THE MECHANISMS THROUGH WHICH INSULIN AND AN INSULIN-MIMETIC REGULATE FOOD INTAKE AND BODY WEIGHT

AIR, ELLEN LOUISE

21 May 2002

No description available.

obesity

Central Nervous System

therapeutics

Type 2 Diabetes Mellitus

food intake

body weight

melanocortins

DISTINCT AND OVERLAPPING ROLES FOR LYSOPHOSPHATIDIC ACID SIGNALING DURING EARLY <i>XENOPUS LAEVIS</i>DEVELOPMENT

LLOYD, ROBERT B., JR

28 September 2006

No description available.

Biology, Cell

Xenopus

G protein-coupled receptor

lysophosphatidic acid

actin

central nervous system

apoptosis

Central Nervous System Associations in Neurofibromatosis Type 1

Lamvik, Kate K.

13 July 2007

No description available.

neurofibromatosis type 1 (NF1)

optic pathway glioma (OPG)

central nervous system (CNS)

Manipulation of Astrocytes After Spinal Cord Injury Using Transforming Growth Factor Alpha

White, Robin Elaine

January 2009

No description available.

Biochemistry

Biomedical Research

Neurology

spinal cord injury

astrocytes

central nervous system

transforming growth factor &945

Modeling direct injection of drugs into the brain

Sarntinoranont, Malisa, Mareci, Thomas H.

30 January 2020

The World Health Organization (WHO) estimates that one billion people worldwide suffer from central nervous system (CNS) disorders [1]. One major issue in treating these disorders is inadequate drug penetration which can be attributed to an effective blood-brain-barrier that limits passage across blood vessels. Low diffusivity of large classes of drug compounds restricts transport across blood vessel walls and subsequent passage through surrounding brain tissues. Tissue transport is emerging as an increasingly important area of research in drug delivery since the vast majority of therapeutic agents must traverse this space before reaching their targets.

info:eu-repo/classification/ddc/530

ddc:530

Neurabin's Influence on Striatal Dependent Behaviors

Wesley Corey (13118523)

19 July 2022

<p> The striatum is a key brain region involved in regulating motor output and integration. The dorsal and ventral subdivisions of the striatum work in concert to mediate the reinforcing and motor behavioral outputs of the striatum. Moreover, dysfunction of these striatal regions is involved in various diseases including Parkinson’s disease and drug addiction. Therefore, understanding and characterizing biochemical and molecular changes within the striatum associated with these diseases is key in devolving novel therapeutics to treat these disease states. The main output neurons of the striatum are GABAergic, medium-spiny neurons (MSNs), and striatal functionality is mediated by neuroplastic changes in MSN activity. Within MSNs, dopaminergic receptor activation triggers a cascade of reversable phosphorylation, which is facilitated by the activation of specific protein kinases and inhibition of specific protein phosphatases. In comparison to the 350 serine/threonine protein kinases expressed within the striatum, there are only 40 major serine/threonine protein phosphatases. However, serine/threonine protein phosphatases, such as protein phosphatase 1 (PP1), gain their target specificity by interacting with phosphatase-targeting proteins. Within the striatum, the neurabins, termed neurabin and spinophilin, are the most abundant PP1 targeting proteins in dendritic spines. Spinophilin’s expression in the striatum has been strongly characterized, and spinophilin has been shown to regulate striatal-dependent motor-skill learning and amphetamine-induced locomotor sensitization. In contrast to spinophilin, neurabin’s expression within the striatum and its involvement in these striatal-dependent behaviors has not been fully probed. I found that neurabin expression in the striatum is not sex-dependent but is age-dependent. In addition to these data, I also present validation of new global, constitutive and conditional neurabin knock-out mouse lines. Finally, I present data that, unlike previous studies in spinophilin knockout mice, neurabin knockout mice have enhanced striatal-dependent motor-skill learning, but do not impact amphetamine-induced locomotor sensitization. Further characterization of neurabin’s expression in the striatum, and its role in these key striatal behaviors could provide a druggable target for therapeutics designed to address striatal dysfunction.   </p>

