Browsing by Person "Blum, Martin"

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Analyse des Flow-abhängigen Symmetriebruchs im Frosch Xenopus : die Funktion des Nodal-Inhibitors Coco
(2015) Getwan, Maike; Blum, Martin
The bilaterally symmetrical vertebrate body plan is characterized by the three body axes, anterior-posterior (AP), dorsal-ventral (DV) and the left-right (LR). The LR-axis is the last one to be specified during embryonic development. Its impact on the morphology of the developing organism is visible after a few days in Xenopus laevis, because of the orientation of the visceral organs, such as the heart, gut and the gall bladder. The first molecular differences between the left and right side can already be detected after one day during early neurulation. It is found at the gastrocoel-roof-plate (GRP), a ciliated epithelium which is essential for symmetry breakage. Cilia rotate to produce a leftward fluid movement, which represses the Cerberus/DAN gene Coco in the lateral cells of the epithelium. As Coco acts as an inhibitor of the coexpressed TGFß-type growth factor Nodal (Xnr1), Xnr1 is flow-dependently released from repression on the left side. Xnr1 is capable to induce a unilateral gene-cascade in the left lateral plate mesoderm (LPM) consisting of Nodal itself, its antagonist Lefty/ antivin and the homeobox gene Pitx2c. A central question in this setting concerns the mechanism by which flow results in the repression of Coco. The analysis of Coco transcription gave a first hint, indicating that Coco mRNA is post-transcriptionally degraded and/ or that its translation is blocked. Gene regulation at the level of mRNA usually occurs through the untranslated regions (UTR), in most cases via the 3UTR. To examine the role of the Coco 3UTR for its regulation, protector-RNAs were used which should protect endogenous Coco mRNA from potential inhibitors. Injections led to the interruption of the flow-dependent Coco repression, verifying regulation of Coco via the 3UTR. As 3UTRs are target sites for microRNAs, loss of function experiments of the processing enzyme Dicer were performed. These experiments verified the involvement of miRNAs in the regulation of Coco. Further analyses identified miR-15a as a central player. The interruption of its synthesis or the specific protection of its binding site within the Coco 3UTR prevented flow-dependent down-regulation of Coco. Epistatic experiments demonstrated that the LR-axis of embryos with inhibited flow could be rescued by addition of the miR-15a precursor on the left side. In summary this thesis work revealed miRNAs as a primary target of leftward flow, upstream of the Nodal inhibitor Coco.
ATP4 and Wnt-signaling are required for ciliogenesis and left-right axis development of Xenopus
(2012) Walentek, Peter; Blum, Martin
The vertebrate body plan displays left-right (LR) asymmetries of organ placement superimposed on an overt bilaterally symmetrical organization. Symmetry is broken during embryogenesis, and asymmetric gene expression precedes asymmetric organ morphogenesis. The proton/potassium pump ATP4 was shown to play a role in LR-development of the frog Xenopus laevis as well as in other deuterostomes. Two opposing models of symmetry-breakage were proposed, the ?ion-flux? and the ?leftward flow? model. The former proposed that symmetry was broken by LR-asymmetric expression of the a-subunit of ATP4 during cleavage stages. The latter claimed a cilia-based leftward flow at the gastrocoel roof plate (GRP) to take center stage during neurulation, i.e. a day later in development. In the present thesis work, the role of ATP4a in symmetry-breakage was re-addressed and evidence for symmetrical expression and function of ATP4a was gathered. ATP4a was shown to be required for two Wnt-signaling dependent steps during the setup of cilia driven leftward flow at the GRP: (1) Wnt/b-catenin (b-cat) dependent expression of Foxj1 during gastrulation, and (2) Wnt/planar cell polarity (PCP) dependent posterior localization of motile cilia during neurulation. These data challenge the ?ion-flux? hypothesis and argue for a conserved ATP4- and cilia-dependent symmetry-breakage mechanism throughout the vertebrates. Furthermore, the function of Wnt-signaling components was analyzed in the context of GRP-formation: The receptor Frizzled 8 (Fz8) and b-cat were required for Foxj1 expression during gastrulation. Morphogenesis of the GRP, posterior polarization of motile cilia and expression of Xnr1 and Coco in somitic cells were all required for LR-development. Loss of non-canonical Xwnt11b-signaling perturbed these process, suggesting that non-canonical Wnt-signaling branches, in addition to Wnt/PCP, were relevant for LR-development. ATP4-mediated Wnt-signaling was also required for Foxj1 expression and motile cilia in other epithelia during Xenopus development, i.e. the skin, floor plate and the ependymal cell layer. In the floor plate b-cat was required for Foxj1 expression downstream of Hedgehog-signaling. In the skin mucociliary epithelium ATP4a and Wnt/b-cat were required downstream of Notch/Delta-mediated cell-type specification of multiciliated cells. This was also true for a new cell type of serotonergic cells described here, which was characterized morphologically, by analysis of gene expression and response to manipulations of Wnt- and Notch/Delta-signaling. In summary, the data presented in this thesis suggest a conserved function of ATP4a and Wnt-signaling in vertebrate symmetry-breakage and Foxj1-dependent ciliogenesis in Xenopus.
