BBB-bypassing polysaccharide mini-GAGR activates the neuronal Nrf2- mediated antioxidant defense system for the treatment of Alzheimer’s disease

Murphy, Kelsey E.

January 2019

No description available.

Neurosciences

THE PHARMACOKINETICS OF METAL-BASED ENGINEERED NANOMATERIALS, FOCUSING ON THE BLOOD-BRAIN BARRIER

Dan, Mo

01 January 2013

Metal-based engineered nanomaterials (ENMs) have potential to revolutionize diagnosis, drug delivery and manufactured products, leading to greater human ENM exposure. It is crucial to understand ENM pharmacokinetics and their association with biological barriers such as the blood-brain barrier (BBB). Physicochemical parameters such as size and surface modification of ENMs play an important role in ENM fate, including their brain association. Multifunctional ENMs showed advantages across the highly regulated BBB. There are limited reports on ENM distribution among the blood in the brain vasculature, the BBB, and brain parenchyma. In this study, ceria ENM was used to study the effect of size on its pharmacokinetics. Four sizes of ceria ENMs were studied. Five nm ceria showed a longer half-life in the blood and higher brain association compared with other sizes and 15 and 30 nm ceria had a higher blood cell association than 5 or 55 nm ceria. Because of the long circulation and high brain association of 5 nm ceria compared with other sizes, its distribution between the BBB and brain parenchyma was studied. The in situ brain perfusion technique showed 5 nm ceria (99%) on the luminal surface of the BBB rather than the brain parenchyma. For biomedical applications in the central nervous system (CNS), it is vital to develop stable and biocompatible ENMs and enhance their uptake by taking advantage of their unique properties. Cross-linked nanoassemblies entrapping iron oxide nanoparticles (CNA-IONPs) showed controlled particle size in biological conditions and less toxicity in comparison to Citrate-IONPs. CNA-IONPs considerably enhanced MRI T2 relaxivities and generated heat at mild hyperthermic temperatures (40 ~ 42°C) in the presence of alternating magnetic field (AMF). Numerous researchers showed mild whole body hyperthermia can increase BBB permeability for potential brain therapeutic application. Compared to conventional hyperthermia, AMF-induced hyperthermia increased BBB permeability with a shorter duration of hyperthermia and lower temperature, providing the potential to enhance IONP flux across the BBB with reduced toxicity. Overall, ENMs with optimized physicochemical properties can enhance their flux across the BBB into the brain with desirable pharmacokinetics, which provide great potential for diagnosis and therapy in the CNS.

Metal-based engineered nanomaterials

ENMs

blood-brain barrier (BBB)

ceria ENM

iron oxide nanoparticles

pharmacokinetics

Pharmaceutics and Drug Design

Pharmacy and Pharmaceutical Sciences

The central regulation of blood pressure and salt appetite by brain 11β- hydroxysteroid dehydrogenase type 2 : a novel gene targeting technique

