BMC Neuroscience
○ Springer Science and Business Media LLC
All preprints, ranked by how well they match BMC Neuroscience's content profile, based on 11 papers previously published here. The average preprint has a 0.01% match score for this journal, so anything above that is already an above-average fit. Older preprints may already have been published elsewhere.
Courtney, A.; Van Dijck, M.; Styfhals, R.; Almansa, E.; Obenhaus, H. A.; Schafer, W. R.; Seuntjens, E.
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Octopus vulgaris and other cephalopods are of increasing interest as neurobiological model organisms. This protocol describes a method to record calcium activity from individual cells in acute brain slices from Octopus vulgaris hatchlings during exogenous application of neurotransmitters. Using this protocol, we characterized single-cell responses to specific neurotransmitters in the optic lobes, which process visual information. The approach is readily adaptable to other cephalopods and small invertebrate species. Graphical abstract O_FIG O_LINKSMALLFIG WIDTH=146 HEIGHT=200 SRC="FIGDIR/small/711860v1_ufig1.gif" ALT="Figure 1"> View larger version (39K): org.highwire.dtl.DTLVardef@1564eaeorg.highwire.dtl.DTLVardef@147b682org.highwire.dtl.DTLVardef@11f3b85org.highwire.dtl.DTLVardef@17c9d70_HPS_FORMAT_FIGEXP M_FIG C_FIG
Garcia, F. C.
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We investigated O-linked {beta}-N-acetylglucosamine (O-GlcNAc), a post-translational modification, in an in vivo Caenorhabditis elegans model of Alzheimers Disease and aging. Employing a chemoenzymatic labeling strategy combined with an automated image processing approach, we analyzed both post-hatching and adult stages of wild-type N2 and transgenic strain expressing human tau V337M under the aex-3 promoter (aex-3p::tau(V337M)). Labeled O-GlcNAc proteins were visualized using fluorescence microscopy and quantified using a region-of-interest-based image analysis pipeline. Morphometric characterization revealed an age-dependent increase in O-GlcNAcylation in wild-type worms, while the AD model showed a progressive decline. In middle-aged transgenic nematodes, O-GlcNAc-labeled regions of interest shifted from anterograde to predominantly retrograde movement, suggesting that aging and neurodegeneration alter O-GlcNAc trafficking dynamics, potentially reflecting impaired synaptic support or enhanced clearance in C. elegans. Graphical Abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=133 SRC="FIGDIR/small/659071v2_ufig1.gif" ALT="Figure 1"> View larger version (26K): org.highwire.dtl.DTLVardef@10d6816org.highwire.dtl.DTLVardef@12ca2d8org.highwire.dtl.DTLVardef@17742b2org.highwire.dtl.DTLVardef@bbc33b_HPS_FORMAT_FIGEXP M_FIG C_FIG
Rami, S.; So, M.; Travis, C.; Jiao, Y.; Shamble, P.; Sorrells, T. R.
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The mosquito Aedes aegypti is an important vector of viral pathogens and serves as a model for other vector species. Pathogens are transmitted when a mosquito bites a host animal, but the neural circuits that control seeking and biting behavior are not known. Here, we detail methods and protocols for the manipulation of neural activity in the mosquito using optogenetics, a key technique to determine the causal relationship between neural circuits and behavior. These methods include rearing mosquitoes for optogenetics and three assays that are designed to measure different steps in the sequence of arousal, attraction, proboscis probing, and engorgement on the blood of host animals. These behaviors occur at different spatial scales and in response to different sensory stimuli. Each behavioral assay is outfitted with red (625 nm) LEDs for optogenetic activation. To detect arousal in response to olfactory stimuli, flight and walking are measured in all three assays. To assay attraction or landing, mosquitoes are presented with a heated blood meal in a large arena. Proboscis probing and engorgement are assayed with video resolution that enables measurement of appendages and abdomen size. The protocol describes machine vision models to enable high-resolution temporal quantification of behavior as well as endpoint measurements of feeding. These methods can be used to test the function of any population of neurons in mosquito biting behavior and can be extended to additional behaviors.
Koopman, M.; Janssen, L.; Nollen, E.
