Integrating Morphogenesis with Underlying Mechanics and Cell Biology

Current Topics in Developmental Biology

Volumn 81, Issue , 2008, Pages 113-133

  Davidson, Lance A ^a  

^a University of Pittsburgh   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ANIMAL; BIOLOGICAL MODEL; BIOMECHANICS; EMBRYO DEVELOPMENT; MORPHOGENESIS; PRENATAL DEVELOPMENT; REVIEW; SYSTEMS BIOLOGY; XENOPUS LAEVIS;

ANIMALS; BIOMECHANICS; EMBRYONIC DEVELOPMENT; MODELS, BIOLOGICAL; MORPHOGENESIS; SYSTEMS BIOLOGY; XENOPUS LAEVIS;

EID: 36148934860     PISSN: 00702153     EISSN: None     Source Type: Book Series    
DOI: 10.1016/S0070-2153(07)81003-9     Document Type: Review

References (95)

1. Afonin B., Ho M., Gustin J.K., Meloty-Kapella C., and Domingo C.R. Cell behaviors associated with somite segmentation and rotation in Xenopus laevis. Dev. Dyn. 235 (2006) 3268-3279
2. Alberts B., Johnson A., Lewis J., Raff M., Roberts K., and Walter P. Molecular Biology of the Cell (2002), Garland Publishing, New York
3. Ariizumi T., Takano K., Asashima M., and Malacinski G.M. Bioassays of inductive interactions in amphibian development. Methods Mol. Biol. 135 (2000) 89-112
4. Baneyx G., Baugh L., and Vogel V. Fibronectin extension and unfolding within cell matrix fibrils controlled by cytoskeletal tension. Proc. Natl. Acad. Sci. USA 99 (2002) 5139-5143
5. Blitz I.L., Andelfinger G., and Horb M.E. Germ layers to organs: Using Xenopus to study "later" development. Semin. Cell Dev. Biol. 17 (2006) 133-145
6. Bolker J.A. Model systems in developmental biology. BioEssays 17 (1995) 451-455
7. Brodland G.W. Do lamellipodia have the mechanical capacity to drive convergent extension?. Int. J. Dev. Biol. 50 (2006) 151-155
8. Davidson L.A., and Keller R.E. Neural tube closure in Xenopus laevis involves medial migration, directed protrusive activity, cell intercalation and convergent extension. Development 126 (1999) 4547-4556
9. Davidson L.A., and Wallingford J.B. Visualizing morphogenesis in the frog embryo. In: Yuste R., and Konnerth A. (Eds). Imaging in Neuroscience and Development: A Laboratory Manual (2005), Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
10. Davidson L.A., Hoffstrom B.G., Keller R., and DeSimone D.W. Mesendoderm extension and mantle closure in Xenopus laevis gastrulation: Combined roles for integrin alpha5beta1, fibronectin, and tissue geometry. Dev. Biol. 242 (2002) 109-129
11. Davidson L.A., Keller R., and Desimone D.W. Assembly and remodeling of the fibrillar fibronectin extracellular matrix during gastrulation and neurulation in Xenopus laevis. Dev. Dyn. 231 (2004) 888-895
12. Davidson L.A., Marsden M., Keller R., and Desimone D.W. Integrin alpha5beta1 and fibronectin regulate polarized cell protrusions required for Xenopus convergence and extension. Curr. Biol. 16 (2006) 833-844
13. De Robertis E.M., and Kuroda H. Dorsal-ventral patterning and neural induction in Xenopus embryos. Annu. Rev. Cell Dev. Biol. 20 (2004) 285-308
14. Elul T., and Keller R. Monopolar protrusive activity: A new morphogenic cell behavior in the neural plate dependent on vertical interactions with the mesoderm in Xenopus [in process citation]. Dev. Biol. 224 (2000) 3-19
15. Elul T.M., Koehl M.A.R., and Keller R.E. Cellular mechanism underlying neural convergence and extension in Xenopus laevis embryos. Dev. Biol. 191 (1997) 243-258
16. Elul T., Koehl M.A., and Keller R.E. Patterning of morphogenetic cell behaviors in neural ectoderm of Xenopus laevis. Ann. NY Acad. Sci. 857 (1998) 248-251
17. Ewald A.J., Peyrot S.M., Tyszka J.M., Fraser S.E., and Wallingford J.B. Regional requirements for Dishevelled signaling during Xenopus gastrulation: Separable effects on blastopore closure, mesendoderm internalization and archenteron formation. Development 131 (2004) 6195-6209