Delimitation of the organizer from the posterior notochord : descriptive and functional studies in mouse and African clawed frog
(2009) Andre, Philipp; Blum, Martin
During vertebrate development, gastrulation is probably the most important phase, as the future body plan is established. Thereby the three body axes anterior-posterior, dorsal-ventral and left-right are determined as well. A central role thereby is taken by the Spemann organizer, as this part of the embryo governs the above mentioned processes. The left-right axis is specified by an extracellular leftward fluid-flow, which results in asymmetric gene expression of the TGFβ factor Nodal. In mice the ciliated epithelium responsible for the fluid-flow as well as the organizer are denominated as ?node?. In contrast to that two distinct entities are thought to be responsible for organizer function and fluid-flow in zebrafish, Xenopus and rabbit embryos. In the present study, it could be shown that this also applies for mouse embryos. In order to prevent further confusion the ciliated epithelium responsible for the fluid-flow was denominated as posterior notochord (PNC) as it is in continuity with the notochord but located anterior to the organizer (?node?). The latter is characterized by the expression of the homeobox gene Goosecoid (Gsc). Gsc possesses, like the tissue of the organizer, the potential to induce an almost complete axis and became therefore famous as ?the organizer gene?. However upon knockout of Gsc in the mouse, surprisingly no gastrulation defects could be detected. Therefore the function of Gsc during gastrulation was investigated using a gain-of-function approach. The analysis of this, in the present and previous studies, indicated that Gsc acts as a switch between two modes of cell movement. Accordingly, Gsc promotes active cell migration and inhibits convergent extension movements. Furthermore it was investigated whether the monoamines adrenaline and serotonin have an influence on the cilia and thus on the leftward fluid-flow, as it was reported in rat and Xenopus experiments. Thereby it could be detected that the addition of adrenaline led to a reduction of the ciliary beat frequency (CBF) and therefore the fluid-flow was attenuated. In contrast to that the addition of serotonin or its antagonists resulted only in minor changes of CBF and thus had no measurable effect on the fluid-flow. The consequences of a malformed PNC were analyzed using embryos mutant for Brachyury (T). Thereby, it was shown that embryos homozygous for this mutation did not develop a functional PNC and thus lacked the fluid-flow. Furthermore a possible cause for the absence of asymmetric Nodal in these embryos was brought into context of an attenuated expression of Fgf8. This indicated that T possesses two distinct roles in left-right development. On the one hand it is necessary for the correct formation of a PNC and on the other hand it is probably needed to maintain the expression of Fgf8, which is a prerequisite for the transcription of Nodal. Finally it was investigated whether these functions were conserved from the African clawed frog Xenopus. Thereby, it could be shown, that Xbra, the homologous gene of T in Xenopus, was also necessary for the formation of the gastrocoel roof plate, the homologous structure of the PNC. Additionally it was observed that the absence of Xbra led to an attenuation of Nodal expression in the midline of Xenopus embryos. This implied that not only the function of Brachyury, but also the process of laterality determination is highly conserved between mammals and amphibians.
Deskriptive und funktionelle Analyse der Mitglieder der Calponin-Genfamilie Xclp1, Xclp2 und Xclp3 während der Embryonalentwicklung von Xenopus laevis
(2008) Schmalholz, Silke; Blum, Martin
The embryonic development of vertebrates is characterized by controlled cell movements. During gastrulation and neurulation cells of the presumptive heart tissue and the neural crest after neural tube closure migrate towards their final position in the embryo. Cell intercalations, which drive the convergent extension (CE) movements to elongate the embryo also depend on active cell migration. The inhibition of CE leads to shortened body axis and neural tube closure defects (NTD). The motility of eukaryotic cells is finally based on the dynamic interaction of cytoskeletal components, which act on the actin filament. Secreted growthfactors of the Wnt family can regulate embryonic cell movement via the non canonical Wnt signaling pathways. The planar cell polarity (PCP) and the Wnt/Ca2+ pathway are thought to be crucial for the process of CE. Up to now there is a lack of knowledge about the cytoskeletal effectors of these signaling cascades. In the presented work, members of the calponin gene family (clp1 to 3) were analysed in this context. Calponins are actin binding proteins, which have been shown to inhibit actin-myosin-interactions and/or to stabilize the actin filament. Expression patterns provided first insights in the transcriptional activity of Xclp1, Xclp2 and Xclp3 during embryonic development. Two Xclp genes (Xclp2 and Xclp3) were already expressed broadly at the onset of gastrulation. Transcription, however, was not detected in the involuted cells, which form the mesodermal germlayer. At neurula stages Xclp2 mRNA was specifically found in the notochord, whereas Xclp3 was expressed in the neuroectoderm. Additionally the migrating cells of the embryonic heart and neural crest were positive for calponin expression. In summary the embryonic calponin pattern correlated with tissues in which cell movements occur. Over- or misexpression experiments were performed to manipulate embryonic calponin function in Xenopus laevis. Gain of function experiments however did not interfere with embryonic development. Probably calponin function was posttranslational negatively regulated in these experiments.The overexpression of calponin proteins, in which specific phosphorylation sites were mutated or known regulatory calponin domains deleted, again didn´t result in altered phenotypes. However, the misexpression of calponin actin binding domaine 2 (ABD2) inhibited the migration of Krox 20 positive neural crest cells, suggesting that in this tissue the Xclp ABD2 acts dominant negative. The presented data are not able to proof or disproof the hypothesis, that calponin proteins are effectors of the non canonical Wnt pathways.
