Perry KJ , Thomas AG , Henry JJ .

R01 EY009844 NEI NIH HHS , EY09844 NEI NIH HHS

	Fig. 1. Morphology of larval cornea tissues in whole mount and transverse sections of Xenopus laevis. (A) Confocal images of an intact excised cornea (pelt) of st502 larvae. (A) Outer epithelial layer labeled with Phalloidin (green), DAPI labeled nuclei (blue) and merged images, respectively. (D) Basal epithelial layer labeled with Phalloidin (green), DAPI (blue) and merged images, respectively. (G) Deeper fibrillar layer labeled with Phalloidin (green), DAPI (blue) and merged images, respectively. (J) DIC image of transverse section of control larval eye showing thin, dual-layered epithelium. (K) Corresponding Hoechst nuclear stained image to that seen in J showing flattened nuclei. (L) DIC image of transverse section of 5-day regenerating larval eye with thickened cells of the epithelium. (M) Corresponding Hoechst nuclear stained image to that seen in L. Gray arrowhead points to one nucleus of the outer cornea epithelial layer and white arrowhead identifies a nucleus in the basal epithelial layer. The gray arrowhead points to the nucleus of a cell of the outer epithelial layer and one located in the basal cornea epithelium is denoted with a white arrowhead. ic; inner cornea; ln, lens; nr, neural retina; oc, outer cornea. Scale bar in M equals 6 μm for A, and 100 μm in J.
	Fig. 2. (A) Larval (st48) Xenopus specimens showing distribution of acetylated tubulin labeled nerves in the head. (A) Right lateral view of the head with anterior to the right, and dorsal to the top of the figure. (B) Superior, dorsal view of the right side of the head with anterior to the left. Asterisks mark branches of sensory nerves that serve the cornea epithelium in A or their origins in B. (C) Confocal images showing different depths of acetylated tubulin immunostaining (red), cell boundaries labeled with phalloidin (green) and DAPI nuclear stain (blue). (C) Acetylated tubulin stained nerves of the outer epithelial layer. (D) Basal epithelial distribution of acetylated tubulin labeled nerves. (E) Fibrillar layer containing labeled nerve trunks with branching structures. (F) Confocal image showing distribution of acetylated tubulin labeled nerves in the cornea (red). (G) Corresponding image showing distribution of Substance P (green). (H) Merged images from F and G showing overlapping acetylated tubulin and Substance P protein localization. an, abducens nerve (CN VI); fb, forebrain; fn, facial nerve (CN VII); gn, glossopharyngeal nerve (CN IX); ion, infraorbital nerve; mn, mandibular nerve; mnb, fine branches of the mandibular nerve; ncn, nasociliary nerve (with m and l, labeling its terminal medial and lateral branches, respectively, which pass to the sides of the olfactory organs (nose)); ofn, olfactory nerve (CN I); omn, oculomotor nerve (CN III); on, optic nerve (CN II); opn, ophthalmic nerve; rn, retrograde branch of nasociliary nerves; son, supraorbital nerve; tn, trochlear nerve (CN IV); tgn, trigeminal nerve (CN V). Scale bar in H equals 150 μm in A and 6 μm in C.
	Fig. 3. Quantitative PCR (qPCR) results for sox2, p63 and oct60 expression during lens regeneration in stage 502 Xenopus laevis larval cornea epithelia. Relative expression levels were compared to control cornea epithelial expression and normalized against odc expression at the same larval stages (st502). Data for each time point was run in triplicate and represents independently pooled cornea samples collected from 0 h (control unoperated corneas), 4 h, 12-h, 1-day, 3-day and 5-days after lens removal. Error bars are indicated in black. Significant expression changes as compared to control unoperated corneas are denoted with an asterisk at the top of each bar graph. Significant expression changes between various key time points compared are noted underneath the X-axis. * denotes p values<0.05 using Students t-test.
