On pathophysiological mechanisms in amyothrophic lateral sclerosis

Grundström, Eva

January 2000

<p>Amyotrophic lateral sclerosis is a fatal, progressive neurodegenerative disease with unknown ethiology. The aim of this study was to increase understanding of the pathophysiological mechanisms of dying motor neurons and wasting muscle tissue in this particular disorder.</p><p>Quantitative receptor autoradiographic methodology was applied on cervical spinal cord sections from patients with ALS to evaluate the specific binding of the acetylcholine transporter ³H-vesamicol in motor neurons. Despite a significant reduction of the number of ventral motor neurons in ALS, the ³H-vesamicol binding was not reduced in ALS compared to control cases, which suggests an increased metabolic activity in remaining motor neurons.</p><p>Motor neurons dying in ALS might go through apoptosis (programmed cell death), so immunohistochemical and TUNEL techniques were applied on thoracic spinal cord from ALS patients to evaluate the possibility of an apoptotic process. The increased Bax expression indicates an apoptotic process and further, motor neurons were TUNEL-positive, indicating DNA degradation caused by programmed cell death.</p><p>Muscle biopsies were obtained from ALS patients, and mRNA levels for the neurotrophic factors GDNF and BDNF were measured and compared to control subjects. GDNF levels were increased in muscle tissue in ALS whereas BDNF levels were unaltered.</p><p>Levels of GDNF and BDNF were also measured in cerebrospinal fluid from ALS patients and controls using ELISA methodology. Levels of BDNF were unaltered in ALS cornpared to controls. GDNF however was not detectable in controls whereas 12 out of 15 ALS patients had measurab1e levels of GDNW. A marked upregulation of endogenous GDNF and GDNF mRNA in ALS CSF and muscle respectively is of special interest in relation to clinical trials where GDNF is administered to this group of patients.</p>

Neurosciences

Amyotrophic lateral sclerosis

ALS

spinal cord

motor neuron

cerebrospinal fluid

CSF

muscle

GDNF

brain-derived neurotrophic factor

BDNF

ACh

vesamicol

apoptosis

Bax

Bcl-2

neurodegeneration

Neurovetenskap

Neurology

Neurologi

On pathophysiological mechanisms in amyothrophic lateral sclerosis

Grundström, Eva

January 2000

Amyotrophic lateral sclerosis is a fatal, progressive neurodegenerative disease with unknown ethiology. The aim of this study was to increase understanding of the pathophysiological mechanisms of dying motor neurons and wasting muscle tissue in this particular disorder. Quantitative receptor autoradiographic methodology was applied on cervical spinal cord sections from patients with ALS to evaluate the specific binding of the acetylcholine transporter 3H-vesamicol in motor neurons. Despite a significant reduction of the number of ventral motor neurons in ALS, the 3H-vesamicol binding was not reduced in ALS compared to control cases, which suggests an increased metabolic activity in remaining motor neurons. Motor neurons dying in ALS might go through apoptosis (programmed cell death), so immunohistochemical and TUNEL techniques were applied on thoracic spinal cord from ALS patients to evaluate the possibility of an apoptotic process. The increased Bax expression indicates an apoptotic process and further, motor neurons were TUNEL-positive, indicating DNA degradation caused by programmed cell death. Muscle biopsies were obtained from ALS patients, and mRNA levels for the neurotrophic factors GDNF and BDNF were measured and compared to control subjects. GDNF levels were increased in muscle tissue in ALS whereas BDNF levels were unaltered. Levels of GDNF and BDNF were also measured in cerebrospinal fluid from ALS patients and controls using ELISA methodology. Levels of BDNF were unaltered in ALS cornpared to controls. GDNF however was not detectable in controls whereas 12 out of 15 ALS patients had measurab1e levels of GDNW. A marked upregulation of endogenous GDNF and GDNF mRNA in ALS CSF and muscle respectively is of special interest in relation to clinical trials where GDNF is administered to this group of patients.