Determination of Laterality in the Rabbit Embryo: Studies on Ciliation and Asymmetric Signal Transfer
(2007) Feistel, Kerstin; Blum, Martin
The midline of the vertebrate embryo plays a pivotal role in the regulation of left-right (LR) asymmetry. In mammals recent interest has focused on a structure situated at the caudal part of the notochord, the posterior notochord (PNC), which is homologous to Kupffer?s vesicle (KV) in fish and the gastrocoel roof plate (GRP) in frog. Despite highly diverging embryonic architecture, the PNC/KV/GRP is the site where motile monocilia set up a directional fluid flow, an event indispensable for the generation of LR asymmetry. Signals created at the PNC/KV/GRP need to be transferred to the periphery of the embryo, where they initiate the left-specifying program in the left lateral plate mesoderm (LPM). In this study morphogenesis and ciliogenesis of the notochordal plate as well as the signaling processes between midline and LPM were studied in the rabbit embryo. Rabbit development progresses through a flat blastodisc phase and represents the typical mode of mammalian embryogenesis. Transcription of ciliary marker genes, the first sign of beginning ciliogenesis, initiated in Hensen?s node and persisted in the nascent notochord. Cilia emerged on cells leaving Hensen?s node anteriorly to form the notochordal plate. Cilia lengthened to about 5µm and polarized from an initially central position to the posterior pole of cells. Electron microscopic analysis revealed 9+0 and 9+2 cilia and a novel 9+4 axoneme intermingled in a salt-and-pepper-like fashion. These data showed that the ciliogenic gene program essential for laterality determination is conserved at the midline of the rabbit embryo. The present study also provided evidence that initiation as well as repression of the Nodal cascade crucially depended on communication between midline and lateral plate (LP). Separation of LP tissue from the midline before, during and after the 2 somite stage demonstrated that signals from the PNC induced and maintained the competence of LPM to express Nodal. Signals from the midline were necessary after the 2 somite stage to maintain a right-sided identity, i.e. absence of Nodal expression. Gap-junction-dependent intercellular communication (GJC) was shown to play a central role in this process. Previously, GJC had been involved in LR axis determination in cleavage stage frog embryos and early blastodisc stages in chick. This study for the first time demonstrates the role of GJC in mammalian embryos. GJs regulate the signaling between midline and periphery: permeable gap junctions were required specifically at the 2 somite stage to repress Nodal induction in the right LPM, whereas closed GJs were a prerequisite for Nodal signaling on the left side. Establishment of the right-sided fate depended on FGF8, the signaling of which was regulated by the opening status of GJs. A 3-step model is proposed for symmetry breakage and induction of the LR signaling cascade in vertebrates: (1) Nodal protein synthesized at the lateral edges of the PNC diffuses bilaterally and confers competence for the induction of the Nodal cascade to the LPM, (2) at the same time the left-specific cascade is actively repressed by action of the GJC/FGF8 module, and (3) following the onset of leftward flow at the PNC repression gets released specifically on the left side at the 2 somite stage, presumably by transient inhibition of GJC. This model not only is consistent with the presented data, but also with published work in other model organisms.
Establishment of a new in vitro culture system and functional analysis of sonic hedgehog and FGF8 in the determination of laterality in the rabbit embryo
(2008) Bitzer, Eva; Blum, Martin
Cilia-driven leftward flow plays a pivotal role in the determination of left-right (LR) asymmetry. In mammals, this extracellular fluid flow is produced by motile monocilia situated on the posterior notochordal plate (PNC). The PNC is homologous to superficial mesoderm derived structures of other species like the gastrocoel roof plate (GRP) in frog and Kupffer's vesicle (KV) in fish. Directional fluid flow created at these structures subsequently leads to the initiation of the left-specifying Nodal signalling cascade in the left lateral plate (LPM). The rabbit develops via a flat blastodisc phase representing the archetypical mode of mammalian embryogenesis. These specific advantages of the rabbit were employed in this study to further examine the role of two central determinants of laterality, namely Sonic hedgehog (Shh) and FGF8, and also extended by the design of a new in vitro culture technique. In this new method, the so-called ring culture, a medium-filled plastic ring was placed upon the extraembryonic tissue of the explanted embryo. In contrast to the semi-dry standard culture method, this setting corresponded more to the in vivo conditions of gastrulating/neurulating rabbit embryos in the uterus. It therefore facilitated stable development of laterality in most cases also when presomite stages were taken into culture. Subsequent analysis showed that this was due to improved development of the PNC. Conversely, in standard-cultured embryos showing altered LR marker gene expression, maturation of the PNC was impaired leading to a disturbance of leftward flow. This study also provided evidence that cilia-driven leftward flow is indispensable for the determination of laterality in rabbit embryos. When the flow was blocked during culture by methylcellulose-containing medium embryos displayed altered LR marker gene expression in a very high proportion. The unilateral gain-of-function of Shh revealed important differences between rabbit and chick embryos. In rabbit, Shh induced right-sided marker gene expression only in the 2 somite stage, whereas in chick this inductive effect lasted from stage 4 until up to the 1-2 somite stage. This indicated that in rabbit Shh works in conjunction with the flow, which has not been described up to now in chick. The systemic inhibition of Shh signalling by cyclopamine led to bilateral expression of LR marker genes in rabbit. This was due to disruption of the floor plate and therefore the loss of the restrictive midline barrier function of Lefty expression as described in Shh mutant mice. FGF8 has a right-sided repressive function in the rabbit implicated in the transfer of laterality cues. In the present study it could be shown that this repressive effect is epistatic to cilia-driven leftward flow, because it also functioned when the flow was blocked. The systemic inhibition of FGF8 signalling with SU5402 caused loss of LR marker gene expression prior to the 2 somite stage but did not influence ciliogenesis or the setup of cilia-driven leftward flow. Taken together, this suggested a dual function for FGF8 signalling: First, it is needed to confer competence to the lateral plate and second, during the 2 somite stage, it is needed for the transfer of LR cues.