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AbstractOptogenetic tools have revolutionized the study of neuronal circuits in Caenorhabditis elegans. The expression of light-sensitive ion channels or pumps under specific promotors allows researchers to modify the behavior of excitable cells. Several optogenetic systems have been developed to spatially and temporally photoactivate light-sensitive actuators in C. elegans. Nevertheless, their high costs and low flexibility have limited wide access to optogenetics. Here, we developed an inexpensive, easy-to-build, and adjustable optogenetics device for use on different microscopes and worm trackers, called the OptoArm. The OptoArm allows for single- and multiple-worm illumination and is adaptable in terms of light intensity, lighting profiles and light-color. We demonstrate the OptoArms power in a population-based study on contributions of motor circuit cells to age-related motility decline. We find that functional decline of cholinergic neurons mirrors motor decline, while GABAergic neurons and muscle cells are relatively age-resilient, suggesting that rate-limiting cells exist and determine neuronal circuit aging.
Baeza-Lehnert, F.; Contreras-Baeza, Y.; Aburto, C.; San Martin, A.
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SignificancePyruvate is a nodal intermediate in cellular metabolism, positioned at the crossroads between glycolysis and fermentative metabolism. It is exchanged between the intracellular and extracellular compartments through the proton-coupled monocarboxylate transporters and between the cytosol and mitochondria through the mitochondrial pyruvate carrier, where it serves as a primary carbon source for respiration. AimOur goal is to present a detailed protocol for quantifying cytosolic pyruvate concentration in neurons at single-cell resolution using a minimally invasive, two-point calibration approach with the FRET-based genetically-encoded fluorescent indicator Pyronic. ApproachThis protocol is based on a non-invasive pharmacological two-point calibration approach, where Pyronics dynamic range ({Delta}RMAX) is established by using trans-acceleration exchange to deplete intracellular pyruvate (RMIN), and by inducing Pyronic saturation (RMAX) through the combination of inhibition of pyruvate export, stimulation of its production, and blockade of its mitochondrial consumption. The protocol also incorporates the previously published KD values for Pyronic obtained from in vitro experiments. This procedure does not require the use of detergents to permeabilize the cells. ResultsImplementing this protocol enables the measurement of absolute cytosolic pyruvate concentrations. This quantitative parameter facilitates comparisons of pyruvate metabolism across different cells, samples and experimental batches, thereby enabling the comparison between a plethora of experimental conditions. ConclusionsThe FRET-based fluorescent indicator Pyronic can be reliably calibrated using a minimally invasive, pharmacology-based two-point calibration protocol in neurons, thus providing a robust and quantitative method to study pyruvate metabolism under various physiological and pathological scenarios.
Lucumi Moreno, E.; Hachi, S.; Nickels, S. L.; Kane, K. I.; Moein, M.; Schwamborn, J. C.; Skupin, A.; Vanden Berghe, P.; Fleming, R. M.
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Monogenic Parkinsons Disease can be caused by a mutation in the leucine-rich repeat kinase 2 (LRRK2) gene, causing a late-onset autosomal dominant inherited form of Parkinsons Disease. The function of the LRRK2 gene is incompletely understood, but several in vitro studies have reported that LRRK2-G2019S mutations affect neurite branching, calcium homeostasis and mitochondrial function, but thus far, there have been no reports of effects on electrophysiological activity. We assessed the neuronal activity of induced pluripotent stem cell derived neurons from Parkinsons Disease patients with LRRK2-G2019S mutations and isogenic controls. Neuronal activity of spontaneously firing neuronal populations was recorded with a fluorescent calcium-sensitive dye (Fluo-4) and analysed with a novel image analysis pipeline that combined semi-automated neuronal segmentation and quantification of calcium transient properties. Compared with controls, LRRK2-G2019S mutants have shortened inter-spike intervals and an increased rate of spontaneous calcium transient induction.
Ladurner, G.; Augustin, M.; Harper, D. J.; Worm, S.; Varaka, M.; May, L.; Patel, Y.; Rohrmoser, T.; Garcia-Ramirez, F.; Garhoefer, G.; Prokesch, M.; Baumann, B.; Merkle, C.
