Background-Ca2ϩ release from the sarcoplasmic reticulum via the ryanodine receptor (RyR2) activates cardiac myocyte contraction. An important regulator of RyR2 function is FKBP12.6, which stabilizes RyR2 in the closed state during diastole. -Adrenergic stimulation has been suggested to dissociate FKBP12.6 from RyR2, leading to diastolic sarcoplasmic reticulum Ca 2ϩ leakage and ventricular tachycardia (VT). We tested the hypothesis that FKBP12.6 overexpression in cardiac myocytes can reduce susceptibility to VT in stress conditions. Methods and Results-We developed a mouse model with conditional cardiac-specific overexpression of FKBP12.6.Transgenic mouse hearts showed a marked increase in FKBP12.6 binding to RyR2 compared with controls both at baseline and on isoproterenol stimulation (0.2 mg/kg IP). After pretreatment with isoproterenol, burst pacing induced VT in 10 of 23 control mice but in only 1 of 14 transgenic mice (PϽ0.05). In isolated transgenic myocytes, Ca 2ϩ spark frequency was reduced by 50% (PϽ0.01), a reduction that persisted under isoproterenol stimulation, whereas the sarcoplasmic reticulum Ca 2ϩ load remained unchanged. In parallel, peak I Ca,L density decreased by 15% (PϽ0.01), and the Ca 2ϩ transient peak amplitude decreased by 30% (PϽ0.001). A 33.5% prolongation of the caffeine-evoked Ca 2ϩ transient decay was associated with an 18% reduction in the Na ϩ -Ca 2ϩ exchanger protein level (PϽ0.05). Conclusions-Increased FKBP12.6 binding to RyR2 prevents triggered VT in normal hearts in stress conditions, probably by reducing diastolic sarcoplasmic reticulum Ca 2ϩ leak. This indicates that the FKBP12.6-RyR2 complex is an important candidate target for pharmacological prevention of VT.
A novel alpha 7 nAChR agonist, 4-(5-methyloxazolo[4,5-b]pyridin-2-yl)-1,4-diazabicyclo[3.2.2]nonane (24, CP-810,123), has been identified as a potential treatment for cognitive deficits associated with psychiatric or neurological conditions including schizophrenia and Alzheimer's disease. Compound 24 is a potent and selective compound with excellent pharmaceutical properties. In rodent, the compound displays high oral bioavailability and excellent brain penetration affording high levels of receptor occupancy and in vivo efficacy in auditory sensory gating and novel object recognition. The structural diversity of this compound and its preclinical in vitro and in vivo package support the hypothesis that alpha 7 nAChR agonists may have potential as a pharmacotherapy for the treatment of cognitive deficits in schizophrenia.
Distinguishing tumors from normal brain cells is important but challenging in glioma surgery due to the lack of clear interfaces between the two. The ability of label‐free third harmonic generation (THG) microscopy in combination with automated image analysis to quantitatively detect glioma infiltration in fresh, unprocessed tissue in real time is assessed. The THG images reveal increased cellularity in grades II–IV glioma samples from 23 patients, as confirmed by subsequent hematoxylin and eosin histology. An automated image quantification workflow is presented for quantitative assessment of the imaged cellularity as a reflection of the degree of glioma invasion. The cellularity is validated in three ways: 1) Quantitative comparison of THG imaging with fluorescence microscopy of nucleus‐stained samples demonstrates that THG reflects the true tissue cellularity. 2) Thresholding of THG cellularity differentiates normal brain from glioma infiltration, with 96.6% sensitivity and 95.5% specificity, in nearly perfect (93%) agreement with pathologists. 3) In one patient, a good correlation between THG cellularity and preoperative magnetic resonance and positron emission tomography imaging is demonstrated. In conclusion, quantitative real‐time THG microscopy accurately assesses glioma infiltration in ex vivo human brain samples, and therefore holds strong potential for improving the accuracy of surgical resection.
