Channelrhodopsin-2–XXL,a powerful optogenetic tool for low-light applications

Channelrhodopsin-2 (ChR2) has provided a breakthrough for the optogenetic control of neuronal activity. In adult Drosophila melanogaster, however, its applications are severely constrained. This limitation in a powerful model system has curtailed unfolding the full potential of ChR2 for behavioral neuroscience. Here, we describe the D156C mutant, termed ChR2-XXL (extra high expression and long open state), which displays increased expression, improved subcellular localization, elevated retinal affinity, an extended open-state lifetime, and photocurrent amplitudes greatly exceeding those of all heretofore published ChR variants. As a result, neuronal activity could be efficiently evoked with ambient light and even without retinal supplementation. We validated the benefits of the variant in intact flies by eliciting simple and complex behaviors. We demonstrate efficient and prolonged photostimulation of monosynaptic transmission at the neuromuscular junction and reliable activation of a gustatory reflex pathway. Innate male courtship was triggered in male and female flies, and olfactory memories were written through light-induced associative training.Identifying causal relationships between neuronal activity and animal behavior is a fundamental goal of neuroscience. Crucially, this task requires testing whether defined neuronal populations are sufficient for eliciting behavioral modules. The development of light-gated ion channels that can be genetically targeted to specific cells has provided a unique solution to this challenge. In pioneering work, such optogenetic effectors or actuators were originally used as multicomponent approaches (1–3). The introduction of Channelrhodopsin-1 (ChR1) (4) and especially ChR2 as a light-sensitive cation channel (5) dramatically advanced the field by providing an efficient and straightforward single-component strategy for stimulating neuronal activity (6, 7).Besides cell-specific targeting of appropriate effector elements, precise neuronal control by optogenetics demands efficient light delivery to the neurons of interest. For behavioral studies, photostimulation is ideally accomplished in intact, freely moving organisms and accompanied by functional readouts. The combination of a rich, well-characterized behavioral repertoire and elegant molecular genetics has contributed to Drosophila’s strong impact on behavioral neurogenetics (8, 9). However, low light transmission through the pigmented cuticle presupposes high light intensities for using ChR2 in flies. This obstacle greatly complicates the experimental setup for freely moving animals, and the required light energies can cause heat damage when stimulation is applied over extended time periods. Moreover, limited cellular availability of all-trans-retinal (hereafter retinal for short) demands adding high retinal concentrations as a dietary supplement. If optical access to target cells is not provided by a translucent body wall (e.g., as in nematodes, zebrafish, and Drosophila larvae), an alternative solution is the implantation of an optical fiber directly into the brain. Although this approach has been used successfully in mammals (10), such an invasive procedure is infeasible for the study of intact small organisms.Due to these restrictions in Drosophila, ChR2 has not reached the popularity attained in other organisms, and instead the field has turned mainly to thermogenetic neuronal stimulation (11–13). As with all techniques, there are also drawbacks to using temperature as a stimulus, such as undesired background activity and a multitude of temperature-sensitive cellular processes and behavioral responses. Photo-liberation of caged ATP, combined with genetic targeting of ATP-gated ion channels, has been introduced as a different optogenetic technique in Drosophila (3, 14). However, its applications are constrained by invasive, time-consuming procedures for injection of caged ATP and a limited experimental time window.Here, we introduce improved ChR2 variants as an alternative approach to address these shortcomings in Drosophila. Compared with wild-type ChR2 (ChR2-wt), expression of these mutants in target cells led to strongly enhanced photocurrents. We provide the first report, to our knowledge, of ChR2-T159C (15, 16) in flies and describe a ChR2 variant, ChR2-XXL (extra high expression and long open state), that is characterized by an extended open-state lifetime, elevated cellular expression, enhanced axonal localization, and reduced dependence on retinal addition. As a consequence, this mutant does not require dietary retinal supplementation to depolarize cells, evoke synaptic transmission, and activate neuronal networks at very low irradiance. These features enabled behavioral photostimulation in freely moving flies using diffuse low-intensity light.     