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PurposeThe optic nerve head (ONH) is a central feature of the retina, affected in many human ocular pathologies, yet it has remained underexplored in most mouse models of disease. We hypothesize that the analysis of the ONH can yield valuable insight into the phenotype of retinal diseases and that pathological changes can be detected using state-of-the-art optical coherence tomography (OCT). MethodsFour mouse models - the 5xFAD, PS19 and APP/PS1 models of Alzheimers disease (AD) as well as the SOD1 knockout mouse model - were imaged using a polarization-sensitive OCT system to investigate potential disease related changes of the ONH. 5xFAD and SOD1 animals were investigated longitudinally to study disease progression. Additionally, aging effects in wild type mice were studied. ResultsTwo different analysis methods for the segmentation of the ONH were implemented and evaluated. Longitudinal changes to the ONH in 5xFAD animals were observed, specifically an increase of ONH volume from 3 to 5 months of age followed by a strong decrease until 9 months of age. Significant differences between transgenic (tg) and non-transgenic (ntg) animals, as well as sex dependent distinctions were found. Also, for the APP/PS1 model disease related differences between ntg and tg APP/PS1 were significant. ConclusionsWe demonstrated a simple segmentation of the ONH structure based on OCT intensity images and show its potential as a preclinical biomarker in amyloid mouse models of AD.
Reynolds, D. A.; Artenyan, E.; Nazaryan, H.; Shanakian, E.; Chen, E.; Abramian, V.; Ghashghaei, A.; Sahabi, K.; Safieh, F.; Momjian, N.; Sunthorncharoenwong, J.; Arisaka, K.
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Motion artifacts remain a barrier to in vivo calcium imaging in Drosophila melanogaster larvae. Here, we evaluate a multimodal immobilization approach that combines a Pluronic F-127 (PF-127) hydrogel with brief diethyl ether vapor exposure (5 minutes, 25{degrees}C) and compare it against hydrogel-only immobilization using custom MATLAB-based analysis software that performs NoRMCorre rigid motion correction. In wide-field GFP recordings at 1 Hz over approximately 60 minutes (N = 15 per group), the multimodal condition significantly reduced motion across all three core metrics after FDR correction (all q < 0.001), with large effect sizes for mean speed (Hedges g = -1.18) and median step size (g = -1.36). In a secondary analysis of the first 30 minutes, uniformly large effect sizes (|g| = 1.10-1.51) were observed, consistent with stronger initial chemical immobilization that partially wanes over the recording period. We implemented a dual-flag quality control system that distinguishes motion data reliability from ROI detection eligibility. Control calcium recordings (33.33 Hz, [~]5 minutes; N = 23) yielded 368 ROIs with a mean SNR 30.4 {+/-} 16.9 and an event rate of 0.228 {+/-} 0.113 Hz. Experimental recordings (N = 21) yielded 295 ROIs with SNR 18.0 {+/-} 10.6 and event rate 0.309 {+/-} 0.188 Hz. SNR was higher in controls (Cliffs{delta} = 0.50, p < 0.001), while event rate was modestly higher in the experimental group at the ROI level ({delta} = -0.22, p < 0.001), though this difference did not reach significance at the sample level, suggesting altered but not suppressed calcium dynamics. These results support a practical, accessible immobilization workflow for larval calcium imaging. HighlightsO_LIBrief ether + hydrogel approach reduces larval motion 85-91% vs. hydrogel alone C_LIO_LIDual-flag QC system separates motion reliability from calcium ROI eligibility C_LIO_LICalcium event rates not suppressed under multimodal immobilization C_LIO_LIComplete MATLAB pipeline for motion analysis and calcium imaging provided C_LIO_LIAccessible protocol requires only standard laboratory supplies C_LI
Alsup, A. M.; Fowlds, K.; Cho, M.; Luber, J. M.
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Insulin secretion from pancreatic {beta}-cells is integral in maintaining the delicate equilibrium of blood glucose levels. Calcium is known to be a key regulator and triggers the release of insulin. This sub-cellular process can be monitored and tracked through live-cell imaging and subsequent cell segmentation, registration, tracking, and analysis of the calcium level in each cell. Current methods of analysis typically require the manual outlining of {beta}-cells, involve multiple software packages, and necessitate multiple researchers - all of which tend to introduce biases. Utilizing deep learning algorithms, we have therefore created a pipeline to automatically segment and track thousands of cells, which greatly reduces the time required to gather and analyze a large number of sub-cellular images and improve accuracy. Tracking cells over a time-series image stack also allows researchers to isolate specific calcium spiking patterns and spatially identify those of interest, creating an efficient and user-friendly analysis tool. Using our automated pipeline, a previous dataset used to evaluate changes in calcium spiking activity in {beta}-cells post-electric field stimulation was reanalyzed. Changes in spiking activity were found to be underestimated previously with manual segmentation. Moreover, the machine learning pipeline provides a powerful and rapid computational approach to examine, for example, how calcium signaling is regulated by intracellular interactions in a cluster of {beta}-cells.
