A patch-clamp study of native and recombinant glutamate receptors

Kamboj, Sunjeev Kumar

January 1996

No description available.

615.1

Particle Image Velocimetry Study on the Stripe Formation in Vertically Vibrated Granules

Deng, Rensheng, Wang, Chi-Hwa

01 1900

Recently, granules under vertical vibrations receive many attentions due to their importance in theoretical research and engineering application. In this paper, a two-dimensional Particle Image Velocimetry (PIV) system was used to examine the f/2 stripe pattern forming in a vertically vibrated granular layer. Since the PIV sampling frequency does not match with the vibrating frequency, a special identification-coupling method was adopted to combine the images taken in different cycles to offer the information in one complete cycle. The measured velocity vectors showed exactly the particle motions at various stages of a motion cycle, illustrating the alternating peaks and valleys on the layer top. Furthermore, quantitative results on the temporal evolution of velocity profiles were obtained and some other interesting phenomena were observed, such as the appearance of local structures (e.g. dual-phase layer structure) and the moving feature of the 'standing point'. The mechanism accounting for the occurrence of stripes on the surface is also discussed. This work will be of interest to a better understanding on pattern formation in the vibrating granular bed. / Singapore-MIT Alliance (SMA)

granule

particle image velocimetry

stripe

vibrating bed

The Chromatin Remodelling Contributions of Snf2l in Cerebellar Granule Neuron Differentiation

Goodwin, Laura Rose

01 October 2018

Recent studies have uncovered de novo mutations of the gene encoding the chromatin remodelling protein Snf2l in patients with schizophrenia, Rett-like syndrome and intellectual disability. Snf2l and its closely related protein, Snf2h, play a critical role in embryonic and post-natal brain development. Murine models lacking functional Snf2h or Snf2l point to complementary activities of these remodelers; Snf2h cKO mice present with a significantly reduced cerebellum, while Snf2l Ex6DEL (exon 6 deleted) cerebella are larger than their wild-type counterparts. Granule neuron progenitors (GNPs) isolated from Ex6DEL cerebella display delayed cell cycle exit and hindered terminal differentiation compared to wild-type controls. Moreover, loss of Snf2l activity results in widespread transcriptome shifts which underlie the Ex6DEL GNP differentiation phenotype. In particular, key transcription factors are differentially expressed without Snf2l remodelling activity. We confirm that ERK pathway activation is misregulated in Ex6DEL GNPs, possibly in response to elevated fibroblast growth factor 8 (Fgf8) expression in these cultures. We find that Snf2l activity maintains the chromatin landscape throughout GNP differentiation, as Ex6DEL cultures have a global increase in chromatin accessibility. We suggest that Snf2l-mediated chromatin condensation is responsible for proper regulation of gene expression programs in GNP differentiation.

ISWI

chromatin remodelling

granule neuron progenitor

cerebellum

A forward genetic approach to identifying novel calcium regulators in Toxoplasma Gondii

LaFavers, Kaice Arminda

25 July 2017

Indiana University-Purdue University Indianapolis (IUPUI) / Toxoplasma gondii is an obligate intracellular eukaryotic pathogen that causes severe neurologic disease in immunocompromised adults and congenitally infected neonates. Events critical to the propagation of T. gondii, such as invasion and egress, are regulated by calcium-dependent signaling. In order to identify unique components of the parasite’s calcium signaling networks, members of the Arrizabalaga laboratory have used a forward genetics approach to isolate mutants with altered sensitivity to the calcium ionophore A23187. Exposing extracellular parasites to A23187 induces protein secretion, motility and cytoskeletal rearrangements and prolonged treatment causes exhaustion of factors required for invasion, which results in what is referred to as ionophore induced death (iiDeath). Mutants capable of surviving this treatment were isolated from a chemically mutagenized population. Whole genome sequencing of one such mutant, MBD2.1, identified a nonsense mutation in a protein of unknown function (TGGT1_069070, ToxoDBv7.2) Complementation of MBD 2.1 with a wild-type copy of TGGT1_069070 restored sensitivity to iiDeath treatment. Endogenous tagging of this locus revealed that the encoded protein is secreted from a unique parasite secretory organelle known as the dense granule into the parasitophorous vacuole, leading to its designation as TgGRA41. Complete knockout of TgGRA41 recapitulates the resistance to iiDeath observed in MBD2.1 but also exhibits a dramatic decrease in propagation in tissue culture not seen in the original mutant. The knockout shows defects in multiple steps of the lytic including compromised invasion efficiency and premature egress of parasites from host cells. Cytosolic calcium measurements of extracellular parasites show enhanced uptake of calcium in the knockout strain as compared to parental and complemented, suggesting that the loss of TgGra41 results in calcium dysregulation. Together, these results provide a novel insight into the role that the parasitophorous vacuole of T. gondii plays in calcium homeostasis and calcium-dependent signaling processes.

