Vandenberg LN , Adams DS , Levin M .

1F32-GM087107 NIGMS NIH HHS , K22-DE016633 NIDCR NIH HHS, R01 EY018168 NEI NIH HHS , R01 GM067227 NIGMS NIH HHS , F32 GM087107 NIGMS NIH HHS , K22 DE016633 NIDCR NIH HHS

	Figure 1. Four examples of tadpoles with perturbed craniofacial structures. In all four examples, the malformed jaw and branchial arch structures appear to “normalize” over time. In contrast, eyes change somewhat in shape but are never completely normalized. In all panels, blue arrowheads indicate malformed eyes, red arrowheads indicate malformed branchial arches, and red arrows indicate malformed jaws. All images are dorsal views except two panels showing ventral views marked with a V. Inset: schematics of the dorsal (top) and ventral (bottom) structures of the head and face. Olf, olfactory bulbs (nostrils); Br, brain; Otc, otocyst; Otl, otolith; MC, Meckel's cartilage (mandible/jaw); H, heart; BA, branchial arches.Download figure to PowerPoint
	Figure 2. Abnormalities in placode-derived tissues persist throughout tadpole stages. Placode-derived structures including eyes, nose, and otolith/otocyst were imaged in tadpoles over a range of ages. A: In a tadpole with conjoined eye–nose tissue at d9, a stalk of tissue clearly connects these two malformed structures. As the animal ages, the nostril moves away from the eye to its normal position, but a small strand of tissue remains connecting these structures. The eye is severely malformed at all ages examined. Pink arrow indicates eye, blue arrowhead indicates nostril, and yellow arrowhead points to the ectopic tissue connecting these two structures. B: A tadpole with a malformed left side is shown. The left otocyst is missing the otolith stones at all ages. Additionally, there is a pocket of abnormal ectopic tissue that is never resorbed. Green arrowheads indicate a normal otolith/otocyst, red arrowheads indicate an otocyst that is missing its otoliths, and the blue arrow indicates ectopic abnormal tissue.Download figure to PowerPoint
	Figure 3. Dorsal and ventral landmarks used for morphometric analysis. A total of 20 ventral (V) and 12 dorsal (D) landmarks were selected on the images collected of unaffected and perturbed tadpoles at several ages. Only perturbed tadpoles with an affected left or right side were used for morphometric analysis; tadpoles with visible defects on both sides were not included. This figure shows the dorsal and ventral landmarks on unaffected and perturbed tadpoles at 23 days postfertilization (d23). Green, unaffected; red, perturbed on left side; blue, perturbed on right side.Download figure to PowerPoint
	Figure 4. Outlines from principal components analysis (PCA) -derived landmark locations indicate that the average face appears to be normalized. A: PCA of dorsal landmarks for each treatment group and age reveal differences in the centroid placement for many landmarks at early stages. However, by later stages, the outlines derived from animals with craniofacial perturbations largely resemble the outlines derived from unaffected tadpoles. Green, unaffected; red, perturbed on the left side; blue, perturbed on the right side. B: PCA of ventral landmarks reveal centroid placements that do not appear to change considerably over time in unaffected tadpoles (green), with the exception of a lengthening of the anterior part of the face at later stages. In contrast, tadpoles with perturbed left (red) and right (blue) sides have branchial arch landmarks that are inappropriately close together and misplaced jaw landmarks at early stages. By late stages, the two halves of these faces are visibly more symmetrical and closely resemble the outlines of unaffected tadpoles.Download figure to PowerPoint
