Novel Mechanisms and Approaches in the Study of Neurodegeneration and Neuroprotection. A Review

Kostrzewa, Richard M., Segura-Aguilar, Juan

01 December 2003

Cellular mechanisms involved in neurodegeneration and neuroprotection are continuing to be explored, and this paper focuses on some novel discoveries that give further insight into these processes. Oligodendrocytes and activated astroglia are likely generators of the pro-inflammatory cytokines, such as the tumor necrosis factor family and interleukin family, and these glial support cells express adhesion receptors (e.g., VCAM) and release intercellular adhesion molecules (ICAM) that have a major role in neuronal apoptosis. Even brief exposure to some substances, in ontogeny and sometimes in adulthood, can have lasting effects on behaviors because of their prominent toxicity (e.g., NMDA receptor antagonists) or because they sensitize receptors (e.g., dopamine D2 agonists), possibly permanently, and thereby alter behavior for the lifespan. Cell cycle genes which may be derived from microglia, are the most-recent entry into the neuroprotection schema. Neuroprotection afforded by some common substances (e.g., melatonin) and uncommon substances [e.g., nicotine, green tea polyphenol (-)-epigallocatechin-3-gallate (EGCG), trolox], ordinarily thought to be simple radical scavengers, now are thought to invoke previously unsuspected cellular mechanisms in the process of neuroprotection. Although Alzheimer's disease (AD) has features of a continuous spectrum of neural and functional decline, in vivo PET imaging and and functional magnetic resonance imaging, indicate that AD can be staged into an early phase treatable by inhibitors of β and γ secretase; and a late phase which may be more amenable to treatment by drugs that prevent or reverse tau phosphorylation. Neural transplantation, thought to be the last hope for neurally injured patients (e.g., Parkinsonians), may be displaced by non-neural tissue transplants (e.g., human umbilical cord blood; Sertoli cells) which seem to provide similar neurotrophic support and improved behavior-without posing the major ethical dilemma of removing tissue from aborted fetuses. The objective of this paper is to invite added research into the newly discovered (or postulated) novel mechanisms; and to stimulate discovery of additional mechanisms attending neurodegeneration and neuroprotection.

Alzheimer disease

astroglia

cell cycle genes

cytokines

human umbilical cord blood

neurodegeneration

neuroprotection

non-neural transplantation

oligodendrocytes

sertoli cells

Biomedical Sciences

Maternal Immune Dysregulation in the Pathogenesis of Neurodevelopmental Disorders: Interleukin-6 as a Central Mechanism and Therapeutic Target of Flavonoids