McNairn, Julie Anne

January 2018

Hypertension is the chronic elevation in blood pressure that is regulated in part through the retention and regulation of sodium retention and excretion in the kidneys. Hence the kidney has been considered the organ that regulates blood pressure. There are a cohort of patients that suffer with high blood pressure due to lack of 11β-hydroxysteroid dehydrogenase-type 2 (11β-HSD2) expression (which inactivates glucocorticoids (GCs), allowing selective activation of mineralocorticoid receptors (MR) by aldosterone) that results in hypertensive and increased salt appetite phenotypes - a condition known as syndrome of apparent mineralocorticoid excess (SAME). This disorder can be recapitulated in the mouse through the global deletion of 11β-HSD2, which results in over activation of the MR driving an elevation in blood pressure. However, the distinction between blood pressure elevation because of kidney dysfunction with loss of 11β-HSD2 or increased salt appetite due to loss of brain 11β-HSD2 expression is not clear from the global 11β-HSD2 knockout model. Salt appetite is regulated by regions of the brain out-with the blood-brain barrier, known as circumventricular organs. In the mouse, salt appetite is controlled by aldosterone-sensitive cells in the nucleus of the solitary tract (NTS) in the brain stem, where 11β-HSD2 is expressed to provide mineralocorticoid selectivity. However, in the fetal brain, 11β-HSD2 is widely expressed, protecting against adverse GC action that alters brain development and increases susceptibility to psychiatric disorders as adults. 11β-HSD2 deletion solely in the brain from embryonic day 12 resulting in GC fetal programming (HSD2BKO) causes effects on both behaviour and salt appetite. To determine the role of developmental versus adult expression of brain 11β- HSD2, mice with deletion of brain 11β-HSD2 from mid gestation (HSD2BKO) and mice with adult deletion of 11β-HSD2 in the NTS using lentivirus (HSD2.v- BKD) were compared. The phenotypes (salt appetite, blood pressure (BP), baroreceptor response (BRR) and cognition), can be categorised as either due to GC fetal programming (as indicated by HSD2BKO groups), or increased activation of MR in adult 11β-HSD2 expressing neurons (recapitulated in the HSD2.v-Cre groups). Salt appetite increased in both HSD2BKO and HSD2.v-BKD cohorts (mean percentage increase 65% n=8 and 46% n=6, compared to their respective controls), leading to an increased BP in both groups (+12% and +8%, respectively) as well as an impaired BRR, indicating all phenotypes are mediated by adult NTS neurons. However, spatial recognition memory (Object-in-Place task) is abolished in HSD2BKO mice, whereas, HSD2.v-BKD mice still retain short-term memory. Our data suggest that neural 11β-HSD2 protects against inappropriate activation of MR by corticosterone to regulate salt appetite and salt-induced rises in blood pressure. However, spatial recognition memory is not influenced by deletion of 11β-HSD2 in the adult brain, confirmation that this phenotype is underpinned by developmental programming by GCs, which is observed in the 11β-HSD2 brain KO. Salt appetite has been shown to be centrally regulated through the adult deletion of 11β-HSD2. From this, our data suggest that an increased salt appetite is due to adult loss of function of 11β-HSD2 rather than GC programming during development. Highlighting the NTS as a region for drug delivery to try and control salt appetite in salt sensitive individuals who struggle with administering a recommended change in diet. To develop this further, minimally invasive modes of delivery of viruses and drugs into the brain were investigated. In so doing, a non-invasive and reversible method to temporarily disrupt the blood brain barrier (BBB) was optimised. The technique required acoustic insonation of ultrasonic contrast agents (CAs) (gas microbubbles) adjacent to the BBB. These microbubbles (SonoVueTM, Bracco) were delivered via tail vein injection into the vasculature. To target the BBB, an ultrasonic transducer was suspended and focused