Kardialer Phänotyp und SUDEP durch Knockout des Nav1.1 Kanalgens (SCN1A) in einem Dravet-Mausmodell / Cardiac phenotype and SUDEP in a Dravet mouse model by knock-out of Nav1.1 sodium channel gene SCN1A

Kaiser, Markus Leonhard

January 2018

SUDEP bezeichnet den plötzlichen und unerwarteten Epilepsietod ohne offensichtliche kausale Todesursache. Junge Patienten, die an der schweren infantilen enzephalo-pathischen Epilepsieform des Dravet-Syndroms (SMEI) leiden, tragen besonderes Risiko an SUDEP zu versterben. Die pathophysiologische Ursache für das Dravet-Syndrom liegt in einem Defekt des brain-type Natriumkanals Nav1.1. Neuere Studien zeigen, dass der ursprünglich als hirnspezifisch geltende Kanal nicht explizit in neuronalem Gewebe, sondern auch im Herzen exprimiert wird. Ziel dieser Arbeit war es daher, die Auswirkungen des Nav1.1-Defektes auf kardialer Ebene zu evaluieren, um eine mögliche Beteiligung von Herzrhythmusstörungen an der Ätiologie des SUDEP aufzudecken. Dazu wurde ein Knockout-Mausmodell hinsichtlich seines kardialen Phänotyps charakterisiert. Mit Hilfe elektrokardiographischer Untersuchungen (EKG) konnte eine gesteigerte Herzfrequenz unter Stressbedingungen festgestellt werden. Die Frequenz lag sowohl bei den Versuchen unter pharmakologischem Stress mittels Isoproterenol als auch unter induziertem Stress mittels Hyperthermie bei den Dravet-Syndrom-Mäusen höher als in dem wildtypischen Kontrollkollektiv. Elektrophysiologische Untersuchungen (EPU) zeigten neben einem erhöhten Schweregrad der induzierbaren Arrhythmien, gemessen anhand eines Arrhythmie-Scores, auch eine erhöhte Quantität ausgelöster Herzrhythmusstörungen. Sowohl unter Ruhebedingungen als auch nach Induktion von Hyperthermie überwogen die aufgezeichneten Arrhythmien bei Dravet-Syndrom-Mäusen. Die Erkenntnisse dieser Studie helfen die Rolle des Nav1.1-Defektes an einer kardialen Beteiligung im Rahmen von SUDEP bei Dravet-Patienten zu beschreiben. Sie zeigen ver-schiedene kardiale Auswirkungen bei Knockout des primär neuronalen Natrium¬kanalgens SCN1A. Weitere Einsichten in diesen Bereich werden angemessene Risikostratifizierung für Epilepsie-Patienten hinsichtlich Ihres SUDEP-Risikos ermöglichen und moderne The-rapieansätze anregen. / Voltage-gated sodium channels (Nav) are responsible for the initiation of action potentials in excitable cells. In this context distinct isoforms of the Nav sodium channel family seem to be important for both neuronal and cardiac excitation. It is known that mutation or knock out of the so called brain type sodium channel Nav1.1-isoform causes a spectrum of epilepsies including severe myoclonic epilepsy of infancy (SMEI) or Dravet Syndrome which is associated with a high risk of sudden unexpected death in epilepsy (SUDEP). Previously it was demonstrated that the brain type sodium channel isoform Nav1.1 is not exclusively expressed in the nervous system but also functionally present in cardiac tissue. Therefore, we hypothesize that patients suffering from neurologic Nav1.1-deseases carry an increased cardiac arrhythmia burden that may be responsible for SUDEP. We characterize the cardiac pathophysiology in an established mouse model of Dravet Syndrome. We used classical surface electrocardiogram recordings (ECG) and invasive programmed stimulation (EPU). This was done under stressing conditions by pharmacological adrenergic application (Isoproterenol) and hyperthermia (39°C). We found that heart rate under stressing conditions was elevated by knock out of Nav1.1 gene. Also arrhythmia inducibility was elevated which was seen in quality and quantity as well. This study helps to describe the role of defect Nav1.1 sodium channel in elevated SUDEP risk of Dravet Syndrome by possible cardiac genesis. Further studies will probably lead to stratify the SUDEP risk in order to find new therapies like implantable cardiac devices.

