Neural crest cell deficiency of c-myc causes skull and hearing defects

The proto-oncogene c-myc has a central role in multiple processes important for embryonic development, including cell proliferation, growth, apoptosis, and differentiation. We have investigated the role of c-myc in neural crest by using Wnt1-Cre-mediated deletion of a conditional mutation of the c-myc gene. c-myc deficiency in neural crest resulted in viable adult mice that have defects in coat color, skull frontal bone, and middle ear ossicle development. Physiological hearing studies demonstrated a significant hearing deficit in the mutant mice. In this report, we focus on the craniofacial and hearing defects. To further examine neural crest cells affected by c-myc deficiency, we fate mapped Wnt1-Cre expressing neural crest cells using the ROSA26 Cre reporter transgene. The phenotype obtained demonstrates the critical role that c-myc has in neural crest during craniofacial development as well as in providing a model for examining human congenital skull defects and deafness.     

Cell migration, pattern formation and cell fate during head development in lungfishes and amphibians

Summary In the evolution of land-living vertebrates, the transition from spending the entire life cycle in the water to first a biphasic (adult on land, eggs and larvae in water) and later a terrestrial life-history mode was achieved by changes in developmental processes and regulatory mechanisms. Lungfishes, salamanders and frogs are studied as examples of species which span this transition. The migration and fate of the embryonic cells that form the head is studied, using experimental embryology (extirpation and transplantation of cells), molecular markers and novel microscopy techniques — such as confocal microscopy. Knowing the migratory routes and fates of the cells that form head structures is important for an elucidation of the changes that took place e.g. when gill arches transformed into head cartilages, and when the specialised larval mouth structures present in today’s frogs and toads arose as an evolutionary innovation. Results so far indicate that the early migration and pattern formation of neural crest cells in the head region is surprisingly conserved. Both the amphibians investigated and the Australian lungfish have the same number of migrating neural crest streams, and the identity of the streams is preserved. The major difference lies in the timing of migration, where there has been a heterochronic shift such that cell migration starts much later in the Australian lungfish than in the amphibians. The molecular mechanisms regulating the formation of streams of cranial neural crest cells seem, at least in part, to be differential expression of ephrins and ephrin receptors, which mediate cell sorting. Our understanding of the behaviour of migrating cells (primarily the more well characterised neural crest cells) could be enhanced by a modelling approach. I present preliminary ideas on how this could be achieved, inspired by recent work on Dictyostelium development and our own previous work on pigment cells and their pattern formation during salamander embryogenesis.     

Requirement for Twist1 in frontonasal and skull vault development in the mouse embryo

Using a Cre-mediated conditional deletion approach, we have dissected the function of Twist1 in the morphogenesis of the craniofacial skeleton. Loss of Twist1 in neural crest cells and their derivatives impairs skeletogenic differentiation and leads to the loss of bones of the snout, upper face and skull vault. While no anatomically recognizable maxilla is formed, a malformed mandible is present. Since Twist1 is expressed in the tissues of the maxillary eminence and the mandibular arch, this finding suggests that the requirement for Twist1 is not the same in all neural crest derivatives. The effect of the loss of Twist1 function is not restricted to neural crest-derived bones, since the predominantly mesoderm-derived parietal and interparietal bones are also affected, presumably as a consequence of lost interactions with neural crest-derived tissues. In contrast, the formation of other mesodermal skeletal derivatives such as the occipital bones and most of the chondrocranium are not affected by the loss of Twist1 in the neural crest cells.     

