The Pax3 and Pax7 paralogs cooperate in neural and neural crest patterning using distinct molecular mechanisms, in Xenopus laevis embryos

Pax3 and Pax7 paralogous genes have functionally diverged in vertebrate evolution, creating opportunity for a new distribution of roles between the two genes and the evolution of novel functions. Here we focus on the regulation and function of Pax7 in the brain and neural crest of amphibian embryos, which display a different pax7 expression pattern, compared to the other vertebrates already described. Pax7 expression is restricted to the midbrain, hindbrain and anterior spinal cord, and Pax7 activity is important for maintaining the fates of these regions, by restricting otx2 expression anteriorly. In contrast, pax3 displays broader expression along the entire neuraxis and Pax3 function is important for posterior brain patterning without acting on otx2 expression. Moreover, while both genes are essential for neural crest patterning, we show that they do so using two distinct mechanisms: Pax3 acts within the ectoderm which will be induced into neural crest, while Pax7 is essential for the inducing activity of the paraxial mesoderm towards the prospective neural crest.     

PTEN基因对早期胚胎神经嵴细胞迁移的作用研究

目的 初步探讨PTEN基因在早期神经嵴细胞迁移中的作用.方法 首先胚胎整体的原位杂交和免疫荧光方法检测鸡胚胎内源性的PTEN基因及蛋白水平的表达情况;其次,利用鸡胚胎体内半侧神经管转染的方法,使神经管一侧PTEN基因过表达,对侧神经管为正常对照侧;最后,通过Pax7的整体胚胎免疫荧光表达观察PTEN基因对其标记的部分神经嵴细胞迁移的影响.结果 内源性PTEN基因在mRNA和蛋白水平表达显示,其在早期胚胎HH4期的神经板即开始明显的表达;通过半侧过表达PTEN基因后观察到过表达PTEN基因侧的头部神经嵴细胞迁移与对照侧相比明显受到抑制,但对躯干部的影响并不明显.结论 PTEN基因可能抑制早期胚胎头部神经嵴细胞的迁移.     

Menin is required in cranial neural crest for palatogenesis and perinatal viability

Menin is a nuclear protein encoded by a tumor suppressor gene that is mutated in humans with multiple endocrine neoplasia type 1 (MEN1). Menin functions as a component of a histone methyltransferase complex that regulates expression of target genes including the cell cycle inhibitor p27^kip1. Here, we show that menin plays a previously unappreciated and critical role in cranial neural crest. Tissue-specific inactivation of menin in Pax3- or Wnt1-expressing neural crest cells leads to perinatal death, cleft palate and other cranial bone defects, which are associated with a decrease in p27^kip1 expression. Deletion of menin in Pax3-expressing somite precursors also produces patterning defects of rib formation. Thus, menin functions in vivo during osteogenesis and is required for palatogenesis, skeletal rib formation and perinatal viability.     

Combined function of HoxA and HoxB clusters in neural crest cells

The evolution of chordates was accompanied by critical anatomical innovations in craniofacial development, along with the emergence of neural crest cells. The potential of these cells to implement a craniofacial program in part depends upon the (non-)expression of Hox genes. For instance, the development of jaws requires the inhibition of Hox genes function in the first pharyngeal arch. In contrast, Hox gene products induce craniofacial structures in more caudal territories. To further investigate which Hox gene clusters are involved in this latter role, we generated HoxA;HoxB cluster double mutant animals in cranial neural crest cells. We observed the appearance of a supernumerary dentary-like bone with an endochondral ossification around a neo-Meckel's cartilage matrix and an attachment of neo-muscle demonstrating that HoxB genes enhance the phenotype induced by the deletion of the HoxA cluster alone. In addition, a cervical and hypertrophic thymus was associated with the supernumerary dentary-like bone, which may reflect its ancestral position near the filtrating system. Altogether these results show that the HoxA and HoxB clusters cooperated during evolution to lead to present craniofacial diversity.     