through coupling gel onto the area of interest in the brain with skull the intact. The optimisation of this technique required determination of the focal position of the 3.5MHz transducer that was utilised, in addition to optimisation of the pulse length, pulse repetition frequency and power output of the ultrasound beam to enable the BBB to be disrupted. In addition, measurement of the attenuation of the ultrasound beam through ex vivo mouse skulls were measured. These results showed a 50% reduction in pressure amplitude from the baseline of 335.2mV (Baseline mean = 100% +/-SEM 0 n=3 (No skull), five regions across the skull averaged 47.79% +/-SEM 1.913 n=25 (using 5 different animals). In in vivo mice, after co-injection of the microbubbles with Evans Blue and insonation of the brain, disruption of the BBB was confirmed by the presence of Evans Blue dye in the brain, with no measurable damage occurring in the brain. This was confirmed by cell and nuclear morphology with no red blood cell extravasation into the surrounding tissue. The parameters used to open the BBB used a peak negative pressure of 2.1MPa (single pulse), transducer frequency 3.5MHz, 35,000 cycles over a 10ms burst at a pulse repetition frequency of 10Hz. The technique when applied in vivo in recovery animals is speculated to work by the focused ultrasound causing the microbubbles to oscillate within the vasculature adjacent to the BBB, resulting in high-shear stresses being generated on the tight junctions within the BBB. The resultant gaps in the BBB allow free circulating compounds (e.g. large dye molecules (Evans Blue - 960.8g/mol molecular weight) and adeno-associated-viruses (25nm with a packing capacity of 4.5kb) within the blood to pass into the brain, but there is no penetration of red blood cells (7μm). Longitudinal mouse experiments demonstrated that within 12-hours these gaps close with no long-term damage observed. Currently, utilising this technique, successful passage of an adeno-associated virus expressing GFP (as a marker) has been shown to pass into the brain (n=6 for each cohort including control) - indicating that the virus requires the ultrasound and microbubbles to facilitate its movement into the brain. Further technique optimisation is being explored looking at the role of CAs used in the opening and disruption of the BBB, comparing composition and size of the CAs. Microbubbles (2-3μm) and nanobubbles (200nm) were compared as well as lipid and non-ionic surfactant surface compositions, using volume of drug delivery and degree of disruption as outputs. Using this technique, the hydrophilic drug mimic calcein was delivered into the brain (n=5 non-ionic surfactant nanobubble, n=5 lipid nanobubble). Results have indicated that the delivery of calcein is most efficient when using non-ionic surfactant nanobubbles as opposed to lipid nanobubbles - with a greater volume of the drug being delivered into the cerebral tissue. Furthermore, the concentration and surface composition of the nanobubble have an effect as to the size and potential damage to the brain when opening the BBB. In conclusion, it has been shown that it is possible to non-invasively open the BBB and deliver viruses and dye into the brain. In addition, this thesis has investigated the use of nanobubbles as both facilitators to opening the BBB and delivery vectors for potentially therapeutic drugs. Finally, a non-invasive opening of the BBB has been achieved using focused ultrasound. Ultimately this non-invasive opening of the BBB can be used to achieve delivery of larger molecules (such as antibodies and viruses) into the brain to target treatments. Focused ultrasound brain targeting can be applied to the potential treatment of salt appetite regulation in the NTS. For the individuals who suffer from salt sensitive hypertension, the NTS can be targeted to reduce the drive to ingest high salt diets. Furthermore, the continuation of research into the central control of BP, salt appetite and baroreceptor reflex control can become better understood, using less invasive delivery techniques to the brain.