Toxoplasma gondii

Calcium

Dense granule

Parasite

Le composant des granules de stress G3BP : caractérisation phénotypique de souris KO, et identification de son interactome ribonucléoprotéique dans le cerveau de souris / The stress granules component G3BP : functional characterization from KO mouse and identification of its ribonucleoprotein interactome in mouse brain

Martin, Sophie

10 December 2012

Les protéines capables de lier des ARNs sont essentielles pour les différentes étapes de maturation de l'ARN messager (ARNm), en dirigeant leur localisation et leur devenir dans la cellule, et en formant avec les ARNs des particules ribonucléoprotéiques (mRNPs). Les mRNPS peuvent former des structures cellulaires dynamiques qui sont adressées vers des fonctions spécifiques. Ces granules, tels que les granules de stress formés suite à un stress cellulaire, contiennent des ARNm dont la traduction est inhibée et qui sont stockés transitoirement. Ma thèse a consisté en la caractérisation fonctionnelle de G3BP (RasGAP SH3 binding protein), une RBP exprimée de façon ubiquitaire chez l'homme et la souris, et impliquée dans l'assemblage des granules de stress. Par recombinaison homologue classique, des souris knock-out pour G3BP ont été générées. Ces souris ont une espérance de vie faible et des défauts du comportement associés au Système Nerveux Central, en particulier un phénotype de type ataxie. Des expériences d'électrophysiologie ont aussi montré une altération de la plasticité synaptique dans l'hippocampe des souris KO. J'ai donc réalisé des expériences d'immunoprécipitation après cross-link (Cross-Linking and Immunoprecipitation, CLIP) pour purifier à partir de cerveau de souris un complexe stable contenant G3BP, et les ARNs associés ont été identifiés par séquençage haut débit (High-Throughput Sequencing, HITS-CLIP). De façon surprenante, la plupart des cibles de G3BP correspondent à des transcrits codants mais qui contiennent des séquences introniques, et des ARNs non codants. De plus, mes résultats ont montré que l'absence de G3BP1 affecte la stabilité de ces transcrits pré-matures spécifiquement dans le cervelet, ce qui peut être corrélé au phénotype d'ataxie des souris KO G3BP1. Cela suggère un nouveau mécanisme de régulation qui passe par la stabilisation de transcrits pré-matures, qui pourraient être convertis en transcrits matures par exemple lors d'un stress et de la séquestration de G3BP dans les granules. / RNA binding proteins (RBPs) are essential in the different steps of processing of the messenger RNAs (mRNAs), directing their localization and fate within the cell, and forming with them the ribonucleoprotein particles (mRNPs). mRNPs can assemble into dynamic cellular structures in which they are routed towards specific functions. RNA granules such as stress granules (SGs) contain translationally silenced mRNPs storing transiently repressed mRNAs.My thesis work consisted in the functional characterization of G3BP (RasGAP SH3 binding protein), an RBP that is expressed ubiquitously in both humans and mice and is involved in the assembly of SGs. Using classical homozygous recombination, viable G3BP1 knock out mice were generated that demonstrated short lifespan.and behavioral defects linked to the Central Nervous System (CNS), notably an ataxia phenotype. Electrophysiology experiments showed an alteration of synaptic plasticity in the hippocampus of KO mice. Therefore, I used Cross-Linking and Immunoprecipitation (CLIP) to purify from mouse brain a stable complex containing G3BP, and performed High-Throughput Sequencing (HITS-CLIP) to identify associated RNAs. Strikingly, most of the G3BP targets correspond to intron sequence-retaining transcripts and non-coding RNAs. My results also showed that G3BP1 depletion influences the stability of these premature transcripts in the cerebellum, which can be correlated to the ataxia phenotype of the G3BP1 KO mice. This comprehensive analysis suggests a new mechanism of gene regulation based on stabilization of silenced premature transcripts which might be converted to mature transcripts under stress condition and sequestration of G3BP in SGs.