Bmp4 and Noggin expression during early thymus and parathyroid organogenesis

The thymus and parathyroids originate from the third pharyngeal pouches, which form as endodermal outpocketings in the pharyngeal region beginning on embryonic day 9 (E9.0) of mouse development. Using organ-specific markers, we have previously shown that thymus and parathyroid-specific organ domains are established within the primordium prior to formation of the organs proper: Gcm2 expression defines the prospective parathyroid cells in the dorsal pouch from E9.5, while Foxn1 is expressed in the thymus domain from E11.25. Bmp (bone morphogenetic protein) signaling has been implicated in thymic epithelial cell differentiation and thymus organogenesis. In the present study, we report expression patterns of Bmp4 and Noggin, a Bmp4 antagonist, in the third pharyngeal pouch using two lacZ transgenic mouse strains. Results from this gene expression study revealed localization of Bmp4 expression to the ventral region of the third pharyngeal pouch endoderm at E10.5 and E11.5, in those cells that will express Foxn1 and form the thymus. Conversely, the expression of Noggin was confined to the dorsal region of the pouch and primordium at these stages, and thus appeared to be co-expressed with Gcm2 in the parathyroid domain. This represents the first detailed study of Bmp4 and Noggin expression during the early stages of thymus and parathyroid organogenesis.     

Novel expression patterns of Pax3/Pax7 in early trunk neural crest and its melanocyte and non‐melanocyte lineages in amniote embryos

Neural crest cells are considered a key vertebrate feature that is studied intensively because of their relevance to development and evolution. Here we report the expression of Pax7 in the dorsal non‐neural ectoderm and in the trunk neural crest of the early chick embryo. Pax7 is expressed in the trunk neural crest migrating along the ventral and dorsolateral routes. Pax7 is first downregulated in the neural crest‐derived neuronal precursors, secondly in the glial, and finally in the melanocyte precursors. Conserved developmental expression in the melanocyte lineage of both Pax3 and Pax7 was evidenced in chick and quail, but only Pax3 in mouse and rat.     

Increased BNip3 and decreased mutant p53 in cisplatin-sensitive PDT-resistant HT29 cells

We have reported previously the isolation of three photodynamic therapy (PDT)-resistant human colon carcinoma HT29 cell lines that show increased expression of the Hsp27 and BNip3 protein and a decreased expression of the mutant p53 protein compared to parental HT29 cells. Since mutant p53 and increased expression of Hsp27 have been associated with resistance to various chemotherapeutic agents, whereas BNip3 is a potent inducer of apoptosis, we were interested in determining whether these PDT-resistant cells were cross-resistant to other cytotoxic agents. We report here that the PDT-resistant HT29 cell lines showed a significant increase in cisplatin sensitivity and an increase in both spontaneous and cisplatin-induced apoptosis compared to parental HT29 cells. In addition, the cisplatin sensitivity of the PDT-resistant HT29 variants and several other clonal variants of HT29 cells correlated with increased BNip3 and decreased mutant p53 protein levels, but not Hsp27 protein levels.     

Xenopus Meis3 protein lies at a nexus downstream to Zic1 and Pax3 proteins, regulating multiple cell-fates during early nervous system development

In Xenopus embryos, XMeis3 protein activity is required for normal hindbrain formation. Our results show that XMeis3 protein knock down also causes a loss of primary neuron and neural crest cell lineages, without altering expression of Zic, Sox or Pax3 genes. Knock down or inhibition of the Pax3, Zic1 or Zic5 protein activities extinguishes embryonic expression of the XMeis3 gene, as well as triggering the loss of hindbrain, neural crest and primary neuron cell fates. Ectopic XMeis3 expression can rescue the Zic knock down phenotype. HoxD1 is an XMeis3 direct-target gene, and ectopic HoxD1 expression rescues cell fate losses in either XMeis3 or Zic protein knock down embryos. FGF3 and FGF8 are direct target genes of XMeis3 protein and their expression is lost in XMeis3 morphant embryos. In the genetic cascade controlling embryonic neural cell specification, XMeis3 lies below general-neuralizing, but upstream of FGF and regional-specific genes. Thus, XMeis3 protein is positioned at a key regulatory point, simultaneously regulating multiple neural cell fates during early vertebrate nervous system development.     

The mouse Dlx-2 (Tes-1) gene is expressed in spatially restricted domains of the forebrain, face and limbs in midgestation mouse embryos

The pattern of RNA expression of the murine Dlx-2 (Tes-1) homeobox gene is described in embryos ranging in age from E8.5 through E11.5. Dlx-2 is a vertebrate homologue of the Drosophila Distal-less (Dll) gene. Dll expression in the Drosophila embryo is principally limited to the primordia of the brain, head and limbs. Dlx-2 is also expressed principally in the primordia of the forebrain, head and limbs. Within these regions it is expressed in spatially restricted domains. These include two discontinuous regions of the forebrain (basal telencephalon and ventral diencephalon), the branchial arches, facial ectoderm, cranial ganglia and limb ectoderm. Several mouse and human disorders have phenotypes which potentially are the result of mutations in the Dlx genes.     