Central nervous system

Neurabin

Spinophilin

Striatum

The Role of Gut-Brain Signalling in Functional Responses to Chronic Social Stress

Bharwani, Aadil

January 2019

Chronic stress has a cumulative physiological impact, causing dysregulation of multiple systems due to allostatic overload. There is growing evidence that one such system, the microbiota, is engaged in persistent bidirectional interplay with the brain—a phenomenon that influences neural function and behaviour. However, the functional role of the microbiota in stress-associated changes and the underlying pathways of communication are unknown. Using a murine model of depression, we demonstrate that chronic stress has top-down effects on the structure of the microbiota community, reducing its richness and diversity, altering its profile, and causing differential abundance of various bacterial genera. These structural changes have functional consequences, including in metabolic pathways responsible for the synthesis of short chain fatty acids, tryptophan, and tyrosine. Using a physiologically active bacteria, Lactobacillus rhamnosus (JB-1), we probed for bottom-up signalling in chronic stress. JB-1 attenuated deficits in anxiety-like and social behaviours, and induced systemic immunoregulatory effects, independent of affecting stress-induced changes in the microbiota. In examining possible mechanisms of gut-brain brain signalling, we observed that in unstressed mice, a single dose of JB-1 causes rapid expression of c-Fos—a marker of neuronal activation—in distributed areas of the brain within 165 minutes, absent behavioural changes. No such effects were observed with heat-killed JB-1, despite that both live and heat-killed preparations facilitated vagal activity. Sub-diaphragmatic vagotomy prevented neuronal activation in most but not all brain regions, suggesting that vagal signalling is critical but indicating the presence of additional independent pathways. Finally, only chronic JB-1 treatment increased ΔFosB expression in the brain, which is indicative of long-term neuronal adaptations, in association with behavioural changes. These studies demonstrate a role for bidirectional gut-brain signalling in chronic stress, and highlight the signalling pathways and brain regions through which gut bacteria exert their influence on host behaviour. / Thesis / Candidate in Philosophy / Stress, which is a leading risk factor for mental illnesses such as depression, drastically affects the microbiota—the community of intestinal bacteria. However, this influence is bidirectional as gut bacteria can also influence the brain. Thus, we sought to understand the role of the microbiota in the negative effects of stress and how these microorganisms interact with the brain. We observed that behavioural changes in mice after chronic stress were associated with inflammation and community-wide changes in the microbiota. Treatment with a bacterial strain, Lactobacillus rhamnosus (JB-1), attenuated changes in behaviour and inflammation, but had no effect on the microbiota composition. We observed that the brain rapidly responded to JB-1 via the vagus nerve, and that chronic treatment caused long-term changes in brain regions. This work will allow us to discover novel pathways that can be targeted with greater specificity in clinical settings, providing an innovative approach to treatment of psychiatric conditions.

