Function of Head-Cocking in Garnett's Greater Bush Baby (Otolemur garnettii)

Head-cocking is rotation of the head about the rostrocaudal axis with a fixed direction of orientation. The behavior is a response to either visual or auditory stimuli according to species. Although head-cocking is prevalent in small primates, its functional significance is unclear. We studied head-cocking in response to a variety of novel visual and acoustic stimuli in Garnett's greater bush babies (Otolemur garnettii). We systematically varied stimulus type (animate vs. inanimate image) and mode of presentation (NON-VIDEO vs. VIDEO) to assess their effects on the head-cocking response. A higher incidence of head-cocking occurred with novel animal images and for NON-VIDEO presentations. Acoustic stimuli suppressed rather than facilitated head-cocking. Juveniles head-cocked much more than adults did. Clearly head-cocking in Otolemur garnettii is primarily involved in visual rather than auditory function. It does not serve simple sensory/perceptual functions such as depth perception or acuity. Instead, in consideration of the importance of novelty to the elicitation of the behavior, the higher incidence in younger animals, and the structure of the visual system, we propose that head-cocking is a motor strategy to encode the parameters of novel images in the process of form learning.     

Purification and partial characterization of a novel hemagglutinating glycoprotein from the cultured mycelia of Hericium erinaceus

HEG-5, a novel glycoprotein with hemagglutinating activity, was firstly isolated and purified from the cultured mycelia of Hericium erinaceus CZ-2. SDS–PAGE, Native-PAGE and MALDI-TOF-MS proved that HEG-5 was a single band with the molecular weight of approximately 14.4 kDa. HEG-5 had the protein: polysaccharide ratio of approximately 10:1 (%/%) and contained d-glucose, l-rhamnose, d-galactose and d-mannose with a molar ratio of 1.00:1.09:2.45:7.14 in polysaccharide fraction. HEG-5 was an acidic glycoprotein with a PI value of 6.3 and the higher content of acidic amino acids (Asp, 12.42 ± 0.25% and Glu, 12.24 ± 0.26%) in protein fraction. FT-IR and NMR spectra revealed that HEG-5 contained the protein and carbohydrate portions with (1→4)-linked β-galactose residues and β-linked glucose residues. Circular dichroism (CD) demonstrated that HEG-5 was a β-sheet predominant glycoprotein. Hemagglutination assay proved it was a thermo-unstable glycoprotein. The HEG-5 structural novelty was finally presented by protein sequencing and modeling by using MALDI-TOF-MS, NCBI blast search and online SWISS-MODEL Workspace service.     

Single point mutation on the gene encoding dysbindin results in recognition deficits

The dystrobrevin‐binding protein 1 (DTNBP1) gene is a candidate risk factor for schizophrenia and has been associated with cognitive ability in both patient populations and healthy controls. DTNBP1 encodes dysbindin protein, which is localized to synaptic sites and is reduced in the prefrontal cortex and hippocampus of patients with schizophrenia, indicating a potential role in schizophrenia etiology. Most studies of dysbindin function have focused on the sandy (sdy) mice that lack dysbindin protein and have a wide range of abnormalities. In this study, we examined dysbindin salt and pepper (spp) mice that possess a single point mutation on the Dtnbp1 gene predicted to reduce, but not eliminate, dysbindin expression. By western blot analysis, we found that spp homozygous (spp ?/?) mutants had reduced dysbindin and synaptosomal‐associated protein 25 (SNAP‐25) in the prefrontal cortex, but unaltered levels in hippocampus. Behaviorally, spp mutants performed comparably to controls on a wide range of tasks assessing locomotion, anxiety, spatial recognition and working memory. However, spp ?/? mice had selective deficits in tasks measuring novel object recognition and social novelty recognition. Our results indicate that reduced dysbindin and SNAP‐25 protein in the prefrontal cortex of spp ?/? is associated with selective impairments in recognition processing. These spp mice may prove useful as a novel mouse model to study cognitive deficits linked to dysbindin alterations. Our findings also suggest that aspects of recognition memory may be specifically influenced by DTNBP1 single nucleotide polymorphisms or risk haplotypes in humans and this connection should be further investigated.     

