Refine
Year of publication
Document Type
- Doctoral Thesis (37)
Has Fulltext
- yes (37)
Is part of the Bibliography
- no (37)
Keywords
- Autism Spectrum Disorder (1)
- CNV 16p11.2 (1)
- Cardiac regeneration (1)
- Cerebral cortex (1)
- Connectomics (1)
- Coronaries (1)
- Development (1)
- EphrinB2 (1)
- Excitatory balance (1)
- Extracellular matrix (1)
Institute
Mitochondrial membrane dynamics is increasingly implicated in various human diseases. Numerous studies show that the protein OPA1 plays a central role in determining mitochondrial ultrastructure and apoptotic remodeling of the inner mitochondrial membrane during Cytochrome c release and apoptosis. Crista junctions are crucial for the regulation of apoptotic Cytochrome c release. Previous publications suggest that OPA1 is required to maintain a normal structure of the inner mitochondrial membrane. The protein MIC60 (Mitofilin) appears to be an essential physical constituent of crista junctions and is also crucial for the general determination of mitochondrial ultrastructure. Furthermore, recent studies suggest that MIC60 is also implicated in Cytochrome c release during apoptosis.
In this regard, the question whether OPA1 is essential for crista junction formation was investigated. In addition to that, the interplay between OPA1 and MIC60 and its physiological role were analyzed. Electron microscopy of OPA1+/- and OPA1+/+ mice, as well as of OPA1-/- and OPA1+/+ MEFs clearly showed that OPA1 plays a role but is not essential for crista junction formation. In contrast to that, the results indicate that OPA1 is crucial to maintain a normal structure of the inner mitochondrial membrane. Immunogold experiments fit well to these observations as OPA1 was found equally distributed throughout the cristae membrane with only a minor part located at crista junctions. MIC60 localization studies showed a clear enrichment at crista junctions. Interaction studies revealed that endogenous OPA1 and MIC60 physically interact with each other. Analysis of protein levels upon OPA1 or MIC60 depletion indicate that both proteins play a dual role in cristae- and crista junction formation in which MIC60 is a physical constituent of crista junctions essential for their formation while OPA1 primarily has a regulatory impact on MIC60 function. Finally, apoptosis assays and cell viability measurements showed that knockout of OPA1 in MEFs leads to increased cellular resistance suggesting that the interplay of these proteins is important for the regulation of crista junction remodeling during apoptosis.
Besides its role in determining mitochondrial ultrastructure, OPA1 mediates inner membrane fusion of mitochondria thereby contributing to mitochondrial quality control. Additionally, proteolytic processing is crucial for the ability of OPA1 to distinguish between functional and dysfunctional mitochondria. Functional mitochondria are fused while dysfunctional mitochondria are not, a process termed selective mitochondrial fusion. Dysfunctional mitochondria were shown to be degraded by mitophagy in a fission-dependent manner. Numerous studies suggest that OPA1 and mitophagy are directly linked. However, this idea is still under debate. Mitophagy is also crucial for mitochondrial quality control, which directly impacts mitochondrial integrity. Furthermore, mitochondrial quality control has been linked to neurodegeneration as demonstrated by the observation that mutations in OPA1 cause the disorder ADOA-1.