18. Ezin A.M., Skoglund P., and Keller R. The midline (notochord and notoplate) patterns the cell motility underlying convergence and extension of the Xenopus neural plate. Dev. Biol. 256 (2003) 100-114
19. Ezin A.M., Skoglund P., and Keller R. The presumptive floor plate (notoplate) induces behaviors associated with convergent extension in medial but not lateral neural plate cells of Xenopus. Dev. Biol. 300 (2006) 670-686
20. Gawantka V., Ellinger-Ziegelbauer H., and Hausen P. Beta 1-integrin is a maternal protein that is inserted into all newly formed plasma membranes during early Xenopus embryogenesis. Development 115 (1992) 595-605
21. Gilbert S.F. Developmental Biology (2006), Sinauer Associates Inc., Sunderland, MA
22. Gildner C.D., Lerner A.L., and Hocking D.C. Fibronectin matrix polymerization increases tensile strength of model tissue. Am. J. Physiol. Heart Circ. Physiol. 287 (2004) H46-H53
23. Habas R., Dawid I.B., and He X. Coactivation of Rac and Rho by Wnt/Frizzled signaling is required for vertebrate gastrulation. Genes Dev. 17 (2003) 295-309
24. Hardin J., and Keller R. The behavior and function of bottle cells during gastrulation of Xenopus laevis. Development 103 (1988) 211-230
25. Harris A.K. Is cell sorting caused by differences in the work of intercellular adhesion? A critique of the Steinberg hypothesis. J. Theor. Biol. 61 (1976) 267-285
26. Harris A.K. Cell motility and the problem of anatomical homeostasis. J. Cell Sci. 8 (1987) 121-140
27. Harris A.K., Wild P., and Stopak D. Silicone rubber substrata: A new wrinkle in the study of cell locomotion. Science 208 (1980) 177-179
28. Heasman J. Maternal determinants of embryonic cell fate. Semin. Cell Dev. Biol. 17 (2006) 93-98
29. Hocking D.C., Smith R.K., and McKeown-Longo P.J. A novel role for the integrin-binding III-10 module in fibronectin matrix assembly. J. Cell Biol. 133 (1996) 431-444
30. Hoffstrom B.G. Integrin function during Xenopus laevis gastrulation. Depart of Cell Biology (2002), Univ. of Virginia, Charlottesville, VA 137
31. Horwitz A.F., and Parsons J.T. Cell biology: Cell migration-movin' on. Science 286 (1999) 1102-1103
32. Hynes R.O. Fibronectins (1990), Springer-Verlag, New York
33. Hyodo-Miura J., Yamamoto T.S., Hyodo A.C., Iemura S., Kusakabe M., Nishida E., Natsume T., and Ueno N. XGAP, an ArfGAP, is required for polarized localization of PAR proteins and cell polarity in Xenopus gastrulation. Dev. Cell 11 (2006) 69-79
34. Ibrahim H., and Winklbauer R. Mechanisms of mesendoderm internalization in the Xenopus gastrula: Lessons from the ventral side. Dev. Biol. 240 (2001) 108-122
35. Jenny A., Darken R.S., Wilson P.A., and Mlodzik M. Prickle and Strabismus form a functional complex to generate a correct axis during planar cell polarity signaling. EMBO J. 22 (2003) 4409-4420
36. Joos T.O., Whittaker C.A., Meng F., DeSimone D.W., Gnau V., and Hausen P. Integrin alpha 5 during early development of Xenopus laevis. Mech. Dev. 50 (1995) 187-199
37. Keller R.E. The cellular basis of epiboly: An SEM study of deep-cell rearrangement during gastrulation in Xenopus laevis. J. Embryol. Exp. Morphol. 60 (1980) 201-234
38. Keller R. Early embryonic development of Xenopus laevis. Methods Cell Biol. 36 (1991) 61-113
39. Keller R. The origin and morphogenesis of amphibian somites. Curr. Top. Dev. Biol. 47 (2000) 183-246
40. Keller R. Shaping the vertebrate body plan by polarized embryonic cell movements. Science 298 (2002) 1950-1954
41. Keller R. Mechanisms of elongation in embryogenesis. Development 133 (2006) 2291-2302
42. Keller R., and Shook D.R. Gastrulation in Amphibians. In: Stern C. (Ed). Gastrulation: From Cells to Embryos (2004), Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY 171-203
43. Keller R., Davidson L., Edlund A., Elul T., Ezin M., Shook D., and Skoglund P. Mechanisms of convergence and extension by cell intercalation. Philos. Trans. R. Soc. London B 355 (2000) 897-922