Parker-Athill, Ellisa Carla

01 January 2012

Activation of the maternal immune system and resultant maternal cytokine expression due to prenatal infection has been implicated as a significant contributor to the pathology of neuropsychiatric and neurodevelopmental disorders such as schizophrenia and Autism Spectrum Disorder (ASD). Increased maternal interleukin-6 (IL-6) expression, observed clinically and in animal models of prenatal infection, and resultant activation of key signaling pathways, has been shown to be a biological indicator of pathology, and a central component of the pathological mechanism. In animal models of prenatal infection and clinically in pregnancy disorders hallmarked by immunological irregularities and increased IL-6 expression, inhibition of IL-6 has been shown to reduce pathological symptoms both maternally and in the exposed offspring. This study aims to demonstrate the ability of IL-6 expression, resulting from prenatal infection, to induce neuropathological and behavioral outcomes that mirror clinical observations seen in disorders such as ASD. More importantly, it shows how flavones luteolin and diosmin, a subclass of the flavonoid family, through inhibition of IL-6 mediated activation of Signal Transducer and Activator of Transcription-3 (Stat3) can reduce these pathologies both in vitro and in vivo. Evidence suggests that flavonoids, a polyphenolic class of naturally occurring plant secondary metabolites, are potent anti-inflammatory agents that can attenuate the expression of cytokines such as IL-6, possibly through the modulation of tyrosine kinase activity. They have been shown to have significant therapeutic potential in disorders hallmarked by increased inflammation or disruptions in immune regulation, such as neurodegenerative disorders and certain cancers. Members such as diosmin have also been shown to be safe during pregnancy, and are currently utilized in the treatment of certain vascular disorders associated with pregnancy. In vitro work undertaken in this study showed that co-administration of luteolin with IL-6 in neural stem cells (NSC) was able to attenuate pathological outcomes induced by IL-6 including aberrant proliferation, over expression of astroglial marker, glial fibrillary acidic protein (GFAP) and changes in cellular morphology. In vivo studies involving luteolin and diosmin further confirmed the therapeutic efficacy of these compounds as similar attenuation of IL-6 mediated maternal and fetal pro-inflammatory cytokine expression and abnormal behaviors in prenatally exposed offspring was observed. Mechanistically, these effects were mediated through inhibition of Stat3 activation although other pathways activated by IL-6 were modulated by flavone co-treatment. Flavonoid treatment during periods of prenatal infection may prove to be a therapeutic intervention for the resultant pathological outcomes seen in offspring through attenuation of the maternal and fetal immune response to infection as well as modulation of signaling pathways in the fetal brain. These compounds may prove therapeutically efficacious for the application in perinatal conditions hallmarked by increased inflammation during pregnancy.

Astroglia

Autism Spectrum Disorder (ASD)

Inflammation

Luteolin

Prenatal Infection

American Studies

Arts and Humanities

Neurosciences

Pharmacology

Development and application of correlative STED and AFM to investigate neuronal cells

Curry, Nathan

January 2018

Over the past three decades in cellular neuroscience there has been a shift towards the view of the 'tripartite synapse', where, astrocytes -- as well as the pre-synapse and post-synapse -- are involved in synaptic signalling. The migration of astrocytes to form branched networks in the brain is, therefore, of great interest in understanding brain development and neuronal function. Migration is a complex interplay between cytoskeletal reorganisation and cell mechanical stiffness. In order to improve understanding of this process, correlative measurements of cytoskeletal organisation and mechanical stiffness are required. To investigate astrocyte migration a technique combining atomic force microscopy (AFM) with stimulated emission depletion (STED) microscopy was developed. First a custom STED microscope was developed. To facilitate the design of this system the theoretical performance of a range of STED techniques (cw-STED, time-gated STED, pulsed STED and RESOLFT) were compared, identifying that pulsed STED theoretically has the highest photon efficiency. A pulsed STED microscope, which uses adaptive optics, was then designed, developed and characterised. The microscope was found to achieve resolutions below 50 nm. The STED microscope was combined with a commercial AFM to study live cells. Using the recently developed SiR-actin and SiR-tubulin dyes and AFM probes optimised for live cell mechanical property studies, images of the actin and tubulin cytoskeleton were correlated with AFM topography and mechanical stiffness measurements. It was found that, in astrocytes, actin contributes significantly both to astrocyte stiffness and topography. Investigations of migrating cells showed differences in actin organisation and mechanical stiffness between the basis and leading edge of migration. A further study was performed, investigating the effects of the gap-junction protein connexin30, which is expressed during the early stages of brain development, on migration. This protein was found to inhibit the actin reorganisation and mechanical stiffness changes observed in basal conditions. Overall the combination of mechanosensitive AFM measurements with advanced microscopy, such as super-resolution, on live cells is a promising approach which will enable a range of investigations, for instance when studying cell structural remodeling during brain development or tumorigenesis.

