Global ETD Search

21	Central sound encoding in the inferior colliculus of mouse models for human auditory synaptopathy and neuropathy Pelgrim, Maike 04 December 2018 (has links) No description available. 570 Otoferlin Inferior Colliculus Single Unit Recording Auditory Neuropathy Ribbon Synapse Hair Cell Hearing Loss Bassoon Spectrin Biologie (PPN619462639)
22	Etude du rôle des propriétés mécaniques des cellules de l'épiderme au cours de l'allongement des embryons de C. elegans / Genetic analysis of epidermal cells mechanical properties during C. elegans embryonic elongation Pasti, Gabriella 19 November 2015 (has links) Mon travail se concentre sur la morphogenèse épithéliale pendant l’élongation embryonnaire de C. elegans. Ce processus s’appuie sur la transmission de signaux mécaniques, jouent un rôle essentiel également au cours de l’homéostasie tissulaire. Le gène pak-1 joue un rôle essentiel au cours des tels processus à la fois chez l’homme et dans l’élongation chez C. elegans. Nous avons montré que α-spectrine (SPC-1) est un nouveau partenaire de la kinase PAK-1. Pendant mon doctorat, j’ai confirmé que la perte simultanée de PAK-1 et de SPC-1 induit des défauts sévères d’élongation, impliquant une rétractation et un collapse général de l’embryon et suggèrent la présence de défauts biomécaniques. Mon travail était destiné à déterminer comment la perte de PAK-1 et SPC-1 influence le comportement mécanique des cellules épidermales. Cette étude permettra de mieux d’établir le rôle de SPC-1 et de PAK-1 dans la morphogenèse épithéliale et de mieux comprendre la régulation des propriétés mécaniques des cellules dans un contexte vivant. / I study epithelial morphogenesis during C. elegans embryonic elongation. This process depends on mechanical cues that also influence tissue homeostasis. The pak-1 gene plays an essential role equally during such processes in human and during C. elegans elongation. Our work identified α-spectrin (SPC-1) as a new interactor of the kinase PAK-1. During my PhD I confirmed that the simultaneous lack of PAK-1 and SPC-1 induces serious elongation defects, including a retraction and general collapse of the embryo and suggests that the mechanical properties of the epidermis are modified. My work aimed to determine how the simultaneous lack of PAK-1 and SPC-1 could influence these processes. Such studies would allow to better establish the role of SPC-1 and PAK-1 during epithelial morphogenesis and to better understand the regulation of cellular mechanical properties in the living organisms. Morphogenèse épithéliale C. elegans PAK-1 Αlpha-spectrine SPC-1 Mécanotransduction Epithelial morphogenesis C. elegans PAK-1 Alpha-spectrin SPC-1 Mechanotransduction 571.8 572.8
23	Molecular physiology of ankyrin-G in the heart:Critical regulator of cardiac cellular excitability and architecture. Makara, Michael A. 12 August 2016 (has links) No description available. Cellular Biology Physiology ankyrin arrhythmia heart failure sodium channel plakophilin CaMKII spectrin intercalated disc late sodium current cardiovascular disease sudden cardiac arrest SCN5A
24	Potential of βII-spectrin as a biomarker of cardiac health Mohammad, Somayya J. January 2022 (has links) No description available. Biology Medicine Molecular Biology Oncology Pharmacy Sciences Physiology Toxicology
25	The ovine lens cytoskeleton McDermott, Joshua D. January 2007 (has links) The lens of the eye is a vital tissue in the visual system, responsible for the collection and focusing of light on to the retina. Comprised of epithelial cells at differing stages of differentiation, the transparency of the lens is dependent on the highly ordered crystalline structure of lens proteins. The lens consists of several proteins including crystallins (α, β, γ) that make up 90% of the soluble protein, and the lens cytoskeletal proteins. Cytoskeletal proteins contribute only a fraction of the total lens protein, but are thought to play an important role in the establishment and maintenance of transparency. Calpain-induced degradation of these proteins may be involved in the development of cataracts. This has been an area of research at Lincoln University where a flock of sheep genetically predisposed to cataract maintained as a cataract development model. The aim of this research was to investigate the distribution of cytoskeletal proteins in the lens, and to examine the effects of calpain proteolysis on these proteins, with the goal of establishing the role of the lens cytoskeletal proteins in the ovine cataract model. A combination of techniques was used including immunohistochemistry, which