Funktionelle Analyse der Gene Brachyury, Goosecoid und Myosin1d für die frühe Musterbildung und Etablierung der Körperachsen während der Embryogenese des Krallenfroschs Xenopus laevis
(2019) Kurz, Sabrina; Blum, Martin
During a fundamental phase of vertebrate embryonic development, gastrulation, the reorganization of the future body plan, is determined. This process controls the embryonic patterning of the antero-posterior (AP) and dorso-ventral (DV) axes, as well as the internal left-right (LR) axis. The establishment of the body axes is initially controlled by the dorsally localized Spemann organizer (SO), whereby the determination of the LR axis takes place the latest. The formation of laterality during subsequent neurulation is executed by a highly conserved mechanism of symmetry breakage within fishes, amphibians and mammals. An extracellular, monocilia-driven fluid-flow („Flow") eventually defines the laterality of the embryo, by left-asymmetric gene expression of the morphogen Nodal. Responsible for the Flow is a ciliated epithelium in the postero-dorsal region of the embryo, which undergoes morphological development and correct positioning during gastrulation and is termed GRP („gastrocoel roof plate") in the frog. Ultimately, this conserved tissue describes the left-right organizer (LRO) and guarantees proper organ situs. The origin and function of the LRO can be traced back to an epithelial organized cell structure on the dorsal surface of the gastrula, characterized by the expression of the canonical Wnt target gene and cilia marker foxj1. Following the specification of this Superficial Mesoderm (SM), the future cells of the LRO invaginate in a directed fashion during gastrulation. The patterns of cellular movement require a restructuring of the actin-cytoskeleton. These migrations, executing the future body plan, are ensured by the PCP- („planar cell polarity”) signaling pathway. This non-canonical Wnt pathway guarantees polarized alignment and migration of cells along the body axes, namely convergent extension (CE). As an organizer gene, the expression of Goosecoid (Gsc) characterizes SO and its’ properties. Contrary to the assumption that a Gsc loss of function thus inhibits gastrulation, no visible impairment was detected in the Knock-Out mouse and Knock-Down in Xenopus. Gain-of-function in the frog, which analyzed the role of Gsc during gastrulation finally demonstrated the homeobox-gene exerting a function in regulating cell movements. Overexpression resulted in impaired CE of dorsal tissue due to defective localization of nuclear proteins of the PCP signaling pathway. Gsc-induced malformations could be compensated by co-injections of associated components. In conclusion, a new function as an inhibitor of PCP-dependent CE during gastrulation was suggested. The morphogenetic movements of CE are responsible for the AP-elongation and LRO-positioning. Both, mechanical forces and cilia-based Flow functionally interact for that matter. In the invertebrate Drosophila, where neither Nodal nor cilia are expressed, organ asymmetry is ensured by internal chirality conducted via motor proteins, such as myosin1d, in a PCP-dependent manner. Similarly, in vertebrates such as Xenopus, myo1d mediates interactions of the actin cytoskeleton asymmetrically, that guarantee laterality of the organ system. The functional preservation of the non-canonical Wnt pathway could be demonstrated by co-injections of PCP core proteins, being able to restore disturbed LRO morphology. The obtained data clearly demonstrated the evolutionary, interspecific, regulation of axis asymmetry by myo1d. Since the strict spatio-temporal regulation of cell movements is fundamental for patterning, CE is propagated by another transcription factor: Brachyury (Tbxt in Xenopus). Its expression induces and controls differentiation of mesodermal cell populations, such as the notochordal cells of the dorsal midline, hence LRO. The necessity specifying progenitor cells in the SM could also be highlighted, showing to be mediated non-cell autonomously to guarantee the induction of foxj1. Additionally, the determination of both tissues is exerted by functional interactions of Tbxt with either PCP-, as well as ß-catenin-dependent Wnt signaling pathway. Loss of Brachyury affects laterality in mutants and morphants. The species-spanning Brachyury-FGF „feedback-loop" for the induction of Nodal and Foxj1 could already act in the SM and showed that function as well as the process of LR development, as suggested between Fgf8 and Brachyury, to be functionally conserved. In Xenopus, signal transduction for SM and foxj1 induction was extended by the function of the Wnt receptor frizzled-8, the ligand and Tbxt target gene wnt11b, and the ventrally acting wnt8a in Whole-Mount embryos and explant co-cultures.
Funktionelle Analyse der Histondeacetylase 6 sowie experimentelle Modellierung von Lateralitätsdefekten während der Links-Rechts-Achsenentwicklung von Xenopus laevis und Paracentrotus lividus
(2017) Tisler, Matthias; Blum, Martin
Vertebrates display an asymmetric positioning of the visceral organs, which is also denominated as left-right body axis. During embryogenesis, an asymmetric gene expression is detectable that is initiated by an evolutionary conserved mechanism of symmetry breakage, which is conserved among deuterostomes. During neurula stages, rotating motile mono-cilia at the so called left-right organizer (LRO) generate an asymmetric stimulus known as extracellular leftward fluid flow that is essential for the unilateral left asymmetric gene expression of the Nodal cascade. Spontaneous mutations or the experimentally induced loss of function of genes influencing ciliogenesis at the LRO, the induction of the Nodal cascade or its propagation lead to left-right defects. Left-right defects are frequently observed in human conjoined twins. Thoracopagous, dicephalic conjoined twins display defects in the arrangement of the inner organs, that are solely reported from the twin located to the right side. While left twins orient the inner organs wildtypically, right twins show a randomization of the left-right axis. The functional cause of the inverted arrangement regarding the right twin has remained enigmatic. It has been hypothesized that the observed laterality determination in conjoined twins, like in wildtype embryos, was dependent on leftward flow. In the course of this thesis, the known unilaterlal left-sided induction of the Nodal cascade in the left conjoined twin, as in singelton embryos, can be linked to leftward flow. The artificial induction of a second body axis leads to a subsequent duplication of the LRO during development. During flow stages endogenous and induced LROs locate in close proximity and display a partial fusion of cell populations. Anti-sense Morpholino Oligomeres or methylcelluose mediated loss of cilia motility lead to a loss of markergene expression in the left-lateral plate mesoderm of the left twin. By combining differential gain- and loss-of-function strategies, it was possible to link the establishment of laterality in conjoined twins to the leftward flow and, moreover, to manipulate it an a predictable manner. The cause of this hitherto enigmatic laterality defects in conjoined twins can therefore be explained by the evolutionary conserved mechanism of left-right establishment. Although the general mechanism of symmetry breakage has been characterized, novel candidate genes are continously beeing identified that act at a specific sequence of this process. The candidate gene histonedeacetylase 6 (hdac6) was shown to impact on left-right development. Anti-sense Morpholino Oligomere induced loss-of-function experiments led to left-right defects in a dose dependent manner regarding, the induction of the genes of the Nodal cascade, indicating a function of hdac6 before fluid flow induced regulation of dand5 mRNA. Taken together: histonedeacetylase 6 acts as modulator of canonical Wnt-signaling in the transcriptional induction of the Wnt-dependent transcription of foxj1, a master control gene of the biogenesis of motile cilia. Loss of Hdac6 leads to defects regarding the ciliogenesis of motile cilia at the LRO as well as the multiciliated epidermis of the embryo. The here presented results represent the first developmental hdac6 loss-of-function phenotype, which was so far not know from Hdac6-/- mice. These experiments shed a new light on the differential in vivo function of this unique histondeacetylase during development. Even though the asymmetric positioning of the inner organs is restricted to vertebrates, the asymmetric expression of the Nodal cascade turns out to be evolutionary conserved among deuterostomes. Comparable to vertebrate species, larvae of the sea urchin (Paracentrotus lividus, Echinodermata) display an asymmetric expression of the Nodal cascade in the ectoderm an during gastrula stages. Experiments from this work could demonstrate that also in sea urchin embryos the asymmetric gene expression depends on motile cilia. The archenteron of gastrula stage embryos was identified and described as homologous structure to vertebrate LROs. Deciliation experiments at different time points of development induce laterality defects and point towards a symmetry breakage during early gastrulation. By this experiments, the cilia dependent establishment of left-right asymmetry is described as a common synapomorphy of the deuterostomes beeing conserved from sea urchin to vertebrates, shedding a new light on the establishment of asymmetric gene expression.