The avian embryo as a model to study the development of the neural crest: a long and still ongoing story

The aim of this review is to evoke briefly the progress that has been made in our knowledge about the contribution of the neural crest to the vertebrate body since it was discovered by Wilhelm His in 1868. Although first studied essentially in amphibian embryos, a large amount of what is known on this very special structure was gained by experimental work carried out on the avian embryo. The making of chimeras between quail and chick has permitted not only to analyse the normal course of neural crest cell migration and differentiation but also to reveal some of the cellular interactions that regulate these events. Looking to the future, we can foresee that the novel methods, which now allow to manipulate gene activities in definite groups of cells and at elected times in the developing embryo, will make the avian model even more instrumental than ever to approach the developmental problems raised by neural crest cell differentiation.     

A fate-map for cranial sensory ganglia in the sea lamprey

Cranial neurogenic placodes and the neural crest make essential contributions to key adult characteristics of all vertebrates, including the paired peripheral sense organs and craniofacial skeleton. Neurogenic placode development has been extensively characterized in representative jawed vertebrates (gnathostomes) but not in jawless fishes (agnathans). Here, we use in vivo lineage tracing with DiI, together with neuronal differentiation markers, to establish the first detailed fate-map for placode-derived sensory neurons in a jawless fish, the sea lamprey Petromyzon marinus, and to confirm that neural crest cells in the lamprey contribute to the cranial sensory ganglia. We also show that a pan-Pax3/7 antibody labels ophthalmic trigeminal (opV, profundal) placode-derived but not maxillomandibular trigeminal (mmV) placode-derived neurons, mirroring the expression of gnathostome Pax3 and suggesting that Pax3 (and its single Pax3/7 lamprey ortholog) is a pan-vertebrate marker for opV placode-derived neurons. Unexpectedly, however, our data reveal that mmV neuron precursors are located in two separate domains at neurula stages, with opV neuron precursors sandwiched between them. The different branches of the mmV nerve are not comparable between lampreys and gnatho-stomes, and spatial segregation of mmV neuron precursor territories may be a derived feature of lampreys. Nevertheless, maxillary and mandibular neurons are spatially segregated within gnathostome mmV ganglia, suggesting that a more detailed investigation of gnathostome mmV placode development would be worthwhile. Overall, however, our results highlight the conservation of cranial peripheral sensory nervous system development across vertebrates, yielding insight into ancestral vertebrate traits.     

Cell-autonomous and nonautonomous actions of endothelin-A receptor signaling in craniofacial and cardiovascular development

Craniofacial and cardiac development relies on the proper patterning of the neural crest-derived ectomesenchyme of the pharyngeal arches, from which many craniofacial and great vessel structures arise. One of the intercellular signaling molecules that is involved in this process, endothelin-1 (ET-1), is expressed in the arch epithelium and influences arch development by binding to its cognate receptor, the endothelin A (ET(A)) receptor, found on ectomesenchymal cells. We have previously shown that absence of ET(A) signaling in ET(A)(-/-) mouse embryos disrupts neural crest cell development, resulting in craniofacial and cardiovascular defects similar in many aspects to those in mouse models of DiGeorge syndrome. These changes may reflect a cell-autonomous requirement for ET(A) signaling during crest cell development because the ET(A) receptor is an intracellular signaling molecule. However, it is also possible that some of the observed defects in ET(A)(-/-) embryos could arise from the absence of downstream signaling that act in a non-cell-autonomous manner. To address this question, we performed chimera analysis using ET(A)(-/-) embryonic stem cells. We observe that, in almost all early ET(A)(-/-) --> (+/+) chimeric embryos, ET(A)(-/-) cells are excluded from the caudoventral aspects of the pharyngeal arches, suggesting a cell-autonomous role for ET(A) signaling in crest cell migration and/or colonization. Interestingly, in the few embryos in which mutant cells do reach the ventral arch, structures derived from this area are either composed solely of wild type cells or are missing, suggesting a second cell-autonomous role for ET(A) signaling in postmigratory crest cell differentiation. In the cardiac outflow tract and great vessels, ET(A)(-/-) cells are excluded from the walls of the developing pharyngeal arch arteries, indicating that ET(A) signaling also acts cell-autonomously during cardiac neural crest cell development.