotypes in MC1R); 3, morphology (detection of any diagnostic morphological character or a set of a unique combination of characters). Integration approaches (in red) from the most conservative to the most inflationist: ITC stands for integration by total congruence (all lines of evidence should be congruent), IPC stands for integration by partial congruence, retained in the present study (at least two lines of evidence are necessary); IC stands for integration by cumulation (one line of evidence is sufficient). Species are represented in split red bars and subspecies in yellow.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702D5B0EFCF0F905193DF8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406502/files/figure.png	https://doi.org/10.5281/zenodo.5406502	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	Figure 6. Typical dorsal patterns of Tarentola species of the Cape Verde Islands (adapted from Joger, 1993).	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702D5B0EFCF0F905193DF8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406496/files/figure.png	https://doi.org/10.5281/zenodo.5406496	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	Figure 3. Parsimony networks corresponding to the PDC, ACM4 and MC1R nDNA sequence variation in Tarentola from the Cape Verde Islands. Lines represent a mutational step, circles haplotypes and dots missing haplotypes. The size of circles is proportional to the number of haplotypes and colours to the number of individuals. The dotted circles represent the most probable ancestral haplotype. Samples from the same island are similarly coloured but with different tonalities for different taxa. For correspondences of sample and location codes see Appendix 1.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702D5B0EFCF0F905193DF8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406500/files/figure.png	https://doi.org/10.5281/zenodo.5406500	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	Figure 5. Magnified dorsal tubercles of Tarentola species of the Cape Verde Islands.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
03C28793702D5B0EFCF0F905193DF8AD.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5406504/files/figure.png	https://doi.org/10.5281/zenodo.5406504	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	Figure 7. Photographs of the dorsal and lateral views of Tarentola of the Cape Verde Islands. A1, T. boavistensis; A2, T. bocagei; A3, T. fogoensis; A4, T. darwini; B1, T. substituta; B2, T. raziana; B3, T. caboverdiana; C, T. nicolauensis; D1, T. gigas (T. gigas brancoensis on the left and T. gigas gigas on the right); D2, T. rudis; D3, T. protogigas protogigas; D4, T. p. hartogi from Brava Island; D5, T. p. hartogi from Rombos Islets; D6, T. maioensis.	2012-01-25	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador		Zenodo	biologists	Vasconcelos, Raquel;Perera, Ana;Geniez, Philippe;Harris, D. James;Carranza, Salvador			