	Fig. 4. Antibody labeling of sox2 (red) in whole Xenopus larval cornea epithelium (st502). (A) Antibody labeling in whole corneas showing the distribution and appearance of labeled cells in regenerating corneas. (A) Control cornea with very few sox2 labeled cells located around the periphery in the limbal zone. (B) Regenerating cornea just 4 h after lens removal. Note the increased number of labeled cells that have appeared in the central cornea. (C) Regenerating cornea 5 days following lens removal with a decreased number of sox2 labeled cells, which are again restricted to the periphery. (D) Representative higher magnification views showing sox2 protein labeling in irregularly-shaped cells of the cornea. The outer periphery or limbal zone is located to the left of each photo and the center of the cornea is towards the right. (D) Distribution of sox2 antibody (red). Some low level sox2 expression is also detected throughout other cells of the cornea epithelium. (E) Corresponding view showing distribution of DAPI stained nuclei (blue). (F) Merged images from D and E. (G) Confocal images of a 3-day regenerating cornea, showing one irregular sox2 expressing cell located in the basal layer (red). Cell boundaries and fibrillar layer are counterstained with phalloidin (green) and DAPI nuclear stain (blue). (G) Outer cornea epithelium. (H) Basal cornea epithelium. The sox2 expressing cell appears to contain multiple nuclei or multi-lobed nucleus. (I) Fibrillar layer with no apparent sox2 labeling. (J) Confocal images of 1-day regenerating cornea epithelium with sox2 antibody labeling (red). (J) Outer cornea epithelium. (K) Basal cornea epithelium with diffuse sox2 label throughout the cells. (L) Deeper fibrillar layer with a multinucleated cell brightly labeled with sox2. This cell appears to either be dividing or squeezing through two adjacent unlabeled cells. cc, central cornea; lz, limbal zone. Scale bar in L indicates 220 μm for A, 40 μm for D, 6 μm for G, and 8 μm for J.
	Fig. 5. Fluorescence light microscopic and confocal images showing antibody labeling of Xenopus whole cornea epithelium (st502). (A) p63 (ΔNp63 isoform) protein labeling of the cornea epithelium. (A) p63 labeling is represented in red. (B) Corresponding image to A with DAPI labeled nuclei (blue). (C) Merged images from A and B. (D) Confocal imaging of p63 antibody labeling. (D) Outer epithelium with no p63 labeling. Cell boundaries and fibrils are counterstained with phalloidin (green). (E) Localized p63 labeling (purple) in every nucleus of the basal epithelium. (F) Fibrillar layer with no p63 labeling. (G) c-myc protein labeling in the peripheral region of the cornea (limbal zone). (G) c-myc localization to multi-lobed cells (red). (H) Corresponding image to G with DAPI stained nuclei. (I) Merged image of G and H. (J) Confocal images of c-myc labeling in cells of the cornea epithelium (limbal zone). (J) Outer cornea epithelium with projections of c-myc labeled cells. (K). Basal cornea epithelium displaying irregular shaped c-myc expressing cells. (L) Deeper fibrillar layer displaying no c-myc labeled cells. Scale bar in L indicates 25 μm for A, 6 μm for D, 50 μm for G, and 10 μm for J.
	Fig. 6. EdU labeling of proliferating cells in isolated intact control Xenopus larval cornea epithelia (pelts) following a single pulse of EdU labeling. Animals were fixed at various time points following injection and EdU detected with fluorescent azide 594. White arrowheads point to the location of the central attachment point of the cornea epithelium to the cornea endothelium. (A) Cornea 1-day post-EdU injection (st502). (A) Fluorescent EdU labeled nuclei (red). Representative pairs of EdU labeled nuclei are denoted with gray arrowheads, of which many can be seen in this specimen. (B) EdU labeled image from A merged with Hoechst 33342 labeled nuclei (blue). (C) Cornea 5-days post-EdU injection (st52). (C) Fluorescent EdU labeled nuclei. Representative clusters of EdU labeled nuclei are noted with gray arrowheads. (D) Merged images from C and corresponding Hoechst labeled nuclei (blue). (E) Cornea 14-days post-EdU injection (st545). (E) Fluorescent EdU labeled nuclei. Representative clusters of EdU labeled nuclei are pointed out with gray arrowheads. (F) Merged images from E and corresponding Hoechst 33342 labeled nuclei. (G) Cornea 28-days post-EdU injection (st567). (G) A few fluorescent EdU labeled nuclei are present in this cornea (denoted by gray arrowheads). (H) Merged images from G and corresponding Hoechst 33342 labeled nuclei. (I) Sections of eyes from animals injected with EdU 14 days prior to fixation. (I) Section of 14-day control case showing the central cornea overlying the optic cup where EdU label occurs mostly in nuclei of the basal epithelium. (J) Corresponding image to I showing additional location of all nuclei labeled with Hoecht. (K) Section of 14-day EdU labeled case (same case shown in K) showing the periphery of the cornea. (K) EdU labeled cells from 14-day control case are shown in red and merged with Hoechst labeled nuclei in L. Scale bar in L indicates 100 μm.