Neuroscience

Stress

Gut-brain signalling

Microbiota

Central nervous system

Vagus nerve

Fos proteins

Depression

Tissue engineering approaches for brain injury applications

Speccher, Alessandra

26 May 2020

Due to the limited regenerative capacity of the central nervous system (CNS) upon injury, regenerative medicine and tissue engineering strategies show great promise for treatment. These aim to restore tissue functions by combining principles of cell biology and engineering, using biomaterial scaffolds which can help in recapitulating the 3D environment of the brain and improving cell survival after grafting. Stroke and TBI are severe forms of disruptions of brain architecture, and two of the leading causes of mortality and morbidity worldwide, as no effective treatments are available. Several studies report how neural stem cells (NSCs) are able to improve functional recovery upon transplantation. However, the efficacy of these treatments is limited because of the mortality these cells are subject to after transplantation. In this context, the transplantation of mesenchymal cells (MSCs) has shown beneficial effects by secreting molecules and factors that help in the healing process. In this study, we tested alginate-based hydrogels as candidates to support human NSCs and MSCs transplantation into the brain, in the view of exploiting the beneficial effects of both and analyzing whether their combined use could have a synergistic effect. In the first part, we studied the suitability of alginate-based scaffolds for the three-dimensional encapsulation and culture of hNSCs and hMSCs. We analyzed their ability to support cell survival, and we evaluated whether changes in their concentration or modifications with ECM molecules could influence cell viability. We showed that the best survival conditions are found when using an RGDs-functionalized alginate scaffold at a low concentration (0.5% w/v). We then worked on the identification of the best conditions for MSCs culture and the definition of coculture conditions. Since serum is necessary for MSCs, but it is reported to induce glial differentiation of NSCs, we explored two different experimental setups. On one hand, we investigated the feasibility to exploit biomaterials to create "compartmentalized" cocultures that would at least partially retain serum. In parallel, we positively observed that MSCs can survive, proliferate and maintain their stemness even in absence of serum, supporting the hypothesis that the use of “compartmentalized” coculture systems would likely be exploitable for MSCs culture. Finally, we tested the reported beneficial effects of MSCs in our 3D culture system, in which NSCs do not show a great viability. Encapsulated NSCs were cultured on an MSCs monolayer, and we analyzed cell survival, proliferation, differentiation and stemness retention. Gene expression analyses highlighted that NSCs maintain stemness characteristics, but we were not able to observe any improvement in NSCs survival in coculture, with respect to standard culture. In the last part of the project we decided to test our system for tissue engineering approaches, exploiting axotomized brain organotypic slices (OSCs). We evaluated the presence of cells 7 days after transplantation, their integration in the OSCs and glial response. Preliminary results suggest that the biomaterial does not cause activation of glial cells, although stem cells do not seem to migrate out of scaffold and integrate into the brain slice.

Rôle de la Galectin-3 extra cellulaire dans la migration des cellules B à travers les barrières du système nerveux central dans le contexte de la sclérose en plaques

Lépine, Paula

12 1900

No description available.

sclérose en plaques

système nerveux central

barrières du système nerveux central

migration

cellules B

galectin-3

multiple sclerosis

central nervous system

central nervous system barriers

B cells

Migration and adhesion associated molecules in lymphoma biology and their potential roles as biomarkers

Lemma, S. (Siria)