In order to analyze a potential link between OPA1 and mitophagy, mitochondrial colocalization with LC3 was analyzed microscopically in primary adult skin fibroblasts isolated from OPA1+/- and OPA1+/+ mice in an age-dependent manner. Fibroblasts from young OPA1+/- mice showed increased colocalization of mitochondria with autophagosomes compared to fibroblasts from young wild type mice suggesting that OPA1 exerts an inhibitory role in mitophagy. This effect was even more pronounced in old mice, which also displayed higher mitophagy levels in general than young mice, consistent with the finding that old mice had higher Parkin levels than young mice. Mitochondrial fragmentation was elevated in fibroblasts from young and old OPA1+/- mice compared to control fibroblasts. However, extensive mitochondrial fusion, which occurred in fibroblasts from old wild type mice, was prevented in old OPA1+/- mice. Furthermore, old wild type mice had decreased numbers of crista junctions compared to young wild type mice, an effect that was not observed in OPA1+/- mice. Despite the observed age-dependent phenotypes in mitochondrial quality control and mitochondrial integrity, deletion of one allele of OPA1 had no influence on the life span in vivo. Analysis of the OPA1-dependent proteome of aging mice, which was performed in collaboration with Ansgar Poetsch and Carina Ramallo-Guevara from Bochum, showed that OPA1-dependent aging is accompanied by a reduction of proteins involved in autophagy. In contrast to that, a switch from glucose to fatty acid metabolism and alterations in apoptotic proteins were observed in both OPA1+/- and OPA1+/+ mice in an age-dependent manner indicating that the changes in proteins implicated in autophagy could be a compensatory response to the diminished inhibitory effect of OPA1 on mitophagy. On the other hand, increased mitochondrial degradation by mitophagy could be a cellular response to itself compensating for the loss of OPA1 mediated fusion thereby contributing to the observation that OPA1+/- and OPA1+/+ mice had no differences in life span. Furthermore, analysis of the OPA1-dependent proteome of aging mice revealed that OPA1, besides its role in mitochondrial fusion, could interact with the fission machinery: MFF and Neuronal pentraxin 1, two proteins involved in mitochondrial fission, were up-regulated in 12-month-old OPA1+/- mice suggesting that a reduced fission activity could contribute to mitochondrial hyperfusion in aged wild- type mice. Nonetheless, the exact nature of the possible interplays between OPA1 and these candidates remains to be investigated.
My PhD work employed genetic and pharmacological manipulations, coupled with highresolution live imaging, to understand intercellular communications during zebrafish cardiovascular development. The heart is the first organ to form, and it is composed of several tissues, among which interactions are crucial. I identified two important interactions between muscular and non-muscular tissues in poorly characterized contexts, and the molecules required for the signalling. First, I discovered an important cellular and molecular crosstalk orchestrating the development of the cardiac outflow tract (i.e., the aortic root in mammals).
Endothelial-derived TGF-beta signalling controls the generation of the local extracellular matrix (ECM). The ECM in turn affects endothelial proliferation as well as smooth muscle cell organization (Boezio et al, 2020; Bensimon-Brito*, Boezio* et al, 2020). In my second project, I investigated the crosstalk between the epicardial layer and the myocardial wall. By generating epicardial-impairment models, I identified a novel role for the epicardium in regulating cardiomyocyte volume during heart development (Boezio et al, 2021). Ultimately, this research contributed to our understanding of how paracrine signalling controls the multicellular interactions integral to organogenesis.
Cerebellar ataxias are a group of neurodegenerative disorders primarily affecting the cerebellum. Although causative mutations in several genes have been identified there is currently no cure for ataxias.
The first part of this dissertation is focused on Spinocerebellar ataxia type 2 (SCA2). SCA2 is a dominant ataxia caused by repeat expansion mutations in the ATXN2 gene, which encodes the protein Ataxin2 (ATXN2). A polyglutamine (polyQ) tract consisting of CAG repeats interrupted by CAA was identified at exon 1 of ATXN2. Healthy individuals have between 22 and 23 glutamines, while expansions longer than 33 CAG repeats cause SCA2. The most noticeable symptom that SCA2 patients show is ataxic gait; however, they also show cerebellar dysarthria, dysdiadochokinesia, and ocular dysmetria caused by the progressive cerebellar degeneration.
To model the SCA2 disease, we generated a new mouse model where 100 CAG repeats were introduced in the mouse Atxn2 gene via homologous recombination. The characterization of this mouse model, Atxn2-CAG100-KIN, demonstrated that it reproduces the symptomatology observed in SCA2 patients. These animals showed significant loss of weight over time, brain atrophy, and motor deficits.
