Does the availability of arboreal honeydew determine the prevalence of ecologically dominant ants in restored habitats?

Ants are extensive users of arboreal sugars, but little is known about how ecological dominance or habitat succession influences this interaction. We investigated how the availability and use of arboreal sugar resources by ants changes across a restoration chronosequence. We surveyed the use and availability of hemipteran honeydew and floral nectar on the two dominant plant genera, Eucalyptus and Acacia, in study sites in south eastern Australia. Sugars used by ants are likely to drive their role as ecosystem engineers, while sugars not used by ants remain available to other organisms. We also tested whether the use of sugars differed between ecologically dominant and non-dominant ants; taxa likely to perform different functions in ecosystems. No floral nectar was available on Acacia, but later successional eucalypts supported more floral resources and fewer mutualist hemiptera. Successional stage significantly affected how much sugar remained unexploited by ants, with similar trends for ant use of sugars. Non-dominant ants used mainly floral nectar, while hemipteran honeydew resources were used disproportionately by dominant ants, consistent with the prediction that this group monopolises persistent carbohydrate resources. This pattern was similar across successional stages, but the difference was least in habitats with the greatest availability of floral nectar, suggesting that high sugar availability may reduce the incentive to defend honeydew. Across habitat types, the proportion of dominant ants increased with the availability of hemipteran honeydew. This suggests that honeydew availability may regulate ecological dominance, thus affecting ant-driven ecosystem processes.     

What does "arboreal locomotion" mean exactly and what are the relationships between "climbing", environment and morphology?

The characteristics of "climbing" in the sense of locomotion or posture on three-dimensional substrates are discussed from a biomechanical viewpoint. For this purpose, the mechanical conditions of the most widely spread modes of locomotion or gaits used in arboreal surroundings are reviewed. This allows precise identification of morphological characteristics of traits that are advantageous, and therefore have a positive selective value. Further, at least some of the environmental and substrate characteristics that need to be present for using a specific gait, are noted. It turns out that the extremity which is placed lower on the substrate, has to carry a higher load. If this extremity is consistently the hindlimb--which actually is the case in primates, because of understandable, though complex reasons--a division of labor is likely to occur between the limbs: the hindlimb becoming stronger and the forelimb weaker, but more versatile. A very specific, and advantageous feature of the primates is their possession of prehensile hands and feet. That means the autopodia are able (1) to produce by themselves, without the aid of body weight, very high frictional resistance, and (2) to transmit tensile forces as well as torsional moments on the substrate. The above-mentioned division of labor between fore- and hindlimbs implies that the former make the first contacts with and explore the properties of parts of the environment. As a next step, prehensile hands on long arms may easily replace length and mobility of the neck in getting hold of food items. So very characteristic traits of human body shape can be derived to a large extent from the necessities of arboreal locomotion: Prehensile hands, long arms, concentration of body weight on the hindlimbs, shortness of the trunk in comparison to limb length.     

Molecular phylogenetics of the arboreal Australian gecko genus Oedura Gray 1842 (Gekkota: Diplodactylidae): another plesiomorphic grade?

The family Diplodactylidae is the most ecologically diverse and geographically widespread radiation of geckos within Australasia. Herein we present a first comprehensive phylogenetic analysis of relationships of diplodactylid geckos currently assigned to the genus Oedura, a group of relatively generalised arboreal Australian geckos. Maximum Likelihood, bayesian and Maximum Parsimony analyses of a combination of over two and a half kilobases of nuclear (PDC, Rag-1) and mitochondrial (ND2, ND4, tRNA) sequence data all identified four distinctive lineages within Oedura s.l. Based on their deep divergences and a suite of diagnostic morphological characters we recognise each of these four lineages as genera, two of which are monotypic and newly described herein. Our molecular data also suggest that Oedura s.l. is not monophyletic, but is instead a plesiomorphic grade restricted to islands of rocky or forested habitat around coastal and central Australia. In contrast, combined analysis of all data suggests the Australian arid zone is dominated by a single comparatively derived and relatively species rich clade including most other genera of Australian Diplodactylidae. Additional data are required to properly resolve basal divergence events within the Diplodactylidae, however the emerging pattern of relationships and divergence is consistent with the hypothesis that monsoonal and temperate lineages are ancestral to the arid zone fauna, but also indicate that arid zone lineages and radiations are relatively old, and potentially date back to the mid Miocene or earlier.     