DNA integrity determination in marine invertebrates by Fast Micromethod

This study was focused toward the adaptation of the previously developed Fast Micromethod for DNA damage determination to marine invertebrates for the establishment of biomonitoring assessment. The Fast Micromethod detects DNA damage (strand breaks, alkali-labile sites and incomplete excision repair) and determines DNA integrity in cell suspensions or tissue homogenates in single microplates. The procedure is based on the ability of the specific fluorochrome dye PicoGreen to preferentially interact with high integrity DNA molecules, dsDNA, in the presence of ssDNA and proteins in high alkaline medium, thereby allowing direct fluorometric measurements of dsDNA denaturation without sample handling and stepwise DNA separations. The results presented herein describe the influence of the DNA amount and the pH of the denaturation media on slopes of the kinetic denaturation curves and calculated strand scission factors (SSFs). The optimal amount of DNA in Mytilus galloprovincialis gills homogenate was found to be 100 ng ml(-1) and the greatest differences in DNA unwinding kinetics (slopes and SSF values) were reached at pH 11.5. The induction of DNA damage and loss of DNA integrity was measured in native DNA isolated from cotton-spinner Holothuria tubulosa, marine sponge Suberites domuncula cells and mussel M. galloprovincialis gills homogenate. DNA damage and loss of DNA integrity were detected after induction by different doses of (gamma-rays, generated by 137Cs 1800 Ci; 0-500 rad in marine sponge S. domuncula cells up to SSFx(-1) values 0.082 +/- 0.012 for the highest radiation dose). Analysis by chemical xenobiotics based on the in vitro action of bleomycin (bleomycin-Fe(II) complex 0-50 or 0-83 microg ml(-1) (microM)) with native DNA from cotton-spinner H. tubulosa and mussel M. galloprovincialis gills homogenate yielded values of 0.537 +/- 0.072 and 0.130 +/- 0.018, respectively. In vivo experiments with mussel M. galloprovincialis gills homogenate by 4-nitroquinoline-N-oxide (NQO; 0-1 microg g(-1) NQO mussel) and benzo[a]pyrene (B[a]P; 0-20 microg g(-1) B[a]P mussel) indicated SSFx(-1) values of 0.121 +/- 0.016 and 0.090 +/- 0.007, respectively, for the highest applied doses of chemical xenobiotics. The analytical technique described here allows simple and fast analysis of DNA integrity, requires very short time for multiple analyses (less than 3 h) and even less than 100 ng DNA per single well (50 ng DNA isolated from cotton-spinner, 12,500 sponge cells or about 10 mg of mussel gills homogenate) in a microplate. This makes the Fast Micromethod applicable for the measurement of DNA integrity of small samples for genotoxicity assessment (biomonitoring), the effects of genotoxins on lower marine taxa or sessile invertebrates in marine environment (e.g. sponges, mussels) and the estimation of directional changes and harmful effects in the ecosystem.     

The A9 allele of the dopamine transporter gene is associated with delirium tremens and alcohol-withdrawal seizure.

BACKGROUND: The dopamine transporter (DAT) plays a key role in homeostatic regulation of dopaminergic neurotransmission and could thus be involved in the variability of two severe alcohol-withdrawal symptoms, alcohol-withdrawal seizure (AWS) and delirium tremens (DT). Interestingly, an association was found between the DAT gene (9-copy repeat) and the risk for these symptoms in two previous case-control studies. METHODS: We reanalyzed the role of the DAT gene in the lifetime risk for AWS and DT in 120 alcohol-dependent patients, taking into account potentially confounding factors. RESULTS: Alcohol-dependent patients with the A(9) allele had experienced AWS or DT at least once (odds ratio [OR] = 2.52, p =.03). This association persisted when excluding patients with antisocial personality comorbidity (OR = 3.48, p =.02) or limiting the analysis to older patients (OR = 8.3, p =.0008). CONCLUSIONS: This study provides convergent data in favor of a significant role of the DAT gene in the risk for some severe withdrawal symptoms. If further replicated in larger samples, the DAT genetic polymorphism could be one of the factors to be analyzed to further assess the risk of some severe alcohol-withdrawal symptoms.     

