Global ETD Search

391	Caracterização do genoma de uma ameba de vida livre (Acanthamoeba castellanii) / Characterization of the genome of a free-living amoeba (Acanthamoeba castellanii) Anita Marzzoco 18 November 1974 (has links) O trabalho descreve um método para isolamento de núcleos morfologicamente intacto e fisiologicamente ativos, além da caracterização parcial do DNA de Acanthamoeba castellanii (linhagem Neff). O DNA celular total de trofozoitos contém quatro famílias com diferentes velocidades de renaturação. A fração com renaturação mais lenta (DNA \"único\"), corresponde ao DNA nuclear (86% do genoma) e apresenta características cinéticas compatíveis com uma complexidade de sequência igual a 1,46x1011 daltons. O DNA reiterado (14% do genoma), compreende três famílias de sequências de nucleotídeos, denominadas \"rápidas\", \"intermediária\" e \"lenta\", com complexidade cinética respectivamente igual a 1,5x106; 2,1x10<SUP.7 e 2,6x108 daltons, presentes em aproximadamente 3x103, 3x102 e 50 cópias. As famílias de DNA reiterado têm localização predominantemente citoplasmática, sendo que as famílias \"intermediárias\" e \"lentas\" fazem parte do genoma mitocondrial. O comportamento cinético heterogêneo do DNA mitocondrial e sua complexidade assemelham-se aos dados existentes para outros microrganismos eucariotos. A constatação de uma espécie de DNA extramitocondrial pode ser relacionada com a descrição anterior de corpúsculos citoplasmáticos contendo DNA ou com a extrusão de cromatina para o citoplasma, verificada no início do encistamento. O DNA de trofozoitos também foi caracterizado quanto ao padrão de sedimentação em gradientes de densidade, desnaturação térmica e composição de bases. O DNA celular total apresenta dois componentes em gradientes de CsCl, caracterizados por densidade de flutuação iguais a 1,717 g/cm3 (Componente maior) e 1,692 g/cm3 (componente menor). O perfil de fusão do DNA mitocondrial sugere heterogeneidade de composição de bases. / Abstract not available. Citologia animal Genomas Animal cytology Genomes
392	A p53-independent role for MDM2-MDMX in cell cycle progression Klein, Alyssa Michelle January 2021 (has links) Mutation or loss of p53 is the most common genetic lesion in human cancers, with simultaneous loss-of-function and gain-of-function pro-oncogenic effects. Because of its critical importance in several processes, including cell cycle arrest and apoptosis, p53 is highly regulated by multiple mechanisms, most certifiably by the MDM2-MDMX heterodimer. The role of MDM2-MDMX in cell cycle regulation through inhibition of p53 has been well-established. In this thesis, I report that loss of either endogenous MDM2 or MDMX, or specifically blocking E3 ligase activity of the heterocomplex, causes a cell cycle arrest independent of p53 expression or mutational status. This arrest is not mediated by activation of the pRb family, but instead is correlated with reduction in E2F1, E2F3, and p73 levels—the latter of which is a p53 family member known to be involved in cell cycle arrest. Remarkably, direct ablation of endogenous p73 produces a similar effect on cell cycle and reduces E2F levels as downregulation of MDM2- MDMX. These data indicate that MDM2 and MDMX, working at least in part as a hetero- complex, play a p53-independent role in cell cycle progression by promoting the activity of E2F family members and p73, making it a potential target of interest in cancers that lack wild-type p53. Cytology Molecular biology Biochemistry Cancer Mutation
393	Aging Actin' Up: A novel aging determinant regulates the actin cytoskeleton, nutrient sensing, and lifespan in Saccharomyces cerevisiae Sing, Cierra Nicole January 2021 (has links) The aging process is unforgiving, targeting a decline in cellular function. Originally, the actin cytoskeleton has not been defined as a hallmark of aging biology, however, numerous studies provide evidence that actin cytoskeleton integrity is declining with age. Mammalian cells express an aged-linked decline in their actin dynamics, consequently defecting their migratory movements, immunological synapse formation, and phagocytosis. Overall, suggesting actin integrity is specifically targeted by aging. Despite the substantial evidence, the underlying mechanism remains elusive, however, current research indicates