Die Bedeutung der extrazellulären Matrix und sezernierter Signalmoleküle für die axonale Wegfindung in Drosophila melanogaster

Hillebrand, Jens.

Unknown Date

Universiẗat, Diss., 2004--Münster (Westfalen).

Axon Death Pathways Converge on Axed to Promote Axon Disassembly

Burdett, Thomas C.

31 March 2017

Axons use a conserved program to actively drive their own destruction after injury. Axon degeneration is present in many neurological disorders and an axon death program could be a major pharmaceutical target to preserve neuronal function. This intrinsic signaling cascade activates pro-degenerative dSarm/Sarm1, rapidly depletes axonal stores of NAD+, and terminates in cytoskeletal breakdown. Conversely, loss of dSarm/Sarm1, maintenance of NAD+ levels or its biosynthetic enzyme Nmnat, result in long-term morphological perseveration of severed axons. Exactly how dSarm/Sarm1 and loss of NAD+ execute axon death remains poorly defined. We sought to uncover novel regulators of axon death and maintenance by performing a deficiency screen and a forward genetic mutagenesis screen in axotomized Drosophila wing sensory neurons. We identified a BTB domain protein enriched in neurons, we named Axundead (Axed), which is specifically required for axon death. Severed axons harboring loss of function mutations in axed, similar to dSarm mutants, remain preserved for 50 days post axotomy. Spontaneous neurodegeneration induced by activated dSarm or dNmnat depletion are both suppressed in axed mutants, but not in dSarm mutant alleles. Additionally, severed axed mutant axons also expressing activated dSarm or lacking Nmnat are preserved. These results indicate that dSarm acts upstream of dNmnat loss, and both events precede essential Axed function and axon destruction. Thus, the axon death pathway converges on Axed function.

Axon Degeneration

Molecular and Cellular Neuroscience

Effects of levetiracetam on axon excitability and synaptic transmission at the crayfish neuromuscular junction

Alshuaib, Shaikhah

09 August 2019

Levetiracetam (LEV) is an antiepileptic drug (AED) that has been shown to mainly enhance synaptic depression and modulate certain voltage and ligand-gated channels, after it gains entry into neurons through endocytosis. Since synaptic terminals and distal axons are the first compartments exposed to LEV, we utilized a crayfish motor axon preparation to investigate whether LEV modulates axonal excitability. Two electrode current clamp from the inhibitor axon of the crayfish opener showed that LEV reduced action potential amplitude (APamp) and enhanced synaptic depression, although these events did not occur at the same time, the latter occurred later than the reduction in APamp. Further examinations of these effects and comparison of antidromic and orthodromic conducting action potentials in LEV suggests that this drug preferentially reduces excitability of the proximal axon despite the expectation that it enters the axon at terminals and reaches distal branches first. Results presented here demonstrate that LEV modulates axonal excitability, which may also contribute to its antiepileptic effects.

Biology

Axon excitability

Epilepsy

Levetiracetam

Anatomical Refinement in the Projection from the Anteroventral Cochlear Nucleus to the Lateral Superior Olive

Molot-Toker, Samuel

20 November 2015

In mammals, the basic computations required for azimuthal sound localization are performed by a group of auditory brainstem nuclei known as the superior olivary complex (SOC). The lateral superior olive (LSO), in the SOC, aids in sound localization by computing intensity differences between sounds arriving at the two ears. It does this by comparing excitatory input from the ipsilateral anteroventral cochlear nucleus (AVCN) with inhibitory input from the ipsilateral medial nucleus of the trapezoid body (MNTB), which is driven by the contralateral AVCN. In order for sounds to be accurately localized, the AVCN-LSO and MNTB-LSO projections must be aligned with each other in a frequency-dependent manner. Rough alignment occurs over the course of development, but a significant amount of circuit refinement is required to achieve adult-like precision. Two types of refinement occur in these pathways: 1) physiological, or functional refinement; and 2) anatomical refinement. Little is known about the latter type of refinement in the AVCN-LSO pathway. In order to study this, I conducted a variety of experiments all aimed at anterogradely labeling a small number of cells projecting from the AVCN to the LSO in juvenile rats. I experimented with several approaches in order to develop the technique of ex vivo, sparse axon labeling in this area of the brain. I show the optimal technique developed after testing various tracers, application methods, and incubation times, among others. This optimized technique can now be used in a future experiment that will uncover and describe anatomical refinement in the AVCN-LSO pathway of the auditory brainstem. / Thesis / Master of Science (MSc)

Auditory

Brainstem

Development

Axon tracing

Gliogenesis and axon pathway formation in Drosophila

Fredieu, John Randal

January 1991

No description available.