Natriumkanal

Ionenkanal

Elektrophysiologische Untersuchung

Elektrokardiografie

Knockout <Molekulargenetik>

ddc:612

The Role of Fc Gamma Receptors in Experimental Arthritis

Andrén, Maria

January 2004

<p>Induction of collagen-induced arthritis (CIA), an animal model for human rheumatoid arthritis, is dependent on anti-collagen type II (CII) antibodies. The effector mechanism by which autoantibodies contribute to inflammatory reactions in autoimmune diseases is not well understood. In this thesis I have studied the effector pathways used by IgG anti-CII antibodies to initiate arthritis, namely the IgG Fc receptors (FcγRs) and the complement system. We have found that FcγRIII is crucial for development of CIA, as CII-immunized mice lacking this receptor do not develop arthritis and IgG1 and IgG2b anti-CII antibodies require FcγRIII to trigger arthritis when transferred to naïve mice. The antibody-mediated arthritis was further enhanced in mice deficient in the inhibitory FcγRIIB, indicating that FcγRIIB regulates the activation of FcγRIII. Furthermore, we demonstrate that FcγRIII exist as three distinct haplotypes in mice, FcγRIII:H, FcγRIII:V and FcγRIII:T. Mice expressing the FcγRIII:H haplotype are more susceptible to CIA than mice expressing the FcγRIII:V haplotype, indicating that certain FcγRIII haplotype predisposes for CIA. We also show that the most likely FcγRIII-expressing effector cell in CIA is the macrophage, since FcγRIII-expressing macrophages exclusively can induce arthritis in FcγRIII-deficient mice challenged for CIA.</p><p>The complement system was also investigated in development of CIA. We found that this effector pathway is also necessary for onset of arthritis, as CIA was inhibited by treatment with anti-complement factor 5 (C5) antibodies. C5-deficient mice could neither develop CIA unless provided with C5-containing sera. </p><p>Taken together, the work presented in this thesis indicates that FcγRs and the complement system are crucial for the induction of experimental arthritis. These findings are important for understanding the mechanisms behind rheumatoid arthritis and blocking of these effector pathways may in the future be used as treatment of rheumatoid arthritis. </p>

Immunology

Rheumatoid arthritis

Antibodies

Fc receptors

Complement

Transgenic/Knockout mice

Immunologi

Immunology

Immunologi

The Role of the SHB Adapter Protein in Cell Differentiation and Development

Kriz, Vitezslav

January 2006

<p>The present study was conducted in order to assess a role of the SH2 domain-containing adapter protein SHB in development and cell differentiation.</p><p>Embryonic stem (ES) cells overexpressing SHB and SHB with an inactive SH2 domain (R522K-SHB) were obtained. Microarray analysis in the SHB clone revealed altered expression of genes connected with neural cell function. The R522K-SHB clone exhibited altered expression of several transcription factors related to development. ES cells were differentiated by forming aggregates named embryoid bodies (EBs). The morphology of EBs was altered in the R522K-SHB clones, which showed fewer cavities. Expression of endodermal markers was decreased in the R522K-SHB EBs. </p><p>To further investigate the role of SHB in differentiation, murine ES cell lines deficient for one (SHB+/-) or both SHB alleles (SHB-/-) were generated. SHB deficient clones increased the expression of mesendodermal and endodermal markers and decreased expression of two receptors, VEGFR2 and FGFR1, connected with blood vessel differentiation. Similarly, blood vessels showed an altered morphology in SHB+/- and SHB-/- EBs after VEGF stimulation. SHB-/- ES cells also formed fewer blood colonies than control ES cells.</p><p>Finally, the role of the SHB adapter protein in vivo was analyzed by generating a SHB deficient mouse (SHB-/-). SHB-/- animals are viable, fertile, but suffer from leukopenia and anemia. SHB-/- animals demonstrate an abnormal morphology of blood vessels in the liver and kidney. Breeding of SHB+/- animals revealed an abnormal segregation of the mutant allele with an increased number of SHB+/- animals and a decreased number of SHB-/- and SHB+/+animals. Backcross analysis of SHB+/- females with SHB+/+ males displayed an increased number of SHB+/- offspring already at the blastocyst level. Simultaneously, embryos from SHB+/- mothers show an increased malformation rate in comparison to embryos from SHB+/+ mothers.</p><p>In summary, the study suggests a role of SHB in reproduction and development and in mesodermal and endodermal specification. </p>