required the development of a specific protocol for ovine lenses. Cytoskeletal proteins were identified using immunohistochemistry in lens tissue sections and exhibited characteristic distributions. Actin displayed preferential distribution in the short sides of the fibre cells in the cortex of the lens but was absent in the lens nucleus, while spectrin in the cortex and nucleus was associated with the fibre cell membrane. Filensin was observed in the outer cortex of lens sections associated with the fibre cell membrane and cytoplasm, although the pattern of localisation was indistinct due to the abundance of filensin breakdown products. Vimentin displayed membrane and cytoplasmic association in the outer cortex that diminished toward the lens nucleus, with membrane associated vimentin only persisting in the deeper regions of the cortex and nucleus. Additionally, the effect of novel calpain inhibitors (Cat0059 and Cat811) in preventing proteolysis of lens cytoskeletal protein was investigated and compared with calpain inhibitors developed elsewhere (SJA6017). The inhibitors were tested at between 10 and 0.1 μM (100 nM). All inhibitors were effective at 10 μM. SJA6017 provided significant protection to vimentin at 1 μM. Cat0059 was found to protect spectrin and filensin at 1 μM, but not vimentin, while inhibitor Cat811 was found to protect spectrin only. SJA6017 added to assays at 100 nM offered significant protection to spectrin, and Cat0059 was found to protect filensin and spectrin to a significant degree at 100 nM, indicating the novel inhibitors were comparable to those developed elsewhere in terms of their effectiveness. Taken together, the evidence presented in this thesis shows the cytoskeletal proteins as crucial elements in the lens. Their pervasive presence coupled with evidence that lens cytoskeletal proteins are sensitive to calpain-induced proteolysis that is inhibited with novel calpain inhibitors suggests that the lens cytoskeletal proteins may be useful targets in cataract prevention for future research. lens immunohistochemistry cytoskeleton actin spectrin vimentin filensin fluorescence microscopy calpain proteolysis inhibitor cataract sheep
26	Nanoparticle Probes for Ultrasensitive Biological Detection and Motor Protein Tracking inside Living Cells Agrawal, Amit 09 November 2006 (has links) Semiconductor quantum dots (QDs) have emerged as a new class of fluorescent probes and labeling agents for biological samples. QDs are bright, highly photostable and allow simultaneous excitation of multiple emissions. Owing to these properties, QDs hold exceptional promise in enabling intracellular biochemical studies and diagnosis with unprecedented sensitivity and accuracy. However, use of QD probes inside living cells remains a challenge due to difficulties in delivery of nanoparticles without causing aggregation and imaging single nanoparticles inside living cells. In this dissertation, a systematic approach to deliver, image and locate single QDs inside living cells is presented and the properties of molecular motor protein driven QD transport are studied. First, spectroscopic and imaging methods capable of differentiating single nanoparticles from the aggregates were developed. These technologies were validated by differentiating surface protein expression on viral particles and by enabling rapid counting of single biomolecules. Second, controlled delivery of single QDs into living cells is demonstrated. A surprising finding is that single QDs associate non-specifically with the dynein motor protein complex and are transported to the microtubule organizing center. Accurate localization and tracking of QDs inside cell cytoplasm revealed multiple dynein motor protein attachment resulting in increased velocity of the QDs. Further, spectrin molecule which is known to recruit dynein motor protein complex to phospholipid micelles was found to associate with the QDs. These results may serve as a benchmark for developing new QD surface coatings suitable for intracellular applications. Since, nanoparticles are similar in size to viral pathogens; better understanding of nanoparticle-cell interactions should also help engineer nanoparticle models to study virus-host cell interactions. (Contains AVI format multimedia files) Immunoassay Single molecule detection Live cell imaging Quantum dots Fluorescence Motor protein Viral trafficking Dynein Microtubule Spectroscopy Respiratory syncytial virus Spectrin Nucleic acid Nanotechnology Intracellular delivery Color colocalization Proteins Magneto optical Enrichment Nanoparticles Molecular probes Quantum dots Fluorescent probes Cells