Role of transcription factor Pax6 in the development of the thalamocortical tract

Clegg, James Matthew

January 2013

During development the nuclei of the thalamus form reciprocal connections with specific regions within the cortex. These connections give rise to the thalamocortical tract. The processes by which axons of the thalamocortical tract are guided to their target regions are poorly understood. It has been shown that diffusible or membrane bound factors can have a chemoattractive or chemorepulsive effect on the tip or growth cone of the axon. Thalamocortical axons may also be guided along ‘pioneer’ axon populations that form a scaffold along which axons may grow. The transcription factor Pax6 has been shown to have a role in a variety of developmental processes such as neuronal patterning, proliferation, migration and axon guidance. It is known that Pax6 is involved in the development of the thalamocortical tract but its exact role is unknown. To explore the role that Pax6 plays in the development of the thalamocortical tract I have used two different mouse models, the small eye (Pax6Sey/Sey) mouse which lacks functional Pax6, and a conditional Pax6 knock-out (Pax6cKO) mouse made using a Gsh2 Cre line that specifically reduces Pax6 expression in the ventral telencephalon and prethalamus. Using the Pax6Sey/Sey mouse I show that thalamocortical axons do not enter the ventral telencephalon in the absence of Pax6 and that a small number of axons incorrectly enter the hypothalamus. In addition axons found within the ventral telencephalon of the mutant do not originate from the thalamus but instead originate from cells within the ventral telencephalon itself. I have found that the expression of guidance molecule Robo2 is reduced in the Pax6Sey/Sey mouse, which may explain why thalamocortical axons enter the hypothalamus. When Pax6 expression is reduced at the prethalamus and ventral telencephalon using the Pax6cKO mouse I show that the majority of thalamocortical axons reach the cortex normally but some axons become disorganized within the thalamus. Pioneer axons which emanate from the prethalamus normally guide thalamocortical axons through the diencephalon but in the Pax6cKO I report that these axons are reduced which may explain the disorganization of thalamocortical axons within the thalamus. Taken together the data from these two models demonstrate that for the thalamocortical tract to form normally Pax6 expression is required in both the cells of the thalamus and in cells that lie along the route of the tract. In addition I provide evidence that Pax6 may influence axon guidance by controlling the expression of guidance molecules and the development of pioneer axon tracts.

612.8

Specific sulphation modifications of heparan sulphate regulate distinct aspects of axon guidance in the developing mouse central nervous system

Conway, Christopher

January 2009

Development of the visual system involves the precise orchestration of neural connections between the retina of the eye, the thalamus (dorsal lateral geniculate nucleus; dLGN) and the superior colliculus (SC). During early development, receptor molecules on the growth cones of retinal ganglion cell (RGC) axons sense molecular guidance cues in the extra cellular matrix (ECM) that define their route and branching behaviour within the visual system. Heparan sulphate proteoglycans (HSPGs) are ECM molecules composed of a core protein and a variable number of disaccharide residues that have been implicated in mediating axon guidance. HSPGs are modified by a number of enzymes that contribute to their structural diversity. Based on this structural diversity; the “heparan sulphate code” hypothesis of Bulow and Hobert (2004) postulated that different HSPG modifications confer different axon navigation responses as the growth cones traverse the local environment. To investigate the roles played by specific modifications of HSPG molecules in the guidance of axons, we examined two lines of mutant mice harbouring mutations in the genes encoding HSPG modifying enzymes, Heparan sulphate-6-O-sulphotransferase-1 (Hs6st1) and Heparan sulphate-2-O-sulphotransferase (Hs2st). These two mutant lines were generated through the use of gene trapping. Previous observations of RGC axon development in the two mutant lines revealed distinct axon guidance errors at the optic chiasm. Loss of Hs6st1 sulphation resulted in RGC axons navigating ectopically into the contralateral eye. Loss of Hs2st sulphation resulted in RGC axons navigating outside the normal boundary of the optic chiasm. Early observations suggested that both Hs2st sulphation and Hs6st1 sulphation have distinct, non-overlapping actions and thus, influence different axon guidance signalling pathways at the optic chiasm. Based on our findings and previous work describing the expression patterns and functions of the chemo-repellent axon guidance molecules, Slit1 and Slit2 at the optic chiasm and their Robo2 in the retina, we formulated the hypothesis of an HSPG sulphation code where Hs2st sulphation is specifically required for Slit1-Robo2 signalling and Hs6st1 sulphation is specifically required for Slit2-Robo2 signalling at the optic chiasm. To further our understanding of the roles Hs2st sulphation and Hs6st1 sulphation have on axon guidance, we looked at a number of key choice points that navigating axons encounter and are known to be influenced by Slit signalling. Further observations of RGC axons at the optic chiasm of Hs2st-/- mutants and Hs6st1-/- mutants showed distinct axon guidance phenotypes, both resulting in statistically significant increases in the width of the optic chiasm at the midline. While Hs6st1 sulphation had no effect on RGC axon navigation within the eye (possibly due to 6-O-sulphation compensation by Hs6st3); the loss of Hs6st1 sulphation at the dLGN resulted in a significant increase in the defasciculation of the optic tract. Observations of other axonal tracts influenced by Slit signalling revealed the importance of Hs2st and Hs6st1 sulphation in aiding callosal axons to successfully traverse the midline in corpus callosum development. Observations of the thalamocortical (TCA)/corticothalamic (CTA) tracts revealed that neither Hs2st sulphation nor Hs6st1 sulphation was required for the development of the mouse TCA tract (the latter may be explained by 6-O-sulphation compensation by Hs6st2). To test whether Hs2st and Hs6st1 enzymes have redundant functions in optic chiasm development, we attempted to create Hs2st-/-/Hs6st1-/- double mutants. A PCR genotyping strategy was developed for the identification of Hs6st1 animals and showed that Hs6st1-/- mutants had high postnatal lethality with only 3% of the offspring surviving to weaning while Hs2st-/-/Hs6st1-/- double mutants all died very early during embryonic development. Observations of Hs2st-/-/Hs6st1+/- mutants and Hs2st+/-/Hs6st1-/- mutants that lacked three of the four Hst alleles showed no differences when compared to single Hst knockouts. Finally, we showed that altered Slit expression at the optic chiasm and Robo expression in the retina could not explain the mutant phenotypes observed in Hs2st-/- mutants and Hs6st1-/- mutants, and therefore we hypothesized that Hs2st sulphation and Hs6st1 sulphation regulate distinct aspects of Slit-Robo signalling at the surface of the navigating axon growth cone.