Neurosciences

Amyotrophic lateral sclerosis

ALS

spinal cord

motor neuron

cerebrospinal fluid

CSF

muscle

GDNF

brain-derived neurotrophic factor

BDNF

ACh

vesamicol

apoptosis

Bax

Bcl-2

neurodegeneration

Neurovetenskap

Neurology

Neurologi

The Role of Lhx2 During Organogenesis : - Analysis of the Hepatic, Hematopoietic and Olfactory Systems

Kolterud, Åsa

January 2004

During embryonic development a variety of tissues and organs such as the lung, eye, and kidney are being formed. The generation of functional organs is regulated by reciprocal cell-cell interactions. Via the secretion of soluble molecules one type of cells affect the fate of their neighboring cells. A central issue in organogenesis is how a cell interprets such extrinsic signals and adopts a specific fate, and how the cell in response to this signal establishes reciprocal signaling. Transcription factors play a critical role in this process and my thesis focuses on the role of the LIM-homeodomain transcription factor, Lhx2, in the development of three different organ systems, the liver, the hematopoietic system and the olfactory system. The liver is formed from endoderm of the ventral foregut and mesenchyme of the septum transversum (st) and its development depends upon signaling interactions between these two tissues. As the liver becomes a distinct organ it is colonized by hematopoietic cells and serves as hematopoietic organ until birth. The fetal liver provides a microenvironment that supports the expansion of the entire hematopoietic system (HS) including the hematopoietic stem cells (HSCs). Liver development in Lhx2-/- embryos is disrupted leading to a lethal anemia due to insufficient support of hematopoiesis. To further investigate the role of Lhx2 in liver development I analyzed gene expression from the Lhx2 locus during liver development in wild-type and Lhx2-/- mice. Lhx2 is expressed in the liver associated st mesenchymal cells that become integrated in the liver and contribute to a subpopulation of hepatic stellate cells in adult liver. Lhx2 is not required for the formation of these mesenchymal cells, suggesting that the phenotype in Lhx2-/- livers is due to the presence of defective mesenchymal cells. The putative role of Lhx2 in the expansion of the HS was examined by introducing Lhx2 cDNA into embryonic stem cells differentiated in vitro. This approach allowed for the generation of immortalized multipotent hematopoietic progenitor cell (HPC) lines that share many characteristics with normal HSCs. The Lhx2-dependent generation of HSC-like cell lines suggests that Lhx2 plays a role in the maintenance and/or expansion of the HS. To isolate genes putatively linked to Lhx2 function, genes differentially expressed in the HPC lines were isolated using a cDNA subtraction approach. This allowed for the identification of a few genes putatively linked to Lhx2 function, as well as several stem cell-specific genes. The antagonist of Wnt signalling, Dickkopf-1 (Dkk-1), was identified in the former group of genes as it showed a similar expression pattern in the fetal liver, as that of Lhx2 and expression of Dkk-1 in fetal liver and in HPC lines appeared to be regulated by Lhx2. This suggests that Dkk-1 plays a role in liver development and/or HSC physiology during embryonic development. During development of the olfactory epithelium (OE) neuronal progenitors differentiate into mature olfactory sensory neurons (OSNs) that are individually specified into over a thousand different subpopulations, each expressing a unique odorant receptor (OR) gene. The expression of Lhx2 in olfactory neurons suggested a potential role for Lhx2 in the development of OSNs. To address this OE from Lhx2-/- and wild-type mice was compared. In the absence of functional Lhx2 neuronal differentiation was arrested prior to onset of OR expression. Lhx2 is thus required for the development of OSN progenitors into functional, individually specified OSNs. Thus, Lhx2 trigger a variety of cellular responses in different organ systems that play important roles in organ development in vivo and stem cell expansion in vitro.

