Notch1 is asymmetrically distributed from the beginning of embryogenesis and controls the ventral center.

Based on functional evidence, we have previously demonstrated that early ventral Notch1 activity restricts dorsoanterior development in Xenopus We found that Notch1 has ventralizing properties and abolishes the dorsalizing activity of ß-catenin by reducing its steady state levels, in a process that does not require ß-catenin phosphorylation by glycogen synthase kinase 3ß. In the present work, we demonstrate that Notch1 mRNA and protein are enriched in the ventral region from the beginning of embryogenesis in Xenopus This is the earliest sign of ventral development, preceding the localized expression of wnt8a, bmp4 and Ventx genes in the ventral center and the dorsal accumulation of nuclear ß-catenin. Knockdown experiments indicate that Notch1 is necessary for the normal expression of genes essential for ventral-posterior development. These results indicate that during early embryogenesis ventrally located Notch1 promotes the development of the ventral center. Together with our previous evidence, these results suggest that ventral enrichment of Notch1 underlies the process by which Notch1 participates in restricting nuclear accumulation of ß-catenin to the dorsal side.

The Chromatin Remodeling Protein Bptf Promotes Posterior Neuroectodermal Fate by Enhancing Smad2-Activated wnt8a Expression.

During vertebrate embryogenesis, the neuroectoderm is induced from dorsal ectoderm and then partitioned into anterior and posterior neuroectodermal domains by posteriorizing signals, such as Wnt and fibroblast growth factor. However, little is known about epigenetic regulation of posteriorizing gene expression. Here, we report a requirement of the chromatin remodeling protein Bptf for neuroectodermal posteriorization in zebrafish embryos. Knockdown of bptf leads to an expansion of the anterior neuroectoderm at the expense of the posterior ectoderm. Bptf functionally and physically interacts with p-Smad2, which is activated by non-Nodal TGF-ß signaling, to promote the expression of wnt8a, a critical gene for neural posteriorization. Bptf and Smad2 directly bind to and activate the wnt8a promoter through recruiting NURF remodeling complex. When bptf function or TGF-ß signal transduction is inhibited, the nucleosome density on the wnt8a promoter is increased. We propose that Bptf and TGF-ß/Smad2 mediate nucleosome remodeling to regulate wnt8a expression and hence neural posteriorization.

Wnt8a and Wnt3a cooperate in the axial stem cell niche to promote mammalian body axis extension.

BACKGROUND: Vertebrate body axis extension occurs in a head-to-tail direction from a caudal progenitor zone that responds to interacting signals. Wnt/ß-catenin signaling is critical for generation of paraxial mesoderm, somite formation, and maintenance of the axial stem cell pool. Body axis extension requires Wnt8a in lower vertebrates, but in mammals Wnt3a is required, although the anterior trunk develops in the absence of Wnt3a. RESULTS: We examined mouse Wnt8a(-/-) and Wnt3a(-/-) single and double mutants to explore whether mammalian Wnt8a contributes to body axis extension and to determine whether a posterior growth function for Wnt8a is conserved throughout the vertebrate lineage. We find that caudal Wnt8a is expressed only during early somite stages and is required for normal development of the anterior trunk in the absence of Wnt3a. During this time, we show that Wnt8a and Wnt3a cooperate to maintain Fgf8 expression and prevent premature Sox2 up-regulation in the axial stem cell niche, critical for posterior growth. Similar to Fgf8, Wnt8a requires retinoic acid (RA) signaling to restrict its caudal expression boundary and possesses an upstream RA response element that binds RA receptors. CONCLUSIONS: These findings provide new insight into interaction of caudal Wnt-FGF-RA signals required for body axis extension.