612.8

Co-factors of LIM-HD transcription factors in neural development and axon pathfinding in zebrafish

Zhong, Zhen

January 2012

The zebrafish neuromuscular system is an elegant model to study neural development. To reveal a specific programme for zebrafish motor axon pathfinding I established a method to selectively block motor axon pathfinding by interfering with LIM domain transcription factor signaling. LIM homeodomain proteins (LIM-HDs) are an important class of transcriptional regulators and involved in neural development as well as neuron fate decision in vertebrates. DD domain dimerization of CLIM (cofactor of LIM-HDs) can activate LIM-HDs and downstream gene transcription while over-expression of dominant-negative CLIM (DN-CLIM), which lacks the DD domain, blocks LIM-HD activity. Motor neurons fluoresce in HB9:GFP transgenic zebrafish as the promoter of the motor neuron specific gene Hb9 drives expression of GFP. Motor axons in DN-CLIM injected HB9:GFP zebrafish are unable to exit the spinal cord, instead they grow inside the spinal cord. Thus axon pathfinding, but not general growth appears to be impaired in these neurons. This provides an excellent research model to find genes involved in motor axon pathfinding downstream of LIM-HDs. Gene array expression profiling was carried out on GFP+ motor neurons by fluorescence-activated flow sorting (FACS) with and without prior injection of DN-CLIM mRNA to elucidate the potential genes relevant to motor axon pathfinding. Genes that were most strongly down-regulated in DN-CLIM injected embryos were considered to belong to a motor axon specific guidance programme. Calca, tac-1 and chodl genes, retrieved from the gene array data, showed specific expression pattern in motor neuron and obvious down-regulation after DN-CLIM injection by in situ hybridization. This validated the array results. Chodl contains a C-type lectin domain representing a potential cell surface receptor for guidance factors. Gene knock-down experiments with two independent morpholinos led to stalling of CaP motor axons at the horizontal myoseptum, a pivotal choice point for axon pathfinding. This suggests that this novel gene specifically affects motor axon pathfinding in zebrafish. Single stranded DNA binding protein 1 (SSDP1) functions as an activator of SSDP1/CLIM/LIM-HD complex which involved in the transcriptional control of embryonic development. To verify how SSDP1 function in neural development in zebrafish, I have cloned Zebrafish SSDP1a and SSDP1b, which are most closely related to mouse and human SSDP1. SSDP1a is widely expressed during zebrafish development while SSDP1b is specifically expressed in sensory trigeminal and Rohon-Beard neurons. Over-expression of the N-terminal portion of SSDP1 (N-SSDP1) increases endogenous CLIM protein levels in vivo and impairs the formation of eyes and midbrain-hindbrain boundary. In addition, SSDP1b knock down impairs trigeminal and Rohon-Beard sensory axon growth. N-SSDP1 can partially rescue the inhibition of axon growth induced by DN-CLIM. These results reveal specific functions of SSDP1 in neural patterning and sensory axon growth which are in part due to the stabilization of LIM-HD/CLIM complexes. In summary, co-factors of LIM-HDs play important roles in neural development, cell fate specification as well as axon pathfinding.