EFEITO ANTIOXIDANTE DE LIPOSSOMAS CONTENDO CREATINA NO PROCESSO DE ISQUEMIA/REPERFUSÃO CEREBRAL EM RATOS: DESENVOLVIMENTO, CARACTERIZAÇÃO E AVALIAÇÃO FARMACOLÓGICA

Borin, Diego Becker

26 March 2013

Made available in DSpace on 2018-06-27T18:56:03Z (GMT). No. of bitstreams: 3 Diego Becker Borin.pdf: 1553948 bytes, checksum: b94d052c85f74f3bcc5e4cadbcb71e67 (MD5) Diego Becker Borin.pdf.txt: 134530 bytes, checksum: f3ad94a2052d1806ff21e9c0ce7733fb (MD5) Diego Becker Borin.pdf.jpg: 3538 bytes, checksum: b4b8b2603cafaeb4736f56efe30f7f1d (MD5) Previous issue date: 2013-03-26 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Creatine is a biomolecule endogenously synthesized from amino acids which can also be obtained through the diet. But it does not permeate easily through the blood-brain barrier (BBB), so the brain must supply their needs through the synthesis of creatine in the central nervous system (CNS) by itself. Creatine has a major role in maintaining stable levels of adenosine triphosphate (ATP) thus keeping the whole body in a proper condition. Neurodegenerative diseases leads to decreases in ATP levels, which compromises cellular metabolism, generating the increase of reactive species that could lead to neuronal cell death. Therefore, it becomes important to increase creatine levels in neurodegenerative diseases, so it could provide new alternative treatments for these diseases. This study aimed to develop and characterize liposomes with creatine, as well as investigate its protective effect in ischemia and reperfusion (I/R) brain model. Two methodologies were used for the preparation of liposomes, the lipid film hydration and ethanol injection. Due the best results were obtained by the ethanol injection method, this was chosen for the preparation of liposomes in in vivo tests. The rats were tested using I/R by clamping bilateral carotid arteries and different groups were treated with creatine (30 mg/kg) in free form (Liv+I/R) and liposomed (Lip+I/R) and compared with the control group and I/R. The animals motor activity, exploratory and memory abilities were evaluated through field tests and passive avoidance, 24 and 48 hours after I/R, respectively. After 72 hours, the animals were euthanized and the brains removed for biochemical determination of levels of reactive species and ascorbic acid (AA), and the biochemical breakdown activity of superoxide dismutase (SOD) and catalase (CAT). The suspensions of liposomes used for the in vivo treatment had homogenous average particle diameter (154 ± 6.9 nm), low polydispersity index (0.211 ± 0.019), pH near neutral (around 6.7), negative potential Zeta (-21 ± 1.8 mV) and association rate around 31%. The results of field tests have shown that I/R caused a change in exploratory activity of animals and increased oxidative stress in the brain of rats subjected to I/R. Liposomes creatine protected the change in exploratory activity and increased oxidative stress in rat cortex. Already in free form, creatine was not able to protect against these changes. With these results, we can conclude that the production of liposomes containing creatine technological feasibility presented, demonstrating the potential to increase the bioavailability of creatine into the CNS via the BBB. / A creatina é uma biomolécula sintetizada endogenamente a partir de aminoácidos, que também pode ser obtida através da dieta. Porém, ela não permeia facilmente através da barreira hematoencefálica (BHE), assim o cérebro deve suprir suas necessidades através da síntese de creatina no próprio sistema nervoso central (SNC). A grande importância da creatina para o funcionamento correto do organismo está em manter estáveis os níveis de adenosina trifosfato (ATP). Doenças neurodegenerativas levam a déficits de ATP, o que compromete o metabolismo celular, gerando espécies reativas (ERs) capazes de levar as células neuronais à morte. Assim, torna-se importante aumentar os níveis de creatina em doenças neurodegenerativas, podendo gerar novas alternativas de tratamento para estas doenças. Desta forma, o presente trabalho teve como objetivo desenvolver e caracterizar lipossomas de creatina, bem como, investigar o seu efeito protetor em um modelo de isquemia e reperfusão (I/R) cerebral. Foram utilizadas duas metodologias para o preparo dos lipossomas, a hidratação do filme lipídico e a injeção de etanol. Devido aos melhores resultados obtidos pelo método de injeção de etanol, este foi escolhido para o preparo dos lipossomas a serem aplicados nos testes in vivo. Os ratos foram submetidos ao processo de I/R pelo clampeamento bilateral das artérias carótidas, sendo os diferentes grupos tratados com a creatina (30 mg/kg) na forma livre (Liv+I/R) e lipossomada (Lip+I/R), sendo comparados com os grupos controle e I/R. A atividade locomotora, exploratória e a memória dos animais foram avaliadas através dos testes de campo aberto e da esquiva passiva, 24 e 48 h após a I/R, respectivamente. Após 72 h, os animais foram eutanasiados e os cérebros removidos para as determinações bioquímicas dos níveis de ERs e ácido ascórbico (AA), e a atividade das enzimas superóxido dismutase (SOD) e catalase (CAT). As suspensões de lipossomas utilizadas para o tratamento in vivo apresentaram diâmetro médio de partícula homogêneo (154 ± 6,9 nm), com baixo índice de polidispersão (0,211 ± 0,019), pH próximo a neutralidade (em torno de 6,7), potencial Zeta negativo (-21 ± 1,8 mV) e taxa de associação em torno de 31%. Os resultados do teste de campo aberto demonstraram que a I/R causou alteração na atividade exploratória dos animais. Além disso, o estudo demonstrou aumento no estresse oxidativo no cérebro de ratos submetidos a I/R. Os lipossomas de creatina protegeram a alteração na atividade exploratória e o aumento do estresse oxidativo em córtex de ratos. Já a creatina na forma livre não foi capaz de proteger contra estas alterações. Através destes resultados, pode-se concluir que a produção de lipossomas contendo creatina apresentou viabilidade tecnológica, demonstrando potencial para aumentar a biodisponibilidade de creatina para o SNC através da BHE.

lipossoma

creatina

barreira hematoencefálica (BHE)

sistema nervoso central (SNC)

liposome, creatine

blood-brain barrier (BBB)

central nervous system (CNS)

CNPQ::ENGENHARIAS

Etude du modèle de rat pour la sclérose latérale amyotrophique: caractérisation de la barrière hémato-encéphalique et applications thérapeutiques / Study of the rat model for amyotrophic lateral sclerosis: characterization of the blood-brain barrier and therapeutical approaches