actin stability as a possible mechanistic aging target. Therefore, our research goal is to further elucidate the mechanism for actin cytoskeleton aging biology in a streamlined model organism, budding yeast, Saccharomyces cerevisiae. Here, we use aging enrichment protocols, streptavidin affinity purification, to isolate a population of older cells to examine any changes in the actin cytoskeleton with age. With an isolated aging population, we analyzed the actin cytoskeleton by testing its stability against a destabilizing drug, Lat-A, and morphology with imaging analysis. We find significant age-associated changes in the actin cytoskeleton, which we later conclude may be a consequence of the age-linked decline in the actin stability that we identified in an aging cell. Additionally, we uncovered a perplexing finding that there is an age-linked decline in actin cable bundling. How actin stability effects actin cable bundling, remains to be determined. However, our actin stability model was further supported by our research characterizing an open reading frame, YKL075C, as a novel actin cable regulatory protein whose deletion: increased actin cable stability, abundance, and mitochondrial quality to extend the replicative lifespan. Upon further insight into YKL075C underlying mechanism, we find YKL075C effects on actin stability and morphology is dependent on alterations in branched-chain amino acid (BCAA) metabolism. Overall, our research discovered a novel actin regulatory protein, Ykl075cp, whose actin function is dependent on BCAA homeostasis, and deleting specifically YKL075C reduces BCAA levels that subsequently increases actin cable stability and abundance to enhance mitochondrial quality and extends longevity. Cytology Aging Cells--Aging Saccharomyces cerevisiae Cytoskeleton
394	Receptor-mediated endocytosis of low density lipoproteins in aortic endothelial cells Sanan, David Austin January 1986 (has links) Lipoprotein binding and metabolism in actively-dividing (subconfluent) and quiescent (postconfluent) bovine aortic endothelial cells (ECs) were qualitatively investigated by fluorescence microscopy using dioctadecylindocarbocyanine-labelled lipoproteins and by indirect immunofluorescence microscopy. LDL and acetylated-LDL (AcLDL) were seen bound to the surfaces of subconfluent ECs (at 4°C or at 37°C), as a random distribution of punctate foci. ECs therefore closely resembled fibroblasts in the distribution of LDL receptors on their surfaces. No binding of LDL was seen on postconfluent EC surfaces by either direct or indirect fluorescence microscopy. The patterns of AcLDL binding on postconfluent ECs resembled those on subconfluent ECs. Intracellular LDL and AcLDL occurred as perinuclear accumulations of large fluorescent disc-shaped profiles in subconfluent ECs. These accumulations were shown to arise from surface-bound material by pulse-chase experiments. Intracellular LDL was absent in the majority of postconfluent ECs, while AcLDL accumulation was massive. "Wounding" of cultures allowed simultaneous assessment of lipoprotein metabolism in quiescent and actively-dividing areas of the same culture. Quantitative assessments of the above-mentioned phenomena were made using ¹²⁵I-labelled lipoproteins. Receptor-mediated binding of LDL decreased five to ten-fold as the cultures modulated from subconfluent to postconfluent morphology. No receptor-bound LDL was detected in postconfluent ECs. Conversely, the amount of AcLDL bound increased at least fivefold during EC growth in parallel cultures. The amounts of lipoproteins endocytosed and metabolised were generally related proportionately to the amounts bound in each case. The distribution of LDL receptors on cultured cells was also investigated at the ultrastructural level using colloidal gold-conjugated LDL as a probe, and similarly labelled antibodies as probes. Whole-mounted cells with receptor probes bound to them were examined directly in the transmission electron microscope. The topographical distribution of LDL receptors has not been investigated by these techniques before. A novel method of preparing cytochemically-labelled, whole-mounted cells from styrene culture dishes was developed and used in this study. LDL Receptors expressed on the surfaces of human skin fibroblasts served to standardise these