LIM-HD ; axon pathfinding ; chodl ; SSDP

Mechanisms of Sirtuin-2 (SIRT2) enhancement of mitochondrial function and axon regeneration in control and diabetic adult sensory neurons

Schartner, Emily

20 September 2016

Rationale and hypothesis: Diabetic sensory neuropathy involves a distal dying-back of nerve fibers. Neuronal mitochondrial function is impaired in diabetes and Sirtuin 2 (SIRT2) is a sensor of redox state that regulates cellular bioenergetics. The role of SIRT2 in regulating the phenotype of adult sensory neurons derived from both control and diabetic rats or wild type and SIRT2 knockout (KO) mice was studied. It was hypothesized that sensory neurons under a hyperglycemic state would have a lowered NAD+/NADH ratio thus deactivating the SIRT2 pathway. It was further hypothesized that the down regulation of SIRT2 would diminish the activity of the AMP-activated protein kinase (AMPK) pathway resulting in mitochondrial dysfunction. This defect would contribute to distal dying-back of axons observed in diabetes. Methodology: Type 1 diabetes was induced in rodents by streptozotocin (STZ). Adult sensory neurons derived from control or STZ-diabetic rats or control and SIRT2 knockout (KO) mice were cultured in defined media with varying doses of neurotrophic factors and D-glucose. Protein levels were determined by quantitative Western blotting and neurite outgrowth quantified by immunocytochemistry. Plasmid transfection was initiated for overexpression of SIRT2 constructs and Seahorse XF24 analyzer was utilized to measure mitochondrial function of cultured neurons. Results: Overexpression of SIRT2 elevated total neurite outgrowth in cultures derived from control and STZ-diabetic rats. Cultures derived from SIRT2 KO mice exhibited diminished neurite outgrowth. The AMPK pathway was inhibited under high glucose treatment through activation of the polyol pathway. Pharmacological inhibition of the polyol pathway improved mitochondrial bioenergetics and neurite outgrowth in sensory neurons. Augmented expression of electron transport proteins and increased mitochondrial mass was associated with enhanced bioenergetic function. Conclusion: SIRT2 is a key component driving mitochondrial function and axon regeneration through the activation of AMPK pathway. In diabetes this pathway is suppressed via elevated polyol pathway activity. / October 2016

SIRT2

Mitochondria

Diabetic Neuropathy

Axon regeneration

Charakterisierung der Rolle des β-Aktin mRNA bindenden Proteins heterogenous nuclear ribonucleoprotein-R für das Axonenwachstum von Motoneuronen / Characterisation of the role of the β-Aktin mRNA binding protein heterogenous nuclear ribonucleoprotein-R for the axonal growth of motoneurons