Post-transcriptional regulation of wnt8a is essential to zebrafish axis development.

wnt8a Is essential for normal patterning during vertebrate embryonic development, and either gain or loss-of-function gene dysregulation results in severe axis malformations. The zebrafish wnt8a locus is structured such that transcripts may possess two regulatory 3' untranslated regions (UTRs), raising the possibility of post-transcriptional regulation as an important mode of wnt8a signaling control. To determine whether both UTRs contribute to post-transcriptional wnt8a gene regulation, each UTR (UTR1 and UTR2) was tested in transient and transgenic reporter assays. Both UTRs suppress EGFP reporter expression in cis, with UTR2 exhibiting a more pronounced effect. UTR2 contains a 6 base sequence necessary for UTR2 regulatory function that is complementary to the seed of the microRNA, miR-430. A target protector morpholino that overlaps the seed complement stabilizes both reporter mRNAs and wnt8a mRNAs, and produces phenotypic abnormalities consistent with wnt8a gain-of-function. In rescue assays, specific functions can be attributed to each of the two wnt8a proteins encoded by the locus. An interplay of wnt8a.1 and wnt8a.2 regulates neural and mesodermal patterning and morphogenesis as well as patterning between brain subdivisions. Thus, post-transcriptional control of wnt8a is essential to fine tune the balance of the signaling outputs of the complex wnt8a locus.

Wnt8a is one of the candidate genes that play essential roles in the elongation of the seahorse prehensile tail.

Seahorses are a hallmark of specialized morphological features due to their elongated prehensile tail. However, the underlying genomic grounds of seahorse tail development remain elusive. Herein, we evaluated the roles of essential genes from the Wnt gene family for the tail developmental process in the lined seahorse (Hippocampus erectus). Comparative genomic analysis revealed that the Wnt gene family is conserved in seahorses. The expression profiles and in situ hybridization suggested that Wnt5a, Wnt8a, and Wnt11 may participate in seahorse tail development. Like in other teleosts, Wnt5a and Wnt11 were found to regulate the development of the tail axial mesoderm and tail somitic mesoderm, respectively. However, a significantly extended expression period of Wnt8a during seahorse tail development was observed. Signaling pathway analysis further showed that Wnt8a up-regulated the expression of the tail axial mesoderm gene (Shh), while interaction analysis indicated that Wnt8a could promote the expression of Wnt11. In summary, our results indicate that the special extended expression period of Wnt8a might promote caudal tail axis formation, which contributes to the formation of the elongated tail of the seahorse. Supplementary Information: The online version contains supplementary material available at 10.1007/s42995-021-00099-7.

Contribution of genetic and epigenetic mechanisms to Wnt pathway activity in prevalent skeletal disorders.

We reported previously that the expression of Wnt-related genes is lower in osteoporotic hip fractures than in osteoarthritis. We aimed to confirm those results by analyzing ß-catenin levels and explored potential genetic and epigenetic mechanisms involved. ß-Catenin gene expression and nuclear levels were analyzed by real time PCR and confocal immunofluorescence. Increased nuclear ß-catenin was found in osteoblasts isolated from patients with osteoarthritis (99 ± 4 units vs. 76 ± 12, p=0.01, n=10), without differences in gene transcription, which is consistent with a post-translational down-regulation of ß-catenin and decreased Wnt pathway activity. Twenty four single nucleotide polymorphisms (SNPs) of genes showing differential expression between fractures and osteoarthritis (WNT4, WNT10A, WNT16 and SFRP1) were analyzed in DNA isolated from blood of 853 patients. The genotypic frequencies were similar in both groups of patients, with no significant differences. Methylation of Wnt pathway genes was analyzed in bone tissue samples (15 with fractures and 15 with osteoarthritis) by interrogating a CpG-based methylation array. Six genes showed significant methylation differences between both groups of patients: FZD10, TBL1X, CSNK1E, WNT8A, CSNK1A1L and SFRP4. The DNA demethylating agent 5-deoxycytidine up-regulated 8 genes, including FZD10, in an osteoblast-like cell line, whereas it down-regulated other 16 genes. In conclusion, Wnt activity is reduced in patients with hip fractures, in comparison with those with osteoarthritis. It does not appear to be related to differences in the allele frequencies of the Wnt genes studied. On the other hand, methylation differences between both groups could contribute to explain the differences in Wnt activity.