Differential Distribution of Retinoic Acid Synthesis in the Chicken Embryo as Determined by Immunolocalization of the Retinoic Acid Synthetic Enzyme, RALDH-2

Retinaldehyde dehydrogenase type 2 (RALDH-2) is a major retinoic acid generating enzyme in the early embryo. Here we report the immunolocalization of this enzyme (RALDH-2-IR) in stage 6-29 chicken embryos; we also show that tissues that exhibit strong RALDH-2-IR in the embryo contain RALDH-2 and synthesize retinoic acid. RALDH-2-IR indicates dynamic and discrete patterns of retinoic acid synthesis in the embryo, particularly within the somitic mesoderm, lateral mesoderm, kidney, heart, and spinal motor neurons. Prior to somitogenesis, RALDH-2-IR is present in the paraxial mesoderm with a rostral boundary at the level of the presumptive first somite; as the somites form, they exhibit strong RALDH-2-IR. Cervical presomitic mesoderm exhibits RALDH-2-IR but thoracic presomitic mesoderm does not. Neural crest cells do not express detectable levels of RALDH-2, but migrating crest cells are associated with RALDH-2 expressing mesoderm. The developing limb mesoderm expresses little RALDH-2-IR; however, RALDH-2-IR is strongly expressed in tissues adjacent to the limb. The most lateral, earliest-projecting motor neurons at all levels of the spinal cord exhibit RALDH-2-IR. Subsequently, many additional motor neurons in the brachial and lumbar cord regions express RALDH-2-IR. Motor neuronal expression of RALDH-2-IR is present in the growing axons as they extend to the periphery, indicating a potential role of retinoic acid in nerve influences on peripheral differentiation. With the exception of a transient expression in the facial/vestibulocochlear nucleus, cranial motor neurons do not express detectable levels of RALDH-2-IR.     

Cranial cartilages: Players in the evolution of the cranium during evolution of the chordates in general and of the vertebrates in particular

The present contribution is chiefly a review, augmented by some new results on amphioxus and lamprey anatomy, that draws on paleontological and developmental data to suggest a scenario for cranial cartilage evolution in the phylum chordata. Consideration is given to the cartilage-related tissues of invertebrate chordates (amphioxus and some fossil groups like vetulicolians) as well as in the two major divisions of the subphylum Vertebrata (namely, agnathans, and gnathostomes). In the invertebrate chordates, which can be considered plausible proxy ancestors of the vertebrates, only a viscerocranium is present, whereas a neurocranium is absent. For this situation, we examine how cartilage-related tissues of this head region prefigure the cellular cartilage types in the vertebrates. We then focus on the vertebrate neurocranium, where cyclostomes evidently lack neural-crest derived trabecular cartilage (although this point needs to be established more firmly). In the more complex gnathostome, several neural-crest derived cartilage types are present: namely, the trabecular cartilages of the prechordal region and the parachordal cartilage the chordal region. In sum, we present an evolutionary framework for cranial cartilage evolution in chordates and suggest aspects of the subject that should profit from additional study.     

Specific and spatial labeling of P0‐Cre versus Wnt1‐Cre in cranial neural crest in early mouse embryos

P0‐Cre and Wnt1‐Cre mouse lines have been widely used in combination with loxP‐flanked mice to label and genetically modify neural crest (NC) cells and their derivatives. Wnt1‐Cre has been regarded as the gold standard and there have been concerns about the specificity of P0‐Cre because it is not clear about the timing and spatial distribution of the P0‐Cre transgene in labeling NC cells at early embryonic stages. We re‐visited P0‐Cre and Wnt1‐Cre models in the labeling of NC cells in early mouse embryos with a focus on cranial NC. We found that R26‐lacZ Cre reporter responded to Cre activity more reliably than CAAG‐lacZ Cre reporter during early embryogenesis. Cre immunosignals in P0‐Cre and reporter (lacZ and RFP ) activity in P0‐Cre/R26‐lacZ and P0‐Cre/R26‐RFP embryos was detected in the cranial NC and notochord regions in E8.0–9.5 (4–19 somites) embryos. P0‐Cre transgene expression was observed in migrating NC cells and was more extensive in the forebrain and hindbrain but not apparent in the midbrain. Differences in the Cre distribution patterns of P0‐Cre and Wnt1‐Cre were profound in the midbrain and hindbrain regions, that is, extensive in the midbrain of Wnt1‐Cre and in the hindbrain of P0‐Cre embryos. The difference between P0‐Cre and Wnt1‐Cre in labeling cranial NC may provide a better explanation of the differential distributions of their NC derivatives and of the phenotypes caused by Cre‐driven genetic modifications.     