In addition, ATXN2 intermediate expansions have been linked to the pathology of Amyotrophic lateral sclerosis (ALS) as a risk factor. ALS is a fatal neurodegenerative disease where the motor neurons in the brain and spinal cord degenerate. A hallmark of ALS is the presence of TDP43-positive inclusions in neurons and glia. Further studies of post mortem spinal cord samples from SCA2 patients showed severe and widespread neurodegeneration of the central somatosensory system. Therefore, it was of interest to further investigate the pathology affection of this tissue in the Atxn2-CAG100-KIN line and the relationship between ATXN2 and TDP43. The characterization of the spinal cord pathology via protein quantification, transcript quantification, and immunohistochemistry showed a preferential affection of RNA binding proteins (RBP) in the spinal cord rather than the cerebellum. The ALS-linked factors TDP43 and TIA1 showed time-dependent co-aggregation with ATXN2 in spinal cord sections together with an increase of CASP3 levels. Therefore, this mouse model can help develop new therapies and evaluate their effect in differently affected areas.
A transcriptome data set from Atxn2-CAG100-KIN spinal cord samples at the final disease stage of this mouse model showed a strong up-regulation of RNA toxicity-, immune- and lysosome-implicated factors. These data pointed to a pathological reactivation of the synaptic pruning and phagocytosis in microglia. ATXN2-positive aggregates were found in microglia from spinal cord sections of 14-month-old Atxn2-CAG100-KIN via immunohistochemistry. The characterization of microglial response and the potentially deleterious effects of the expanded ATXN2 in this cell type could lead to therapies to improve patients’ living standards or delay the symptoms’ onset.
The second part of this thesis was focused on an autosomal recessive form of cerebellar ataxia, Ataxia Telangiectasia (A-T), with childhood onset. A-T patients show severe cerebellar atrophy manifesting as ataxia when the child starts to walk. The genetic cause of A-T is loss-of-function-mutations in the Ataxia Telangiectasia Mutated gene (ATM). ATM is a kinase involved in DNA damage response, oxidative stress, insulin resistance, autophagy via mTOR signaling, and synaptic function.
Working with proteome data from cerebrospinal fluid of 12 A-T patients and 12 healthy controls, we aimed to define novel biomarkers that would allow following the neurodegeneration in extracellular fluid. Additional validation efforts with ~2-month-old Atm-knock-out (Atm-/-) cerebellar samples helped us to define a scenario were the deficit of vesicle-associated ATM alters the secretion of ApoB, reelin, and glutamate. As extracellular factors, apolipoproteins and their cargo such as vitamin E may be useful for neuroprotective interventions.
Even one century after Santiago Ramón y Cajal’s groundbreaking contribu- tions to neuroscience, one of the most fundamental questions in the field is still largely open, namely understanding how the shape of a dendrite is adapted to its specific biological function. A systematic investigation of this problem is challenging both technically and conceptually because neurons have diverse genetic, molecular, morphological, connectional and functional properties.
In the light of the preceding, dendritic arborisation (da) neurons of the Drosophila melanogaster larva PNS have proven to be an excellent model system for the study of such growth and patterning processes. Structure and function in these cell classes are intimately intertwined, as class type-specific dendritic arbour differentiation processes are required to satisfy a given phys- iological need. Also, there is a remarkable genetic toolkit that enables one to selectively and reproducibly label, image and manipulate each one of these sensory neuron classes. In this thesis, I address the aforementioned open problem by linking single-cell patterning, information processing and wiring optimisation in sensory da neurons to behaviour in Drosophila larva.
In particular, I study Class I ventral peripherical dendritic arborisation (c1vpda) neurons. These are a class of proprioceptive neurons that relay information on the position of the larva’s body back to the CNS during crawling behaviour to assure proper locomotion. Their stereotypical comb- like shaped dendritic branches spread along the body-wall, and they get noticeably deformed during crawling behaviour. The bending of the den- dritic branches is hypothesised to be a possible mechanism to transduce the mechanosensory inputs arising from cuticle folding. Interestingly, c1vpda neurons do not necessarily satisfy optimal wiring constraints since they are required to pattern into a specific shape to fulfil their function. Therefore, I considered the da system to study how the specific functional requirements may be combined with optimal wiring constraints during development.