Cell biology

SHB

transgene

ES cells

cavitation

knockout

mouse

vasculogenesis

hematopoiesis

endoderm

mesoderm

malformation

Cellbiologi

The Role of Fc Gamma Receptors in Experimental Arthritis

Andrén, Maria

January 2004

Induction of collagen-induced arthritis (CIA), an animal model for human rheumatoid arthritis, is dependent on anti-collagen type II (CII) antibodies. The effector mechanism by which autoantibodies contribute to inflammatory reactions in autoimmune diseases is not well understood. In this thesis I have studied the effector pathways used by IgG anti-CII antibodies to initiate arthritis, namely the IgG Fc receptors (FcγRs) and the complement system. We have found that FcγRIII is crucial for development of CIA, as CII-immunized mice lacking this receptor do not develop arthritis and IgG1 and IgG2b anti-CII antibodies require FcγRIII to trigger arthritis when transferred to naïve mice. The antibody-mediated arthritis was further enhanced in mice deficient in the inhibitory FcγRIIB, indicating that FcγRIIB regulates the activation of FcγRIII. Furthermore, we demonstrate that FcγRIII exist as three distinct haplotypes in mice, FcγRIII:H, FcγRIII:V and FcγRIII:T. Mice expressing the FcγRIII:H haplotype are more susceptible to CIA than mice expressing the FcγRIII:V haplotype, indicating that certain FcγRIII haplotype predisposes for CIA. We also show that the most likely FcγRIII-expressing effector cell in CIA is the macrophage, since FcγRIII-expressing macrophages exclusively can induce arthritis in FcγRIII-deficient mice challenged for CIA. The complement system was also investigated in development of CIA. We found that this effector pathway is also necessary for onset of arthritis, as CIA was inhibited by treatment with anti-complement factor 5 (C5) antibodies. C5-deficient mice could neither develop CIA unless provided with C5-containing sera. Taken together, the work presented in this thesis indicates that FcγRs and the complement system are crucial for the induction of experimental arthritis. These findings are important for understanding the mechanisms behind rheumatoid arthritis and blocking of these effector pathways may in the future be used as treatment of rheumatoid arthritis.

Immunology

Rheumatoid arthritis

Antibodies

Fc receptors

Complement

Transgenic/Knockout mice

Immunologi

Immunology

Immunologi

The Role of the SHB Adapter Protein in Cell Differentiation and Development

Kriz, Vitezslav

January 2006

The present study was conducted in order to assess a role of the SH2 domain-containing adapter protein SHB in development and cell differentiation. Embryonic stem (ES) cells overexpressing SHB and SHB with an inactive SH2 domain (R522K-SHB) were obtained. Microarray analysis in the SHB clone revealed altered expression of genes connected with neural cell function. The R522K-SHB clone exhibited altered expression of several transcription factors related to development. ES cells were differentiated by forming aggregates named embryoid bodies (EBs). The morphology of EBs was altered in the R522K-SHB clones, which showed fewer cavities. Expression of endodermal markers was decreased in the R522K-SHB EBs. To further investigate the role of SHB in differentiation, murine ES cell lines deficient for one (SHB+/-) or both SHB alleles (SHB-/-) were generated. SHB deficient clones increased the expression of mesendodermal and endodermal markers and decreased expression of two receptors, VEGFR2 and FGFR1, connected with blood vessel differentiation. Similarly, blood vessels showed an altered morphology in SHB+/- and SHB-/- EBs after VEGF stimulation. SHB-/- ES cells also formed fewer blood colonies than control ES cells. Finally, the role of the SHB adapter protein in vivo was analyzed by generating a SHB deficient mouse (SHB-/-). SHB-/- animals are viable, fertile, but suffer from leukopenia and anemia. SHB-/- animals demonstrate an abnormal morphology of blood vessels in the liver and kidney. Breeding of SHB+/- animals revealed an abnormal segregation of the mutant allele with an increased number of SHB+/- animals and a decreased number of SHB-/- and SHB+/+animals. Backcross analysis of SHB+/- females with SHB+/+ males displayed an increased number of SHB+/- offspring already at the blastocyst level. Simultaneously, embryos from SHB+/- mothers show an increased malformation rate in comparison to embryos from SHB+/+ mothers. In summary, the study suggests a role of SHB in reproduction and development and in mesodermal and endodermal specification.