Super, R.; Bui, B. V.; Xie, J.; Bou-Antoun, P.; Scholz, L.; Jusuf, P. R.
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Zebrafish (Danio rerio) are an important vertebrate model for vision and neuroscience research. In the larval stages, the aquatic species begins to elicit the optomotor response (OMR) to stabilize themselves in water -- a behaviour that may be exploited in the laboratory to measure visual acuity. However, up to now, the measurement of the OMR in juvenile and adult zebrafish has been limited due to their behavioural complexity. Here, we optimize a protocol to assay zebrafish aged between 4 and 9 weeks-post-fertilization, by displaying sinusoidal gratings parallel to the zebrafish eye to elicit a robust OMR. We assessed the visual spatial-frequency tuning function of an environmentally induced myopia model to confirm the sensitivity and robustness of the protocol. Additionally, we show the OMR is sensitive to the contrast and temporal resolution of the sinusoidal gratings. Furthermore, we found that the time between stimulus presentations impact the spatial-frequency tuning function likely as time is required for zebrafish to return to baseline swimming after eliciting the OMR. Finally, we found that the OMR after ten versus twenty seconds of stimulus onset appears comparable; indicating that robust OMR responses in zebrafish can be elicited through relatively short stimulus presentations. Through the experiments conducted, we present an optimized protocol specific to zebrafish. The protocol may be used to follow the progression or treatment efficacy of progressive neurological disorders including specific visual disorders and higher brain functions with visual endophenotypes. Ultimately, this protocol allows for high-throughput robust measures of visual and neural function in zebrafish.
Gomez, A.; Gonzalez, S.; Oke, A.; Luo, J.; Duong, J. B.; Esquerra, R. M.; Zimmerman, T.; Capponi, S.; Fung, J. C.; Nystul, T. G.
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Measurements of Drosophila fecundity are used in a wide variety of studies, such as investigations of stem cell biology, nutrition, behavior, and toxicology. In addition, because fecundity assays are performed on live flies, they are suitable for longitudinal studies such as investigations of aging or prolonged chemical exposure. However, standard Drosophila fecundity assays have been difficult to perform in a high-throughput manner because experimental factors such as the physiological state of the flies and environmental cues must be carefully controlled to achieve consistent results. In addition, exposing flies to a large number of different experimental conditions (such as chemical additives in the diet) and manually counting the number of eggs laid to determine the impact on fecundity is time-consuming. We have overcome these challenges by combining a new multiwell fly culture strategy with a novel 3D-printed fly transfer device to rapidly and accurately transfer flies from one plate to another; the RoboCam, a low-cost, custom built robotic camera to capture images of the wells automatically; and an image segmentation pipeline to automatically identify and quantify eggs. We show that this method is compatible with robust and consistent egg laying throughout the assay period; and demonstrate that the automated pipeline for quantifying fecundity is very accurate (r2 = 0.98 for the correlation between the automated egg counts and the ground truth) In addition, we show that this method can be used to efficiently detect the effects on fecundity induced by dietary exposure to chemicals. Taken together, this strategy substantially increases the efficiency and reproducibility of high throughput egg laying assays that require exposing flies to multiple different media conditions.
Leong, L. M.; Rhee, J. K.; Kim, H.; Seong, J.; Woo, J.; Han, K.; Storace, D. A.; Baker, B. J.