Glinka, Michael

January 2011

Bei Yeast Two-Hybrid Untersuchungen wurde in unserer Arbeitsgruppe das RNA-Bindungsprotein hnRNP-R als Interaktionspartner von SMN gefunden und es konnte gezeigt werden, dass hnRNP-R mit SMN in Axonen von primären Motoneuronen kolokalisiert (Rossoll et al., 2002). hnRNP-R assoziiert mit der β-Aktin mRNA und nach Überexpression kommt es zu einer Akkumulation von β-Aktin in den Wachstumskegeln von neuronalen Zellen, sowie zu verstärktem Neuritenwachstum bei PC12 Zellen. Wird die SMN-Bindungsdomäne von hnRNP-R deletiert, ist dieser Effekt stark reduziert (Rossoll et al., 2003). Auf diesen in vitro Befunden ist die Hypothese begründet, dass hnRNP-R an der Translokation der β-Aktin mRNA in die Wachstumskegel von neuronalen Zellen beteiligt ist. Deshalb wurde im Rahmen dieser Arbeit die Rolle von hnRNP-R bei der Entwicklung in Neuronen des Nervensystems näher untersucht. Dazu wurden Zebrafisch Embryonen als in vivo Modellsystem für Morpholino vermittelte Knockdown Untersuchungen gewählt. Zunächst wurde ein gegen murines Protein hergestelltes hnRNP-R Antiserum charakterisiert und gezeigt, dass es das Zebrafisch Protein spezifisch erkennt. Dieses Antiserum wurde in Western Blot Analysen verwendet um den hnRNP-R Knockdown in Zebrafisch Embryonen zu verifizieren. Bei den hnRNP-R Morpholino injizierten Embryonen konnten dosisabhängig axonale Veränderungen beobachtet werden. Diese Veränderungen stimmen mit einem Krankheitsmodell für SMA im Zebrafisch überein. Es konnte gezeigt werden, dass das Überleben primärer Motoneurone in Zebrafisch Embryonen nicht beeinträchtigt ist und dass andere neuronale Zellen keine signifikante Beeinflussung durch einen hnRNP-R Knockdown erfahren. Um die Spezifität des axonalen Phänotyps, der durch hnRNP-R Knockdown hervorgerufen wurde zu belegen, wurde mit muriner hnRNP-R mRNA ein Rescue-Experiment durchgeführt. Es konnte gezeigt werden, dass dabei der axonale Phänotyp weitestgehend wieder aufgehoben wurde. Parallel zu den Zebrafisch Experimenten wurde ein hnRNP-R Knockout Konstrukt mittels homologer Rekombination in Escherichia coli hergestellt und in murine embryonale Stammzellen elektroporiert. Die Charakterisierung einer hnRNP-R Knockout Maus könnte weitere bedeutende Einsichten in die in vivo Funktionen von hnRNP-R bei der Embryonalentwicklung und speziell der Entwicklung von Motoneuronen gewähren. Um der Frage nach zu gehen, welche mRNAs in Wachstumskegeln von Axonen primärer Maus Motoneuronen zu finden sind oder durch Transportprozesse lokal akkumuliert sind,wurden Versuche unternommen, um mittels Laser-Mikrodissektion einzelne Wachstumskegel von Motoneuronen für Untersuchungen der enthaltenen mRNAs zu gewinnen. Erstmalig ist es im Rahmen dieser Arbeit gelungen, kompartimentalisierte Kulturen von primären Motoneuronen der Maus zu etablieren. Damit wurde die Grundlage geschaffen, um RNA-Profile von distalen Zellkompartimenten wie den Axonen und Wachstumskegeln zu bestimmen. / In previous yeast two-hybrid studies, we have shown that hnRNP-R is an interaction partner of SMN and that it co-localises with SMN in axons of primary motor neurons (Rossoll et al., 2002). hnRNP-R associates with the β-actin mRNA and after overexpression, an accumulation of β-actin in growth cones of neuronal cells and elongated neurite growth of pc12 cells could be observed. If the SMN binding domain of hnRNP-R was deleted, this effect was strongly reduced (Rossoll et al., 2003). On this in vitro observations the hypothesis is based, that hnRNP-R plays an important role in the translocation of β-actin mRNA to the growth cones of neuronal cells. For that reason, the role of hnRNP-R in the development of neuronal cells of the nervous system was investigated in more detail, in line with this thesis. We have chosen embryonic zebrafish as an in vivo model system for morpholino mediated knockdown analysis of hnRNP-R. First of all an antiserum that has been generated against murine hnRNP-R protein was characterised and it could be shown that it specifically recognises the zebrafish protein. This antiserum was used in western blot analysis to verify the hnRNP-R knockdown in embryonic Zebrafish. Dose dependent axonal phenotypes could be described in hnRNP-R morpholino injected embryos, that resembled the alterations, observed in a disease model for SMA in zebrafish. We could show that the survival of motor neurons in zebrafish embryos was not impaired and that other populations of neuronal cells, were not significantly affected by the hnRNP-R knockdown. To prove the specificity of the axonal phenotype after hnRNP-R knockdown, a rescue experiment with co-injected mouse hnRNP-R mRNA has been performed, that nearly abolished the axonal phenotype. In parallel to the zebrafish experiments an hnRNP-R knockout construct was made by homologues recombination in Escherichia coli. This construct has been electroporated into embryonic stem cells of mice, and obtained clones have been screened. The characterisation of an hnRNP-R knockout mouse could reveal important insights of in vivo functions of hnRNP-R in embryonic development and especially the development of motor neurons. To answer the question, which mRNAs are located in growth cones of primary mouse motor neurons, or are locally accumulated due to mRNA transport processes, growth cones of primary mouse motor neurons have been cut by laser micro dissection. For the first time, compartmentalised cell cultures of primary motor neurons could be established during this thesis, providing the background to generate detailed RNA profiles of distal cell compartments like axons and growth cones.

Heterogene Ribonucleoproteine

Actin

Motoneuron

Axon

ddc:570