Diversity of den sites used by pine martens Martes martes: a response to the scarcity of arboreal cavities?

• 1 We compiled a sample of 370 pine marten dens to test the hypothesis that a scarcity of sites leads to the use of suboptimal structures.
• 2 The sample was influenced by detection methods. Radio-tracking revealed cryptic dens but few natal dens; chance encounters revealed dens in buildings and other man-made structures. A total of 82.8% of natal dens were detected by chance encounters.
• 3 Most dens were associated with trees (44.3%), rocks (27.6%) and buildings (13.8%). The natal den subsample comprised buildings (44.3%), trees (22.8%), other man-made structures (17.1%) and rocks (14.3%). A total of 69.6% of dens were elevated and typically in structures offering limited shelter. Only 9.8% of all dens were in elevated tree cavities.
• 4 This diversity of dens reflects a scarcity of arboreal cavities. The alternative structures are suboptimal in terms of energetic costs and risks of predation, and this may limit breeding success in some populations.

     

Species’ surrogacy for conservation planning: caveats from comparing the response of three arboreal rodents to habitat loss and fragmentation

The use of surrogate species in conservation planning has been applied with disappointing results on relatively large sets of species. It could still prove useful for optimizing conservation efforts when considering a small set of species with similar ecological requirements, however few field tests of this nature have been carried out. The aim of this research is to compare the response of three arboreal rodent species—the fat dormouse (Glis glis), the hazel dormouse (Muscardinus avellanarius) and the red squirrel (Sciurus vulgaris)—to habitat loss and fragmentation, with the aim of identifying priorities for conservation and evaluating possible optimization of conservation efforts under different scenarios: habitat restoration and selection of focal patches. We studied the distribution of the three species in a sample of patches in a highly fragmented landscape in central Italy, using a patch-landscape scale approach. The distribution was studied by using hair tubes, nestboxes and nocturnal surveys. The three species showed analogous responses to increasing isolation and decreasing size of habitat patches; what differed however, was the magnitude of responses. Our results show possible application of surrogacy within this restricted group of species, however several caveats arise depending on the conservation strategy and available funding. If habitat restoration is the objective, then the fat dormouse should be the target species for guiding size and isolation of patches. On the other hand, the magnitude of the differences and patch requirements for this species, question the feasibility of these conservation actions. If selection of focal patches for conservation is the objective then selecting the fat dormouse as a focal/umbrella species would overlook areas suitable for the other two species. Feasible optimisation of conservation efforts may be possible only between the red squirrel and the hazel dormouse.     

Trade‐offs between eating and moving: what happens to the locomotion of slender arboreal snakes when they eat big prey?

The capacity to consume large prey evolved long ago in snakes. Subsequently, many specialized arboreal snake species convergently evolved slender bodies, presumably well‐suited for moving on thin branches and steep slopes, although how this accentuates changes in their shape and weight after eating and creates trade‐offs with locomotor performance is poorly understood. Hence, we tested whether the performance and modes of locomotion of a specialized arboreal snake (Boiga irregularis) changed after eating one or two mice when crawling on cylinders with and without pegs and on horizontal or 45° slopes. On surfaces with pegs: (1) only lateral undulation was used; (2) speed decreased with increased meal size; and (3) unexpectedly, more sideways toppling occurred than without pegs. On the horizontal cylinders without pegs, most unfed snakes used lateral undulation with continuous sliding contact, whereas, after eating two mice, most snakes periodically stopped and gripped the cylinder with speeds of concertina locomotion similar to those for the lateral undulation of unfed snakes. Thus, the behaviour of switching to a gripping mode of locomotion (concertina) circumvented some of the constraints of a slender limbless body plan, for which bulky meals alter shape and can impede the movement of the propulsive structures. © 2014 The Linnean Society of London, Biological Journal of the Linnean Society, 2015, 114 , 446–458.     