Goosecoid und Calponin : zwei neue Regulatoren des PCP-Signalwegs
(2012) Ulmer, Bärbel Maria; Blum, Martin
Vertebrate embryogenesis relies on morphogenetic movements such as cell migration and convergent extension (CE). The planar cell polarity (PCP) branch of non-canonical Wnt signaling governs the orientation of cells along embryonic axes. PCP-signaling leads to intracellular polarization of proteins such as Dishevelled, Prickle and Vangl2, resulting in activation of small GTPases such as Rho and Rac, and consequently oriented alignment of the cytoskeleton. This polarity is required for CE, namely for the intercalation of bipolar cells, during gastrulation and neurulation. CE promotes elongation of the notochord and the neural plate, which is a prerequisite of neural tube closure. Previous work had shown that misexpression of the transcription factor Goosecoid (Gsc) in the primitive streak of the mouse and in the dorsal marginal zone of the frog led to neural tube closure defects. The present work demonstrates that misexpression of Gsc inhibits CE in vivo and ex vivo. Gsc gain-of-function (Gsc-GOF) prevented the membrane localization of Dishevelled in the frog animal cap assay, suggesting a disturbance of the PCP pathway. The Gsc-induced phenotypes could be rescued by co-injection of core components of the PCP pathway, Vangl2 and Prickle. Overexpression of RhoA and the non-canonical Wnt11, rescued the effect of Gsc-GOF. Brachyury, a transcriptional activator of Wnt11 and known target of Gsc, was also able to rescue the effect of Gsc-GOF. Gsc thus acted as a repressor of PCP-mediated CE. Furthermore, loss of function experiments in Xenopus were conducted to reveal the endogenous function of Gsc. Due to the conserved and distinct expression of Gsc in Spemann's organizer and the induction of double axes upon injection of Gsc into the ventral marginal zone in Xenopus, a function of Gsc in the specification of dorsal tissue was predicted. The lack of gastrulation defects in the Gsc knock-out mouse, however, questioned an early role of Gsc. The repression of the PCP pathway by Gsc-GOF suggested a novel role of Gsc in the regulation of cell movements. Interestingly, Gsc is expressed in a distinct population of cells in the early organizer, which migrate out of the organizer during early gastrulation to form the prechordal mesoderm. In contrast, the subsequent involuting cells of the notochord undergo CE. Gsc knock-down in the frog reduced the prechordal plate resulting in a narrowing of eye distance. Furthermore, activin-induced CE in animal cap explants was enhanced by Gsc loss-of-function. These findings are consistent with a novel function of the organizer gene Gsc in the regulation of cell movements during early gastrulation, namely the repression of PCP-mediated CE as a prerequisite of active migration of the prechordal mesoderm. The directed migration of neural crest cells represents another embryological process which depends on PCP-signaling. Previous work showed expression of Calponin2 in neural crest cells. Moreover, inhibition of Calponin1 by the Rho-Kinase has been described. In Xenopus, Calponin2 localized to cell protrusion of delaminating and migrating neural crest cells. Loss of function of Calponin2 prevented the polarized outgrowth of cell extensions in neural crest explants and thus migration of neural crest cells. Moreover, additional stress fibers were formed in the central area of neural crest cells at the expense of the peripheral, cortical actin cytoskeleton. The PCP pathway directs migration via the activation of RhoA and inhibition of Rac in the cell compartment opposed to the leading edge. This suggested an interaction of PCP-signaling and Calponin2 during the migration of neural crest cells, which was examined by rescue experiments in vivo and in neural crest explants. Calponin2 knock-down rescued Wnt11 and Rho-Kinase loss-of-function, strongly suggesting that the actin-binding protein Calponin2 acts as an effector of the PCP pathway and directs the polarization of the actin cytoskeleton in migrating neural crest cells. In summary the present work involved two novel regulators of PCP-mediated CE, Gsc at the transcriptional level and Calponin2 as an effector of the actin cytoskeleton.