Developmental biology

LIM-homeobox gene

Lhx2

fetal liver

hepatic stellate cells

hematopoietic stem cells

septum transversum

self-renewal

odorant receptor genes

olfactory epithelium

olfactory sensory neuron

Utvecklingsbiologi

Developmental biology

Utvecklingsbiologi

Regulatory Effects of the Actin-binding Proteins Moesin and MyosinII on Synaptic Activity at the Drosophila Neuromuscular Junction

Seabrooke, Sara

23 February 2011

The nervous system is made up of specialized cells which receive and respond to environmental stimuli. Intercellular communication in the nervous system is achieved predominantly through chemical synaptic transmission. Within the chemical synapse, the actin cytoskeleton plays a major role in regulating synaptic activities, although the extent and clarity in our understanding of these processes is still limited. Using the genetically pliable model, Drosophila melanogaster, this thesis begins to unravel contributions of actin binding proteins to synaptic development and physiology at the larval neuromuscular junction (NMJ). Two actin binding proteins, Moesin and Nonmuscle Myosin II (NMMII) were selected for study based on previous studies implicating them in synaptic development. Combining genetics, fluorescent imaging and electrophysiological recordings this thesis unveils previously unidentified functions for Moesin and NMMII in morphology and physiology of the Drosophila NMJ. Moesin was found to help restrain synaptic growth but did not affect synaptic physiology. By correlating morphological and electrophysiological measurements in Moesin mutants, it was determined that physiology and morphology can be independently regulated at the NMJ. NMMII was used to investigate a role for actin binding proteins in physiology at the Drosophila NMJ. By using the fluorescent imaging technique, FRAP, this becomes the first research to implicate NMMII in unstimulated synaptic vesicle mobility. FRAP indicated that vesicle mobility was highly dependent on the expression level of NMMII. Electrophysiological analysis of NMMII indicated distinct mechanisms for spontaneous and evoked vesicle release. NMMII expression exhibited a positive correlation with basal synaptic transmission and was important in mobilizing vesicles for synaptic potentiation. In addition, NMMII was found to be involved in a high frequency dependent low frequency depression. This work begins to identify how vesicles traverse within boutons and suggests differential mechanisms of synaptic release, both of which are partially dependent of NMMII expression. Studying Moesin and NMMII have revealed a complex interplay between the actin cytoskeleton and synaptic function and together this research furthers our understanding of how the actin cytoskeleton regulates synaptic activity.

Drosophila

neuroscience

Moesin

Myosin

neuromuscular junction

physiology

neuron

synaptic transmission

potentiation

high frequency

N-ethylmaleimide sensitive factor

morphology

FRAP

electrophysiology

vesicle

low frequency depression

development

actin

cytoskeleton

growth

neural

nervous

0317

0719

0379

Regulatory Effects of the Actin-binding Proteins Moesin and MyosinII on Synaptic Activity at the Drosophila Neuromuscular Junction

Seabrooke, Sara

23 February 2011

The nervous system is made up of specialized cells which receive and respond to environmental stimuli. Intercellular communication in the nervous system is achieved predominantly through chemical synaptic transmission. Within the chemical synapse, the actin cytoskeleton plays a major role in regulating synaptic activities, although the extent and clarity in our understanding of these processes is still limited. Using the genetically pliable model, Drosophila melanogaster, this thesis begins to unravel contributions of actin binding proteins to synaptic development and physiology at the larval neuromuscular junction (NMJ). Two actin binding proteins, Moesin and Nonmuscle Myosin II (NMMII) were selected for study based on previous studies implicating them in synaptic development. Combining genetics, fluorescent imaging and electrophysiological recordings this thesis unveils previously unidentified functions for Moesin and NMMII in morphology and physiology of the Drosophila NMJ. Moesin was found to help restrain synaptic growth but did not affect synaptic physiology. By correlating morphological and electrophysiological measurements in Moesin mutants, it was determined that physiology and morphology can be independently regulated at the NMJ. NMMII was used to investigate a role for actin binding proteins in physiology at the Drosophila NMJ. By using the fluorescent imaging technique, FRAP, this becomes the first research to implicate NMMII in unstimulated synaptic vesicle mobility. FRAP indicated that vesicle mobility was highly dependent on the expression level of NMMII. Electrophysiological analysis of NMMII indicated distinct mechanisms for spontaneous and evoked vesicle release. NMMII expression exhibited a positive correlation with basal synaptic transmission and was important in mobilizing vesicles for synaptic potentiation. In addition, NMMII was found to be involved in a high frequency dependent low frequency depression. This work begins to identify how vesicles traverse within boutons and suggests differential mechanisms of synaptic release, both of which are partially dependent of NMMII expression. Studying Moesin and NMMII have revealed a complex interplay between the actin cytoskeleton and synaptic function and together this research furthers our understanding of how the actin cytoskeleton regulates synaptic activity.