Cell biology

SHB

transgene

ES cells

cavitation

knockout

mouse

vasculogenesis

hematopoiesis

endoderm

mesoderm

malformation

Cellbiologi

Functions of REP27 and the low molecular weight proteins PsbX and PsbW in repair and assembly of photosystem II

Garcia Cerdan, Jose Gines

January 2009

Oxygenic photosynthesis is the major producer of both oxygen and organic compounds on earth and takes place in plants, green algae and cyanobacteria. The thylakoid membranes are the site of the photosynthetic light reactions that involve the concerted action of four major protein complexes known as photosystem II (PSII), cytochrome b6f complex, ATP synthase and photosystem I (PSI). The function of PSII is of particular interest as it performs the light–driven water splitting reaction driving the photosynthetic electron transport. My thesis addressed different aspects of PSII assembly and the functions of its low molecular weight PSII subunits PsbX and PsbW. Photosynthesis in green algae and higher plants is controlled by the nucleus. Many proteins of nuclear origin participate in the regulation of the efficient assembly of the photosynthetic protein complexes. In this investigation we have identified one of these nuclear encoded auxiliary proteins of photosystem II, REP27, which participates in the assembly of the D1 reaction center protein and repair of photodamaged PSII in the green algae Chlamydomonas reinhardtii. Interestingly, PSII is specially enriched in Low Molecular Weight (LMW) subunits that have masses less than 10kDa. These proteins account for more than the half of the PSII subunits. Several questions remains poorly understood regarding the LMW: Which is their evolutionary origin? What function do they perform in the protein complex? Where are they located in the protein structure? In this investigation the functions of two of these LMW subunits (PsbX and PsbW) have been studied using antisense inhibition and T-DNA knockout mutant plants in Arabidopsis thaliana. Deficiency of the PsbX protein leads to impaired accumulation and functionality of PSII. Characterization of PsbW knock-out plants show that PsbW participates in stabilization of the macro-organization of PSII and the peripheral antenna (Light Harvesting Complex, LHCII) in the grana stacks of the chloroplast, also known as PSII-LHCII supercomplexes.

Photosynthesis

photosystem II reaction center

PSII-LHCII supercomplex

antisense plant

T-DNA knockout plant

auxiliary protein

Mechanics of Atherosclerosis, Hypertension Induced Growth, and Arterial Remodeling

Hayenga, Heather Naomi

2011 May 1900

In order to create informed predictive models that capture artery dependent responses during atherosclerosis progression and the long term response to hypertension, one needs to know the structural, biochemical and mechanical properties as a function of time in these diseased states. In the case of hypertension more is known about the mechanical changes; while, less is known about the structural changes over time. For atherosclerotic plaques, more is known about the structure and less about the mechanical properties. We established a congruent multi-scale model to predict the adapted salient arterial geometry, structure and biochemical response to an increase in pressure. Geometrical and structural responses to hypertension were then quantified in a hypertensive animal model. Eventually this type of model may be used to predict mechanical changes in complex disease such as atherosclerosis. Thus for future verification and implementation we experimentally tested atherosclerotic plaques and quantified composition, structure and mechanical properties. Using the theoretical models we can now predict arterial changes in biochemical concentrations as well as salient features such as geometry, mass of elastin, smooth muscle, and collagen, and circumferential stress, in response to hemodynamic loads. Using an aortic coarctation model of hypertension, we found structural arterial responses differ in the aorta, coronary and cerebral arteries. Effects of elevated pressure manifest first in the central arteries and later in distal muscular arteries. In the aorta, there is a loss and then increase of cytoskeleton actin fibers, production of fibrillar collagen and elastin, hyperplasia or hypertrophy with nuclear polypoid, and recruitment of hemopoeitic progenitor cells and monocytes. In the muscular coronary, we see similar changes albeit it appears actin fibers are recruited and collagen production is only increased slightly in order to maintain constant the overall ratio of ~55 percent. In the muscular cerebral artery, despite a temporary loss in actin fibers there is little structural change. Contrary to hypertensive arteries, characterizing regional stiffness in atherosclerotic plaques has not been done before. Therefore, experimental testing on atherosclerotic plaques of Apolipoprotein E Knockout mice was performed and revealed nearly homogenously lipidic plaques with a median axial compressive stiffness value of 1.5 kPa.