Although the molecular machinery of dendrite patterning in c1vpda neurons is well studied, the precise elaboration of the comb-like shaped dendrites of these cells remains elusive. Moreover, even though a lot of work has been put into the description and quantification of growth processes of the nervous system, there are still few solid and standardised models of arbour staging and patterning. Importantly, the defining parameters that determine the dendrite elaboration program that in turn is responsible for creating the final arbour morphology are still unknown. As a result, unraveling possible universal stages of dendrite elaboration shared between different model systems and cell types is challenging.
Thus, in order to understand the development of the fine regulation of branch outgrowth that leads to the observed terminal arbour morphology in the mature cell, I collected in vivo, long-term, non-invasive high temporal res- olution time-lapse recordings of dendritic trees during the differentiation process in the embryo and its maturation phase in the larva. For further analysis, I developed new algorithms that quantified the structural changes in dendrite morphology in the time-lapse videos. My approach provides a framework to analyse such developmental data, or any dataset comprising continuous morphological dynamical processes in an unbiased way. Using these newly developed methods, I examined the development of a sample of c1vpda cells and identified five stages of differentiation in these data: initial stem polarization, extension, pruning, stabilization, and isometric stretching during larval stages.
The beginning of the growth process is marked by the polarisation of the main stem. Subsequently, during the extension phase, branches emerge interstitially from the existing main stem. Later, higher-order branches sprout from pre-existing lateral branches, increasing arbour complexity. This is followed by a pruning stage where developmental intermediate dendritic branches are removed. This step leads to a spatial rearrangement of the dendritic tree. The end of the pruning step is followed by a stabilisation period where arbour morphology remains virtually unaltered in the embryo. After hatching, c1vpda dendrites experience an isometric scaling, with their branching complexity and pattern being invariant across all larval stages.
After dissecting the c1vpda dendrites spatiotemporal differentiation process, I established a link between dendritic shape and behaviour. I measured intra- cellular Ca++ activity in the dendrite branches of l1 larvae during forward locomotion, while simultaneously recording branch deformation using a dual genetic line. I reported that post-embryonic c1vpda dendrites Ca++ responses increased in freely crawling larvae. Furthermore, I showed strong correlations between Ca++ signal and deformation of the comb-like dendritic ranches during body-wall contractions.
Then, using a geometrical model, I provided evidence that the pruning stage could reorganise the dendrite morphology to maximise mechanosensory re- sponses during body wall contraction. I showed that the angle orientation of each side branch correlates with the bending curvature and thus with the me- chanical displacement of the cell membrane during locomotion. During the pruning phase, I observed a preferential reduction of less efficient branches with low bending curvature, influencing the mechanisms of dendritic sig- nal integration of c1vpda sensory neurons. I proceeded to quantify branch dynamics at single tip resolution during pruning, providing evidence that a simple random pruning mechanism is sufficient to remodel the tree structure compatible with the observed way.
I used these time-lapse data to constrain a new computational noisy growth model with random pruning based on optimal wiring principles. This model is able to generate highly realistic synthetic c1vpda morphologies. The model furthermore requires few parameters to generate highly accurate temporal development trajectories and morphologies at single-cell level. Utilising this data and model enabled me to investigate upon the hypothesis that a noisy dendrite growth and random pruning mechanism synergise to achieve den- dritic trees efficient in terms of both wiring and function. My findings show how single neurons can create functionally specialised dendrites while min- imising wiring costs, elucidating how general principles of self-organisation may be involved in the generation of these structures.
This thesis reports on the results obtained by expression photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons from Caenorhabditis elegans (C. elegans) and the characterization of the role of a single neuron, RIS, during locomotion in the adult animal.
Pharmacological activation of adenylyl cyclases through Forskolin is known to induce increased neuronal output in diverse model organisms through a protein kinase A (PKA) dependent mechanism. Nevertheless, pharmacological assays are not spatially restricted, do not allow for precise and acute activation nor to cessation of the signal. Thus, an optogenetic approach for was selected trough the expression of photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons of Caenorhabditis elegans (C. elegans). This model organism was chosen due to its transparency, ease of maintenance, fast generation cycles as well as for being an eutelic animal. Further, its genome has been fully sequenced and the connectome of the neuronal network is known, thus allowing for precise analysis of neuronal function. Furthermore, the molecular mechanisms governing neuronal functions are well conserved up to primates. Mainly two optogenetical tools were applied, bPAC and the light gated cation channel channelrhodopsin 2 (ChR2).
