Browsing by Subject "Left-right organizer"

Now showing 1 - 3 of 3

Axes determination in the frog Xenopus laevis : the function of the goosecoid, myo1d and dmrt2
(2020) Tingler, Melanie Bianca; Schweickert, Axel
During early embryogenesis, pattern formation processes along the head-trunk (anteroposterior, AP), belly-back (dorsoventral, DV) and left-right (LR) body axis generate the fundamental body plan of the bilateria. The formation of the LR axis is exceptional because externally our body is bilateral symmetric whereas most inner organs are shaped and positioned asymmetrically. The three body axes are basically specified during gastrulation and neurulation by a set of developmental control genes. The aim of this work was to analyze the function of the highly conserved genes, goosecoid (gsc), myosin1d (myo1d) und dmrt2 during body axis determination in Xenopus. The first chapter of this work describes the activity of the homeobox transcription factor Goosecoid during AP- and DV-axis formation. Gsc acts as an autoregulatory transcriptional repressor and importantly is expressed in the Spemann Organizer (SO) of all vertebrate embryos. The SO represents the main dorsal signaling center for primary axis induction, regulates embryonic patterning and cell movements. It is further required for AP i.e. head and trunk development. Transferring of SO or gsc misexpression to ventral half of embryos resultes in secondary axis formation i.e. siamnese twins. However, SO function of Gsc was enigmatic, as gsc mutants showed no defects on early developmental processes what challenged Gsc function in the SO. In this chapter, gsc was characterized by conducting gain of function experiments in the embryonic midline of Xenopus embryos. Gsc was able to repress planar cell polarity (PCP) in a cell- and non-cell autonomous fashion leading to neural tube closure defects. In the early gastrulae, Gsc separates the head from the trunk mesoderm by repressing the mesodermal t-box gene transcription factor T (Tbxt). This inhibition allows the migration of the head mesodermal cells whereas the trunk notochord elongates by mediolateral intercalation. Gsc activity on PCP signaling seems to be specific for vertebrates only and correlates with the presence of two novel domains. The determination of the LR body axis is discussed in the second chapter of this work. At the so called left-right organizer (LRO) a cilia-mediated leftward-fluid flow initiates the symmetry breaking event in neurulae embryos. Lateral sensory cells (sLRO) of the LRO perceive flow on the left side and translate it into the left asymmetric induction of the highly conserved Nodal cascade. If and how the unconventional, actin-associated motor protein Myosin1d (Myo1d) as well as the transcription factor Doublesex and mab-3 related 2 (Dmrt2) intervene in LR specification was analyzed in this chapter. In evolutionary terms the study of myo1d was of high interest because in Drospohila, which lacks a ciliary flow mechanism, the homologous gene, myo31df, controls LR axis determination. Manipulations of myo1d in Xenopus demonstrated that in vertebrates Myo1d is involved in the cilia-based symmetry breakage event. By interacting with the PCP signaling pathway, Myo1d ensures leftward-fluid flow by regulating ciliary outgrowth and polarization. In Drosophila and Xenopus Myo1d interacts with PCP signaling and seems to link an ancestral symmetry breaking mechanism of the fly to the newly evolved leftward-fluid flow in vertebrates. Based on studies in zebrafish, which identified Dmrt2 as another factor involved in LR development and somitogenesis, we started the analysis of dmrt2 in Xenopus. Somitogenesis and laterality determination which on first sight are functionally distinct processes were analyzed in the context of dmrt2 function. In Xenopus, flow-sensing cells are affiliated to the somitic cell lineage and therefor paraxial mesoderm specification is crucial for setting up a functional LRO. Dmrt2 specifies the paraxial mesoderm and especially the sLRO by inducing the myogenic transcription factor myf5 in early gastrulae. This demonstrated for the first time experimentally how somitogenesis and laterality determination are intertwined and describes the genesis of the Xenopus sLRO cells in more detail.
Establishment of the body axes in Xenopus laevis through goosecoid, myosin 1d and bicaudal c
(2021) Maerker, Markus Ferdinand; Schweickert, Axel
The bilaterian body plan consists of three body axes: the anteroposterior (AP; head-trunk/tail), the dorsoventral (DV; back-belly) and the left-right (LR; placement of inner organs) axis. Axis formation occurs during early embryogenesis and is critical for further development and viability of the embryo. In this comprehensive study three highly conserved determinants were functionally analyzed in the context of axis development. The first chapter of this work covers the autoregulatory, homeodomain containing, repressor gene goosecoid (gsc), whose most prominent expression marks the Spemann-(Mangold) organizer (SO). The SO is the primary dorsal signaling center and is instructive for tissue patterning along the DV and AP axes. Transplanting the SO or misexpressing gsc on the opposite ventral side of an embryo is sufficient to establish a new/secondary AP axis. However, its function during normal development in the SO remained enigmatic as the gsc loss of function (LOF) lead to no severe early developmental defects. To elucidate the function of gsc, timed gain of function (GOF) experiments were performed. Gsc efficiently repressed the planar cell polarity (PCP)/Wnt signaling pathway leading to severe gastrulation and neurulation defects. This novel Gsc function was correlated with two vertebrate specific domains, suggesting an evolutionary new function of Gsc with the emergence of jaws/neural crests in vertebrates. The second chapter of this study addresses the functions of Myosin1d (Myo1d) and Bicaudal c1 (Bicc1) during the LR axis determination in vertebrates. In this group LR symmetry breakage takes place at a ciliated epithelium called LR organizer (LRO). The initial cue for the asymmetric LR axis development is a cilia-driven leftward fluid flow. These cilia have to be correctly polarized through PCP/Wnt signaling. Interestingly, the invertebrate Drosophila melanogaster also displays a distinct LR axis but uses a cilia independent, yet not fully understood, mechanism. It depends on a myo1d homologous gene, myo31DF, and PCP. To unravel a potential common evolutionary origin of the bilaterian LR axis myo1d was analyzed during Xenopus laevis lateralization. Myo1d LOF experiments disturbed LR axis formation by compromising PCP dependent outgrowth and polarization of LRO cilia. These experiments link the PCP/Myosin based mechanism of flies to the newly evolved cilia/flow dependent mode of vertebrate LR axis determination suggesting actomyosin as common ancestral LR determinant. Contrary to Myo1d, Bicc1 was already described for its function during polarization of flow producing LRO cilia. However bicc1s expression is most prominent in the sensory LRO cells (sLRO). These cells detect the fluid flow and translate it into left-sided signaling of the morphogen Nodal1 and consequently asymmetric LR axis formation. These cells downregulate the expression of the secreted Nodal1 antagonist DAN domain family member 5 (dand5) in response to flow. Bicc1s function was re-evaluated with respect to its function in sLRO cells. Ex vivo and in vivo experiments involving GOF as well as LOF experiments showed that Bicc1 regulates both dand5 and nodal1 via a direct and indirect post-transcriptional mechanism, respectively. In the process of dand5 regulation several other LR determinants and regulatory events were linked with the Bicc1 dependent mechanism: Dicer1 dependent microRNA repression of dand5 and a proposed cation channel Polycystin 2 mediated Bicc1 modification. These results highlight the importance of a tightly controlled Dand5 protein level as decisive for the overall outcome of the LR symmetry breakage in vertebrates.
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).