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Rapid and reproducible optical transitions of a fluorescent protein (FP) can be achieved with a Genetically Encoded Voltage Indicator (GEVI) via manipulation of the membrane potential. These transitions revealed novel effects of internal mutations near the chromophore that would not be detected under steady state conditions. Mutating an internal threonine (T203) affected the speed of the voltage-dependent fluorescence transition suggesting a conformational change inside the protein. These optical transitions also demonstrated interplay between internal and externally oriented sidechains of the {beta}-can structure. Replacing the steric hindrance of a phenylalanine near the chromophore with threonine (F165T) did not alter the resting fluorescence but resulted in a more complex fluorescent transition providing evidence for a flexible chromophore undergoing conformational changes. F165T orientation was influenced by the flanking external amino acids at positions 164 and 166 with 164F/165T/166T exacerbating the complexity of the voltage-dependent transition while 164T/165T/166F reduced the flexibility of the chromophore resembling the transition pattern of the original F165 version. Alphafold predictions reveal a threonine switch with different orientations of the F165T internal side chain depending on the direction of the offset in polarity at external positions 164 and 166. The crystal structures of the pH-sensitive FP, Super Ecliptic pHluorin and two derivatives solved in varying pH conditions also indicate interactions between the external protein surface and the internal environment providing another example of a threonine switch near the chromophore at T203. This ability to orient internal sidechains has led to the development of a novel GEVI that gets brighter upon depolarization of the plasma membrane, works at low light levels, is less susceptible to physiological pH, and provides in vivo signals. These observations affecting fluorescent transitions should also prove valuable to the development of any FP-based biosensor.
Manuel, N.; Mallipudi, M.; Gajwani, A.; Gopalkrishna Shetty Sreenivasa Murthy, S.; Jupiter, D. C.; Krishnan, B.
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Drosophila melanogaster serves as a powerful model for studying neurodegenerative diseases, often employing the GAL4-UAS system for targeted gene expression. Electroretinograms (ERGs) provide a robust in vivo functional readout of neuronal integrity and are increasingly used to assess disease progression and therapeutic interventions in these models. However, the genetic background upon which these models are built, particularly the widely used w1118 white-eyed mutant, can significantly influence baseline ERG characteristics. This study systematically characterizes ERG responses in wild-type Canton S (CS), w1118, and a w1118line carrying a UAS-hPLD1 construct (which includes a mini-white gene). We demonstrate profound differences in ERG amplitudes, waveforms, and responses to varying light stimuli (intensity and duration) between these genotypes, as well as significant sex-specific variations. Notably, w1118 flies exhibit markedly larger ERG amplitudes compared to CS, while the hPLD1 line shows partial compensation. We also introduce a novel quadrant-based analysis of the receptor potential, revealing distinct "fingerprints" for each genotype. These findings underscore that the w1118 background is not electrophysiologically neutral and can intrinsically alter neuronal responses. This has critical implications for interpreting ERG data from neurodegeneration models, as these background effects could mask or mimic disease-related changes. Researchers must consider these baseline differences and potential sex-specific effects to accurately attribute observed ERG phenotypes to the gene or condition under investigation. Graphical Abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=88 SRC="FIGDIR/small/626125v2_ufig1.gif" ALT="Figure 1"> View larger version (20K): org.highwire.dtl.DTLVardef@1b655f0org.highwire.dtl.DTLVardef@1c412e7org.highwire.dtl.DTLVardef@1b52fe3org.highwire.dtl.DTLVardef@5af680_HPS_FORMAT_FIGEXP M_FIG C_FIG HighlightsO_LIERG profiles differ significantly between CS, w1118, and w1118; UAS-hPLD1 flies. C_LIO_LIThe w1118 background, common in GAL4-UAS studies, exhibits distinct ERG features. C_LIO_LISex-specific differences in ERG responses are prominent and genotype-dependent. C_LIO_LIUAS-hPLD1 insertion (with mini-white) partially alters the w1118 ERG phenotype. C_LIO_LIResults caution the interpretation of ERG data in w1118 neurodegeneration models. C_LI
Olcay, B. O.
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Developing a reliable detection of olfactory performance for early Alzheimers disease (AD) diagnosis remains challenging. Existing methods, such as psychophysical and event-related potential approaches, provide limited consistency in quantifying olfactory function. This study introduces a novel and objective framework that analyzes olfactory-stimulus-evoked EEG synchronizations of the subjects for AD diagnosis. We calculated the time-resolved wavelet coherence between EEG signals and then determined the timings (i.e., latency and duration) that describe when olfactory-stimulus-induced EEG channel interactions begin and end for each channel and frequency band. These timings, as well as the mean synchronization values in these segments, were used as features for diagnosis. Our framework, when cross-correntropy was used as a synchronization measure, exhibited a notable diagnostic accuracy in mild AD detection. The most discriminating feature between mild AD and healthy subjects was found to be the latency of synchronization between Fp1 and Fz in the low{theta} band, which showed significantly high correlation with clinical test scores. Furthermore, our framework achieved 100% diagnosis accuracy when EEG features and clinical test scores were used together. Our findings show that inter-channel short-lived synchronization timings serve as useful and complementary metrics about subjects olfactory performance and their neurological conditions.
