Project description:Molecular left-right (L-R) asymmetry is established at the node of the mouse embryo as a result of the sensing of a leftward fluid flow by immotile cilia of perinodal crown cells and the consequent degradation of Dand5 mRNA on the left side. We here examined how the fluid flow induces Dand5 mRNA decay. We found that the first 200 nucleotides in the 3' untranslated region (3'-UTR) of Dand5 mRNA are necessary and sufficient for the left-sided decay and to mediate the response of a 3’-UTR reporter transgene to Ca2+, the cation channel Pkd2, the RNA-binding protein Bicc1 and their regulation by the flow direction. We show that Bicc1 preferentially recognizes GACR and YGAC sequences, which can explain the specific binding to a conserved GACGUGAC motif located in the proximal Dand5 3'-UTR. The Cnot3 component of the Ccr4-Not deadenylase complex interacts with Bicc1 and is also required for Dand5 mRNA decay at the node. These results suggest that Ca2+ currents induced by leftward fluid flow stimulate Bicc1 and Ccr4-Not to mediate Dand5 mRNA degradation specifically on the left side of the node.

Project description:Non-syndromic facial asymmetry is commonly found in dentofacial deformity populations with skeletal malocclusions. Asymmetry of this type may result from imbalanced growth and function of both the jaw and associated muscles. Among the multiple genes that interact to affect the craniofacial musculoskeletal complex during pre and postnatal growth and development, NODAL signaling pathwy (NSP) genes are active in adult skeletal muscle and may be key factors in development, growth and maintenance of facial asymmetry. It is of interest to determine whether expression of NODAL pathway genes might differ in masseter muscles between individuals with malocclusion that have facial asymmetry and normal symmetry. Human Transcriptome 2.0 GeneChips (HTA2.0) were used to examine global gene expression in masster muscles between malocclusion subjects with posterior facial asymmetry and with normal facial symmetry. Eleven patients undergoing orthoganthic surgery were selected for comparison of masseter muscle gene expression on microarrays. Two subjects had posterior facial asymmetry (one with class II open bite and one with class III open bite malocclusion) and nine subjects had normal facial symmetry (three with class II open bite, two with class III open bite and four with class II deep bite malocclusion). RNA representative of total gene expression in masseter muscles of the malocclusion subjects with and without posterior facial asymmetry was prepared for labeling and hybridization on HTA2.0 chips. The two subjects with facial asymmetry clustered separately from eight other malocclusion subjects by a principle component analysis (PCA), even though one had a class II and the other a class III malocclusion. Sample 4L_Open_II is from a subject who has sleep apnea. Data from 4L_Open_II clustered independent of the asymmetry group and the eight other subjects of the symmetry group by PCA and was not included in analysis of differential expression with facial symmetry. Masseter muscles are paired jaw muscles (i.e. right and left masseter). In some cases, there was not sufficient quantity/quality of RNA from one side, thus the other side was used. Please note that the following information is provided in the 'source name' field of each sample record; subject ID number; either left or right masseter; J CRANIOFAC SURG_ID# corresponding to the data presented in the manuscript

Project description:Establishment of left-right (LR) asymmetry occurs shortly after gastrulation and utilizes a cascade of events. In the mouse, LR symmetry is broken at the node, involves signal relay to the lateral plate, and results in asymmetric organ morphogenesis. How information transmits from the node to the lateral plate remains unclear. Noting that embryos lacking Sox17 exhibit defects in both gut endoderm formation and LR patterning, we investigated a connection between these two processes. We noted an endoderm-specific absence of the critical gap junction component, Connexin43, in Sox17 mutants. Dye-coupling experiments revealed planar gap junction coupling across the gut endoderm in wild-type but not mutant embryos. The role for gap junction communication in LR patterning was confirmed by pharmacological inhibition. Collectively, our data demonstrate communication across gap junctions in gut endoderm as a mechanism for information relay between node and lateral plate critical for the establishment of LR asymmetry in mice. Total RNA isolated from embryonic regions of wild-type embryos at EHF stages, three samples per well, in triplicates