	Figure 5. Canonical variate analysis indicates that tadpoles with perturbed craniofacial features become indistinguishable from unaffected tadpoles. A: Analysis of ventral landmarks reveals significant differences between the three groups (unaffected [n = 10], perturbed left side [n = 17], perturbed right side [n = 19]) at early ages (d9, d23, d30). However, in later stages, these groups are no longer statistically distinguishable (P > 0.01). B: Canonical variate analysis reveals more complicated statistical relationships for dorsal landmarks. At early stages (d9, d23, d30) the three treatment groups are clearly different from each other. However, at d51–90 and d91–131, there are no longer any statistical differences distinguishing the perturbed groups from the unaffected controls (P > 0.01). Finally, at d131–167, both groups with perturbed faces were statistically distinguishable from unaffected controls (P < 0.01). For all panels, P values indicated in red are the differences between animals with perturbed left sides and unaffected controls. P values indicated in blue are the differences between animals with perturbed right sides and unaffected controls.Download figure to PowerPoint
	Figure 6. Anterior structures “calculate” their distances from each other during the normalization process. A: Landmarks for the left and right jaws, and the left and right nostrils were located in images collected from all three groups at d9, d23, d30, d51–d90, d91–d130, and d131–d167. This image shows the location of jaws (X) and nostrils (O) in unaffected and perturbed tadpoles at the earliest and latest ages examined. B: To calculate the relative differences in location of each landmark along the anterior–posterior and left–right axes, the coordinates describing the position of each landmark at day 167 were subtracted from the coordinates describing the location of the same landmark at d9. Shown here are two examples of the relative differences in location of the left jaw and left nostril in unaffected tadpoles. Clearly, between d9 and d167, the left nostril moves further in the anterior and right directions compared with the jaw on the same side. C: Quantification of movements in the anterior–posterior and left–right axes for left and right jaws and nostrils. In unaffected tadpoles (green), the majority of movements between d9 and d131–167 were in the anterior direction with little movement along the left–right axis. Animals with perturbations on the left side (red) had extensive anterior movements of the left jaw that were more than twice the distance moved in unaffected tadpoles, and decreased movements in the anterior direction for structures on the right side (jaw and nostril). Animals with perturbations on the right side (blue) had heightened movements of the right jaw that were largely in the anterior direction. Sample sizes for all analyses: unaffected n = 10, perturbed left side n = 10, perturbed right side n = 9.Download figure to PowerPoint
	Figure 7. Correct placement of craniofacial structures defined relative to the distance from the brain and the angle from the midline. A: Distances from the front of the brain (yellow square) were measured for nostrils (green dotted lines) and jaws (pink dotted lines) at each age. The angle from the midline (yellow line) was also calculated. B: As an example, the location of the left jaw is shown here at each timepoint measured for unaffected tadpoles (green) and tadpoles with perturbed left sides (red). The movements of the jaw in controls are relative minimal. In contrast, the position of the jaw is highly variable in animals with perturbed left sides. However, the final position of the jaw is very similar between these two groups. The movements of the jaw in controls are relative minimal. In contrast, the position of the jaw is highly variable in animals with perturbed left sides. However, the final position of the jaw is very similar between these two groups. C, D: When the distance from the brain and angle from the midline are quantified, it is clear that animals with perturbations in their craniofacial structures (red, perturbed left sides, n = 10; blue, perturbed right sides, n = 9) eventually achieve normal values for these parameters similar to those observed in unaffected controls (green, n = 10).Download figure to PowerPoint
