25 research outputs found
Olfactory Interference during Inhibitory Backward Pairing in Honey Bees
Background: Restrained worker honey bees are a valuable model for studying the behavioral and neural bases of olfactory plasticity. The proboscis extension response (PER; the proboscis is the mouthpart of honey bees) is released in response to sucrose stimulation. If sucrose stimulation is preceded one or a few times by an odor (forward pairing), the bee will form a memory for this association, and subsequent presentations of the odor alone are sufficient to elicit the PER. However, backward pairing between the two stimuli (sucrose, then odor) has not been studied to any great extent in bees, although the vertebrate literature indicates that it elicits a form of inhibitory plasticity. Methodology/Principal Findings: If hungry bees are fed with sucrose, they will release a long lasting PER; however, this PER can be interrupted if an odor is presented 15 seconds (but not 7 or 30 seconds) after the sucrose (backward pairing). We refer to this previously unreported process as olfactory interference. Bees receiving this 15 second backward pairing show reduced performance after a subsequent single forward pairing (excitatory conditioning) trial. Analysis of the results supported a relationship between olfactory interference and a form of backward pairing-induced inhibitory learning/ memory. Injecting the drug cimetidine into the deutocerebrum impaired olfactory interference. Conclusions/Significance: Olfactory interference depends on the associative link between odor and PER, rather than between odor and sucrose. Furthermore, pairing an odor with sucrose can lead either to association of this odor to PER or t
Non-verbal IQ Gains from Relational Operant Training Explain Variance in Educational Attainment: An Active-Controlled Feasibility Study
Research suggests that training relational operant patterns of behavior can lead to increases in general cognitive ability and educational outcomes. Most studies to date have been under-powered and included proxy measures of educational attainment. We attempted to extend previous findings with increased experimental control in younger children (aged 6.9–10.1 years). Participants (N = 49) were assigned to either a relational training or chess control group. Over 5 months, teachers assigned class time to complete either relational training or play chess. Those who were assigned relational training gained 8.9 non-verbal IQ (NVIQ) points, while those in the control condition recorded no gains (dppc2 = .99). Regression analyses revealed that post-training NVIQ predicted reading test scores (conducted approximately 1 month later) over and above baseline NVIQ in the experimental condition only, consistent with what we might expect in a full test of far transfer towards educational outcomes
Active and dynamic mitochondrial S-depalmitoylation revealed by targeted fluorescent probes
S-palmitoylation regulation has been studied mostly in the cytosol and its role in mitochondria is unclear. Here the authors develop fluorescent mitochondria-targeted probes and find that depalmitoylation occurs in mitochondria and it’s influenced by alterations in mitochondrial lipid homeostasis
Whole-genome enrichment and sequencing of Chlamydia trachomatis directly from clinical samples.
BACKGROUND: Chlamydia trachomatis is a pathogen of worldwide importance, causing more than 100 million cases of sexually transmitted infections annually. Whole-genome sequencing is a powerful high resolution tool that can be used to generate accurate data on bacterial population structure, phylogeography and mutations associated with antimicrobial resistance. The objective of this study was to perform whole-genome enrichment and sequencing of C. trachomatis directly from clinical samples. METHODS: C. trachomatis positive samples comprising seven vaginal swabs and three urine samples were sequenced without prior in vitro culture in addition to nine cultured C. trachomatis samples, representing different serovars. A custom capture RNA bait set, that captures all known diversity amongst C. trachomatis genomes, was used in a whole-genome enrichment step during library preparation to enrich for C. trachomatis DNA. All samples were sequenced on the MiSeq platform. RESULTS: Full length C. trachomatis genomes (>95-100% coverage of a reference genome) were successfully generated for eight of ten clinical samples and for all cultured samples. The proportion of reads mapping to C. trachomatis and the mean read depth across each genome were strongly linked to the number of bacterial copies within the original sample. Phylogenetic analysis confirmed the known population structure and the data showed potential for identification of minority variants and mutations associated with antimicrobial resistance. The sensitivity of the method was >10-fold higher than other reported methodologies. CONCLUSIONS: The combination of whole-genome enrichment and deep sequencing has proven to be a non-mutagenic approach, capturing all known variation found within C. trachomatis genomes. The method is a consistent and sensitive tool that enables rapid whole-genome sequencing of C. trachomatis directly from clinical samples and has the potential to be adapted to other pathogens with a similar clonal nature
K(2P)2.1 (TREK-1)-activator complexes reveal a cryptic selectivity filter binding site
Polymodal thermo- and mechanosensitive two-pore domain potassium (K-2P)
channels of the TREK1 subfamily generate `leak' currents that regulate
neuronal excitability, respond to lipids, temperature and mechanical
stretch, and influence pain, temperature perception and anaesthetic
responses(1-3). These dimeric voltage-gated ion channel (VGIC)
superfamily members have a unique topology comprising two pore-forming
regions per subunit(4-6). In contrast to other potassium channels, K-2P
channels use a selectivity filter `C-type' gate(7-10) as the principal
gating site. Despite recent advances(3,11,12), poor pharmacological
profiles of K2P channels limit mechanistic and biological studies. Here
we describe a class of small-molecule TREK activators that directly
stimulate the C-type gate by acting as molecular wedges that restrict
interdomain interface movement behind the selectivity filter. Structures
of K(2P)2.1 (also known as TREK-1) alone and with two selective K(2P)2.1
(TREK-1) and K(2P)10.1 (TREK-2) activators-an N-aryl-sulfonamide, ML335,
and a thiophene-carboxamide, ML402-define a cryptic binding pocket
unlike other ion channel small-molecule binding sites and, together with
functional studies, identify a cation-p interaction that controls
selectivity. Together, our data reveal a druggable K-2P site that
stabilizes the C-type gate `leak mode' and provide direct evidence for
K-2P selectivity filter gating