Behavioral assays of bPAC photostimulation in cholinergic neurons recapitulated previous work performed with the photoactivatable adenylyl cyclase from Euglena gracilis (EuPACa), in which swimming frequency and speed on solid substrate were increased. Electrophysiological recordings of body wall muscle (BWM) cells by Dr. Jana F. Liewald showed that bPAC photoactivation led to an increase in miniature postsynaptic current (mPSC) rate and, in contrast to ChR2 invoked depolarization, also amplitude. Analysis of mutants deficient in neuropeptidergic signaling (UNC- 31) via electrophysiology performed by Dr. Jana F. Liewald showed that the increase in mPSC amplitude due to bPAC photoactivation requires neuropeptide release. This was confirmed by co-expression of bPAC with the neuropeptide marker NLP-21::Venus and subsequent fluorescence analysis of release, exploiting the fact that released neuropeptides are ultimately degraded by scavenger cells (coelomocytes). These were enriched with NLP-21::Venus after bPAC photostimulation, but no fluorescence could be observed in the UNC-31 mutants.
Additional analysis of the electrophysiological data performed by myself showed no modulation of mPSC kinetics dues to neuropeptidergic release induced by bPAC. Hence, neuropeptide release and action sites were in the cholinergic neurons, the latter including cholinergic motoneurons.
Dr. Szi-chieh Yu provided electron microscopy images of high pressure frozen, bPAC or ChR2 expressing animals. These were tagged by myself for automatic analysis of ultrastructural properties of the cholinergic presynapse, also during photoactivation of both optogenetic tools. Photoactivation of both induced a reduction of synaptic vesicles, with ChR2 showing a more severe effect. In contrast to ChR2, though, bPAC also reduced the amount of dense core vesicles (DCV), the neuropeptide transporters. Additionally, long bPAC photoactivation as well as ChR2 photoactivation led to the appearance of large vesicles (LV), presumably in response to the increased SV fusion rate. bPAC photostimulation also induced an increase in SV size, not observed after ChR2 photostimulation. In UNC-31 mutants, bPAC photostimulation could not lead to the SV size increase, a further argument for the presynaptic effect of the released neuropeptide. Additional analysis of electrophysiology paired with pharmacology, performed by Dr. Jana F. Liewald, showed that mPSC amplitude increase requires the function of the vesicular acetylcholine transporter.
A further effect observed in the ultrastructure of bPAC photostimulated cholinergic presynapses was a shift in the distribution of SV regarding the dense projection. An analysis of cAMP pathway mutants showed that synapsin is required for bPAC induced behavior effects. Synapsin is known to mediate SV tethering to the cytoskeleton. Here, I show evidence for a new role of synapsin in controlling the availability of DCVs for fusion and thus, in neuropeptidergic signaling.
In the second part of my thesis I characterized the function of the GABAergic interneuron RIS in the neuronal network of C. elegans. RIS was shown to induce lethargus, a sleep-like state, during all larval molts, but its function in the adult animal was not yet described. Specific RIS expression of ChR2 achieved by a recombinase based system allowed to acutely depolarize the neuron during locomotion, which led to an acute behavioral stop. Diverse signal transduction pathway mutants were analyzed showing that the phenotype was induced by neuropeptidergic signaling. Through mutagenesis followed by whole genome sequencing data analysis as well as analysis of RIS specific RNA sequencing data further narrowed the signal transduction pathway to mediate the locomotion stop behavior. Since the neuropeptide and, to some extent, the neuron are conserved across nematodes, an argument is outlined in favor of the conservation of this sleep-like state.
In addition, since ChR2 could induce neuropeptidergic signaling from RIS, secretion of vesicles is regulated by variable pathways depending on the neuronal identity. Nevertheless, expression of bPAC in RIS allowed to optogenetically increase the probability of short stops, as observed by expression of a calcium sensor (GCaMP) in RIS and analysis of its intrinsic activity in the adult animal.