Left-right asymmetry in Xenopus laevis : functional dissection of leftward flow
(2009) Vick, Philipp; Blum, Martin
Despite their external bilateral symmetry, vertebrates have a conserved left right (LR) asymmetry of their inner organs. For all vertebrates, it is well-known that the asymmetric organogenesis is preceded by the left-sided nodal signaling cascade during embryonic development. A question which has not been settled in detail is how the first asymmetrically directed signal arises, which activates nodal only on the left side. In mice and fish embryos an extracellular leftward fluid flow ? generated by rotating cilia ? was shown to be functionally necessary for gene activation. Recently, this process has also been demonstrated in frog embryos and its mechanic inhibition caused laterality defects. This raised the question if this process is also conserved among vertebrates. The aim of this study was to analyze the mechanism of flow in the frog in the context of the known models. Thereby, its prerequisites and the exact mode of activation of the left-sided genes should be assessed. Finally, general conclusions on the symmetry breakage of vertebrates were to be drawn. Loss of function of axonemal dynein heavy chains inhibited ciliary movement, fluid flow and laterality development of the embryos. By showing that flow was only necessary on the left half of the ciliated epithelium (GRP), definite statements could be made concerning origin, identity and possibility of a transported substance. Moreover, a function for GRP morphogenesis and thus for the generation of flow were proven for the serotonin receptor 3 and the calcium channel Pkd2. These results did not confirm the hypothesis that Pkd2 causes a flow-dependent left-sided calcium signal. Consequently, this contradicted the so-called "2-cilia model" in favor of an early morphogenetic function in frog. In the course of a collaboration it could be shown, that the RNA-binding protein xBic-C has a conserved function for cilia polarization and thus for the flow in both Xenopus and mice. Additionally, up to now, a right-sided nodal inhibitory function has been assigned to the protein coco. However, the exact mechanism was unknown. By specific, combined left- and right-sided loss of function experiments with coco, nodal and the above mentioned components, it could be demonstrated that coco but not nodal is directly dependent on leftward flow. With the flow, coco was downregulated on the left side only and could thus no longer inhibit nodal there. Loss of flow or xBic-C function ? but not that of Pkd2 ? could be rescued by coco inhibition; this revealed a clear hierarchy. Taken together a sequence of conditions could be formulated: Pkd2 and the serotonin receptor 3 are obligatory for the formation of the GRP and correct flow before neurulation. xBic-C also precedes the flow and is required for cilia polarization but seemed also to have a further function. coco is downstream of the fluid flow and is downregulated as its direct consequence on the left side. nodal, in turn, is downstream of this order and is only released on the left side where it can thus act as a putative mediator to transfer the generated signal into the lateral plate mesoderm. These results are discussed in terms of evolutionary origin and conservation.
Multiple Funktionen des FGF-Signalwegs regulieren die Lateralitätsentwicklung im Krallenfrosch Xenopus
(2013) Schneider, Isabelle; Blum, Martin
Early embryogenesis governs the formation of the three body axis. Like in a cartesian coordinate system, the LR-axis is defined by the generation of the anterior-posterior and the dorso-ventral axis. In the course of laterality specification, the original LR-symmetry has to be broken to enable the asymmetric arrangement of inner organs in a specific manner. This is mediated by the expression of conserved gene cascade, namely the Nodal gene cascade, which is expressed in the left but not in the right lateral plate mesoderm of the neurula stage embryo. Symmetry breakage, which leads up to this asymmetric Nodal gene cascade, is manifested by a cilia-based leftward fluid flow. The flow generating epithelium is located at the posterior end of the notochord and expresses Nodal in a bilateral symmetrical mode. This early Nodal domain is a prerequisite of the later asymmetric Nodal gene cascade. Despite the conserved nature of Nodal expression and of leftward flow, no conservation of the role of the FGF signaling has been described for mouse, chick, rabbit and zebrafish. In this work the role of FGF signaling in Xenopus laevis LR-development was investigated. Using of a receptor antagonist to inhibit FGF signaling revealed two temporally distinguishable functions. Firstly, FGF signaling in early gastrula stages is required for the proper expression of FoxJ1, the master control gene of motile cilia. Here, FGF signaling acts in the process of ciliogenesis of the symmetry-breaking epithelium, which is represented by the GRP (“gastrocoel roof plate”) in Xenopus. Secondly, FGF acts in a cilia-independent manner on the bilateral Nodal expression. A series of descriptive and functional studies revealed that these cells constitute the somitic part of the GRP and that inhibition of FGF signaling leads to the loss of these cells. Interestingly, the effect on ciliogenesis is consistent with the role of FGF signaling in zebrafish, whereas the loss of bilateral Nodal expression is in line with the hypomorpic Fgf8 mutant mouse. The description of these two successive functions in Xenopus indicates a higher degree of conservation of the role of FGF signaling than suggested so far. The FGF signaling pathway splits into several branches, two of which play important roles in the early development of Xenopus embryos. Activation of MAPK signaling is implicated in the induction of mesoderm, whereas the PLC/PKC/Calcium signaling branch impacts on morphogenetic movements. FGF-mediated control of Foxj1 expression was temporally correlated with FGF signaling that acts on mesoderm specification. As a consequence, mesodermal gene expression and blastopore closure was seriously affected by loss of FGF signaling at early gastrula stages. By starting inhibition experiments during gastrula stages, when mesoderm induction is almost finished, general mesoderm specification defects were avoided but the effect on the somitic GRP cells persisted. To unravel which FGF-induced signaling branch acted on the two different functions of FGF described here, the PLC/PKC/Calcium signaling branch was inhibited using the antagonist Sprouty1. Sprouty1 gain of function experiments had no effect on ciliogenesis, but caused loss of somitic GRP cells comparable to loss of function experiments using the FGF receptor antagonist. This suggests that the FGF-dependent formation of these cells is regulated by the PLC/PKC/Calcium pathway. A specific role of Calcium was supported by experiments using a calcium-permeable channel. Despite this, ciliogenesis was not affected by inhibition of PLC/PKC/Calcium, suggesting a role of MAPK for the early function of FGF. In conclusion, this work demonstrates two functions of FGF signaling in Xenopus LR-development, which furthermore are consistent with a conserved function of FGF signaling in vertebrate LR-axis determination. Novel insights into the role of FGF signalling in the very cells which sense leftward flow at the lateral margin of the GRP will open new approaches to analyse laterality specification in more detail.