What's retinoic acid got to do with it? Retinoic acid regulation of the neural crest in craniofacial and ocular development

Retinoic acid (RA), the active derivative of vitamin A (retinol), is an essential morphogen signaling molecule and major regulator of embryonic development. The dysregulation of RA levels during embryogenesis has been associated with numerous congenital anomalies, including craniofacial, auditory, and ocular defects. These anomalies result from disruptions in the cranial neural crest, a vertebrate‐specific transient population of stem cells that contribute to the formation of diverse cell lineages and embryonic structures during development. In this review, we summarize our current knowledge of the RA‐mediated regulation of cranial neural crest induction at the edge of the neural tube and the migration of these cells into the craniofacial region. Further, we discuss the role of RA in the regulation of cranial neural crest cells found within the frontonasal process, periocular mesenchyme, and pharyngeal arches, which eventually form the bones and connective tissues of the head and neck and contribute to structures in the anterior segment of the eye. We then review our understanding of the mechanisms underlying congenital craniofacial and ocular diseases caused by either the genetic or toxic disruption of RA signaling. Finally, we discuss the role of RA in maintaining neural crest‐derived structures in postembryonic tissues and the implications of these studies in creating new treatments for degenerative craniofacial and ocular diseases.     

Crossing the frontier: a hypothesis for the origins of meristic constraint in mammalian axial patterning

Serially homologous systems with high internal differentiation frequently exhibit meristic constraints, although the developmental basis for constraint is unknown. Constraints in the counts of the cervical and lumbosacral vertebral series are unique to mammals, and appeared in the Triassic, early in their history. Concurrent adaptive modifications of the mammalian respiratory and locomotor systems involved a novel source of cells for muscularization of the diaphragm from cervical somites, and the loss of ribs from lumbar vertebrae. Each of these innovations increased the modularity of the somitic mesoderm, and altered somitic and lateral plate mesodermal interactions across the lateral somitic frontier. These developmental innovations are hypothesized here to constrain the anteroposterior transposition of the limbs along the column, and thus also cervical and thoracolumbar count. Meristic constraints are therefore regarded here as the nonadaptive, secondary consequences of adaptive respiratory and locomotor traits.     

Lipid interactions with in vitro development of mammalian zygotes

Rabbit zygotes were tested for their ability to sequester radiolabeled acetate, oleate, and arachidonate in intracellular lipid. Radiolabeled arachidonic acid was concentrated 170 ± 28-fold (mean ± SEM) and oleic acid was concentrated 105 ± 26-fold in zygotic lipids during 6 hr of culture when compared with the initial concentrations in culture medium. Acetate was not concentrated into lipids by cultured zygotes. Both long chain fatty acids were incorporated mainly as triglyceride. Polydimethylsiloxane fluid, used to cover the microdroplets of medium during culture, demonstrated lipophilic properties. This characteristic was utilized to indirectly transfer lipids to culture medium, permitting examination only of lipoidal properties of test extracts on embryonal development. For rabbit zygotes, blood plasma extract was detrimental and whole blood extract was beneficial for embryonal cleavage rates during the first 24 hr of culture. A higher proportion of mouse zygotes developed to blastocysts when cultured in modified Ham's F-10 medium compared to BMOC medium, and this difference was negated by inclusion of a lipid extract prepared from rabbit oviductal fluid in the culture system. Comparison of fatty acid analyses of the lipid extracts with development rates of zygotes suggests that modified rates of embryo development may be associated with ratios of individual fatty acids presented to the culture medium rather than with the presence of any single fatty acid.     