Stabilité ARN

Plasticité synaptique

Granule de stress

RNA stability

Synaptic plasticity

Stress granule

Morphology and Molecular Organization of Developing Wheat Starch Granules

Waduge, Renuka N.

03 August 2012

During starch synthesis, knowledge of how the supra molecular organization of starch granules occur is still unknown. This dissertation begins exploring the changes to wheat starch morphology, structure and organization during granule development. Starches from wheat seeds harvested at different days after anthesis were isolated and studied for their molecular organization at different scales. The interaction of granular starch to iodine vapor was used to reveal information about the physical state of the polymers in the granules. Both large and small granule populations initiated as spherical shaped granules, but large granules changed into lenticular shape, while small granules remained spherical. Blocklet, lamellae, and crystalline structures were well developed already at seven days of maturity, suggesting their presence at the center of mature granules. Furthermore, (i) the size of blocklets decreased from center to the periphery in both granule populations, but at all developmental stages, they were larger in small granules than in large granules; (ii) Lamellae repeat distance was shorter close to the center of granules; (iii) B-type crystallites were mixed with A-type crystallites at the center of granules from both populations, but the proportion of B-type crystallites was higher in large granules, which correlated with a higher proportion of amylopectin long chains in these granules; (iv) The relative crystallinity (RC) of starches from both populations was higher at the center of the granule than that at the periphery. RC was lower in large granules than in small granules suggesting influence of the higher amylose content in large granules, which introduces more defects reducing RC. AFM visualized surfaces with features different from the regular type of surface among immature starch granules, which was interpreted as the amorphous growth ring of the starch granule. Exposure of starches to iodine vapor demonstrated different levels of molecular organization between them and revealed possible interaction of inter-cluster chain segments and spacer segments of amylopectin with iodine. In-situ AFM imaging of the granule surface exposed to iodine vapor under humid conditions revealed that glucan polymers or polymer segments in between and on top of blocklets have the ability to interact with iodine.

Starch

Wheat

Granule Architecture

Immature granules

Molecular organization

Granule morphology

AFM

Experience-dependent persistent expression of zif268 during rest is preserved in the aged dentate gyrus

Gheidi, Ali, Azzopardi, Erin, Adams, Allison, Marrone, Diano

January 2013

BACKGROUND:Aging is typically accompanied by memory decline and changes in hippocampal function. Among these changes is a decline in the activity of the dentate gyrus (DG) during behavior. Lasting memory, however, is thought to also require recapitulation of recent memory traces during subsequent rest - a phenomenon, termed memory trace reactivation, which is compromised in hippocampal CA1 with progressive age. This process has yet to be assessed in the aged DG, despite its prominent role in age-related memory impairment. Using zif268 transcription to measure granule cell recruitment, DG activity in adult and aged animals was assessed both during spatial exploration and as animals remained at rest in the home cage in order to detect potential memory-related replay.RESULTS:Consistent with the observation of memory trace reactivation in DG, the probability that an individual granule cell transcribes zif268 during rest in the animal's home cage is increased by recent experience in a novel environment. Surprisingly, a comparable increase was observed in the probability of granule cells in the aged DG expressing zif268 during rest. Moreover, no significant age-related difference was observed in the number of granule cells expressing zif268 during rest. Thus, the number and pattern of granule cell expression of zif268 during rest is preserved in aged animals, despite a significant decline in exploration-related zif268 expression.CONCLUSIONS:These data lead to the hypothesis that the input the aged DG receives from backprojections from CA3 (the region widely hypothesized to mediate reactivation) remains functionally intact despite loss of innervation from the perforant path.