	Fig. 7. EdU labeling (red) of nuclei in proliferating cells during different time point of lens regeneration in Xenopus eyes. (A) Cornea 1-day post EdU injection and lens removal (st502). (A) Fluorescence light micrograph of cornea pelt showing presence of EdU labeled nuclei (red). (B) Corresponding image to A showing additional location of all nuclei labeled with Hoecht (blue). (C) Higher magnification confocal image of 1-day regenerating cornea showing outer cornea epithelial layer with no appreciable EdU labeling. Nuclei are stained with Hoechst. (D) Deeper focal plane showing corresponding basal cornea epithelial layer with presence of EdU labeled nuclei. (E) Deeper fibrilar layer showing presence of some nuclei, one of which is EdU labeled. (F) Regenerating cornea 5-days post-EdU injection and lens removal (st52). (F) Fluorescent EdU labeled nuclei in 5-day regenerating cornea. Gray arrow shows location of intense EdU labeling. (G) Corresponding image to F showing additional location of all nuclei labeled with Hoecht (blue). The location of a regenerating lens placode is enlarged in the inset. This could represent the point of attachment of a larger lens vesicle that detached from the cornea upon excision from the animal. (H) Higher magnification confocal image of an organized regenerating lens placode 5-days after EdU addition and lens removal. (H) Image showing lens placode with EdU labeling in red. (I) Corresponding image of H showing nuclei labeled with Hoecsht. (J) Merged fluorescence images in H and I. (K) Section of eye showing EdU labeled cells present in a regenerated lens 14 days after EdU injection and lens removal. The cornea is at the upper edge of these images. (K) Section of eye showing the lens containing red EdU labeled nuclei. (N) Merged image from K combined with corresponding Hoechst labeled nuclei. (M) Cornea implantation experiment where larvae (st502) were labeled with EdU, chased for 7 days, following which the outer cornea was excised and implanted into the vitreous chamber of an unlabeled control larvae (st502). (M) DIC image of eye 7-days after cornea implant. Small regenerating lens is outlined in black. (N) Corresponding image to M showing EdU-labeled nuclei. Note EdU labeled nuclei within the regenerating lens, outlined in white. (O) Merged fluorescence images shown in M and N. imc, EdU labeled implanted donor cornea; ln, lens; nr, neural retina; oc, outer cornea; pce, peripheral cornea epithelium; vc, vitreous chamber. Scale bar in T equals 100 μm in A, F; 60 μm in G (inset); 6 μm in C; 10 μm in H; 15 μm in K, and 40 μm in M.
	Supplementary Fig. S1. Expression of pluripotency genes in control corneas (C), during days 1 of lens regeneration (R), and in flank (F) epithelium as assayed by RT-PCR. All PCR products were verified by sequence analysis. 1 kb standards (st) are to the far left, as indicated.