Nicaise, Charles

22 December 2010

The selective degeneration of motoneurons in the spinal cord, the brainstem and the brain cortex is the core pathology of amyotrophic lateral sclerosis (ALS), but evidences suggest that the neighbouring non-neuronal cells are also involved in the disease progression. Beside Riluzole, only drug approved to treat this fatal neurodegenerative disease, new pharmaceutical agents or novel strategies including stem cell therapy are currently under development and evaluated preclinically in front line on mutant SOD1 rodents mimicking all hallmarks of the human disease. <p>Current intravenously delivered drugs tested in ALS therapy assume an intact blood-brain barrier and suppose the passage across the endothelium to hit their targets in the CNS parenchyma. If BBB impairment occurs in ALS, it may lead to revision of planned pharmaceutical treatment. In the first part of the work, we have validated the mutant SOD1 rat model of ALS and we characterized properties and integrity of its BBB. We observed a significant BBB disruption at symptomatic phase of ALS, evidenced by blood protein leakage, IgG accumulation and microhemorrhage. To look for the mechanism of BBB opening, we demonstrated that the expression of key genes involved in the BBB integrity was decreased. At the ultrastructure, the morphology of endothelial cells and vascular astrocyte end-feet was altered. Our results suggest that BBB disruption is a late event in ALS disease course and appears like a consequence of the local degenerative process or neuroinflammation rather than a cause. Since a lot of extracellular oedema and swollen astrocyte end-feet were found in mutant SOD1 rats, we also looked at the expression and localization of aquaporin-4, a key protein involved in CNS water movement. We found that its expression was highly increased in the symptomatic phase of ALS course and we hypothesize that this overexpression might be related to the resolution of oedema after BBB opening. <p>In the second part of the work, we considered an original, easy, non-invasive and safe therapeutical approach of stem cell delivery in ALS rats. Since ALS affects the motoneurons throughout the CNS, we decided to use the bloodstream to deliver neural stem cells. We studied cell homing, survival, proliferation, integration and differentiation. Interestingly, the highest efficiency of cell delivery to the CNS was found in symptomatic ALS and the lowest in healthy animals. Neural stem cells injected into ALS animals preferentially colonized the motor cortex, hippocampus and spinal cord. We detected their successful differentiation into neural lineages by the appearance of MAP2-, GFAP-positive cells and the decrease of nestin expression.<p>One of the realistic near-term clinical goals for ALS is the transplantation of stem cells that counteract the loss of motoneurons by secreting neuroprotective factors. Accordingly, we evaluated in vitro the expression of neurotrophic factors released by stem cells after stimulation with tissue extracts from ALS rats. The aim of this paradigm was to determine whether the ALS environment triggers neuroprotective factors release from stem cells. Mesenchymal stem cells and neural stem cells were able to express a wider range of growth factors than fibroblasts. According to the stem cell population stimulated, we obtained differential expression pattern, raising the choice of cell population for appropriate clinical applications in ALS.<p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

Disciplines biomédicales diverses

Médecine pathologie humaine

Amyotrophic lateral sclerosis

Blood-brain barrier

Sclérose latérale amyotrophique

Barrière hémato-encéphalique

BBB

stem cells

ALS

SEX- AND AGE-DEPENDENT WESTERN-DIET INDUCED BLOOD-BRAIN BARRIER DYSREGULATION AND RELATIONSHIP TO BEHAVIOR, HYPERGLYCEMIA, BODY WEIGHT, AND MICROGLIA

Elizabeth Sahagun (5930825)

28 April 2022

<p>There has been a rapid shift in food environment of Western cultures that has increased consumption of diets high in fat and sugar, which have imparted negative effects on metabolic and neurocognitive health. There is also building evidence that the adverse effects of Western diet</p> <p>(WD) are different in males and females, such that males are impacted more at an earlier age and females are impacted later in life. The underlying biological mechanisms linking WD and neurocognitive health are often associated with energy dysregulation or neuroinflammation. WD</p> <p>disrupts glucose homeostasis and causes low grade inflammation in the body, and these can impact</p> <p>the brain by disrupting the blood-brain barrier (BBB). The BBB is the microvasculature found throughout the entire brain that tightly regulates what compounds get into the brain to ensure optimal neuronal function. WD disrupts the BBB, however, the effects of WD on BBB integrity</p> <p>in females and younger individuals remain largely unknown. Based on the metabolic and behavioral effects of WD, we hypothesized that the effects are age- and sex- specific. To test this, we gave male and female rats access to a WD for 8-10 weeks starting in juvenile period (post-natal</p> <p>day 21) or in adulthood (post-natal day 75), then measured body weight, behavior, glucose tolerance, the density of two different markers of BBB integrity. We also measured density of resident immune cells (microglia) to assess the relationship between inflammation and BBB integrity. First, we focused on the impact of hyperglycemia on the BBB since elevated glucose alters glucose transporter 1 (GLUT1). We found sex- and age- specific decreases in GLUT1 density in the prefrontal cortex and hippocampus—two brain regions commonly associated with neurocognitive impairments associated with WD. Correlational comparisons between WD and chow (CH) animals also found that the typically relationship between glucose tolerance and</p> <p>GLUT1 in the PFC and hippocampus were overall disrupted in WD animals. Second, we measured the leakage of albumin, a blood protein, since WD depletes the tight junctions that would typically prevent albumin from entering the brain and triggering a neuroinflammatory response. We did not find an increase in albumin density in WD animals, however, we found a main effect of age which</p> <p>offers insight to differential susceptibilities to BBB leakage. Third, we focused on inflammation and found that WD did not impact microglia density in our experiments, nor did it correlate with GLUT1, albumin, or behavior. Collectively, our findings support the hypothesis that the impact of</p> <p>WD on the BBB is sex- and age- specific, suggest that WD does not increase leakage of compounds such as albumin, and highlights the nuanced relationships between WD, metabolic disruption, behavioral deficits, and neuroinflammation.  </p>