Enjin, A.; Giri, G.
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Understanding how organisms detect environmental humidity remains a fundamental problem in sensory biology. While specialized sensory neurons in insect antennae can detect changes in humidity, the mechanism underlying this ability is not fully understood. Here, we present an integrated approach combining precise humidity control, rapid cryo-preservation, and serial block-face scanning electron microscopy (SBF-SEM) to investigate the ultrastructure of hygrosensilla in the vinegar fly Drosophila melanogaster. We developed a deep learning-based segmentation pipeline to analyze three-dimensional structural features of sensilla exposed to different humidity conditions at stable temperature. Our analysis reveals consistent differences in sensilla width between high (80% RH) and low (26% RH) humidity conditions across all chambers of the sacculus. Additionally, we identified chamber-specific patterns in sensilla tapering, indicating specialized structural adaptations across different sensilla populations. The observed structural changes suggest a potential role for mechanical transduction in humidity sensing. This study establishes a technical framework for high-resolution analysis of sensory organs while providing new insights into the structural basis of humidity detection. Our findings advance our understanding of how specialized sensory organs might transduce environmental signals into neural responses.
Bednarczyk, P.; Beresewicz-Haller, M.; Lewandowska, J.; Kulawiak, B.; Wrzosek, A.; Zablocka, B.; Szewczyk, A.; Kalenik, B.
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Photobiomodulation (PBM) is a therapeutic approach based on illumination with red or near-infrared (NIR) light. Cytochrome c oxidase (COX), a terminal enzyme of the mitochondrial respiratory chain, contains copper centers (CuA and CuB) that absorb light within the red and NIR spectral range, making it a potential primary photoacceptor at wavelengths around 820 nm. PBM appears to be a promising strategy for the treatment and prevention of neurological disorders. Elucidating its precise molecular mechanisms may help optimize therapeutic outcomes. Using patch-clamp method, we showed that illumination with 820 nm light activates mitochondrial large-conductance calcium-activated potassium (mitoBKCa) channels in rat hippocampal mitochondria. Moreover, 820 nm light caused neuroprotective effect in NMDA-treated organotypic hippocampal cultures. Consistently, activation of mitoBKCa channel by 820 nm light illumination was observed in mitochondria isolated from glioma U-87 MG cells. To further investigate the role of mitoBKCa channel, we used CRISPR/Cas9- developed U-87 MG cells lacking the -subunit of the BKCa channel (dBK cells). Comparative transcriptomic analysis of illuminated wild-type and dBK cells revealed significant differences in gene expression profiles. In summary, our results show two types of cellular responses to the PBM. An acute effect involving activation of the mitoBKCa channel and a long-term effect associated with extensive transcriptome remodeling. Both mechanisms may contribute to the cytoprotective effect of 820 nm near-infrared light. HighlightsO_LI820 nm light activates hippocampal mitochondrial BKCa channels C_LIO_LI820 nm light induces hippocampal neuroprotection under excitotoxic conditions C_LIO_LI820 nm light causes intensive transcriptome remodeling in glioma cells C_LIO_LIBKCa channels modulate a subset of transcriptomic responses to 820 nm light C_LI Graphical abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=171 SRC="FIGDIR/small/731043v1_ufig1.gif" ALT="Figure 1"> View larger version (20K): org.highwire.dtl.DTLVardef@5a5595org.highwire.dtl.DTLVardef@a8ddb2org.highwire.dtl.DTLVardef@72ec20org.highwire.dtl.DTLVardef@ec46da_HPS_FORMAT_FIGEXP M_FIG C_FIG
Sun, S.; Zhu, C.; Ma, M.; Ni, B.; Chen, L.; Zhu, H.; Zuxiang, L.