Arresta, Lens-forming competence in the epidermis of Xenopus laevis during development. 2005, Pubmed, Xenbase

Arresta, Lens-forming competence in the epidermis of Xenopus laevis during development. 2005, Pubmed , Xenbase
Belmonte, Neural basis of sensation in intact and injured corneas. 2004, Pubmed
Beuerman, Sensory denervation of the rabbit cornea affects epithelial properties. 1980, Pubmed
Bick, Total substitution of bromodeoxyuridine for thymidine in the DNA of a bromodeoxyuridine-dependent cell line. 1974, Pubmed
Bosco, Transdifferentiation of ocular tissues in larval Xenopus laevis. 1988, Pubmed , Xenbase
Bosco, Lens formation from cornea in the presence of the old lens in larval Xenopus laevis. 1980, Pubmed , Xenbase
Cannata, The optic vesicle promotes cornea to lens transdifferentiation in larval Xenopus laevis. 2008, Pubmed , Xenbase
Cao, POU-V factors antagonize maternal VegT activity and beta-Catenin signaling in Xenopus embryos. 2007, Pubmed , Xenbase
Cao, Xenopus POU factors of subclass V inhibit activin/nodal signaling during gastrulation. 2006, Pubmed , Xenbase
Chang, Acute wound healing in the human central corneal epithelium appears to be independent of limbal stem cell influence. 2008, Pubmed
Chang, Systematic search for recipes to generate induced pluripotent stem cells. 2011, Pubmed
Christen, Regeneration and reprogramming compared. 2010, Pubmed
Cotsarelis, Existence of slow-cycling limbal epithelial basal cells that can be preferentially stimulated to proliferate: implications on epithelial stem cells. 1989, Pubmed
Davanger, Role of the pericorneal papillary structure in renewal of corneal epithelium. 1971, Pubmed
Davies, Corneal stem cells and their origins: significance in developmental biology. 2010, Pubmed
Day, Transdifferentiation from cornea to lens in Xenopus laevis depends on BMP signalling and involves upregulation of Wnt signalling. 2011, Pubmed , Xenbase
Di Girolamo, Stem cells of the human cornea. 2011, Pubmed
Di Iorio, Isoforms of DeltaNp63 and the migration of ocular limbal cells in human corneal regeneration. 2005, Pubmed
Du, Multipotent stem cells in human corneal stroma. 2005, Pubmed
Dua, Limbal epithelial crypts: a novel anatomical structure and a putative limbal stem cell niche. 2005, Pubmed
FREEMAN, LENS REGENERATION FROM THE CORNEA IN XENOPUS LAEVIS. 1963, Pubmed , Xenbase
Funderburgh, PAX6 expression identifies progenitor cells for corneal keratocytes. 2005, Pubmed
Gargioli, The lens-regenerating competence in the outer cornea and epidermis of larval Xenopus laevis is related to pax6 expression. 2008, Pubmed , Xenbase
Gilbard, Tear film and ocular surface changes in a rabbit model of neurotrophic keratitis. 1990, Pubmed
Gratzner, Monoclonal antibody to 5-bromo- and 5-iododeoxyuridine: A new reagent for detection of DNA replication. 1982, Pubmed
HANNA, Cell production and migration in the epithelial layer of the cornea. 1960, Pubmed
Heasman, Beta-catenin signaling activity dissected in the early Xenopus embryo: a novel antisense approach. 2000, Pubmed , Xenbase
Henry, The cellular and molecular bases of vertebrate lens regeneration. 2003, Pubmed
Henry, Inductive interactions in the spatial and temporal restriction of lens-forming potential in embryonic ectoderm of Xenopus laevis. 1987, Pubmed , Xenbase
Henry, Early tissue interactions leading to embryonic lens formation in Xenopus laevis. 1990, Pubmed , Xenbase
Henry, The matured eye of Xenopus laevis tadpoles produces factors that elicit a lens-forming response in embryonic ectoderm. 1995, Pubmed , Xenbase
Henry, Molecular and cellular aspects of amphibian lens regeneration. 2010, Pubmed , Xenbase
Henry, Characterizing gene expression during lens formation in Xenopus laevis: evaluating the model for embryonic lens induction. 2002, Pubmed , Xenbase