Western diet

Sex differences

blood-brain barrier

GLUT1

BBB leakage

hyperglycemia

obesity

IBA1+

hippocampus

prefrontal cortex

Early life diet

The Effects of Cold and Freezing Temperatures on The Blood Brain Barrier and Aquaporin 1, 4, and 9 Expression in Cope's Gray Treefrog (Hyla Chrysoscelis)

Felemban, Dalal Nouruldeen

January 2016

No description available.

Physiology

Biology

Neurobiology

Histology

AQP

BBB

Freezing

Freeze Tolerant

AQP1

AQP4

AQP9

Gray Treefrog

Hyla Chrysoscelis

Evans Blue

Glycerol

Brain

Aquaporin

Blood Brain Barrier

Nationale und regionale Identität von Fernsehprogrammen. Eine Analyse der Programminhalte von ZDF, ORF 2, BR und MDR. / National and Regionale Identity of TV Programmes. A Content Analysis of the TV Channels of ZDF, ORF 2, BR and MDR.

Ihle, Holger

13 May 2011

No description available.

300 Sozialwissenschaften

Soziologie

Social Sciences

nationale Identität

regionale Identität

Fernsehen

deutsche Identität

österreichische Identität

Regionalfernsehen

Nation

Region

Inhaltsanalyse

national identity

regional identity

TV

German identity

Austrian identity

regional TV programme

nation

region

content analysis

05.36

05.20

BBB 170: Fernsehen

BBB 220: Inhalte

Einzelthemen. Programmsparten {Rundfunk-

Fernsehjournalismus}

Altération de la barrière hémato-encéphalique et autoimmunité dans l'épilepsie : rôle des Immunoglobulines G et recherche de biomarqueurs. / Blood-brain barrier impairment and autoimmunity in epilepsy : role of Immunoglobulins G and biomarkers identification.