Drosophila

neuroscience

Moesin

Myosin

neuromuscular junction

physiology

neuron

synaptic transmission

potentiation

high frequency

N-ethylmaleimide sensitive factor

morphology

FRAP

electrophysiology

vesicle

low frequency depression

development

actin

cytoskeleton

growth

neural

nervous

0317

0719

0379

Electrical and Optical Characterization of Group III-V Heterostructures with Emphasis on Terahertz Devices

Weerasekara, Aruna Bandara

03 August 2007

Electrical and optical characterizations of heterostructures and thin films based on group III-V compound semiconductors are presented. Optical properties of GaMnN thin films grown by Metalorganic Chemical Vapor Deposition (MOCVD) on GaN/Sapphire templates were investigated using IR reflection spectroscopy. Experimental reflection spectra were fitted using a non - linear fitting algorithm, and the high frequency dielectric constant (ε∞), optical phonon frequencies of E1(TO) and E1(LO), and their oscillator strengths (S) and broadening constants (Γ) were obtained for GaMnN thin films with different Mn fraction. The high frequency dielectric constant (ε∞) of InN thin films grown by the high pressure chemical vapor deposition (HPCVD) method was also investigated by IR reflection spectroscopy and the average was found to vary between 7.0 - 8.6. The mobility of free carriers in InN thin films was calculated using the damping constant of the plasma oscillator. The terahertz detection capability of n-type GaAs/AlGaAs Heterojunction Interfacial Workfunction Internal Photoemission (HEIWIP) structures was demonstrated. A threshold frequency of 3.2 THz (93 µm) with a peak responsivity of 6.5 A/W at 7.1 THz was obtained using a 0.7 µm thick 1E18 cm−3 n - type doped GaAs emitter layer and a 1 µm thick undoped Al(0.04)Ga(0.96)As barrier layer. Using n - type doped GaAs emitter layers, the possibility of obtaining small workfunctions (∆) required for terahertz detectors has been successfully demonstrated. In addition, the possibility of using GaN (GaMnN) and InN materials for terahertz detection was investigated and a possible GaN base terahertz detector design is presented. The non - linear behavior of the Inter Pulse Time Intervals (IPTI) of neuron - like electric pulses triggered externally in a GaAs/InGaAs Multi Quantum Well (MQW) structure at low temperature (~10 K) was investigated. It was found that a grouping behavior of IPTIs exists at slow triggering pulse rates. Furthermore, the calculated correlation dimension reveals that the dimensionality of the system is higher than the average dimension found in most of the natural systems. Finally, an investigation of terahertz radiation efect on biological system is reported.

Quantum efficiency

Dielectric function

Dark current

Responsivity

Plasma frequency

Neuron-like pulses

High frequency dielectric constant

Negative differential resistance

Correlation dimension

Embedding dimension

Bifurcation

Return maps

Arrhenius

Dielectric function

Absorption coefficient

Detectors

Terahertz

Optical Phonon

Infrared

Astrophysics and Astronomy

Physics

From molecular pathways to neural populations: investigations of different levels of networks in the transverse slice respiratory neural circuitry.

Tsao, Tzu-Hsin B.