Third harmonic generation (THG) microscopy is a label-free imaging technique that shows great potential for rapid pathology of brain tissue during brain tumor surgery. However, the interpretation of THG brain images should be quantitatively linked to images of more standard imaging techniques, which so far has been done qualitatively only. We establish here such a quantitative link between THG images of mouse brain tissue and all-nuclei-highlighted fluorescence images, acquired simultaneously from the same tissue area. For quantitative comparison of a substantial pair of images, we present here a segmentation workflow that is applicable for both THG and fluorescence images, with a precision of 91.3 % and 95.8 % achieved respectively. We find that the correspondence between the main features of the two imaging modalities amounts to 88.9 %, providing quantitative evidence of the interpretation of dark holes as brain cells. Moreover, 80 % bright objects in THG images overlap with nuclei highlighted in the fluorescence images, and they are 2 times smaller than the dark holes, showing that cells of different morphologies can be recognized in THG images. We expect that the described quantitative comparison is applicable to other types of brain tissue and with more specific staining experiments for cell type identification.
Intraflagellar transport (IFT), a bidirectional intracellular transport mechanism in cilia, relies on the cooperation of kinesin-2 and IFT-dynein motors. In Caenorhabditis elegans chemosensory cilia, motors undergo rapid turnarounds to effectively work together in driving IFT. Here, we push the envelope of fluorescence imaging to obtain insight into the underlying mechanism of motor turnarounds. We developed an alternating dual-color imaging system that allows simultaneous single-molecule imaging of kinesin-II turnarounds and ensemble imaging of IFT trains. This approach allowed direct visualization of motor detachment and reattachment during turnarounds and accordingly demonstrated that the turnarounds are actually single-motor switching between opposite-direction IFT trains rather than the behaviors of motors moving independently of IFT trains. We further improved the time resolution of single-motor imaging up to 30 ms to zoom into motor turnarounds, revealing diffusion during motor turnarounds, which unveils the mechanism of motor switching trains: detach–diffuse–attach. The subsequent single-molecule analysis of turnarounds unveiled location-dependent diffusion coefficients and diffusion times for both kinesin-2 and IFT-dynein motors. From correlating the diffusion times with IFT train frequencies, we estimated that kinesins tend to attach to the next train passing in the opposite direction. IFT-dynein, however, diffuses longer and lets one or two trains pass before attaching. This might be a direct consequence of the lower diffusion coefficient of the larger IFT-dynein. Our results provide important insights into how motors can cooperate to drive intracellular transport.
Supplementary data are available at Bioinformatics online.
Gene editing technology has been at its mature stage with the successful development of TALENs and CRISPR/Cas enzymes. The genetically modified endonucleases of ZFNs, TALENs, and CRISPR/Cas are widely used in the development of genetically modified cells or organisms. Among the enzymes that possess gene editing ability, CRISPR/Cas is the latest member with high efficiency in gene editing and simplicity in cloning. This review discusses the discovery of CRISPR, the development of the CRISPR/Cas system, and its applications as a new gene editing system.
The advance of mobile electronics applications has been demanding higher drop/shock reliability performance under more severe drop/shock impacts. This in turn is requiring the board level reliability (BLR) drop test to be able to reach higher peak acceleration, particularly higher than 5000 G. One method to reach this high acceleration is to use an apparatus called Dual Mass Shock Amplifier (DMSA) attached onto a conventional drop tester. The conventional drop tester typically generates a primary impact in the range of 1000 ~ 2000 G, and the DMSA, which hangs above the drop table of the drop tester and continues to fall down immediately following the primary impact, is capable to generate a secondary impact with the drop table with magnitude 2~5x of the primary impact in terms of peak acceleration. In this study, the mechanics of drop test and DMSA was introduced and modeled with Newton physics. Two DMSAs with various different features were custom-designed, fabricated, assembled, and tested. Various aspects of the DMSA, including materials, layout, weight, gap height, holding mechanism, were evaluated and addressed. The effects of drop height, weight of DMSA, and gap height on the change of velocity and peak acceleration of secondary impact were studied. The strain on BLR drop test board under high acceleration impact was measured and discussed. Consistency of the shock amplification characterized by C pk was studied and method to improve the consistency was discussed. It is demonstrated through this study that using DMSA can be a simple, economical, and consistent method to achieve high acceleration for BLR drop test.
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