Fascia dentata

egr1

ngfi-a

Reactivation

Replay

Granule cell

IEG

Hippocampus

Investigating the Fate of Pre-neoplastic Cells in a Mouse Model of Medulloblastoma

Kessler, Jessica Dawn

January 2009

<p>Studying the early stages of cancer can provide important insight into the molecular basis of the disease. In many human cancers, such as prostate, pancreatic, and colon cancer, a pre-neoplastic, or intermediate, stage of the disease has been identified. The pre-neoplastic stage is presumed to be a transition during which normal cells undergo malignant transformation. However, the link between the pre-neoplastic cells and end-stage disease has never been formally established. To investigate the fate of such cells, the patched (ptc) mutant mouse, a model for the brain tumor medulloblastoma was used. Pre-neoplastic cells (PNCs) are found in most ptc mutants during early adulthood, but only 15% of these animals develop tumors. Although PNCs are found in mice that develop tumors, the ability of PNCs to give rise to tumors has never been demonstrated directly, and the fate of cells that do not form tumors remains unknown. Genetic fate mapping and orthotopic transplantation provided definitive evidence that PNCs give rise to tumors and showed that the predominant fate of PNCs that do not form tumors is differentiation. Moreover, N-myc, a gene commonly amplified in medulloblastoma, can dramatically alter the fate of PNCs, preventing differentiation and driving progression to tumors. Importantly, N-myc allows PNCs to grow independently of hedgehog signaling, making the resulting tumors resistant to hedgehog antagonists. These studies provide the first direct evidence that PNCs can give rise to tumors, and demonstrate that identification of genetic changes that promote tumor progression is critical for designing effective therapies for cancer.</p> / Dissertation

Biology, Molecular

granule cell precursors

medulloblastoma

patched

pre

neoplastic lesions

The Role of Otx2 in Bypassing Restrictions of Hindbrain Progenitor Cell Proliferation and the Mechanisms of its Dysregulation in Medulloblastoma

Wortham, Matthew

January 2012

<p>Medulloblastoma is the most common malignant brain tumor in children. The understanding of the genetic alterations in this tumor is emergent, and many such genetic driver events have yet to be functionally-characterized. Our studies have sought to understand the causes and consequences of OTX2 dysregulation in established medulloblastomas and in its putative cellular origins. Using a tumor genetic approach, we have uncovered frequent OTX2 copy number gains driving expression of this oncogene in a subset of medulloblastomas. However, OTX2 is frequently expressed in medulloblastomas independent of genomic copy number gain, and we thus sought to understand the transcriptional regulation of this gene in these tumors. We have found that chromatin accessibility, promoter DNA methylation, and activity of a distal downstream enhancer is distinct between OTX2-expressing and -nonexpressing medulloblastomas. Notably, autoregulation serves to maintain OTX2 expression in some medulloblastomas, whereas DNA methylation actively suppresses OTX2 in tumors not expressing this gene. Finally, we describe the effect of expressing Otx2 (the mouse homolog of OTX2) aberrantly in the developing mouse hindbrain, revealing that Otx2 disrupts spatiotemporal restrictions of neuronal progenitor cell proliferation. The effect of Otx2 in vivo is transient, with ectopically-proliferating cells give way to differentiated neurons. We found that OTX2 expression was not able to give rise to high penetrance medulloblastoma when combined with P53 deletion or double heterozygosity for P53 and PTEN. Thus, although Otx2 alters migration and proliferation dynamics of hindbrain neuronal progenitor cells, further studies are needed to identify the genetic alterations that cooperate with this oncogene to give rise to medulloblastoma.</p> / Dissertation