22 August 2017

Abstract Lymphomas are a heterogeneous group of malignancies that arise from lymphatic tissues. Diffuse large B-cell lymphoma (DLBCL) is the most common lymphoma sub-type. It is an aggressive malignancy with an increasing incidence. The prognosis of DLBCL has improved significantly, but problems also remain. The clinical significance of central nervous system (CNS) relapses has become increasingly important. As secondary CNSL (sCNSL) and primary CNS lymphoma (PCNSL) are known to have poor prognoses; the prevention of sCNSL is of crucial importance. Peripheral T-cell lymphomas (PTCL) are rare neoplasms and include several lymphoma subtypes that possess complex and also overlapping morphological and immunophenotypic characteristics. The identification of different entities has improved, but the biological knowledge remains scarce when compared to DLBCL. The optimal treatment schemas for PTCLs are still lacking and they have long been treated with the same therapies as B-cell lymphomas, mainly with suboptimal treatment results. The aim of this study was to identify poor prognostic markers in DLBCL and PTCLs and potential biological markers for the prediction of DLBCL CNS relapse. The study material included patients with systemic DLBCL without CNS affision (sDLBCL), sCNSL, PCNSL and PTCLs. The expression of epithelial-mesenchymal transition (EMT) transcription factors (TFs), chemokines and their receptors and adhesion-, migration- and inflammatory responses-associated molecules were studied by means of immunohistochemistry. IEM was used to verify the specific subcellular location of the studied molecules. GEP was performed on 12 PTCL samples in order to compare the poor prognosis group with the good prognosis group and on one sDLBCL and one sCNSL sample from the time of primary diagnosis. The EMT TFs were found to be expressed in both DLBCL and PTCLs, where they ultimately proved to have prognostic relevance as well. In PTCLs, these TFs were able to delineate a disease group with a specific gene-expression profile. CXCR4, CXCR5, ITGA10, PTEN and CD44 were found to be differently expressed between DLBCL cases with CNS affision when compared to those without CNS disease. These molecules seem to play a role in the development of CNS relapse and hopefully, if further verified, will lead towards the identification of biological markers for CNS relapse prediction. / Tiivistelmä Lymfoomat ovat heterogeeninen ryhmä imukudossyöpiä, joista diffuusi suurisoluinen B-solulymfooma (DLBCL) on yleisin alatyyppi. Se on aggressiivinen maligniteetti, jonka insidenssi on noussut viime vuosina. DLBCL potilaiden ennuste on parantunut merkittävästi, mutta yhä osa potilaista menehtyy tautiinsa. DLBCL:n keskushermostorelapsin kliininen merkitys on tänä päivänä aiempaa suurempi. Sekundaarisen keskushermostolymfooman (sCNSL) ja primaarin aivolymfooman (PCNSL) ennusteet ovat nykyhoidoilla huonoja, joten keskushermostorelapsin ennaltaehkäiseminen on tärkeää. Perifeeriset T-solulymfoomat (PTCLs) ovat ryhmä harvinaisia neoplasioita, joka sisältää useita eri alatyyppejä, joiden morfologiset ja immunofenotyyppiset ominaisuudet ovat monimuotoisia ja osin päällekkäisiä. Eri entiteettien indentifiointi on parantunut, mutta PTCL:ien biologinen tietämys on yhä DLBCL:aa heikompaa. PTCL:ien optimaalinen hoito ei ole selvillä ja tätä tautiryhmää on pitkään hoidettu samoilla hoidoilla kuin DLBCL:aa, mutta huonommilla hoitotuloksilla. Tutkimuksen tavoitteena oli löytää huonon ennusteen markkereita, joilla myös pystyttäisiin ennustamaan DLBCL:n keskushermostorelapsia. Aineisto koostui DLBCL, sCNSL, PCNSL ja PTCL näytteistä. Immunohistokemiallisilla värjäyksillä tutkittiin epiteliaalis-mesenkymaalisen transition (EMT) transkriptiotekijöitä (TF), kemokiinireseptoreita sekä adheesioon-, migraatioon ja inflammaatioon assosioituja molekyylejä. Immunoelektronimikroskopialla varmennettiin molekyylien lokalisaatio soluissa. Geeniekspressioprofiloinnilla (GEP) verrattiin kahdentoista hyvän ja huonon ennusteen ryhmään kuuluvan PTCL näytteen välisiä geeniekspressioeroja sekä kahden DLBCL potilaan näytteitä, joista toiselle kehittyi keskushermostorelapsi. EMT TF:ien ekspressiota nähtiin DLBCL ja PTCL näytteissä, joissa niillä myös todettiin olevan ennusteellista merkitystä. PTCL:ssa TF:t pystyivät erottelemaan tautiryhmän, jolla oli oma spesifinen geeniekspressioprofiilinsa. CXCR4, CXCR5, ITGA10, PTEN ja CD44 ekspressio oli erilaista systeemisissä DLBCL tapauksissa verrattuna sCNSL tapauksiin. Edellä mainituilla molekyyleillä näyttää olevan oma roolinsa keskushermostotaudin kehittymisessä ja jos nämä tulokset pystytään vahvistamaan tulevissa tutkimuksissa, johtavat ne toivottavasti kohti keskushermostorelapsiriskin tarkempaa tunnistamista.

adhesion

central nervous system lymphoma

central nervous system prophylaxis

chemokine receptors

diffuse large B-cell lymphoma

epithelial-mesenchymal transition

migration

prognosis

adheesio

diffuusi suurisoluinen B-solulymfooma

ennuste

epiteliaalis-mesenkymaalinen transitio

kemokiinireseptorit

keskushermostolymfooma

keskushermostoprofylaksia

migraatio