Ko-Expression des astroglialen GFAP- und des oligodendrozytären PLP-Promotors in Müllerzellen der Retina: Aktivierung durch Läsionen

Lycke, Christian

07 January 2015

Die Dissertation befasst sich mit der Untersuchung der Ko-Expression des GFAP- und des PLP-Promotors in Müllerzellen der Netzhaut transgener Mäuse. Die verwendete Mauslinie ist tripel-transgen für den GFAP- und den PLP-Promotor sowie für einen ROSA26-Reporter. Durch die Quantifizierung der EYFP-Expression in Müllerzellen konnte gezeigt werden, dass es nach akuter ischämischer Schädigung sowie einer angeborenen retinalen Degeneration in Müllerzellen zu einer Aktivierung des oligodendrozytären PLP-Promotors kommt. Weiterhin wurde festgestellt, dass die Aktivierung des Transkriptionsfaktors Sox-9, der sowohl für die Entwicklung der Müllerzellen als auch für die Oligodendrogenese von entscheidender Rolle ist, mit dieser Promotoraktivierung korreliert. Diese Ergebnisse implizieren, dass Müllerzellen im Rahmen ihrer Stammzelleigenschaften in der Lage sind, auf embryonale Entwicklungsprozesse, die auch die oligodendrozytäre Zellreihe beinhalten, zurückgreifen zu können.

Müllerzellen

Gliazellen

Astroglia

Koexpression

EYFP

Sox9

GFAP

PLP

transgenes Mausmodell

Netzhaut

Retina

Cre-Rekombinase

SplitCre

retinal Müller cells

Müller glia

Muller cells

glia cells

astroglia

co-expression

EYFP

Sox9

PLP

GFAP

Cre recombinase

SplitCre

retina

ddc:610

Müllerzellen

Retina

GFAP

PLP

Cre

SplitCre

Ko-Expression des astroglialen GFAP- und des oligodendrozytären PLP-Promotors in Müllerzellen der Retina: Aktivierung durch Läsionen: Ko-Expression des astroglialen GFAP- und desoligodendrozytären PLP-Promotors in Müllerzellen der Retina:Aktivierung durch Läsionen

