Diversification across biomes in a continental lizard radiation

Ecological opportunity is a powerful driver of evolutionary diversification, and predicts rapid lineage and phenotypic diversification following colonization of competitor‐free habitats. Alternatively, topographic or environmental heterogeneity could be key to generating and sustaining diversity. We explore these hypotheses in a widespread lineage of Australian lizards: the Gehyra variegata group. This clade occurs across two biomes: the Australian monsoonal tropics (AMT), where it overlaps a separate, larger bodied clade of Gehyra and is largely restricted to rocks; and in the larger Australian arid zone (AAZ) where it has no congeners and occupies trees and rocks. New phylogenomic data and coalescent analyses of AAZ taxa resolve lineages and their relationships and reveal high diversity in the western AAZ (Pilbara region). The AMT and AAZ radiations represent separate radiations with no difference in speciation rates. Most taxa occur on rocks, with small geographic ranges relative to widespread generalist taxa across the vast central AAZ. Rock‐dwelling and generalist taxa differ morphologically, but only the lineage‐poor central AAZ taxa have accelerated evolution. This accords with increasing evidence that lineage and morphological diversity are poorly correlated, and suggests environmental heterogeneity and refugial dynamics have been more important than ecological release in elevating lineage diversity.     

DISPERSAL AND EVOLUTION OF THE PACIFIC BASIN GEKKONID LIZARDS GEHYRA OCEANICA AND GEHYRA MUTILATA

The Pacific island geckos Gehyra mutilata and Gehyra oceanica were studied on several Pacific Basin archipelagos to determine the degree that their distributions have been modified by humans (as commensals), through the analysis of protein variation using starch gel electrophoresis. Gehyra mutilata is an anthropophilic species that is widespread in the Pacific Basin and Southeast Asia. No protein variation was found in the Pacific Basin and southern Asia, although there were fixed allelic differences between populations of southern Asia and those further north. These results suggest possible recent human-aided transport across the Pacific from a population that experienced a genetic bottleneck in southern Asia. Gehyra oceanica, based on protein variation, consists of two natural groups in the Pacific, a northern (Micronesian) form and a southern (Melanesian and Polynesian) form. The northern form has very similar gene frequencies across its range in Micronesia. The southern form has its greatest allelic diversity in the south-central Pacific. F-statistics for G. oceanica in the south fall within the range of values in the literature for mainland Australian species of Gehyra that are not human commensals and for other island lizards that have been considered as natural dispersers. These values are consistent with the hypothesis that G. oceanica was naturally dispersed across the Pacific, prior to the arrival of humans and that the equatorial currents are a barrier to natural, north-south gene flow/dispersal in Pacific Basin lizards. However, human-aided dispersal within the northern and southern regions cannot be ruled out. By comparing the ecology of these two species, G. oceanica has the adaptations necessary for natural oversea dispersal, whereas G. mutilata has an ecology consistent with human-mediated dispersal, in support of the conclusions from the genetic data.     

Invasive house geckos are more willing to use artificial lights than are native geckos

There is increasing concern about the ecological effects of light pollution, as artificial lighting spreads with urban expansion. While artificial lighting can negatively affect some species, others use it in novel ways. In tropical and subtropical regions, artificial lighting has created a novel niche: the ‘night light’ niche. Geckos living as human commensals (house geckos) are apparently well adapted to occupy this niche. In an urban area in north‐eastern Australia, we found that the invasive Asian house gecko Hemidactylus frenatus (Gekkonidae) occupies a broader range of light environments in the field than does the native gecko Gehyra dubia (Gekkonidae). Experimental removal of the invasive species from a building indicated that it did not behaviourally influence the light environments chosen by the native species in the short term; they continued to use darker areas even after the invasive species was removed. In Y‐maze experiments, neither species showed a significant preference for light or dark areas; however, preliminary data suggest the invasive species was more willing to explore the Y‐maze than the native species. The willingness of H. frenatus to forage closer to lights, where insect abundance is typically higher, might account for its success as a global invader of human environments, even in areas where other gecko species are established.     

Eimeria cicaki sp. n. and Isospora thavari sp. n. from the House Lizard Gehyra mutilata Boulenger in Malaysia*

SYNOPSIS. Oocysts and endogenous stages of new species of Eimeria and Isospora from the house lizard, Gehyra mutilata, are described. The ellipsoid to subspherical 2-layered oocysts of E. cicaki averaged 24.0 × 21.0 μm. Polar granules are present. Micropyle and oocyst residuum are absent. Ellipsoid sporocysts average 12.2 × 9.0 μm. A sporocyst residuum is present, but the Stieda body is absent. Endogenous stages are in epithelial cells of the small intestine. The subspherical single-layered oocysts of I. thavari average 23.8 × 22.8 μm. The polar granule is present; micropyle and oocyst residuum are absent. Ellipsoid sporocysts average 12.8 × 9.4 μm. Stieda body and sporocyst residuum are present. There are endogenous stages in epithelial cells of the small intestine.     

Microsatellite DNA markers for Australian geckos

Nine highly polymorphic microsatellite markers were developed for Gehyra variegata from an enriched library screened for tetranucleotide repeats. An average of 19.44 alleles per locus and an average observed heterozygosity of 0.86 were found in 81 samples from fragmented populations in the Western Australian wheatbelt. Different gecko species exhibit varying rates of extinction in fragmented landscapes and the genetic markers were developed to test whether these difference are due to different rates of dispersal. The loci were tested for their ability to cross amplify in 12 species of Australian Gekkonidae and Pygopodidae, in an attempt to identify species which might be amenable to population genetic analysis using these microsatellite markers.