Mechanobiology

Atomic Force Microscopy

Multiscale Modeling

Growth and Remodeling

ApoE Knockout Mice

Immunoflourescence

The role of Vitamin D metabolic enzymes in bone development and repair /

Naja, Roy Pascal.

January 2008

The CYP27B1 enzyme that synthesizes 1alpha,25-(OH) 2D, is expressed in chondrocytes, suggesting that local production of 1alpha,25-(OH)2D could play an autocrine or paracrine role in the differentiation of these cells. To test this hypothesis, we have engineered mutant mice that do not express the Cyp27b1 gene in chondrocytes. This led to increased width of the hypertrophic zone of the growth plate at E15.5, increased bone mass in neonatal long bones, and increased expression of the chondrocytic differentiation markers Indian Hedgehog and PTH/PTHrP receptor. VEGF mRNA levels were decreased, accompanied by decreased PECAM-1 immunostaining, suggesting a delay in vascularization. We have also engineered mice overexpressing a Cyp27b1 transgene in chondrocytes. The transgenic mice showed a partial mirror image phenotype compared to the tissue-specific inactivation model. These results support an autocrine/paracrine role of 1alpha,25-(OH) 2D in endochondral ossification and chondrocyte development in vivo. / The CYP24A1 enzyme is involved in the catabolic breakdown of 1alpha,25-(OH)2D but also synthesizes the 24R,25-(OH) 2D metabolite. Studies in chicken suggest a role for 24R,25-(OH) 2D in fracture repair. We induced stabilized transverse mid-diaphysial fractures of the tibia in four-month-old wild-type and Cyp24a1-deficient mice. Examination of the callus sections showed delayed hard callus formation in the homozygous mutant animals compared to wild-type littermates. RT-qPCR showed perturbed levels of type X collagen transcripts in mutant mice at 14 and 21 days post-fracture, reflecting the delayed healing. Rescue of the impaired healing by subcutaneous injection of 24R,25-(OH)2D3 normalized the histological appearance of the callus, static histomorphometric index and type X collagen mRNA expression, while 1alpha,25-(OH)2D 3 did not. These results show that Cyp24a1 deficiency delays fracture repair and strongly suggest that vitamin D metabolites hydroxylated at position 24, such as 24R,25-(OH)2D, play an important role in the mechanisms leading to normal fracture healing.

Bone and Bones -- physiology.

Receptors, Calcitriol -- metabolism.

Mice, Knockout.

Mice.

Examination of the Role of Dopamine D3 Receptors in Behavioural Sensitization to Ethanol

