Project description:During development, Hox genes are activated in a time sequence following their relative positions on their clusters, leading to the proper identities of structures along the rostral to caudal axis. To understand the mechanism operating this Hox timer, we used ES-cells derived stembryos and show that the core of the process involves the start of transcription at the anterior part of the cluster, following Wnt signaling, and a concomitant loading of cohesin complexes enriched on the transcribed DNA segments, i.e., with an asymmetric distribution in favor of the anterior part the gene cluster. Chromatin extrusion then occurs with, along with time, successively more posterior CTCF sites acting as transient insulators, thus generating a progressive time-delay in the activation of more posterior-located genes due to long-range contacts with a flanking TAD. Mutant stembryos support this model and reveal that the iterated presence of evolutionary conserved and regularly spaced intergenic CTCF sites control the precision and the pace of this temporal mechanism.

Project description:During development, Hox genes are activated in a time sequence following their relative positions on their clusters, leading to the proper identities of structures along the rostral to caudal axis. To understand the mechanism operating this Hox timer, we used ES-cells derived stembryos and show that the core of the process involves the start of transcription at the anterior part of the cluster, following Wnt signaling, and a concomitant loading of cohesin complexes enriched on the transcribed DNA segments, i.e., with an asymmetric distribution in favor of the anterior part the gene cluster. Chromatin extrusion then occurs with, along with time, successively more posterior CTCF sites acting as transient insulators, thus generating a progressive time-delay in the activation of more posterior-located genes due to long-range contacts with a flanking TAD. Mutant stembryos support this model and reveal that the iterated presence of evolutionary conserved and regularly spaced intergenic CTCF sites control the precision and the pace of this temporal mechanism.

Project description:During development, Hox genes are activated in a time sequence following their relative positions on their clusters, leading to the proper identities of structures along the rostral to caudal axis. To understand the mechanism operating this Hox timer, we used ES-cells derived stembryos and show that the core of the process involves the start of transcription at the anterior part of the cluster, following Wnt signaling, and a concomitant loading of cohesin complexes enriched on the transcribed DNA segments, i.e., with an asymmetric distribution in favor of the anterior part the gene cluster. Chromatin extrusion then occurs with, along with time, successively more posterior CTCF sites acting as transient insulators, thus generating a progressive time-delay in the activation of more posterior-located genes due to long-range contacts with a flanking TAD. Mutant stembryos support this model and reveal that the iterated presence of evolutionary conserved and regularly spaced intergenic CTCF sites control the precision and the pace of this temporal mechanism.

Project description:During development, Hox genes are activated in a time sequence following their relative positions on their clusters, leading to the proper identities of structures along the rostral to caudal axis. To understand the mechanism operating this Hox timer, we used ES-cells derived stembryos and show that the core of the process involves the start of transcription at the anterior part of the cluster, following Wnt signaling, and a concomitant loading of cohesin complexes enriched on the transcribed DNA segments, i.e., with an asymmetric distribution in favor of the anterior part the gene cluster. Chromatin extrusion then occurs with, along with time, successively more posterior CTCF sites acting as transient insulators, thus generating a progressive time-delay in the activation of more posterior-located genes due to long-range contacts with a flanking TAD. Mutant stembryos support this model and reveal that the iterated presence of evolutionary conserved and regularly spaced intergenic CTCF sites control the precision and the pace of this temporal mechanism.

Project description:Differential Hox gene expression is central for specification of axial neuronal diversity in the spinal cord. Here, we uncover an additional function of Hox proteins in the developing spinal cord, restricted to B cluster Hox genes. We found that members of the HoxB cluster are expressed in the trunk neural tube of chicken embryo earlier than Hox from the other clusters, with poor antero-posterior axial specificity and with overlapping expression in the intermediate zone (IZ). Gain-of-function experiments of HoxB4, HoxB8 and HoxB9, respectively representative of anterior, central, and posterior HoxB genes, resulted in ectopic progenitor cells in the mantle zone. The search for HoxB8 downstream targets in the early neural tube identified the Leucine Zipper Tumor Suppressor 1 gene (Lzts1), which expression is also activated by HoxB4 and HoxB9. Gain and loss of function experiments showed that Lzts1, expressed endogenously in the IZ, controls neuronal delamination. These data collectively indicate that HoxB genes have a generic function in the developing spinal cord, controlling the expression of Lzts1 and neuronal delamination.

Project description:Temporal and spatial colinear expression of Hox genes determines the specification of positional identities of the embryo. Post-translational modifications of histones contribute to transcriptional regulation, and are required for proper control of biological processes, including differentiation and development. Lysine demethylase 7A (Kdm7a) demethylates lysine 9 di-methylation of histone H3 (H3K9me2) and participates in transcriptional activation of developmental genes. However, the role of Kdm7a during mouse embryonic development remains to be elucidated. Here, we show that Kdm7a-/- mice exhibit anterior homeotic transformation of the axial skeleton (i.e. an increase in the number of presacral elements). Importantly, posterior Hox genes (caudally from Hox9) are specifically down-regulated in Kdm7a-/- embryos, which correlate with increased levels of H3K9me2. Taken together, these data suggest that Kdm7a is able to control transcription of posterior Hox genes, likely through its demethylating activity, and thereby regulating anterior-posterior development in mice.