	Figure 8. Craniofacial structures following metamorphosis of unaffected and perturbed tadpoles. A: Froglets were raised from unaffected tadpoles or tadpoles with craniofacial perturbations. Tadpoles with eye malformations metamorphosed into frogs with severe eye deformities. In contrast, tadpoles with defects in their jaws and/or branchial arches developed into froglets with normal exterior morphologies. The one exception was a froglet with a slight protrusion of the skin under the left eye. B: High resolution CT scans reveal remarkably normal craniofacial bone structures in the faces of froglets raised from tadpoles with craniofacial malformations. One froglet had slightly narrowed jaw bones (orange arrows) and a small section of the parasphenoid bone was absent (white arrow). Three orientations are shown from each sample. C: High resolution CT images of soft tissues reveal eye deformities (yellow arrow) only in those froglets raised from tadpoles with eye malformations. These images show similar coronal planes through the heads of froglets. D: Canonical variate analysis indicates that animals with either left eye perturbations (red) or right eye perturbations (blue) are significantly different from unaffected controls (green). However, froglets that were raised from tadpoles with malformed jaws and/or branchial arches (black) were not distinguishable from unaffected controls. P values indicated in red are the differences between animals with perturbed left eyes and unaffected controls, P values indicated in blue are the differences between animals with perturbed right eyes and unaffected controls, and P values in black are the differences between animals with jaw/branchial arch defects during tadpole stages and unaffected controls.Download figure to PowerPoint
	Figure 9. An algorithmic model for the mechanism dictating normalized position of craniofacial structures. A: During the first few hours of life, perturbations in bioelectricity can produce abnormal face states that manifest within a few days of development. Over a period of several weeks/months, a “ping” signal is sent between an “organizing center” and each craniofacial structure. If the organ is positioned properly, the ‘organizing center’ communicates a “stop” signal, migration of the organ halts, and the resulting face is normal in both tadpole and froglet stages. If the organ is not positioned appropriately, no “stop” signal is given, so the organ moves/migrates and the cycle of “ping” and “move/migrate” continues until the organ is properly localized. B: This system of ping/move/stop occurs independently in each organ/structure. Thus, if for example the ‘organizing center’ is located in the forebrain, a ping (blue arrow) is communicated between the brain and each structure (for example, each nostril). If the location of a structure is correct (i.e. on the unaffected side of an individual), the “stop” signal is sent (red arrow). But if this stop signal is not sent, the organ continues to move (shown here as a mislocalized nostril on the perturbed side, yellow arrow).Download figure to PowerPoint
	COVER PHOTOGRAPH: Visualization of the developing neural tube and craniofacial structures using pH and membrane voltage reporter dyes in Xenopus laevis embryos. Manipulation of pH and membrane voltage via misexpression of subunit c of the H(+) -V-ATPase produces craniofacial abnormalities that are capable of normalizing themselves as the animal develops and ages. From Vandenberg et al., Developmental Dynamics 241:863-878, 2012.

Adams, Inverse drug screens: a rapid and inexpensive method for implicating molecular targets. 2006, Pubmed

Adams, Inverse drug screens: a rapid and inexpensive method for implicating molecular targets. 2006, Pubmed
Albertson, Roles for fgf8 signaling in left-right patterning of the visceral organs and craniofacial skeleton. 2005, Pubmed
Alfandari, Mechanism of Xenopus cranial neural crest cell migration. 2010, Pubmed , Xenbase
Basch, Molecular mechanisms of neural crest induction. 2004, Pubmed
Birnbaum, Slicing across kingdoms: regeneration in plants and animals. 2008, Pubmed
Borghi, Intercellular adhesion in morphogenesis: molecular and biophysical considerations. 2009, Pubmed