Flow hemodynamics regulates endothelial cell (EC) responses and laminar shear stress induces an atheroprotective and quiescent phenotype. The flow-responsive transcription factor KLF2 is a pivotal mediator of endothelial quiescence, but the precise mechanism is unclear. In this doctoral study, we assessed the hypothesis that laminar shear stress and KLF2 regulate endothelial quiescence by controlling endothelial metabolism.
Laminar flow exposure and KLF2 over expression in HUVECs reduced glucose uptake. Endothelial specific deletion of KLF2 (EC-KO) in mice and subsequent infusion of labeled glucose in Langendorff perfused hearts induced glucose uptake in ECs lacking KLF2. Bioenergetic measurements revealed that KLF2 reduces and glycolytic acidification in vitro.
Mechanistically, RNA sequencing analysis of shear stimulated ECs showed reduced expression of key glycolytic enzymes Hexokinase 2, PFKFB3 and PFK-1. KLF2 also reduced expression of these enzymes at protein level. KLF2 knockdown in shear stimulated ECs reversed the reduction in expression of PFKFB3 and PFK-1, indicating KLF2-dependency. Promoter analysis revealed KLF binding sites in the promoter of PFKFB3 and KLF2 over expression markedly reduced PFKFB3 promoter activity which was abolished on mutation of the KLF binding site. In addition, PFKFB3 knockdown reduced glycolysis while over expression increased glycolysis. Over expression of PFKFB3 along with KLF2 partially reversed the KLF2-mediated reduction in glycolysis. Importantly, PFKFB3 over expression reversed KLF2-mediated reduction in angiogenic sprouting and network formation in vitro. Ex-vivo aortic ring assays revealed an increase in endothelial sprouting from aortas from KLF2 EC-KO mice, which was partially reversed upon PFKFB3 inhibition by 3-PO.
In conclusion, work performed during this doctoral thesis demonstrates that laminar shear stress and KLF2 mediated repression of endothelial metabolism via regulation of PFKFB3 contributes to the anti-angiogenic and quiescent properties of the endothelium.
Ischemic heart disease caused by occlusion of coronary vessels leads to the death of downstream tissues, resulting in a fibrotic scar that cannot be resolved. In contrast to the adult mammalian heart, the adult zebrafish heart can regenerate following injury, enabling the study of the underlying cellular and molecular mechanisms. One of the earliest responses that take place after cardiac injury in adult zebrafish is coronary revascularization. Previous transcriptomic data from our lab show that vegfc, a well-known regulator of lymphatic development, is upregulated early after injury and peaks at 96 hours post cryoinjury, coinciding with the peak of coronary endothelial cell proliferation. To test the hypothesis that vegfc is involved in coronary revascularization, I examined its expression pattern and found that it is expressed by coronary endothelial cells after cardiac damage. Using a loss-of-function approach to block Vegfc signaling, I found that it is required for coronary revascularization during cardiac regeneration. Notably, blocking Vegfc signaling resulted in a significant reduction in cardiomyocyte regeneration. Using transcriptomic analysis, I identified the extracellular matrix component gene emilin2a and the chemokine gene cxcl8a as effectors of Vegfc signaling. During cardiac regeneration, cxcl8a is expressed in epicardium-derived cells, while the gene encoding its receptor cxcr1 is expressed on coronary endothelial cells. I found that overexpressing emilin2a increases coronary revascularization, and induces cxcl8a expression. Using loss-of-function approaches, I observed that both cxcl8a and cxcr1 are required for coronary revascularization after cardiac injury.
Altogether, my findings indicate that Vegfc acts as an angiocrine factor that plays an important role in regulating cardiac regeneration in zebrafish. Mechanistically, Vegfc promotes the expression of emilin2a, which promotes coronary proliferation, at least in part by enhancing Cxcl8a-Cxcr1 signaling. This study helps in understanding the mechanisms underlying coronary revascularization during cardiac regeneration, with promising therapeutic applications for human heart regeneration.