26 August 2010

By exploiting the concept of emergent network properties and the hierarchical nature of networks, we have constructed several levels of models facilitating the investigations of issues in the area of respiratory neural control. The first of such models is an intracellular second messenger pathway model, which has been shown to be an important contributor to intracellular calcium metabolism and mediate responses to neuromodulators such as serotonin. At the next level, we have constructed new single neuron models of respiratory-related neurons (e.g. the pre-Btzinger complex neuron and the Hypoglossal motoneuron), where the electrical activities of the neurons are linked to intracellular mechanisms responsible for chemical homeostasis. Beyond the level of individual neurons, we have constructed models of neuron populations where the effects of different component neurons, varying strengths and types of inter-neuron couplings, as well as network topology are investigated. Our results from these simulation studies at different structural levels are in line with experiment observations. The small-world topology, as observed in previous anatomical studies, has been shown here to support rhythm generation along with a variety of other network-level phenomena. The interactions between different inter-neuron coupling types simultaneously manifesting at time-scales orders of magnitude apart suggest possible explanations for variations in the outputs measured from the XII rootlet in experiments. In addition, we have demonstrated the significance of pacemakers, along with the importance of considering neuromodulations and second-messenger pathways in an attempt to understand important physiological functions such as breathing activities.

Computational neurophysiology

Computational neuroscience

Simulation techniques

Neuron modeling

Second-passenger pathway modeling

Neuromodulation

Respiratory control

pacemakers

Small-world topology

CAN-pacemaker

Non-linear bifurcation analysis

NAP-pacemaker

Neurons

Estradiol Induced Changes In Neuronal Excitability And Neuron-Astrocyte Signaling In Mixed Hippocampal Cultures