How will climate novelty influence ecological forecasts? Using the Quaternary to assess future reliability

Future climates are projected to be highly novel relative to recent climates. Climate novelty challenges models that correlate ecological patterns to climate variables and then use these relationships to forecast ecological responses to future climate change. Here, we quantify the magnitude and ecological significance of future climate novelty by comparing it to novel climates over the past 21,000 years in North America. We then use relationships between model performance and climate novelty derived from the fossil pollen record from eastern North America to estimate the expected decrease in predictive skill of ecological forecasting models as future climate novelty increases. We show that, in the high emissions scenario (RCP 8.5) and by late 21st century, future climate novelty is similar to or higher than peak levels of climate novelty over the last 21,000 years. The accuracy of ecological forecasting models is projected to decline steadily over the coming decades in response to increasing climate novelty, although models that incorporate co‐occurrences among species may retain somewhat higher predictive skill. In addition to quantifying future climate novelty in the context of late Quaternary climate change, this work underscores the challenges of making reliable forecasts to an increasingly novel future, while highlighting the need to assess potential avenues for improvement, such as increased reliance on geological analogs for future novel climates and improving existing models by pooling data through time and incorporating assemblage‐level information.     

Multiple origins of secondary temporal fenestrae and orbitozygomatic junctions in birds

Orbitozygomatic junctions (bony connections between the postorbital and zygomatic processes) and secondary temporal fenestrae have long been known to occur in a few avian species, but no comprehensive study of this phenomenon has ever been published. Having surveyed all non‐passerine and most passerine families, we established that the orbitozygomatic junction evolved 18–20 times independently in Cracidae, Phasianoidea (Odontophoridae and Phasianidae), Gastornis, Columbidae (three times), Pteroclidae (Syrrhaptes), Aptornis, Thinocoridae (Thinocorus), Scolopacidae (possibly twice), Ciconiidae (twice), Brachypteraciidae (Uratelornis), Picidae (Picus spp.), Psittacidae (Melopsittacus), Cacatuidae, and Alaudidae (twice). The junction arises in evolution as a result of either elongation of the two processes that meet at angles or the appearance of a bony cross‐bridge in place of a ligament or aponeurosis. In the first case, the junction is initially non‐adaptive, as indicated by its extreme variation (e.g., in Cracinae and Ciconiidae), and may or may not prove functional as an exaptation. Whenever adaptive, the junction supports an expansion of the adductor mandibulae externus (primarily its pars media). In addition, a rostral extension of the tympanic wing has come to cross the temporal fossa in Strigidae (at least twice) and probably Podargus. Altogether, secondary bony connections across the temporal fossa evolved independently at least 21–23 times in neornithine birds.     

From stowaways to karst‐aways: unloading the Peninsular Malaysia endemic Polyalthia brunneifolia (Annonaceae)

Detailed examination of specimens collected from limestone outcrops in Peninsular Malaysia and previously included in Polyalthia brunneifolia shows that they do not belong in this species. Three new species are described to accommodate these collections: Polyalthia chinii I.M.Turner & Utteridge from Bukit Serdam, Raub, Pahang; P. guabatuensis I.M.Turner & Utteridge from Batu Caves, Selangor, and P. guamusangensis I.M.Turner & Utteridge from Gua Musang, Kelantan. Conservation assessments are included for the new species and the general threats faced by species confined to limestone hills are discussed. In addition, an updated key to all species of Polyalthia known from Peninsular Malaysia is provided.     

Evolution of the molluscan body plan: the case of the anterior adductor muscle of bivalves

The separated shell plates with the rearranged musculature (adductor muscle) is a novelty for bivalves. Despite its importance in the bivalve bodyplan, the development of the anterior adductor muscle remains unresolved. In this study, we investigate the myogenesis of the bivalve species Septifer virgatus to reveal the developmental origin of the larval muscles in bivalves, focusing on the anterior adductor muscle. We observed that larval retractor muscles are differentiated from the ectomesoderm in bivalves, and that the anterior adductor muscles are derived from primordial larval retractor muscles via segregation of the myoblast during the veliger larval stage. Through the comparative study of myogenesis in bivalves and its related taxa, gastropods, we found that both species possess myoblasts that emerge bilaterally and later meet dorsally. We hypothesize that these myoblasts, which are a major component of the main larval retractor in limpets, are homologous to the anterior adductor muscle in bivalves. These observations imply that the anterior adductor muscle of bivalves evolved as a novel muscle by modifying the attachment sites of an existing muscle.     

Genotypes on the move: some things old and some things new shape the genetics of colonization during species invasions

When we set a species loose outside of its historical range, we create opportunities to test fundamental questions about how populations establish, adapt, disperse, and ultimately define range boundaries. A particularly controversial issue here is how genetic variation among and within populations contributes to the dynamics of species distributions. In this issue of Molecular Ecology, Rosenthal and colleagues (2008) seize an opportunity to examine how multiple introductions create genetically distinct establishment events and how these are incorporated into invasive spread. Their findings suggest that a particular recombinant lineage of Brachypodium sylvaticum may be responsible for most of the recent expansion of this invader, highlighting the potential importance of genetic novelty and historical context for colonization success.