Vertebrate cranial evolution: Contributions and conflict from the fossil record

In modern vertebrates, the craniofacial skeleton is complex, comprising cartilage and bone of the neurocranium, dermatocranium and splanchnocranium (and their derivatives), housing a range of sensory structures such as eyes, nasal and vestibulo-acoustic capsules, with the splanchnocranium including branchial arches, used in respiration and feeding. It is well understood that the skeleton derives from neural crest and mesoderm, while the sensory elements derive from ectodermal thickenings known as placodes. Recent research demonstrates that neural crest and placodes have an evolutionary history outside of vertebrates, while the vertebrate fossil record allows the sequence of the evolution of these various features to be understood. Stem-group vertebrates such as Metaspriggina walcotti (Burgess Shale, Middle Cambrian) possess eyes, paired nasal capsules and well-developed branchial arches, the latter derived from cranial neural crest in extant vertebrates, indicating that placodes and neural crest evolved over 500 million years ago. Since that time the vertebrate craniofacial skeleton has evolved, including different types of bone, of potential neural crest or mesodermal origin. One problematic part of the craniofacial skeleton concerns the evolution of the nasal organs, with evidence for both paired and unpaired nasal sacs being the primitive state for vertebrates.     

Thickness of the normal skull in the American Blacks and Whites.

Normal skull thickness has been measured in a general hospital population of 300 blacks and 200 whites in America. In both groups, there is a rapid increase in skull thickness during the first two decades of life, followed by a small uniform increase reaching a peak in the fifth and sixth decades. The sex differences are variable, but in certain age groups the females in both races have significatly thicker parietal and occipital bones than their male counterpart. The frontal bone is thicker in the white male than in the black, and the parietooccipital thicker in the blacks than in the whites. Some suggestions are offered to explain the sex and racial difference noted.     

Irreversible effects of retinoic acid pulse on Xenopus jaw morphogenesis: new insight into cranial neural crest specification

Jaws are formed by cephalic neural crest (CNCCs) and mesodermal cells migrating to the first pharyngeal arch (PA1). A complex signaling network involving different PA1 components then establishes the jaw morphogenetic program. To gather insight on this developmental process, in this study, we analyze the teratogenic effects of brief (1–15 min) pulses of low doses of retinoic acid (RA: 0.25–2 µM) or RA agonists administered to early Xenopus laevis (X.l.) embryos. We show that these brief pulses of RA cause permanent craniofacial defects specifically when treatments are performed during a 6‐hr window (developmental stages NF15–NF23) that covers the period of CNCCs maintenance, migration, and specification. Earlier or later treatments have no effect. Similar treatments performed at slightly different developmental stages within this temporal window give rise to different spectra of malformations. The RA‐dependent teratogenic effects observed in Xenopus can be partially rescued by folinic acid. We provide evidence suggesting that in Xenopus, as in the mouse, RA causes craniofacial malformations by perturbing signaling to CNCCs. Differently from the mouse, where RA affects CNCCs only at the end of their migration, in Xenopus, RA has an effect on CNCCs during all the period ranging from their exit from the neural tube until their arrival in the PA1. Our findings provide a conceptual framework to understand the origin of individual facial features and the evolution of different craniofacial morphotypes. Birth Defects Res (Part B) 89:493–503, 2010. © 2010 Wiley‐Liss, Inc.     

J. P. Hill and Katherine Watson's studies of the neural crest in marsupials

In the early part of the 20th century, J. P. Hill and K. P. Watson embarked on a comprehensive study of the development of the brain in Australian marsupials. Their work included series from three major groups: dasyurids, peramelids, and diprotodonts, covering early primitive streak through brain closure and folding stages. While the major part of the work was on the development of the brain, in the course of this work they documented that cellular proliferations from the neural plate provided much of the mesenchyme of the branchial arches. These proliferations are now known to be the neural crest. However, except for a very brief note, published shortly after Hill's death, this work was never published. In this study, I present Hill and Watson's work on the development of the early neural plate and the neural crest in marsupials. I compare their findings with published work on the South American marsupial, Monodelphis domestica and demonstrate that patterns reported in Monodelphis are general for marsupials. Further, using their data I demonstrate that in dasyurids, which are ultra-altricial at birth, the neural crest migrates early and in massive quantities, even relative to other marsupials. Finally, I discuss the historical context and speculate on reasons for why this work was unpublished. I find little support for ideas that Hill blocked publication because of loyalty to the germ layer theory. Instead, it appears primarily to have been a very large project that was simply orphaned as Watson and Hill pursued other activities.     