Project description:Establishment of left-right (LR) asymmetry occurs shortly after gastrulation and utilizes a cascade of events. In the mouse, LR symmetry is broken at the node, involves signal relay to the lateral plate, and results in asymmetric organ morphogenesis. How information transmits from the node to the lateral plate remains unclear. Noting that embryos lacking Sox17 exhibit defects in both gut endoderm formation and LR patterning, we investigated a connection between these two processes. We noted an endoderm-specific absence of the critical gap junction component, Connexin43, in Sox17 mutants. Dye-coupling experiments revealed planar gap junction coupling across the gut endoderm in wild-type but not mutant embryos. The role for gap junction communication in LR patterning was confirmed by pharmacological inhibition. Collectively, our data demonstrate communication across gap junctions in gut endoderm as a mechanism for information relay between node and lateral plate critical for the establishment of LR asymmetry in mice.

Project description:WGS of two individuals with developmental dyslexia and situs inversus.

Project description:Symmetry breaking in gastruloid development

Project description:Symmetry breaking in gastruloid development

Project description:Morphogenesis of vertebrate embryos requires extracellular matrix (ECM) in multiple developmental contexts1. Symmetry-breaking events in initially homogenous tissues trigger collective cellular dynamics which follow fluid-like behaviors, and the ECM, which is in constant engagement with morphing tissues, also undergoes fluid-like motion2–4. Cell and ECM deformations require coordination, however the interplay between them at cellular and tissue-scale remains largely unexplored. Here, we reveal a novel mechanism coupling morphogenetic events and epithelia-driven ECM flow. We show that exposure to ECM components triggers periodic morphogenesis of dome-shaped structures in human pluripotent stem cell monolayers, driven by directional ECM flow towards the sites of morphogenesis. We show that this flow is initiated by local symmetry-breaking events, is driven by microvilli and requires unperturbed flow conditions and cytoskeletal contractility. A theoretical model shows that a reaction-diffusion-like mechanism is responsible for organizing local morphogenesis into global tissue-wide events. The cell patterning landscape predicted by the model is experimentally recapitulated during mesoderm differentiation. We further validate ECM flow in 3D gastruloids and in quail embryos during primitive streak formation. These results uncover a new role for the ECM: in addition to being a site of cell adhesion, structural support and mechanical force generation5, as is currently established, we show that directional transport of ECM, termed ECM flow, is a major contributor in sustaining epithelial morphogenesis and differentiation.

Project description:Non-syndromic facial asymmetry is commonly found in dentofacial deformity populations with skeletal malocclusions. Asymmetry of this type may result from imbalanced growth and function of both the jaw and associated muscles. Among the multiple genes that interact to affect the craniofacial musculoskeletal complex during pre and postnatal growth and development, NODAL signaling pathwy (NSP) genes are active in adult skeletal muscle and may be key factors in development, growth and maintenance of facial asymmetry. It is of interest to determine whether expression of NODAL pathway genes might differ in masseter muscles between individuals with malocclusion that have facial asymmetry and normal symmetry. Human Transcriptome 2.0 GeneChips (HTA2.0) were used to examine global gene expression in masster muscles between malocclusion subjects with posterior facial asymmetry and with normal facial symmetry.

Project description:<p>Heterotaxy syndrome is a congenital anomaly syndrome accompanied by thoracic and abdominal situs abnormalities. The study cohort comprises of individuals with heterotaxy or related congenital heart disease (CHD) who have undergone exome sequencing. The purpose of the study is to elucidate the molecular genetics of the disorder as well as contribute to knowledge about the biology of normal and abnormal development of left-right anatomic asymmetry. These results will further help delineate genotype-phenotype associations and provide important information on the causes, management, and prognosis of heterotaxy syndrome.</p>