Studies of human genetic diseases and developmental processes with the frog Xenopus laevis
(2020) Ott, Tim; Blum, Martin
Next generation sequencing is a driving force behind the identification of genes and alleles that are suspected to cause human genetic diseases. In silico tools are routinely used in the clinical everyday life to characterize unknown genotypes. However, these tools have a limited predictive accuracy and can only provide a first-line assessment. Especially un- or less studied genes require in every case predictive in vivo model systems that allow conclusions about disease associations. Classically, mice and zebrafish are utilized for such research, which concomitantly deepens the understanding of the involved developmental processes. In this collection of studies, the African clawed frog Xenopus laevis was used to explore and promote its suitability for the analysis of potential human disease genes, variants and their associated developmental processes. The first chapters covers potential candidate genes for primary ciliary dyskinesia (PCD). The second chapter addresses if an actin based motor protein and a novel metzincin peptidase, encoded by myosin ID (MYO1D) and leishmanolysin like peptidase (LMLN2)/tout-de-travers (TDT), respectively, are potentially causative for PCD independent laterality defects. The third chapter deals with two candidates for neurodevelopmental disorders, namely hyaluronan mediated motility receptor (HMMR) and progesterone immunomodulatory binding factor 1 (PIBF1).
The role of serotonin and gap junctions in left-right development of Xenopus laevis
(2011) Beyer, Tina; Blum, Martin
In vertebrates, the correct determination of the left-right (LR) axis is essential for accurate placement of the inner organs, such that the heart points to the left, lung lobation differs between left and right side, spleen and stomach are located on the left,liver on the right body side and the gut coils asymmetrically. Disturbance of this organization can lead to severe impairments of organ function. In the African clawed frog Xenopus laevis, already in four-day old tadpoles asymmetric organ arrangement is visible. This coordinated organ development strictly requires prior Nodal cascade activity in the left lateral plate mesoderm (LPM) in all model organisms examined so far. The initial symmetry breaking event necessary for unilateral induction of Nodal signaling is still under debate. In X. laevis, two models, namely 'ion-flux' and 'cilia-driven leftward fluid flow', were discussed in this context. Leftward flow was first described in the mouse model and later on in fish and rabbit, whereas the 'ion-flux' hypothesis is supported by data derived from chick development. In the present work it was intended to enlighten this putative discrepancy by re-investigating the function of two 'ion-flux' components in context of leftward flow in the model organism X. laevis. First, a link between cell-cell communication via gap junctional communication (GJC)and LR axis establishment was analyzed by using heptanol for general inhibition of channel conductance on the one hand, and single knock-down (KD) of specific subunits on the other hand. Both treatments resulted in absence of the left-sided Nodal cascade. The KD led to shorter GRP cilia when compared to wildtype embryos and loss of bilateral Nodal expression at the GRP margin, respectively. Furthermore, heptanol treatments of stages in which the GRP already has been fully developed also resulted in laterality defects, thus implying a second function of GJC most likely for the signal transfer to the left side. These results indicated a role of GJC in leftward flow establishment and/or post-flow in neurula stages rather than a function in early cleavage stages for LR determination. Second, the early signaling function of the neurotransmitter serotonin (5-HT) was inhibited by over-expression of either a frog or a human receptor ligand binding domain(LBD). In addition, specific KD of a receptor class 3 subunit was performed. Both applications resulted in impaired left-sided marker gene expression and disturbed GRP morphogenesis. Remarkably, marker gene expression of the superficial mesoderm(SM) which gives rise to the GRP during development, was reduced in 5-HT signaling impaired embryos. Very importantly, receptor 3 specific 5-HT signaling was shown to represent a necessary competence factor required for Wnt-dependent axis development in the frog double axis induction assay. Besides the new function of 5-HT during early development, it was further shown that the expression of the SM marker Foxj1 (a master regulator of motile cilia) depended on maternal factors. Based on the work presented here, the following model is proposed: (1) Foxj1 expression is induced maternally, followed by (2) zygotic refinement in post-MBT stages, i.e. inhibition on the ventral and maintenance on the dorsal side. In the organizer region, an interplay of Wnt and 5-HT signaling is required for dorsal development.(3) Cilia driven leftward flow initiate an unknown downstream signal which is transferred to the left LPM. Both events, leftward flow and transfer, require active GJC. (4) A to date unknown signal gets transferred towards the left LPM in a GJC-dependent process and induces the Nodal cascade activity, a prerequisite for proper organ arrangement. Taken together, the data presented in this study indicate that the directed fluid flow in neurula embryos represent the decisive step for symmetry breakage with the 'ion-flux' components being involved in correct flow function.
Towards a unifying model of symmetry breakage in Xenopus laevis : serotonin signaling and the cilia-driven leftward flow
(2011) Thumberger, Thomas; Blum, Martin
Orientation of the three vertebrate body axes anterior-posterior (AP), dorso-ventral (DV) and left-right (LR) is specified during early embryogenesis. Whereas the formation of the AP and DV axes is well understood, it is not finally resolved how and when the left and right sides get molecularly distinct. All deuterostomes analyzed so far, however, display an asymmetric left-sided expression of the TGF-β factor Nodal during embryonic development which precedes asymmetric organogenesis. In zebrafish, medaka, mouse and rabbit embryos a cilia-driven extracellular leftward fluid flow was shown to be causal for the left asymmetric induction of the Nodal gene cascade during early neurulation. In X. laevis, leftward flow was also shown to be driven by a mono-ciliated epithelium in the posterior part of the archenteron roof (gastrocoel roof plate, GRP). Mechanical blockage of this current resulted in laterality defects. Despite the apparent evolutionary conservation of flow, an earlier mechanism to specify the LR axis during early cleavage stages has been reported in X. laevis. Based on mostly inhibitor experiments, the so-called 'ion-flux' hypothesis was put forward which proposes an electrogenic transport and asymmetric accumulation of determinants as early as at the 32-64 cell stage. The monoamine serotonin is the core-effector of this hypothesis and was reported to asymmetrically accumulate at the ventral right blastomeres of early cleavage stage embryos. The aim of this study was to investigate putative interactions of the two apparently opposing mechanisms for breaking the initial LR symmetry of the Xenopus zygote. Reinvestigation of serotonin localization could not confirm the initial report. Further, serotonin signaling was shown to be necessary for LR axis formation on the dorsal but not ventral side, more specifically as a competence factor for the canonical Wnt-pathway. Detailed analyses of specimens impaired for serotonin signaling revealed requirement of serotonin signaling for specification of the superficial mesoderm (SM) which gives rise to the GRP and, consequently, to leftward flow. Leftward flow thus indirectly depends on dorsal serotonin signaling. In a further part of the present thesis, a re-examination of laterality in Siamese twins was performed. It has been known since the earliest experimental investigations of laterality that in induced and naturally occurring Siamese twins the left twin consistently displays wildtype orientation of the visceral organs whereas the orientation in the right twin is randomized. In experimentally induced conjoined twins, this observation holds true regardless of which twin is the induced. A model of symmetry breakage, in order to be plausible, thus should also be able to account for this phenomenon. When experimentally induced twins were analyzed for leftward flow, in the majority of cases a continuous leftward flow was observed, i.e. both twins shared one GRP. Thus, laterality cue(s) get translocated towards the far left side, i.e. only the left embryo receives the wildtype asymmetric information, regardless if it is the induced or endogenous twin. In rare case X. laevis conjoined axes developed far apart from one another such that two separate GRPs and individual leftward flows were observed, a condition that enabled both axes to exhibit a left-sided Nodal cascade. These experiments strongly suggest that Spemann's organizer itself is necessary and sufficient to establish all three body axes. In conclusion, the present analysis of laterality determination in the frog Xenopus supports evolutionary conservation of leftward flow as symmetry breaking event, as previously reported for mouse, rabbit and bony fish.