Oncology

Granule Neuron Precursors

Hindbrain

Medulloblastoma

OTX2

Retinoic Acid

ENDOSOMAL MEMBRANE FUSION IN MACROPHAGES AND NK CELLS

Stephanie Wood

Unknown Date

The immune system is comprised of specific cell types that communicate and interact via a range of soluble and surface-bound molecules to defend the body against pathogens. Many gaps remain in our understanding of the subcellular trafficking pathways that regulate the diverse functions of the immune system. The central aim of this thesis was to investigate transport through the endocytic pathway, focussing in particular on the unique organelles and functions of this pathway in immune cells. Two subsets of immune cells were of particular interest in this thesis, macrophages and natural killer (NK) cells. These cell types both perform a range of functions that contribute to both innate and adaptive immunity. Another common thread between these cells is that they both perform functions involving specialised endocytic organelles and pathways. Macrophages utilise their endocytic pathways to perform several unique functions; phagocytosis, endocytosis and degradation of foreign proteins for presentation on MHC class II molecules, and signalling of Toll-like receptors from endosomes. Even secretion of cytokines such as tumour necrosis factor alpha (TNFα) by macrophages requires transport through an endosomal compartment, the recycling endosome, as recently discovered in this laboratory (Murray et al., 2005a). NK cells utilise specialised secretory lysosomes to deliver a lethal hit to carefully identified target cells, providing an alternative example of specialised endocytic trafficking in the immune system. Of the many protein families that regulate subcellular trafficking, the SNARE, Rab, Munc and exocyst proteins were focussed on during this thesis. The localisation and function of members of these families in the endocytic pathway were investigated. Novel results in macrophages concerned the role of Vti1b in endocytosis, a process with implications for MHC class II antigen presentation and TLR detection of endocytosed particles. Alteration of Vti1b protein levels in the cells significantly decreased uptake and degradation of endocytic cargo. A role for Rab11 and the recycling endosome in antigen presentation was also studied. MHC class II was detected in recycling endosomes, and overexpression of a mutant Rab11 protein altered the distribution of MHC class II, suggesting a role for Rab11 in subcellular trafficking during antigen presentation. Preliminary results also suggest a role for the exocyst protein Sec15 at the recycling endosome in macrophages, providing a new target for investigation of the regulation of TNFα secretion. The recycling endosome is emerging as a vital transport hub during cytokine secretion, phagocytosis and possibly other cellular functions in macrophages. This project also involved the unique opportunity to examine primary NK cells from patients with a number of genetic immunodeficiencies caused by mutations to trafficking proteins. The autosomal recessive immunodeficiencies Griscelli syndrome type 2 (GS2) and familial haemophagocytic lymphohistiocytosis types 3 (FHL3) and 4 (FHL4) are associated with loss-of-function of Rab27a, Munc13-4 and syntaxin 11 (Stx11), respectively. These diseases involve a loss of cytotoxic function by cytotoxic CD8+ T lymphocytes and NK cells, but the precise molecular role of these proteins in granule release is incompletely understood. In freshly isolated, resting NK cells from healthy subjects, PMA and ionomycin stimulation or conjugation to susceptible target cells induced colocalisation of endogenous Rab27a and Munc13-4 to perforin-containing granules. In Rab27a-deficient cells, which showed defective degranulation and cytotoxicity induced by signals for both natural and antibody-dependent cellular cytotoxicity, Munc13-4 failed to colocalise with perforin upon activation. Unexpectedly, Rab27a and Munc13-4 localisation to lytic granules was selectively induced by different receptor signals, demonstrating specificity for regulation of lytic granule maturation by target cell ligand expression. Recruitment of the SNARE protein Vti1b, which has not previously been associated with NK cell function or secretory lysosome release, to perforin granules was also discovered. Unexpectedly, Stx11 was not localised to perforin granules. These experiments have contributed to our understanding of the precise molecular roles of Munc13-4, Rab27a and Stx11 in NK cell granule release. Overall, this thesis presents novel and important results from studies of subcellular transport through the endocytic pathways of macrophages and NK cells. These results advance our understanding of several immune functions, and a number of human genetic immunodeficiencies. This new knowledge of the role of endocytic organelles and fusion machinery in these processes provides exciting targets for future research.

Snare

Endosome

granule

Macrophage

NK cell

Membrane Fusion

Haemophagocytic lymphohistiocytosis