Wise promotes coalescence of cells of neural crest and placode origins in the trigeminal region during head development

While most cranial ganglia contain neurons of either neural crest or placodal origin, neurons of the trigeminal ganglion derive from both populations. The Wnt signaling pathway is known to be required for the development of neural crest cells and for trigeminal ganglion formation, however, migrating neural crest cells do not express any known Wnt ligands. Here we demonstrate that Wise, a Wnt modulator expressed in the surface ectoderm overlying the trigeminal ganglion, play a role in promoting the assembly of placodal and neural crest cells. When overexpressed in chick, Wise causes delamination of ectodermal cells and attracts migrating neural crest cells. Overexpression of Wise is thus sufficient to ectopically induce ganglion-like structures consisting of both origins. The function of Wise is likely synergized with Wnt6, expressed in an overlapping manner with Wise in the surface ectoderm. Electroporation of morpholino antisense oligonucleotides against Wise and Wnt6 causes decrease in the contact of neural crest cells with the delaminated placode-derived cells. In addition, targeted deletion of Wise in mouse causes phenotypes that can be explained by a decrease in the contribution of neural crest cells to the ophthalmic lobe of the trigeminal ganglion. These data suggest that Wise is able to function cell non-autonomously on neural crest cells and promote trigeminal ganglion formation.     

Retinoic acid and mammalian craniofacial morphogenesis

Retinoic acid is a morphogenetic signalling molecule in vertebrate embryos, one being known to perform a specific function in organizing the body pattern along the anteroposterior axis. This molecule has especially attracted research attention because retinoic acid treatment will also induce abnormal morphogenesis, particularly in the craniofacial structures. The present review discusses recent molecular insights revealing how the retinoic acid signal is transduced within a cell, specifically focusing on the involvement of cranial neural crest cells in retinoic acid-induced abnormal morphogenesis in the mammalian head     

GSKIP,an inhibitor of GSK3β, mediates the N‐cadherin/β‐catenin pool in the differentiation of SH‐SY5Y cells

Emerging evidence has shown that GSK3β plays a pivotal role in regulating the specification of axons and dendrites. Our previous study has shown a novel GSK3β interaction protein (GSKIP) able to negatively regulate GSK3β in Wnt signaling pathway. To further characterize how GSKIP functions in neurons, human neuroblastoma SH‐SY5Y cells treated with retinoic acid (RA) to differentiate to neuron‐like cells was used as a model. Overexpression of GSKIP prevents neurite outgrowth in SH‐SY5Y cells. GSKIP may affect GSK3β activity on neurite outgrowth by inhibiting the specific phosphorylation of tau (ser396). GSKIP also increases β‐catenin in the nucleus and raises the level of cyclin D1 to promote cell‐cycle progression in SH‐SY5Y cells. Additionally, overexpression of GSKIP downregulates N‐cadherin expression, resulting in decreased recruitment of β‐catenin. Moreover, depletion of β‐catenin by small interfering RNA, neurite outgrowth is blocked in SH‐SY5Y cells. Altogether, we propose a model to show that GSKIP regulates the functional interplay of the GSK3β/β‐catenin, β‐catenin/cyclin D1, and β‐catenin/N‐cadherin pool during RA signaling in SH‐SY5Y cells. J. Cell. Biochem. 108: 1325–1336, 2009. © 2009 Wiley‐Liss, Inc.