Untersuchungen des Einflusses von Chemotherapie auf Tumor-assoziierte Fibroblasten bei Karzinomen der Lunge und Brust in vivo und in verschiedenen ex vivo Modellen
(2009) Sonnenberg, Maike; Blum, Martin
Carcinomas are complex tissues in which the genetically altered epithelial tumor cells interact with their microenvironment, which plays a pivotal role in growth and survival of the whole tumor. Therefore, also the response of the tumor stroma may be important for the therapeutic success. The aim of the study was to clarify how tumor-associated fibroblasts (TAFs) respond to chemotherapy. We established a grading system for the activity of the TAFs based on cell counts and cell morphology within neoadjuvant treated breast cancer specimens. We compared both the stromal compartment and the tumor compartment before and after therapy to evaluate the response to chemotherapy. In this in vivo study a response of the stromal compartment was detected in samples with a high stromal activity grade before chemotherapy. To investigate the direct, more acute response of TAFs we established different ex vivo systems. On the one hand, the response to chemotherapy was tested in primary isolated TAFs from tumor tissue. On the other hand, a tissue slice culture was established to investigate the direct effect of the chemotherapy on TAFs and tumor cells within their intact microenvironment. For the cell culture experiments freshly isolated TAFs from breast and lung tumors were used. The chemosensitivity to Cisplatinum and Paclitaxel of the primary isolated TAFs was determined and compared with a panel of established human tumor cell lines. The TAFs turned out to be resistant to Paclitaxel, whereas they showed a heterogeneous response to Cisplatinum. One reason for this heterogeneous response to Cisplatinum could be the existence of somatic mutations and/or polymorphisms within DNA-damage response genes. Somatic mutations within the p53 tumor suppressor gene play a critical role in the response of tumor cells to chemotherapeutics. In this study, however, no somatic mutation was detected in any of the TAFs from lung. In other studies, different polymorphisms could be correlated with the sensitivity to cytotoxic stress. In this study, a non-significant trend towards the chemosensitivity of TAFs from lung carcinomas and the p53-Arg72Pro polymorphism could be observed, whereas the ERCC1-Asn118Asn und Mdm2-T/G309 polymorphisms had no influence on the chemosensitivity. The chemosensitivity of the TAFs was also determined within their microenvironment on the basis of tissue culture experiments performed with breast and lung carcinomas. Tumor tissue slices from breast carcinomas were treated for 72 h with Paclitaxel, whereas the tissue slices from lung carcinomas were treated with Cisplatinum. To investigate the response of the different cell types to the tested chemotherapeutic drugs within the intact microenvironment, the tissue slices were fixed and stained immunhistochemically for proliferative active and dead cells. Half of the cultivated tissue slices from breast carcinomas showed a decrease in cell counts of proliferating cells, whereas half of the cases showed an increase of dead cells after the treatment with Paclitaxel in tumor and stroma cells. The tissue slices of the lung carcinomas showed a decrease in proliferating tumor cells after Cisplatinum treatment in comparison to the untreated controls. The stroma compartment showed no proliferative activity so one could not expect a response regarding a decrease of proliferating stroma cells. Two cases showed a response to Cisplatinum regarding an increase in cell death in both cell compartments. Short term exposure to Paclitaxel led to a parallel reaction of both tumor and stromal cells in tissue culture experiments, whereas isolated TAFs from breast tumors turned out to be resistant to Paclitaxel. In contrast, isolated TAFs from lung carcinomas are significantly more sensitive to Cisplatinum than TAFs within their intact microenvironment. Consequently, the microenvironment of the tumor plays a crucial role in chemosensitivity. The central role of the microenvironment for response of TAFs to cytotoxic drugs is also demonstrated by the results obtained with lung cancer tissues. These observations indicate that, in addition to intrinsic factors, the microenvironment determines the sensitivity of TAFs to cytotoxic therapy. In summary, this work demonstrates for the first time, not only the tumor cells but also the stromal cells are an important target for the chemotherapy. Intrinsic and extrinsic factors play an important role in chemosensitivity. On the one hand, the tumor microenvironment is responsible for therapy response of TAFs and on the other hand the genotype may play a crucial role in chemosensitivity. Both, tumor and stroma cells react in parallel to chemotherapy, so you can assume that both cell types are responsible for the chemosensitivity. Some therapeutic approaches could be the inhibition of either the tumor or stromal cell compartment to increase the chemosensitivity of the whole tumor.