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BackgroundTransient pentylenetetrazol (PTZ) treatment on zebrafish larvae has been widely accepted a promising animal model for human epilepsy. However, this model is not ideal due to its acuteness and lack of recurrent seizures, which are the key feature of epilepsy in human disease. It is important to develop a more sensitive zebrafish model for epilepsy with well-controlled, predictable, recurrent seizures.\n\nNew MethodThe new method includes an experimental setup and a treatment protocol. The setup tracks the locomotion activity of up to 48 larvae simultaneously, while a visual stimulus can be presented to each of the 48 animals individually. The protocol treated the larvae through a water bath in 5 mM PTZ while being stimulated with rotating grating stimuli for 1 hour/day from 5 to 7 days postfertilization.\n\nResultsThe setup captured the locomotion activity of zebrafish larvae during visual stimulation. The new protocol generated recurrent responses after flashing lights 4 hours post PTZ treatment. The effects could be suppressed by the anti-epileptic drug valproic acid. The characteristics of the visual stimulus play a major role in this kindling model.\n\nComparisons with Existing MethodsWe compared the proposed method with the transient PTZ model and confirmed that the flashing-light-evoked recurrent seizure is a new feature in addition to the transient changes.\n\nConclusionsThe new method generated non-drug-triggered predictable recurrent seizures in response to intermittent photic stimulation in zebrafish larvae and may serve as a sensitive method for anti-epileptic drug screening or a new research protocol in epilepsy research.
Otero, M.; Prieur, Y.; El-Deredy, W.; Weinstein, A.
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Visually evoked steady-state potentials (SSVEPs) are neural responses elicited by visual stimuli oscillating at specific frequencies. In this study, we introduce a novel LED display system designed specifically for steady-state visual stimulation, offering precise control over visual stimulus parameters, including frequency resolution, luminance, and the ability to control the phase at the end of the stimulation. The LED display provides a personalized, modular, and affordable option for experimental setups. Based on the Teensy 3.2 board, the display utilizes Direct Digital Synthesis and Pulse Width Modulation techniques to control the LEDs. Its performance is validated through four experiments: the first two measure LED light intensities directly, while the last two assess the displays impact on EEG recordings. The results demonstrate that the display can deliver a stimulus suitable for generating SSVEPs with the desired frequency and phase resolution. We provide comprehensive documentation, including all necessary codes and electrical diagrams, as an open-source resource. This facilitates the replication and adaptation of the system for specific experimental requirements, enhancing its potential for widespread use in the field of neuroscience.
Robledo-Sanchez, K. C. M.; Ruiz-Suarez, J. C.
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General anesthesia (GA) has been under scientific scrutiny since its discovery more than a century ago, resulting in conceptually different proposed mechanisms to explain its origin and operation. Two mechanisms stand out: the lipid and the protein hypothesis. The Meyer-Overton rule (the more anesthetics dissolve in octanol, the greater their action) backups the first hypothesis, while the ligand-receptor interaction, specifically on ion channels, sustains the second. A recent study on Drosophila melanogaster draws attention to the possibility that both paradigms come together to explain GA synergistically, with the important caveat that this hybrid mechanism lies in the existence of lipid rafts in which cholesterol plays an essential role. Using two model organisms, the water flea (D. magna) and the nematode C. elegans, we give a further step to clarify this puzzle by carrying out anesthetic experiments with xenon and nitrous oxide. First, the obtained dose-response curves are very steep, implying that Hill coefficients greater than one are needed to describe them correctly, supporting an unspecific action mechanism. Second, we show that the animals response to both gases is influenced by a cholesterol diet modification, thus proving that this lipid promotes anesthetic induction. Our findings reenforce the idea that GA is driven by an allosteric induction rather than selective actions on single-target receptors.
Dehkharghanian, T.; Hashemiaghdam, A.; Ashrafi, G.
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SignificanceThe firefly enzyme luciferase has been used in a wide range of biological assays, including bioluminescence imaging of ATP. The biosensor Syn-ATP utilizes subcellular targeting of luciferase to nerve terminals for optical measurement of ATP in this compartment. Manual analysis of Syn-ATP signals is challenging due to signal heterogeneity and cellular motion in long imaging sessions. Here, we have leveraged machine learning tools to develop a method for analysis of bioluminescence images. AimOur goal was to create a semi-automated pipeline for analysis of bioluminescence imaging to improve measurements of ATP content in nerve terminals. ApproachWe developed an image analysis pipeline that applies machine learning toolkits to distinguish neurons from background signals, and excludes neural cell bodies, while also incorporating user input. ResultsSide-by-side comparison of manual and semi-automated image analysis demonstrated that the latter improves precision and accuracy of ATP measurements. ConclusionsOur method streamlines data analysis and reduces user-introduced bias, thus enhancing the reproducibility and reliability of quantitative ATP imaging in nerve terminals.