Hori, Heat-shock responsive genes identified and validated in Atlantic cod (Gadus morhua) liver, head kidney and skeletal muscle using genomic techniques. 2010, Pubmed
Kuwayama, Distinct substance P and calcitonin gene-related peptide immunoreactive nerves in the guinea pig eye. 1987, Pubmed
Lavker, Heterogeneity in epidermal basal keratinocytes: morphological and functional correlations. 1982, Pubmed
Lavker, Epidermal stem cells. 1983, Pubmed
Lavker, Epidermal stem cells: properties, markers, and location. 2000, Pubmed
Lucier, Central projections of the ethmoidal nerve of the cat as determined by the horseradish peroxidase tracer technique. 1986, Pubmed
Majo, Oligopotent stem cells are distributed throughout the mammalian ocular surface. 2008, Pubmed
Maki, Expression of stem cell pluripotency factors during regeneration in newts. 2009, Pubmed , Xenbase
Marfurt, The somatotopic organization of the cat trigeminal ganglion as determined by the horseradish peroxidase technique. 1981, Pubmed
Marfurt, Central projections and trigeminal ganglion location of corneal afferent neurons in the monkey, Macaca fascicularis. 1988, Pubmed
Marfurt, Morphology and neurochemistry of canine corneal innervation. 2001, Pubmed
Marfurt, Origins of the renal innervation in the primate, Macaca fascicularis. 1989, Pubmed
McDevitt, alpha-, beta- and gamma-Crystallins in the regenerating lens of Notophthalmus viridescens. 1982, Pubmed
McKenna, Innervation of the mouse cornea during development. 2011, Pubmed
Morgan, Organization of corneal afferent axons in the trigeminal nerve root entry zone in the cat. 1987, Pubmed
Morrison, Conserved roles for Oct4 homologues in maintaining multipotency during early vertebrate development. 2006, Pubmed , Xenbase
Müller, Corneal nerves: structure, contents and function. 2003, Pubmed
Pellegrini, p63 identifies keratinocyte stem cells. 2001, Pubmed
Reyer, Macrophage invasion and phagocytic activity during lens regeneration from the iris epithelium in newts. 1990, Pubmed
Reyer, Macrophage mobilization and morphology during lens regeneration from the iris epithelium in newts: studies with correlated scanning and transmission electron microscopy. 1990, Pubmed
Ruskell, Ocular fibres of the maxillary nerve in monkeys. 1974, Pubmed
Salic, A chemical method for fast and sensitive detection of DNA synthesis in vivo. 2008, Pubmed
Sasaoka, Overall distribution of substance P nerves in the rat cornea and their three-dimensional profiles. 1984, Pubmed
Schermer, Differentiation-related expression of a major 64K corneal keratin in vivo and in culture suggests limbal location of corneal epithelial stem cells. 1986, Pubmed
Schuff, Characterization of Danio rerio Nanog and functional comparison to Xenopus Vents. 2012, Pubmed , Xenbase
Slack, Regional biosynthetic markers in the early amphibian embryo. 1984, Pubmed
Stepp, The corneal epithelial stem cell niche. 2005, Pubmed
Tervo, Substance P immunoreactive nerves in the rodent cornea. 1981, Pubmed
Thoft, The X, Y, Z hypothesis of corneal epithelial maintenance. 1983, Pubmed
Ueno, Dependence of corneal stem/progenitor cells on ocular surface innervation. 2012, Pubmed
Waggoner, Lens differentiation from the cornea following lens extirpation or cornea transplantation in Xenopus laevis. 1973, Pubmed , Xenbase
Waggoner, DNA synthesis during lens regeneration in larval Xenopus laevis. 1975, Pubmed , Xenbase
Waldman, A comparison between bromodeoxyuridine and 3H thymidine labeling in human breast tumors. 1991, Pubmed
Yamada, The effect of digestion with keratanase (Pseudomonas sp.) on certain histochemical reactions for glycosaminoglycans in cartilaginous and corneal tissues. 1982, Pubmed
Yamada, Macrophage activity in Wolffian lens regeneration. 1972, Pubmed