Synaptic plasticity is the basis for information storage, learning and memory and is achieved by modulation of the synaptic transmission. The amount of active AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazol-propionic acid) receptors at the synapse determines the transmission properties, therefore the regulation of AMPA receptor trafficking affects the synaptic strength. The protein GRIP (glutamate receptor interacting protein) binds to AMPA receptors and is one of the important regulators of AMPA receptor stability at the synapse (Dong et al., 1997; Osten et al., 2000). Previous studies have shown that the ablation of ephrinB2 or ephrinB3 in the nervous system leads to severe defects in hippocampal LTP (long term potentiation) and LTD (long term depression) (Grunwald et al., 2004). We found that ephrinB2 ligands play an important role in the stabilization of AMPA receptors at the cellular membrane (Essmann et al., 2008). Treating cultured hippocampal neurons with AMPA resulted in a robust AMPA receptor internalization, which could be inhibited by simultaneous ephrinB2 activation with soluble EphB4-Fc fusion proteins. Conditional hippocampal ephrinB2 knock-out (KO) neurons showed enhanced constitutive internalization of AMPA receptors. Interaction and interference experiments revealed that ephrinB ligands and AMPA receptors are bridged by GRIP. This interaction is regulated by phosphorylation of a single serine residue in close proximity to the C-terminal PDZ protein target site in ephrinB ligands (Essmann et al., 2008). To investigate the in vivo relevance of this previously undescribed feature of ephrinB reverse signaling, we generated ephrinB2 S-9>A knock-in mice, where the serine at position -9 was replaced by an alanine to prevent phosphorylation. The mutated ephrinB2 of this mouse line was expressed and able to form clusters following stimulation with the preclustered receptor EphB4-Fc. Surface ephrinB2 cluster size and cluster number was slightly smaller in comparison to wild type (WT) mice. Analyzing AMPA receptor internalization, we oserved an increased basal GluR2 endocytosis in cultured hippocampal neurons of ephrinB2 S-9>A mice. Dendrite and spine morphology was similar in pyramidal CA1 neurons of brain slices from adult ephrinB2 S-9>A and WT mice, suggesting a redundancy between the different ephrinB familily members.
Apart from regulating AMPA receptor stability at the synapse, GRIP1 also has an important role in the secretory pathway to deliver cargo proteins along microtubules to dendrites and synapses (Setou et al., 2002). Proteins involved in synaptic transmission and plasticity, as well as lipids required for the outgrowth and remodeling of dendrites and axons have to be transported. We showed in our laboratory with a directed proteomic analysis using the tandem affinity purification-mass spectrometry methodology (Angrand et al., 2006) and with immunoprecipitation assays with brain lysates that the small regulatory protein 14-3-3 interacts with GRIP1. Further immunoprecipitation assays with lysates from HeLa cells transfected with various parts and sequence mutants of GRIP1 revealed that threonine 956 in the linker region L2 between PDZ6 and PDZ7 of GRIP1 is necessary for the interaction with 14-3-3. GRIP1 has been postulated to influence dendritic arborization and maintenance in hippocampal neurons in culture due to defective kinesin-dependent transport along microtubules (Hoogenraad et al 2005). In order to address the role of the association of GRIP1 and 14-3-3 in dendritogenesis, we transfected rat hippocampal neurons with GRIP1-WT and GRIP1 mutants and performed Sholl analysis to evaluate dendritic arborization defects. We could observe striking increased formation and growth of dendrites in developing neurons as well as in mature neurons overexpressing GRIP1-WT. However, overexpression of GRIP1-T956A, where the threonine 956 was replaced by an alanine to prevent phosphorylation, did not show enhanced dendritogenesis, indicating a role for threonine 956 phosphorylation in dendrite branching. To investigate the importance of the interaction between GRIP1 and 14-3-3 in vivo, we generated transgenic mouse lines with a GRIP1-T956A transgene or a GRIP1-WT transgene as control. These mice were crossed with heterozygous GRIP1 mice and by further breedings we obtained some surviver mice carrying either the wild type or the mutated GRIP1 transgene in the usually embryonic lethal GRIP1-KO background (Bladt et al., 2002; Takamiya et al., 2004). In embryonic day (E) 14.5 cultured hippocampal GRIP1-KO neurons we could observe reduced dendritic growth. We also showed reduced GluR2 staining on the dendritic surface in cultured hippocampal neurons from GRIP1-KO and GRIP1-KO neurons containing the GRIP1-T956A transgene. GRIP1-KO neurons containing the GRIP1-WT transgene showed a similar surface GluR2 signal intensity as WT neurons. Reduced surface GluR2 staining in GRIP1-KO neurons and GRIP1-KO neurons with the GRIP1-T956A transgene might be a consequence of defective kinesin-dependent transport of GluR2 to dendrites, indicating an important role of threonine 956 phosphorylation of GRIP1 for GluR2 trafficking.