Michalak, Zuzanna

28 June 2012

L'épilepsie est une maladie neurologique chronique caractérisée par des crises spontanées et récurrentes. Les crises sont générées par un déséquilibre dans le fonctionnement des neurotransmetteurs et des canaux ioniques qui contrôlent l'excitabilité. L'épileptogenèse est majoritairement associée à des pertes neuronales, une gliose, une inflammation plus ou moins importants. Un tiers des patients deviennent réfractaires. Récemment, plusieurs équipes ont montré une association entre les épilepsies focales pharmacorésistantes et la rupture de la barrière hémato-encéphalique (BHE). De plus, une implication du système immunitaire ainsi qu'une cause auto-immune de l'épilepsie ont été suggérées. Dans cette thèse, nous avons observé dans le tissu de patients atteints d'épilepsie pharmacorésistante du lobe temporal (ELT), des fuites d'Immunoglobulines G (IgG) dans le parenchyme et leur accumulation dans les neurones présentant des signes de neurodégénérescence. Le récepteur d'IgG de grande affinité FcyRI est surexprimé sur les cellules ayant une morphologie de type microglie/ macrophages, tandis que le récepteur de faible affinité FcyRIII et le récepteur inhibiteur FcγRII sont moins présents. Dans ce même tissu nous avons noté que les protéines du complément C3c et C5b9 sont exprimées. Ensuite, nous avons étudié si le modèle murin d'épilepsie focale induite par injection intra-amygdalienne de kaïnate reproduit la physiopathologie de l'ELT associée à une rupture de la BHE. ZO-1, la principale protéine des jonctions serrées, présente un marquage discontinu indiquant que la BHE a été affectée. Nous avons remarqué des fuites d'IgGs et d'albumine ainsi que leur accumulation dans le parenchyme coïncidant avec la survenue des crises. La présence d‘IgG dans l'épilepsie pourrait également avoir une cause auto-immune. Nous avons utilisé des puces à protéines pour identifier des antigènes qui induisent une réponse immunitaire, dans le plasma des patients atteints d'ELT, Nous avons sélectionné 19 auto-anticorps spécifiques qui peuvent servir de potentiels biomarqueurs diagnostiques L'ensemble de ces résultats suggère que les fuites d'IgG sont associées à une déficience neuronale, conduisant à des changements immunologiques dans le foyer épileptique qui participent à la pathogénèse de l'ELT. Nous pensons qu'une meilleure interprétation des profils de ces auto-anticorps pourrait offrir de nouvelles perspectives thérapeutiques. / Epilepsy is a chronic neurologic disorder characterized by recurrent unprovoked seizures. Seizures are generated by an imbalance in the functioning of neurotransmitters and ion channels that control excitability. Epileptogenesis is mostly associated with neuronal loss, gliosis, and inflammation more or less important. A third of patients become drug refractory. Recently, several teams have shown an association between drug-resistant focal epilepsy and disruption of the blood-brain barrier (BBB). In addition, a possible role of the immune system and an autoimmune nature in epilepsy has been suggested. In this thesis, in the tissue of patients with drug-resistant temporal lobe epilepsy (TLE), leakage of immunoglobulin G (IgG) into the parenchyma and IgG accumulation in neurons with attendant signs of neurodegeneration was observed. In addition, the high affinity IgG receptor, FcγRI was expressed on microglia/macrophage shaped cells. The expression of the low affinity IgG receptor, FcγRIII and the inhibitory IgG receptor, FcγRII was decreased. In the same tissue the complement proteins C3c and C5b9 were present on astrocyte/ microglia and macrophage/ microglia shaped cells respectively. Then, we evaluated whether the mouse model of focal epilepsy induced by intra-amygdala microinjection of kainic acid reproduced a pathophysiology of TLE associated with BBB impairment. ZO-1, the main tight junction protein presented discontinuous staining indicating that BBB was affected. Both IgG and albumin extravasations from blood vessels were noted and its parenchymal accumulation was concomitant with seizure occurrence. Another hypothesis of IgG presence in epilepsy incriminates an auto-immune cause. Protein microarray technology was used for identification in pooled plasma samples, of antigens that bind plasma antibody from TLE patients. 19 potential autoantibodies were identified as potential diagnostic biomarkers. Together, these observations suggest that IgG leakage is associated with neuronal impairment, leading to immunological changes in epileptic focus involved in the pathogenesis of TLE. A better interpretation of the profiles of these autoantibodies could offer new therapeutic and diagnostic perspectives.

Barrière hémato-encéphalique (BHE)

Epilepsie du lobe temporale (ELT)

Autoanticorps

Jonction serrée

Puces à protéines

Kainate

Blood-brain barrier (BBB)

Temporal Lobe Epilepsy (TLE)

Autoantibodies

Tight Junctions (TJs)

Protein Microarrays

Kainate

616

In vivo peptide biomarker screening for molecular imaging in eae neuroinflammation / Identification in vivo de biomarqueurs peptidiques pour l’imagerie moléculaire dans le modele eae de neuroinflammation