Brugmann, Induction and specification of the vertebrate ectodermal placodes: precursors of the cranial sensory organs. 2005, Pubmed , Xenbase
Brugmann, Craniofacial ciliopathies: A new classification for craniofacial disorders. 2010, Pubmed
Chang, Diversity, topographic differentiation, and positional memory in human fibroblasts. 2002, Pubmed
Chenevix-Trench, Cleft lip with or without cleft palate: associations with transforming growth factor alpha and retinoic acid receptor loci. 1992, Pubmed
Cooper, Bentho-pelagic divergence of cichlid feeding architecture was prodigious and consistent during multiple adaptive radiations within African rift-lakes. 2010, Pubmed
Cordero, Cranial neural crest cells on the move: their roles in craniofacial development. 2011, Pubmed , Xenbase
Couzin, Collective cognition in animal groups. 2009, Pubmed
Dane, Handedness differences in widths of right and left craniofacial regions in healthy young adults. 2004, Pubmed
Dane, Relations among hand preference, craniofacial asymmetry, and ear advantage in young subjects. 2002, Pubmed
Deisboeck, Collective behavior in cancer cell populations. 2009, Pubmed
Dolk, The prevalence of congenital anomalies in Europe. 2010, Pubmed
FARINELLA-FERRUZZA, [Reciprocal transplantations of tail bud between Discoglossus and Triton]. 1953, Pubmed
French, Pattern regulation in epimorphic fields. 1976, Pubmed
Gitton, Evolving maps in craniofacial development. 2010, Pubmed
Goodwin, A statistical mechanics of temporal organization in cells. 1964, Pubmed
Harris, Detecting an undiagnosed case of nonsyndromic facial dysmorphism using geometric morphometrics. 2008, Pubmed
Hart, Genetic studies of craniofacial anomalies: clinical implications and applications. 2009, Pubmed
Holder, Confirmation of an association between RFLPs at the transforming growth factor-alpha locus and non-syndromic cleft lip and palate. 1992, Pubmed
Hu, Unique organization of the frontonasal ectodermal zone in birds and mammals. 2009, Pubmed
Hu, A SHH-responsive signaling center in the forebrain regulates craniofacial morphogenesis via the facial ectoderm. 2009, Pubmed
Jones, Prevention of the neurocristopathy Treacher Collins syndrome through inhibition of p53 function. 2008, Pubmed
Kish, The eye as an organizer of craniofacial development. 2011, Pubmed
Klingenberg, MorphoJ: an integrated software package for geometric morphometrics. 2011, Pubmed
Klingenberg, Prenatal alcohol exposure alters the patterns of facial asymmetry. 2010, Pubmed
Kouskoura, The genetic basis of craniofacial and dental abnormalities. 2011, Pubmed
Lecuit, Orchestrating size and shape during morphogenesis. 2007, Pubmed
Leucht, Embryonic origin and Hox status determine progenitor cell fate during adult bone regeneration. 2008, Pubmed
Levin, Large-scale biophysics: ion flows and regeneration. 2007, Pubmed
Levin, Left-right asymmetry in embryonic development: a comprehensive review. 2005, Pubmed
Marcucio, Molecular interactions coordinating the development of the forebrain and face. 2005, Pubmed
Martin, Pulsation and stabilization: contractile forces that underlie morphogenesis. 2010, Pubmed
Martin, Parallels between tissue repair and embryo morphogenesis. 2004, Pubmed
Matt, Impairing retinoic acid signalling in the neural crest cells is sufficient to alter entire eye morphogenesis. 2008, Pubmed
Matt, Retinoic acid-dependent eye morphogenesis is orchestrated by neural crest cells. 2005, Pubmed
Mayor, Induction and development of neural crest in Xenopus laevis. 2001, Pubmed , Xenbase
Minoux, Molecular mechanisms of cranial neural crest cell migration and patterning in craniofacial development. 2010, Pubmed
Molotkov, Retinoic acid guides eye morphogenetic movements via paracrine signaling but is unnecessary for retinal dorsoventral patterning. 2006, Pubmed
Mondia, Long-distance signals are required for morphogenesis of the regenerating Xenopus tadpole tail, as shown by femtosecond-laser ablation. 2011, Pubmed , Xenbase
Niehrs, On growth and form: a Cartesian coordinate system of Wnt and BMP signaling specifies bilaterian body axes. 2010, Pubmed