Project description:Temporal and spatial colinear expression of Hox genes determines the specification of positional identities of the embryo. Post-translational modifications of histones contribute to transcriptional regulation, and are required for proper control of biological processes, including differentiation and development. Lysine demethylase 7A (Kdm7a) demethylates lysine 9 di-methylation of histone H3 (H3K9me2) and participates in transcriptional activation of developmental genes. However, the role of Kdm7a during mouse embryonic development remains to be elucidated. Here, we show that Kdm7a-/- mice exhibit anterior homeotic transformation of the axial skeleton (i.e. an increase in the number of presacral elements). Importantly, posterior Hox genes (caudally from Hox9) are specifically down-regulated in Kdm7a-/- embryos, which correlate with increased levels of H3K9me2. Taken together, these data suggest that Kdm7a is able to control transcription of posterior Hox genes, likely through its demethylating activity, and thereby regulating anterior-posterior development in mice.

Project description:Background: Freshwater planarians are well known for their regenerative abilities. Less well known is how planarians maintain spatial patterning in long-lived adult animals or how they re-pattern tissues during regeneration. HOX genes are good candidates to regulate planarian spatial patterning, yet the full complement or genomic clustering of planarian HOX genes has not yet been described, primarily because only a few have been detectable by in situ hybridization, and none have given morphological phenotypes when knocked down by RNAi. Results: Because the planarian Schmidtea mediterranea (S. med) is unsegmented, appendage-less, and morphologically simple, it has been proposed that it may have a simplified HOX gene complement. Here we argue against this hypothesis and show that S. med has a total of 13 HOX genes, which represent homologs to all major axial categories, and can be detected by whole-mount in situ hybridization using a highly-sensitive method. In addition, we show that planarian HOX genes do not cluster in the genome, yet 5/13 have retained aspects of axially-restricted expression. Finally, we confirm HOX gene axial expression by RNA-deep-sequencing 6 anterior-to-posterior “zones” of the animal, which we provide as a dataset to the community to discover other axially-restricted transcripts. Conclusions: Freshwater planarians have an unappreciated HOX gene complexity, with all major axial categories represented. However, we conclude based on adult expression patterns that planarians have a derived body plan and their asexual lifestyle may have allowed for large changes in HOX expression from the last common ancestor between arthropods, flatworms, and vertebrates. Using our in situ method and axial zone RNAseq data, it should be possible to further understand the pathways that pattern the anterior-posterior axis of adult planarians.

Project description:Hox genes are essential regulators of embryonic development. They are activated in a temporal sequence following their topological order within their genomic clusters. Subsequently, states of activity are fine-tuned and maintained to translate into domains of progressively overlapping gene products. While the mechanisms underlying such temporal and spatial progressions begin to be understood, many of their aspects remain unclear. We have systematically analyzed the 3D chromatin organization of Hox clusters in vivo, during their activation using high-resolution circular chromosome conformation capture (4C-seq). Initially, Hox clusters are organized as single 3D chromatin compartments decorated with bivalent chromatin marks. Their progressive transcriptional activation is associated with a dynamic bi-modal 3D organization, whereby the genes switch one after the other, from an inactive to an active 3D compartment. These local 3D dynamics occur within a larger constitutive framework of interactions within the surrounding Topological Associated Domains, which confirms previous results that regulation of this process in primarily cluster intrinsic. The local step-wise progression in time can be stopped and memorized at various body levels and hence it may accounts for the various chromatin architectures previously described at different anterior to posterior body levels for the same embryo at a later stage. Circular Chromosome Conformation Capture (4C-seq) samples from mouse ES cells and mouse embryonic samples at different stages of development. Data based on 41 biological samples.

Project description:Hox genes are essential regulators of embryonic development. They are activated in a temporal sequence following their topological order within their genomic clusters. Subsequently, states of activity are fine-tuned and maintained to translate into domains of progressively overlapping gene products. While the mechanisms underlying such temporal and spatial progressions begin to be understood, many of their aspects remain unclear. We have systematically analyzed the 3D chromatin organization of Hox clusters in vivo, during their activation using high-resolution circular chromosome conformation capture (4C-seq). Initially, Hox clusters are organized as single 3D chromatin compartments decorated with bivalent chromatin marks. Their progressive transcriptional activation is associated with a dynamic bi-modal 3D organization, whereby the genes switch one after the other, from an inactive to an active 3D compartment. These local 3D dynamics occur within a larger constitutive framework of interactions within the surrounding Topological Associated Domains, which confirms previous results that regulation of this process in primarily cluster intrinsic. The local step-wise progression in time can be stopped and memorized at various body levels and hence it may accounts for the various chromatin architectures previously described at different anterior to posterior body levels for the same embryo at a later stage. RNA-seq from mouse ES cells and mouse embryonic stage E10.5 forebrain. Data based on 2 biological samples.