27	Elucidating the reversibility of ataxia Šuminaite, Daumante January 2017 (has links) Heterozygous and recently identified homozygous mutations in the SPTBN2 gene, encoding b-III spectrin, are implicated in spinocerebellar ataxia type 5 (SCA5) and spectrin-associated autosomal recessive cerebellar ataxia type 1 (SPARCA1), respectively. Our mouse model, lacking b-III spectrin (KO), mimics the progressive human phenotype displaying motor deficiencies as well as reduced Purkinje cell firing frequency followed by dendritic tree degeneration and cell death. The aims of this study were to evaluate progression of Purkinje cell degeneration following loss of b-III spectrin function and determine whether the reintroduction of C-terminus (C-trm) of b-III spectrin to the cerebellum is enough to halt, alleviate or reverse the disease phenotype. Additionally, this study investigated whether the abnormal electrophysiological and morphological phenotypes of Purkinje cells from KO mice are re-capitulated in a primary cerebellar culture and if so, whether they could be rescued by modulating calcium signaling. Morphological and histological analyses revealed that Purkinje cell degeneration is not uniform throughout the cerebellum of KO mice with Purkinje cells from posterior cerebellar regions possessing significantly smaller dendritic trees when compared to anterior cerebellum (p=0.0003, N=4-6, n=11-29). Similarly, significant reduction in Purkinje cell density was observed in posterior, not anterior regions of KO mice when compared to WT animals (p=0.014, N=3) and reduced tonic firing is most significant in Purkinje cells from the posterior cerebellum compared to WT mice (p=0.0328, N=3-6, n=11-29), with posterior KO PCs appearing to have elevated input resistance. Two-week expression of C-trm b-III spectrin in 3-month old KO animals significantly reduced Purkinje cell input resistance when compared to non-transduced cells (p=0.0139, N=4-5, n=15), but no effect was seen 9 months after viral injection. In contrast, a difference in cell surface area was no longer detected between WT and KO animals at 12 months of age following 9-months of viral expression. Nevertheless, using the elevated beam test motor deterioration was still observed 5 months after surgery (p=0.0023, N=4). In contrast, earlier stereotaxic injections at 6-weeks of age had a positive effect on mice motor performance with no deterioration in performance detected 5 months after the surgery. Latency to stay on the rotarod at 3 rpm was also significantly extended 6 months after stereotaxic injections at 6-weeks of age with slower motor deterioration (p=0.0348, N=6). In primary cerebellar cultures, Purkinje cells from KO animals exhibit an abnormal morphology with significantly more dendritic branches (p < 0.0001, N=4-7, n=35-69) and a larger total dendritic length (p=0.0079). Chronic application of 2 μM mibefradil, a T-type calcium channel blocker, was observed to reduce total dendritic length and branching in KO animal cultures bringing these morphological measurements closer to WT Purkinje cell levels. Finally although after 14 days in vitro 40% of Purkinje cells were found to be spontaneously firing, no significant difference in firing frequency (p=0.9434) or input resistance (p=0.8434, N=4, n=6-10) was detectable between WT and KO cultures. In summary, Purkinje cells in posterior cerebellar regions of KO mice were found to be more susceptible to dendritic degeneration and cellular death than cells in the anterior cerebellum. Expression of C-trm b-III spectrin at 3 months of age had an immediate effect on cell input resistance and a modest effect on Purkinje cell morphology but no effect on motor decline. Viral injections at 6-weeks of age, however, significantly slowed motor decline. Although an abnormal KO cell morphology could be successfully recapitulated in primary cell culture, it was not possible to discern any differences in electrophysiological properties. Nevertheless, the abnormal cell morphology was successfully modified in vitro by manipulating calcium signaling via T-type calcium channels.
28	Sound encoding in mutant mice with disrupted action potential generation Yamanbaeva, Gulnara 21 August 2017 (has links) No description available. 570 WRB PSD-95 AMPA receptors recycling ßIV-spectrin single unit in vivo recording spiral ganglion neuron in vivo electrophysiology STED microscopy inner hair cell ribbon synapse otoferlin cochlear nucleus neuron action potential generation sound encoding Biologie (PPN619462639)

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