Lycke, Christian

26 June 2014

Die Dissertation befasst sich mit der Untersuchung der Ko-Expression des GFAP- und des PLP-Promotors in Müllerzellen der Netzhaut transgener Mäuse. Die verwendete Mauslinie ist tripel-transgen für den GFAP- und den PLP-Promotor sowie für einen ROSA26-Reporter. Durch die Quantifizierung der EYFP-Expression in Müllerzellen konnte gezeigt werden, dass es nach akuter ischämischer Schädigung sowie einer angeborenen retinalen Degeneration in Müllerzellen zu einer Aktivierung des oligodendrozytären PLP-Promotors kommt. Weiterhin wurde festgestellt, dass die Aktivierung des Transkriptionsfaktors Sox-9, der sowohl für die Entwicklung der Müllerzellen als auch für die Oligodendrogenese von entscheidender Rolle ist, mit dieser Promotoraktivierung korreliert. Diese Ergebnisse implizieren, dass Müllerzellen im Rahmen ihrer Stammzelleigenschaften in der Lage sind, auf embryonale Entwicklungsprozesse, die auch die oligodendrozytäre Zellreihe beinhalten, zurückgreifen zu können.:Inhaltsverzeichnis ....................................................................................................................... 3 Bibliographische Darstellung ..................................................................................................... 5 Abkürzungsverzeichnis und Erläuterungen ................................................................................ 6 1 Einleitung ............................................................................................................................ 8 1.1 Die Retina als Teil des Auges ................................................................................................. 8 1.1.1 Aufbau .............................................................................................................................. 8 1.2 Die gliale Müllerzelle ............................................................................................................ 12 1.2.1 Definition und Morphologie der Müllerzellen ............................................................... 12 1.2.2 Funktion .......................................................................................................................... 13 1.2.3 Ursprung und Ontogenese der Müllerzelle ..................................................................... 14 1.3 Erkrankungen der Netzhaut .................................................................................................. 15 1.3.1 Akute Läsionen ............................................................................................................... 15 1.3.2 Chronische Erkrankungen der Netzhaut ......................................................................... 15 1.3.3 Die Rolle der Müllerzelle in der erkrankten Retina ....................................................... 16 1.4 Mausgenetik .......................................................................................................................... 18 1.4.1 Das Cre-loxP-System ..................................................................................................... 18 1.5 Pax-6 und Sox-9: Transkriptionsfaktoren spezifizieren das Zellschicksal ........................... 24 1.5.1 Die PAX-Familie ............................................................................................................ 24 1.5.2 SOX-9-Gene ................................................................................................................... 25 2 Ziele .................................................................................................................................. 26 3 Material und Methoden ..................................................................................................... 27 3.1 Material ................................................................................................................................. 27 3.1.1 Chemikalien .................................................................................................................... 27 3.1.2 Antikörper ....................................................................................................................... 27 3.1.3 Größenstandards ............................................................................................................. 28 3.1.4 Mauslinien ...................................................................................................................... 29 3.1.5 Geräte ............................................................................................................................. 31 3.2 Methoden .............................................................................................................................. 31 3.2.1 Genotypisierung transgener Mäuse ................................................................................ 31 3.2.2 Akute retinale Läsion durch Anlegen eines erhöhten Augeninnendrucks („high intraocular pressure“, HIOP) .......................................................................................... 37 3.2.3 Herstellung und Fixierung der retinalen Gewebsproben ................................................ 37 3.2.4 Immunhistochemische Färbungen .................................................................................. 38 3.2.5 Mikroskopische Auswertung .......................................................................................... 39 3.2.6 Datenverarbeitung und Statistik ..................................................................................... 41 4 Ergebnisse ......................................................................................................................... 42 4.1 Technische Aspekte: Vergleich der Quantifizierung in Ganzpräparate und Querschnitte ... 42 4.1.1 Vergleich der Abbildungen ............................................................................................ 42 4.1.2 Auszählung Retina-Ganzpräparate ................................................................................. 43 4.1.3 Auszählung der Zellen in Querschnitten der Netzhaut ................................................... 45 4.1.4 Vergleich der Quantifizierung von Ganzpräparaten und Querschnitten ........................ 46 4.1.5 Quantifizierung ............................................................................................................... 48 4.2 Analyse der Reporterexpression in der Retina tripel-transgener Mäuse ............................... 49 4.2.1 Quantitative Auswertung GS-positiver Müllerzellen ..................................................... 49 4.2.2 Quantitative Auswertung EYFP-positiver Müllerzellen ................................................ 51 4.2.3 Auswertung des prozentualen Anteils der EYFP-positiven Müllerzellen ...................... 53 4.3 Auswertung der Transkriptionsfaktorexpression von Pax-6 und Sox-9 ............................... 56 4.3.1 Auswertung der Pax-6-positiven Müllerzellen ............................................................... 57 4.3.2 Auswertung der Sox-9-positiven Müllerzellen .............................................................. 60 5 Diskussion ......................................................................................................................... 63 5.1 Die GFAP-Expression in der Müllerzellgliose ..................................................................... 63 5.2 Auswertung und Vergleich der retinalen Ganzpräparate und Querschnitte ......................... 64 5.3 Die Untersuchung der Promotoraktivität nach retinaler Ischämie ........................................ 65 5.4 Die Untersuchung der Promotoraktivität bei angeborener retinaler Degeneration ............... 66 5.5 Die Rolle der Transkriptionsfaktoren Pax-6 und Sox-9 ........................................................ 68 5.5.1 Pax-6 ............................................................................................................................... 68 5.5.2 Sox-9 ............................................................................................................................... 69 5.6 Einordnung der Ergebnisse in die Zellbiologie der Müllerzelle ........................................... 72 6 Zusammenfassung ............................................................................................................. 74 7 Literaturverzeichnis .......................................................................................................... 77 8 Lebenslauf ......................................................................................................................... 83 9 Danksagung ....................................................................................................................... 84 10 Eigenständigkeitserklärung ............................................................................................... 85

info:eu-repo/classification/ddc/610

ddc:610