Nishi, The vacuolar (H+)-ATPases--nature's most versatile proton pumps. 2002, Pubmed
Nogi, Eye regeneration assay reveals an invariant functional left-right asymmetry in the early bilaterian, Dugesia japonica. 2005, Pubmed
Nuckolls, Progress toward understanding craniofacial malformations. 1999, Pubmed , Xenbase
Ogawa, Generation model of positional values as cell operation during the development of multicellular organisms. 2011, Pubmed
Oh, Facial asymmetry in unilateral coronal synostosis: long-term results after fronto-orbital advancement. 2008, Pubmed
Oviedo, Allometric scaling and proportion regulation in the freshwater planarian Schmidtea mediterranea. 2003, Pubmed
Parsons, Morphogenesis of the zebrafish jaw: development beyond the embryo. 2011, Pubmed
Pilot, Compartmentalized morphogenesis in epithelia: from cell to tissue shape. 2005, Pubmed
Proff, The molecular mechanism behind bone remodelling: a review. 2009, Pubmed
Ross, Craniofacial growth, maturation, and change: teens to midadulthood. 2010, Pubmed
Rossant, Expression of a retinoic acid response element-hsplacZ transgene defines specific domains of transcriptional activity during mouse embryogenesis. 1991, Pubmed
Saadeh, Microsurgical correction of facial contour deformities in patients with craniofacial malformations: a 15-year experience. 2008, Pubmed
Sadaghiani, Neural crest development in the Xenopus laevis embryo, studied by interspecific transplantation and scanning electron microscopy. 1987, Pubmed , Xenbase
Sant'Anna, Fetal alcohol syndrome and developing craniofacial and dental structures--a review. 2006, Pubmed
Schlosser, Induction and specification of cranial placodes. 2006, Pubmed , Xenbase
Sharabi, Mechanotransduction: the missing link in the facial aging puzzle? 2010, Pubmed
Shi, Three-dimensional gradients of voltage during development of the nervous system as invisible coordinates for the establishment of embryonic pattern. 1995, Pubmed
Singh, Three-dimensional nasal changes following nasoalveolar molding in patients with unilateral cleft lip and palate: geometric morphometrics. 2005, Pubmed
Singh, Digital diagnostics: Three-dimensional modelling. 2008, Pubmed
Slater, Cranial osteogenesis and suture morphology in Xenopus laevis: a unique model system for studying craniofacial development. 2009, Pubmed , Xenbase
Streit, The preplacodal region: an ectodermal domain with multipotential progenitors that contribute to sense organs and cranial sensory ganglia. 2007, Pubmed
Suzuki, The mitochondrial phylogeny of an ancient lineage of ray-finned fishes (Polypteridae) with implications for the evolution of body elongation, pelvic fin loss, and craniofacial morphology in Osteichthyes. 2010, Pubmed
Theveneau, Collective cell migration of the cephalic neural crest: the art of integrating information. 2011, Pubmed
Trueb, Skeletal development in Xenopus laevis (Anura: Pipidae). 1992, Pubmed , Xenbase
Vandenberg, Far from solved: a perspective on what we know about early mechanisms of left-right asymmetry. 2010, Pubmed
Vandenberg, V-ATPase-dependent ectodermal voltage and pH regionalization are required for craniofacial morphogenesis. 2011, Pubmed , Xenbase
Vandenberg, Perspectives and open problems in the early phases of left-right patterning. 2009, Pubmed
Vasquez, Optimization of volumetric computed tomography for skeletal analysis of model genetic organisms. 2008, Pubmed , Xenbase
von Cramon-Taubadel, The problem of assessing landmark error in geometric morphometrics: theory, methods, and modifications. 2007, Pubmed
Voskoboynik, Striving for normality: whole body regeneration through a series of abnormal generations. 2007, Pubmed
Wang, Regeneration, repair and remembering identity: the three Rs of Hox gene expression. 2009, Pubmed
Weisensee, Secular changes in craniofacial morphology of the Portuguese using geometric morphometrics. 2011, Pubmed
Young, Quantitative analyses link modulation of sonic hedgehog signaling to continuous variation in facial growth and shape. 2010, Pubmed
Zambuzzi, MMP-9 and CD68(+) cells are required for tissue remodeling in response to natural hydroxyapatite. 2009, Pubmed