Harrison, Sarah Jane

31 July 2008

Dopamine D3 receptors (D3Rs) have been implicated in mediating behavioural sensitization to various drugs of abuse, but their role in ethanol (EtOH) sensitization has not been directly examined. Neil Richtand proposed a role for D3Rs in the modulation of sensitization by acting as an inhibitor of D1/D2 receptor-mediated behaviours, and several reports suggest D3Rs up-regulate in response to chronic drugs of abuse. In separate experiments, we examined EtOH sensitization in D3R knockout (KO) as well as in D1R and D2R KO mice. We also examined amphetamine sensitization in D3R KOs compared to wild type mice. We challenged C57Bl/6 and DBA/2 mice with a D3R agonist (PD128907) and antagonist (U99194A) to examine how acute and chronic D3R activation and inactivation may affect the induction and expression of EtOH sensitization. We investigated D1/D3R interactions in sensitized and control mice and examined whether EtOH sensitization leads to changes in D3R binding using [125I]-7-OH-PIPAT autoradiography. Results showed that D3R KOs, were resistant to EtOH but not to amphetamine sensitization. Chronic but not acute D3R blockade with U99194A inhibited the induction, whereas acute D3R activation with PD128907 attenuated the expression of EtOH sensitization. In our D1/D3R interaction study we observed that although PD128907 attenuated D1 agonist-induced hyperactivity with SKF81297, this effect was the same in sensitized and control animals, even though sensitized mice were more responsive to PD128907 than controls. This enhanced response, which suggests a functional up-regulation of D3Rs, was not accompanied by changes in D3R binding as indicated by autoradiography, and could mean that functional changes in the D3R associated with EtOH sensitization occur elsewhere than at the level of the membrane-bound receptor. Taken together, these results suggest a modulatory role for the D3R in EtOH but not amphetamine sensitization, where D3R activation attenuates the expression and D3R blockade prevents the induction of EtOH sensitization. These results are important because a better understanding of the role of the D3R in EtOH sensitization may help not only to identify some of the underlying neural mechanisms of sensitization, but also help in the identification of treatment strategies for patients that may be susceptible to alcohol abuse.

Behavioural Neuroscience

Neuropharmacology

Dopamine D3 Receptors

Behavioural Sensitization

Ethanol

Dopamine Receptor Knockout Mice

0317

Examination of the Role of Dopamine D3 Receptors in Behavioural Sensitization to Ethanol

Harrison, Sarah Jane

31 July 2008

Dopamine D3 receptors (D3Rs) have been implicated in mediating behavioural sensitization to various drugs of abuse, but their role in ethanol (EtOH) sensitization has not been directly examined. Neil Richtand proposed a role for D3Rs in the modulation of sensitization by acting as an inhibitor of D1/D2 receptor-mediated behaviours, and several reports suggest D3Rs up-regulate in response to chronic drugs of abuse. In separate experiments, we examined EtOH sensitization in D3R knockout (KO) as well as in D1R and D2R KO mice. We also examined amphetamine sensitization in D3R KOs compared to wild type mice. We challenged C57Bl/6 and DBA/2 mice with a D3R agonist (PD128907) and antagonist (U99194A) to examine how acute and chronic D3R activation and inactivation may affect the induction and expression of EtOH sensitization. We investigated D1/D3R interactions in sensitized and control mice and examined whether EtOH sensitization leads to changes in D3R binding using [125I]-7-OH-PIPAT autoradiography. Results showed that D3R KOs, were resistant to EtOH but not to amphetamine sensitization. Chronic but not acute D3R blockade with U99194A inhibited the induction, whereas acute D3R activation with PD128907 attenuated the expression of EtOH sensitization. In our D1/D3R interaction study we observed that although PD128907 attenuated D1 agonist-induced hyperactivity with SKF81297, this effect was the same in sensitized and control animals, even though sensitized mice were more responsive to PD128907 than controls. This enhanced response, which suggests a functional up-regulation of D3Rs, was not accompanied by changes in D3R binding as indicated by autoradiography, and could mean that functional changes in the D3R associated with EtOH sensitization occur elsewhere than at the level of the membrane-bound receptor. Taken together, these results suggest a modulatory role for the D3R in EtOH but not amphetamine sensitization, where D3R activation attenuates the expression and D3R blockade prevents the induction of EtOH sensitization. These results are important because a better understanding of the role of the D3R in EtOH sensitization may help not only to identify some of the underlying neural mechanisms of sensitization, but also help in the identification of treatment strategies for patients that may be susceptible to alcohol abuse.

Behavioural Neuroscience

Neuropharmacology

Dopamine D3 Receptors

Behavioural Sensitization

Ethanol

Dopamine Receptor Knockout Mice

0317