colloidal gold techniques and fortuitously led to new information on receptor distribution. Normal (FGo) and LDL receptor-negative mutant fibroblasts (GM 2000) acted as positive and negative controls respectively. Normal fibroblast LDL receptors were grouped into clusters consistent in size with coated pits (200 - 500 nm in diameter). A novel finding was the presence of a diffuse population of receptors scattered randomly amongst the clustered receptors. Another mutant fibroblast, GM 2408A, known to have an aberrant LDL receptor distribution, was also examined. Its receptors were shown to be dispersed singly, and in occasional groups of two and three, at random over the cell surfaces. No clusters were detected. The receptor-negative GM 2000 bound virtually no probes. While not as sensitive as the colloidal gold-conjugated LDL probe, an antireceptor monoclonal antibody (IgG-C7), localised by indirect immunogold labelling, gave similar results when applied to the above cells. This was taken as strong corroborative evidence that the LDL receptor distributions as determined by colloidal gold-conjugated LDL were correct. It is suggested that the dispersed population of receptors on normal fibroblasts may represent newly-emerged recycling receptors which have yet to cluster in coated pits. A further new finding reported here is the existence of the same two patterns of LD L receptors, dispersed and clustered, on the surface of subconfluent ECs. It was noted, from the study of whole-mounted and thin-sectioned cells, that the receptors were preferentially arranged in rings following the circumference of coated pit areas on the cell surface. Often these rings associated in groups or even coalesced into compound clusters. The significance of these groupings is not yet understood. In sharp contrast to the situation on subconfluent ECs, no LDL receptors (probed with the extremely sensitive colloidal-gold conjugated LDL) could be detected at the EM level on the surface of postconfluent ECs. Active cells in wounded postconfluent monolayers expressed abundant receptors detected at the EM level. It is concluded that postconfluent quiescent bovine aortic ECs in vitro metabolise virtually no LDL via the LDL-receptor pathway due to a vanishingly low number of LDL receptors. This contrasts with the ability of postconfluent cells to metabolise relatively large amounts of AcLDL via a receptor-mediated mechanism. The significance of these conclusions is discussed with respect to the interaction of plasma lipoproteins with the endothelium in vivo. Endocytosis Receptors, LDL Lipoproteins, LDL Endothelium - Cytology
395	Mechanisms of Basal Ganglia Development Lieberman, Ori Jacob January 2020 (has links) Animals must respond to external cues and changes in internal state by modifying their behavior. The basal ganglia are a collection of subcortical nuclei that contribute to action selection by integrating sensorimotor, limbic and reward information to control motor output. In early life, however, animals display distinct behavioral responses to risk and reward and enhanced vulnerability to neuropsychiatric disease. This arises from the postnatal maturation of brain structures such as the striatum, the main input nucleus of the basal ganglia. Here, using biochemical, electrophysiological and behavioral approaches in transgenic mice, I have explored the molecular and circuit mechanisms that control striatal maturation. In Chapter 1, I begin by reviewing the structure, physiology and function of the basal ganglia, with an emphasis on the striatum. I then describe the existing literature on the development and maturation of striatal neurons and their afferents. In Chapter 2, I review the molecular mechanisms of macroautophagy, a lysosomal degradation pathway that has recently been implicated in the regulation of neurotransmission, including its contribution to neuronal development, neurotransmitter release, and postsynaptic function. The subsequent chapters can be split into two themes. In the first, encompassing chapters 3 and 4, I characterize the postnatal maturation of striatal physiology and define circuit mechanisms that control this process. In Chapter 3, I demonstrate that dopamine (DA) neurotransmission in the striatum initiates the maturation of striatal projection neuron (SPN) intrinsic