Spontaneous reports of hypersensitivity adverse drug reactions in Portugal: a retrospective analysis

ABSTRACT

Background

Hypersensitivity adverse drug reactions (ADRs) are usually serious, unpredictable, and associated with high morbidity and mortality. This study describes cases of hypersensitivity ADRs spontaneously reported in Central Portugal.     

Inhibitory effects of extracts from the marine alga Caulerpa taxifolia and of toxin from Caulerpa racemosa on multixenobiotic resistance in the marine sponge Geodia cydonium

The invasive growth of the introduced green alga Caulerpa taxifolia, already affecting the richness and diversity of the littoral ecosystems, has become a major ecological problem in the Mediterranean Sea. Previously, we demonstrated that the water pollutant tributyltin induces apoptosis in tissue of the marine sponge Geodia cydonium at concentrations of 3 μM and higher. Here we show that exposure of G. cydonium to low (non-toxic) concentrations of Caulerpa extract or purified caulerpin (10 μg/ml) together with low doses of tributyltin (1 μM; non-toxic), results in a strong apoptotic effect. Evidence is presented that the enhancement of toxicity of tributyltin by Caulerpa extract is at least partially caused by inhibition of the multixenobiotic resistance (MXR) pump by the algal toxin. Caulerpa extract, as well as caulerpin, strongly enhance the accumulation of the test substrate of MXR, rhodamine B, in the gills of the mussel Dreissena polymorpha, used as a model system for testing MXR-inhibiting potential.     

Multiple drug exposure as a risk factor for the seriousness of adverse drug reactions

macedo a.f., alves c., craveiro n. & marques f.b. (2011) Journal of Nursing Management  19, 395–399
Multiple drug exposure as a risk factor for the seriousness of adverse drug reactions Aim The aim of the present study was to validate the hypothesis that multiple drug exposure is an independent risk factor for serious adverse drug reactions (ADRs). Background Adverse drug reactions (ADRs) are an important cause of iatrogenic disease, the majority being preventable. Multiple drug exposure, ageing and female gender have been identified as important risk factors for an increased incidence of ADRs. Method ADR reports received by the central Portugal Regional Pharmacovigilance Unit, between January 2001 and December 2009, were studied. Results Nearly half (47.4%) of ADRs reports were considered serious, from which 66.7% reported multiple drug exposure (mean 3.07 ± 2.2; maximum 13). After adjusting for gender, simultaneous exposure to three or more drugs was significantly associated with an increased risk of serious ADRs [odds ratio (OR) 1.23; 95% confidence interval (CI) 1.02–1.51]. Conclusions The present results support that multiple drug exposure is an independent risk factor for serious ADRs. Such findings are of importance in both medicines benefit/risk ratio evaluations and patient safety monitoring. Implications for nursing management A new level of nursing involvement is needed in both the detection of ADRs and prevention of serious outcomes, particularly in high-risk patients.     

Induction of labor in twin gestation: lessons from a population based study

Introduction: The route of delivery and the role of induction of labor in twin gestations are controversial. The aim of this study was to determine the efficacy of induction of labor in twin gestations.

Methods: This retrospective population based cohort study included 4605 twin gestations divided into following groups: 1) spontaneous parturition (n?=?2937, 63.78%); 2) induction of labor (n?=?653, 14.2%) and 3) elective cesarean delivery (n?=?1015, 22.04%).

Results: The rate of vaginal delivery in the labor induction group was 81% (529/653). In comparison to the other study groups, induction of labor in twins was independently associated with a 77% reduction in the risk of cesarean delivery (OR 0.23; 95% CI 0.18–0.31) and a 78% reduction in the risk of postpartum death for the second twin (OR 0.22; 95% CI 0.05–0.94). The rate of nulliparity, term delivery and labor dystocia was higher in the induction of labor group (p?<?0.001 in all comparisons).

Conclusions: Our results suggest that induction of labor in twin gestation is successful and is independently associated with substantial reduction in the risk of cesarean delivery and postpartum death of the second twin.