Rao, Shilpa P

08 1900

One of the defining characteristics of the brain is its plasticity, which is the ability to alter and reorganize neuronal circuits. The brain is constantly being shaped and moulded by the external world through endogenous factors like neurotransmitters, growth factors and circulating hormones. 17β-estradiol, which is the most potent estrogen among the group of ovarian steroid hormones, has widespread effects throughout the central nervous system. Apart from its actions on regions of the brain concerned with reproduction, estradiol has profound effects on brain areas not classically associated with reproductive function like cerebral cortex, midbrain, brainstem, hippocampus and spinal cord. This enables the hormone to influence learning and memory, emotions, affective state, cognition, motor coordination and pain sensitivity. Estradiol exerts these effects by regulating gene expression via intracellular estrogen receptors. In addition to this, the hormone interacts with receptors at the cell membrane to rapidly alter the electrical activity of neurons and astrocytes, and regulate second messenger systems. The aim of this study was to investigate the cellular and functional effects of estradiol on neuronal networks and on signaling between neurons and astrocytes in primary mixed hippocampal cultures. Estradiol is proconvulsant; it increases neuronal excitability and decreases the threshold for seizures. This property of estradiol is instrumental in precipitating catamenial seizures in women with epilepsy. These are epileptic seizures influenced by cyclical hormone changes and occur in over one-third to half of women with epilepsy. In the first part of the work, the effects of 24-hour estradiol treatment on hippocampal neurons were investigated using fluorescence imaging and electrophysiological techniques. Further, the ability of gabapentin, an antiepileptic drug sometimes used to treat hormone sensitive seizures, to counteract the effects of estradiol was studied. Synaptic vesicles were labeled by uptake of FM 1-43, and high K+- triggered exocytotic release was monitored by fluorescence imaging. The reduction in intensity of FM 1-43 fluorescence, which is a measure of vesicular release, was enhanced by estradiol, suggesting that estradiol upregulates the exocytotic machinery. The high K+-evoked intracellular Ca2+ rise in neurons, studied by loading the neurons with the Ca2+ indicator dye fluo-3 AM, was potentiated following estradiol treatment. Electrophysiological recordings from neurons following estradiol treatment showed an increase in the frequency of miniature excitatory postsynaptic currents (mEPSCs) and a larger number of mEPSC events with a predominant NMDA component. Many of the estradiol-induced excitatory effects on the neuronal network were abolished by incubating the cultures with a combination of estradiol and gabapentin suggesting a mechanism of action for the drug in the treatment of hormone sensitive seizures. Glial cells were once regarded as passive, supportive elements in the nervous system. This view of glial cells has drastically changed over the past decade and it is now known that glial cells are dynamic signaling elements in the brain. In view of the emerging importance of glia in the physiology of the nervous system and accumulating evidence of direct effects of steroid hormones on these cells, the subsequent part of the work delves into the consequences of 24-hour estradiol treatment on astrocytes and neuron-to-astrocyte signaling. Estrogen receptors have been described on both neurons and astrocytes in the hippocampus suggesting a complex interplay between the two cell types in mediating the effects of the hormone. Astrocytes sense and respond to neuronal activity with a rise in intracellular calcium concentration, ([Ca2+]i). Astrocyte ([Ca2+]i) transients can modulate neuronal activity, indicating a bi-directional form of communication between neurons and astrocytes. Using simultaneous electrophysiology and calcium imaging techniques, neuronal activity-evoked ([Ca2+]i) changes in fluo-3 AM loaded astrocytes were monitored. Action potential firing in neurons, elicited by injecting depolarizing current pulses, was associated with ([Ca2+]i) elevations in adjacent astrocytes which could be blocked by 200 µM MCPG and also 1 µM TTX. Comparison of astrocytic ([Ca2+]i) transients in control and estradiol treated cultures revealed that the amplitude of the ([Ca2+]i) transient, the number of responsive astrocytes and the ([Ca2+]i) wave velocity were all significantly reduced in estradiol treated cultures. ([Ca2+]i) rise in astrocytes in response to local application of the metabotropic glutamate receptor agonist t-ACPD was attenuated in estradiol treated cultures suggesting functional changes in the astrocyte metabotropic glutamate receptor following 24-hour treatment with estradiol. Since astrocytes can modulate synaptic transmission by release of glutamate, the attenuated ([Ca2+]i) response seen following estradiol treatment could have functional consequences on astrocyte-neuron signaling. The acute effects of estradiol on astrocyte-to-astrocyte and astrocyte-to-neuron signaling have been addressed in the next part of the study. Bidirectional communication between neurons and astrocytes involves integration of neuronal inputs by astrocytes, and release of gliotransmitters that modulate neuronal excitability and synaptic transmission. In addition to its rapid actions on neuronal electrical activity, estradiol can rapidly alter astrocyte ([Ca2+]i) levels through a plasma membrane-associated estrogen receptor. The functional consequences of acute estradiol treatment (5 min) on astrocyte-astrocyte and astrocyte-neuron communication were investigated using calcium imaging and electrophysiological techniques. Mechanical stimulation of an astrocyte evoked a ([Ca2+]i) rise in the stimulated astrocyte, which propagated to the surrounding astrocytes as a ([Ca2+]i) wave. Following acute treatment with estradiol, the amplitude of the ([Ca2+]i) elevation in astrocytes around the stimulated astrocyte was attenuated. Further, estradiol inhibited the ([Ca2+]i) rise in individual astrocytes in response to the metabotropic glutamate receptor agonist, t-ACPD. Mechanical stimulation of astrocytes induced ([Ca2+]i) elevations and electrophysiological responses in adjacent neurons. Estradiol rapidly attenuated the astrocyte-evoked glutamate-mediated ([Ca2+]i) rise and slow inward current in neurons. Also, the incidence of astrocyte-induced increase in spontaneous postsynaptic current frequency was reduced in presence of estradiol. The effects of estradiol were stereo-specific and reversible following washout. These findings indicate that the regulation of neuronal excitability and synaptic transmission by astrocytes is sensitive to rapid estradiol mediated hormonal control.

Brain Reception

Neural Network (Brain)

Signal Transduction

Hippocampal Neurons - Estradiol Effects

Neuronal Networks - Estradiol Effects

Estradiol

Astrocyte-Astrocyte - Estradiol Effects

Hippocampal Cultures

17ß-estradiol

Neurobiology

Metabolomics studies of ALS a multivariate search for clues about a devastating disease /

Wuolikainen, Anna,

January 2009

Diss. (sammanfattning) Umeå : Umeå universitet, 2009. / Härtill 5 uppsatser. Även tryckt utgåva.

Gene therapy in spinal muscular atrophy RNA-based strategies to modulate the pre-mRNA splicing of survival motor neuron /

Baughan, Travis, Lorson, Christian

January 2008

The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from PDF of title page (University of Missouri--Columbia, viewed on March 10, 2010). Vita. Thesis advisor: Lorson, Christian L. "December 2008" Includes bibliographical references