excitability. I show that DA signaling leads to the maturation of SPN excitability via increased activity of the potassium channel, Kir2. Interestingly, introduction of DA beginning in adulthood could not rescue SPN hyperexcitability while it could during the juvenile period. In Chapter 4, I characterize the maturation of cholinergic interneurons (ChIs) in the striatum and describe the biophysical mechanisms that drive increases in spontaneous activity that occur in ChIs during postnatal development. Finally, I show that the functional maturation of ChIs leads to changes in DA release during the postnatal period. The second theme includes Chapters 5 and 6, in which I explore the role of macroautophagy in striatal function and development. In chapter 5, I used biochemical approaches to show that autophagic flux is suppressed postnatally in the striatum due to increased signaling through the kinase activity of the mammalian target of rapamycin. In Chapter 6, I generated conditional knockouts of Atg7, a required macroautophagy gene, in different populations of SPNs and find that macroautophagy plays cell-type specific roles in SPN physiology. In one subtype of SPNs, macroautophagy regulates intrinsic excitability via degradation of Kir2 channels, which is the first demonstration of macroautophagic control of neuronal excitability. Finally, in Chapter 7, I conclude with a general discussion, where I highlight themes in the molecular and circuit mechanisms of striatal maturation and their implication for neurodevelopmental disease. Neurosciences Cytology Basal ganglia Neurons Corpus striatum
396	Accuracy and Added Value of Triage Beyond Segregating Potentially Neoplastic Effusions in Immediate Wet Preparation Arabi, Haitham, Yousef, Nida, Han, Liying, Bandyopadhyay, Sudeshna, Feng, Jining, Al-Abbadi, Mousa 01 January 2009 (has links) Objective: To study the accuracy and value of immediate wet preparation (WP) procedure on effusion and washing cytologic specimens. Study Design: Two hundred specimens were identified over 3 months in our cytology laboratory, including 102 pleural effusion, 59 peritoneal effusion, 28 pelvic washing and 11 pericardial fluid specimens. WP slides were prepared, stained with toluidine blue (TB) and evaluated. Findings were reported as negative, suspicious or positive for malignant cells. For negative specimens, the remaining prepared slides were stained together. For suspicious or positive interpretation, slides were stained separately. Accuracy and additional benefits from this immediate triage step were studied. Results: Interpretation of slides resulted in 152 negative, 34 positive and 14 suspicious for malignancy. Analysis for additional values resulted in immediate interpretation relayed to clinicians, additional fluid centrifuged for adequate sediment in samples with scant cellularity, selection of bloody specimens for acid washing procedures, selection of cases to optimize cell block preparation when pivotal histologic evaluation or immunohistochemistry was anticipated and selection of cases for potentially needed ancillary studies. Accuracy, sensitivity, specificity and positive and negative predictive values were high. Conclusion: WP using the TB is accurate, sensitive and highly specific and has considerable value beyond segregating potential neoplastic cases. cytology effusion toluidine blue wet preparation
397	Energy coupling for ion transport in Beta vulgaris Petraglia, Teresa. January 1980 (has links) No description available. Ion mobility spectroscopy. Plant translocation. Beets -- Cytology.
398	A calcium-dependent potassium channel in corn (Zea mays) suspension cells / Ketchum, Karen Ann January 1990 (has links) No description available. Corn -- Cytology. Ion channels. Potassium channels.
399	Cell interactions in abnormal neural tube and neural crest cell development of splotch mice Moase, Connie E. (Connie Evelyn) January 1991 (has links) No description available. Neural tube -- Abnormalities. Mice -- Genetics. Mice -- Cytology.
400	Composition and function of the pyrenoids of algal chloroplasts McKay, R. Michael L. (Robert Michael Lee) January 1991 (has links) No description available. Porphyridium cruentum. Chloroplasts. Algae -- Cytology. Chlorella pyrenoidosa.

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