First arboreal 'pelycosaurs' (Synapsida: Varanopidae) from the early Permian Chemnitz Fossil Lagerstätte,SE Germany,with a review of varanopid phylogeny

A new fossil amniote from the Fossil Forest of Chemnitz (Sakmarian-Artinskian transition, Germany) is described as Ascendonanus nestleri gen. et sp. nov., based on five articulated skeletons with integumentary preservation. The slender animals exhibit a generalistic, lizard-like morphology. However, their synapsid temporal fenestration, ventrally ridged centra and enlarged iliac blades indicate a pelycosaur-grade affiliation. Using a renewed data set for certain early amniotes with a similar typology found Ascendonanus to be a basal varanopid synapsid. This is the first evidence of a varanopid from Saxony and the third from Central Europe, as well as the smallest varanopid at all. Its greatly elongated trunk, enlarged autopodia and strongly curved unguals, along with taphonomical observations, imply an arboreal lifestyle in a dense forest habitat until the whole ecosystem was buried under volcanic deposits. Ascendonanus greatly increases the knowledge on rare basal varanopids; it also reveals a so far unexpected ecotype of early synapsids. Its integumentary structures present the first detailed and soft tissue skin preservation of any Paleozoic synapsid. Further systematic results suggest a varanodontine position for Mycterosaurus, the monophyly of South African varanopids including Anningia and the distinction of a skeletal aggregation previously assigned to Heleosaurus, now renamed as Microvaranops parentis gen. et sp. nov.     

Impact of Argentine ants (<Emphasis Type="Italic">Linepithema humile</Emphasis>) on an arboreal ant community in Doñana National Park,Spain

Due to the invasive character of the exotic Argentine ant (Linepithema humile), its use of aphids in trees, and the ecological importance of the Doñana National Park (Spain) that is invaded by this species, we designed a study to analyze the extent of the problem with native species of arboreal ants. By searching for de visu the species that inhabited 182 cork trees, we found out that the structure of the community of native arboreal ants has been greatly influenced by interspecific competition. The introduced species L. humile and the native species Crematogaster scutellaris and Lasius brunneus are dominant, while Camponotus lateralis and Camponotus truncatus are subordinate species associated with C. scutellaris. The distribution of the species in the trees depends on these relationships. Species richness is determined by tree size, thus, when a tree is large enough all native species may appear together. However, in areas colonized by L. humile, this is the only species occupying the tree, regardless of tree size. L. humile is displacing native arboreal ant species as shown by the fact that from 1992 to 2000 the exotic species occupied 23 new cork trees (of the 182 studied) previously inhabited by native species.     

An arboreal spider protects its offspring by diving into the water of tank bromeliadsUne araignée arboricole utilise les réservoirs d’eau des broméliacées pour se protéger et protéger son cocon

Cupiennius salei (Ctenidae) individuals frequently live in association with tank bromeliads, including Aechmea bracteata, in Quintana Roo (Mexico). Whereas C. salei females without egg sacs hunt over their entire host plant, females carrying egg sacs settle above the A. bracteata reservoirs they have partially sealed with silk. There they avoid predators that use sight to detect their prey, as is known for many bird species. Furthermore, if a danger is more acute, these females dive with their egg sacs into the bromeliad reservoir. An experiment showed that this is not the case for males or females without egg sacs. In addition to the likely abundance of prey found therein, the potential of diving into the tank to protect offspring may explain the close association of this spider with bromeliads. These results show that, although arboreal, C. salei evolved a protective behavior using the water of tank bromeliads to protect offspring.