The heart is the first functional organ that develops in the embryo. To become a functional organ, it undergoes several morphogenetic processes. These morphogenetic events involve different cell types, that interact with each other and respond to the surrounding extracellular matrix, as well as intrinsic and extrinsic mechanical forces, assuming different behaviors. Additionally, transcription factor networks, conserved among vertebrates, control the development.
To have a better understanding of cell behavior during development, it is necessary to find a model system that allows the investigation in vivo and at single-cell resolution. Thanks to the common evolutionary origin of the different cardiac structures, together with the conserved molecular pathways, the two-chambered zebrafish heart offers many advantages to study cell behavior during cardiac morphogenesis. Here, using the zebrafish heart as a model system, I uncovered the cell behavior behind two of the main cardiac morphogenetic events: cardiac wall maturation and cardiac valve formation.
In the first part of this study, I investigated how the cardiac wall is maintained at the molecular level. Using genetic, transcriptomic, and chimeric analyses in zebrafish, we find that Snai1b is required for myocardial wall integrity. Global loss of snai1b leads to the extrusion of CMs away from the cardiac lumen, a process we show is dependent on cardiac contractility. Examining CM junctions in snai1b mutants, we observed that N-cadherin localization was compromised, thereby likely weakening cell-cell adhesion. In addition, extruding CMs exhibit increased actomyosin contractility basally, as revealed by the specific enrichment of canonical markers of actomyosin tension - phosphorylated myosin light chain (active myosin) and the α-catenin epitope α-18. By comparing the transcriptome of wild-type and snai1b mutant hearts at the early stages of CM extrusion, we found the dysregulation of intermediate filament genes in mutants including the upregulation of desmin b. We tested the role of desmin b in myocardial wall integrity and found that CM-specific desmin b overexpression led to CM extrusion, recapitulating the snai1b mutant phenotype. Altogether, these results indicate that Snai1 is a critical regulator of intermediate filament gene expression in CMs and that it maintains the integrity of the myocardial epithelium during embryogenesis, at least in part by repressing desmin b expression.
In the second part of this study, I focused on the behavior of valve cells during cardiac development. Using the zebrafish atrioventricular valve, I focus on the valve interstitial cells which confer biomechanical strength to the cardiac valve leaflets. We find that initially AV endocardial cells migrate collectively into the cardiac jelly to form a bilayered structure; subsequently, the cells that led this migration invade the extracellular matrix (ECM) between the two EC monolayers, undergo an endothelial-to-mesenchymal transition as marked by loss of intercellular adhesion, and differentiate into VICs. These cells proliferate and are joined by a few neural crest-derived cells. VIC expansion and a switch from a pro-migratory to an elastic ECM drive valve leaflet elongation. Functional analysis of Nfatc1 reveals its requirement during VIC development. Zebrafish nfatc1 mutants form significantly fewer VICs due to reduced proliferation and impaired recruitment of endocardial and neural crest cells during the early stages of VIC development. Analysis of downstream effectors reveals that Nfatc1 promotes the expression of twist1b, a well-known regulator of epithelial-to-mesenchymal transition. This study shows for the first time that Nfatc1 regulates zebrafish VICs formation regulating valve EMT in part by regulating twist1b expression. Moreover, it proposes the zebrafish valve as an excellent model to study the cellular and molecular process that regulate VIC development and dysfunction.
In conclusion, my work: 1) identified an unsuspected role of Snai1 in maintaining the integrity of the myocardial epithelium, opening new avenues in its role in regulating cellular contractility; 2) uncovered the function of Nfatc1 in the establishment of the VIC, establishing a new model to study valve development and function.