Vargas Sanchez, Jeinny

06 December 2013

Dans les maladies neurodégénératives comme la sclérose en plaques, la neuro-inflammation modifie l'activité de la barrière hémato-encéphalique (BHE) par des altérations cellulaires et moléculaires complexes. La caractérisation de tels changements moléculaires par une approche d'étiquetage in vivo justifie la recherche d’outils de ciblage fiables et de biomarqueurs. Les stratégies pour définir in vivo ces marqueurs sont cependant compliquées par la pléthore de molécules cibles accessibles, par l’intrication des régions atteintes au sein du tissu sain et par les altérations structurales potentielles des molécules cibles étudiées par histopathologie. Le but de ce travail est de rationaliser la découverte de biomarqueurs des altérations moléculaires dans les tissus par une stratégie de sélection in vivo de répertoires de phages présentant des peptides à leur surface (phage display), les ligands présents dans les deux répertoires (sain et pathologique) étant ensuite soustraits physiquement. Cette stratégie de soustraction (« PhiSSH ») permettant d’enrichir un répertoire en ligands spécifiques est d’un intérêt majeur dans le cas de répertoires complexes tels ceux obtenus dans des sélections in vivo.Nous présentons l'application de cette stratégie dans le modèle de rat de la sclérose en plaques, l’Encéphalomyélite Autoimmune Expérimentale (EAE), où les lésions disséminées dans le système nerveux central engendrent la sélection d’une grande quantité de clones s’associant au tissu sain, par comparaison avec les rats témoins en bonne santé. L'efficacité de la technique de soustraction a été contrôlée par séquençage massif des trois repertoires, «EAE», «SAIN», et «SOUSTRACTION». Plus de 95 % des clones communs aux répertoires EAE et contrôle sont absents du répertoire de la soustraction. Un ensemble de clones de phages et des peptides synthétisés chimiquement dessinés après l’analyse bioinformatique du répertoire de soustraction a été testé a) sur des tissus de rats EAE et sains et b) sur des cellules humaines en culture (HCMEC/D3) constituant un modèle de BHE, dans des conditions inflammatoires, (activation IL- 1ß) ou non activées. Un des clones et quatre peptide testés ont montré une association spécifique sur les cellules endothéliales de BHE dans des conditions inflammatoires. Pour identifier la cible d’un phage spécifique des lésions neuro-inflammatoires, nous avons mis en œuvre un procédé de création de liaison covalente entre ce phage et les protéines exprimées par des cellules de BHE cultivées en présence d’IL-1ß, puis effectué une analyse par spectométrie de masse. La galectine-1 est apparue comme une cible potential de ce phage. La découverte de biomarqueurs spécifiques de modifications moléculaires et cellulaires de régions inflammatoires disséminées dans les tissus sains, comme c’est le cas dans la plupart des pathologies présentant une activité neuro–inflammatoire, sera facilitée par l’utilisation de la stratégie de soustraction PhiSSH décrite dans ce document. / In neurodegenerative disorders like multiple sclerosis, neuroinflammation modifies the blood brain barrier (BBB) status by causing complex cellular and molecular alterations. Characterization of such molecular changes by an in vivo labeling approach is most challenging to generate reliable in vivo targeting tools and biomarkers. In vivo strategies to define such markers are, however, hampered by the plethora of the accessible target molecules, the vicinity of diseased target expression among healthy tissue and the potentially structural alterations of target molecules when studied by histopathology. The aim of this work is to streamline the biomarker discovery of pathological molecular tissue alterations by in vivo selection of phage displayed peptide repertoires that are further submitted to physical DNA subtraction (“PhiSSH”) of sequences encoding common peptides in both repertoires (HEALTHY and PATHOLOGY). The strategy of Subtraction allows thus the enrichment of clones specific for one repertoire and is of particular interest for complex repertoires produced by in vivo selection. We present the application of this strategy in the multiple sclerosis rat model, Experimental Autoimmune Encephalomyelitis (EAE) pathology, where target lesions are disseminated in the central nervous system (CNS) generating a large amount of clones binding to healthy tissue among the recovered repertoire clones binding to the lesions by comparison with healthy control rats. The efficiency of the subtraction was monitored by massive sequencing of the three repertoires, «EAE», «HEALTHY», and «SUBTRACTION». More than 95% of the clones common to EAE and Healthy repertoires were shown to be absent from the Subtraction repertoire. A set of randomly chosen clones and synthesized peptides from the EAE and subtraction repertoires were tested for differential labeling of a) diseased and healthy animal tissues and b) an in vitro BBB model, in IL-1ß challenged and resting control state culture human cells (hCMEC/D3). One of the phage clones and 4 chemically synthesized peptides showed specific binding to brain ECs in neuro-inflammatory conditions. Using a strategy of crosslinking of an EAE specific phage clone on protein targets expressed by IL-1ß activated ECs followed by mass spectrometry, we propose hypothetically Galectin-1 as a possible target of this phage. PhiSSH will be useful for in vivo screening of small peptide combinatorial libraries for the discovery of biomarkers specific of molecular and cellular alterations untangled with healthy tissues, as in most pathologies presenting neuroinflammatory activity.

Barrière hémato-encéphalique (BHE),

Sclérose en plaques

Neuro-inflammation

Biomarqueurs

Phages présentant des peptides

Soustraction

Blood brain barrier (BBB)

Multiple sclerosis

Neuroinflammation

Biomarker

Phage display

Subtraction