44. Keller R., Davidson L.A., and Shook D.R. How we are shaped: The biomechanics of gastrulation. Differentiation 71 (2003) 171-205
45. Koehl M.A.R. Biomechanical approaches to morphogenesis. Semin. Dev. Biol. 1 (1990) 367-378
46. Lane M.C., and Keller R. Microtubule disruption reveals that Spemann's organizer is subdivided into two domains by the vegetal alignment zone. Development 124 (1997) 895-906
47. Lane M.C., and Sheets M.D. Heading in a new direction: Implications of the revised fate map for understanding Xenopus laevis development. Dev. Biol. 296 (2006) 12-28
48. Larkin K., and Danilchik M.V. Ventral cell rearrangements contribute to anterior-posterior axis lengthening between neurula and tailbud stages in Xenopus laevis. Dev. Biol. 216 (1999) 550-560
49. Lee C., Scherr H.M., and Wallingford J.B. Shroom family proteins regulate {gamma}-tubulin distribution and microtubule architecture during epithelial cell shape change. Development 134 (2007) 1431-1441
50. Lee G., Hynes R., and Kirschner M. Temporal and spatial regulation of fibronectin in early Xenopus development. Cell 36 (1984) 729-740
51. Lo C.M., Wang H.B., Dembo M., and Wang Y.L. Cell movement is guided by the rigidity of the substrate. Biophys. J. 79 (2000) 144-152
52. Longo D., Peirce S.M., Skalak T.C., Davidson L., Marsden M., Dzamba B., and DeSimone D.W. Multicellular computer simulation of morphogenesis: Blastocoel roof thinning and matrix assembly in Xenopus laevis. Dev. Biol. 271 (2004) 210-222
53. Malacinski G.M., Ariizumi T., and Asashima M. Work in progress: The renaissance in amphibian embryology. Comp. Biochem. Physiol. B Biochem. Mol. Biol. 126 (2000) 179-187
54. Marsden M., and DeSimone D.W. Regulation of cell polarity, radial intercalation and epiboly in Xenopus: Novel roles for integrin and fibronectin. Development 128 (2001) 3635-3647
55. Marsden M., and DeSimone D.W. Integrin-ECM interactions regulate cadherin-dependent cell adhesion and are required for convergent extension in Xenopus. Curr. Biol. 13 (2003) 1182-1191
56. Minsuk S.B., and Keller R.E. Surface mesoderm in Xenopus: A revision of the stage 10 fate map. Dev. Genes Evol. 207 (1997) 389-401
57. Mogilner A., Wollman R., and Marshall W.F. Quantitative modeling in cell biology: What is it good for?. Dev. Cell 11 (2006) 279-287
58. Nakatsuji N., Smolira M.A., and Wylie C.C. Fibronectin visualized by scanning electron microscopy immunocytochemistry on the substratum for cell migration in Xenopus laevis gastrulae. Dev. Biol. 107 (1985) 264-268
59. Nieuwkoop P.D., and Faber J. Normal Tables of Xenopus laevis (Daudin) (1967), Elsevier/North-Holland Biomedical Press, Amsterdam
60. Nobes C.D., and Hall A. Rho, rac, and cdc42 GTPases regulate the assembly of multimolecular focal complexes associated with actin stress fibers, lamellipodia, and filopodia. Cell 81 (1995) 53-62
61. Papan C., Boulat B., Velan S.S., Fraser S.E., and Jacobs R.E. Formation of the dorsal marginal zone in Xenopus laevis analyzed by time-lapse microscopic magnetic resonance imaging. Dev. Biol (2007)
62. Park T.J., Gray R.S., Sato A., Habas R., and Wallingford J.B. Subcellular localization and signaling properties of dishevelled in developing vertebrate embryos. Curr. Biol. 15 (2005) 1039-1044
63. Pelham Jr. R.J., and Wang Y. Cell locomotion and focal adhesions are regulated by substrate flexibility. Proc. Natl. Acad. Sci. USA 94 (1997) 13661-13665
64. Platt J.R. Strong inference. Science 146 (1964) 347-353
65. Ramos J.W., and DeSimone D.W. Xenopus embryonic cell adhesion to fibronectin: Position-specific activation of RGD/synergy site-dependent migratory behavior at gastrulation. J. Cell Biol. 134 (1996) 1-14
66. Ramos J.W., Whittaker C.A., and DeSimone D.W. Integrin-dependent adhesive activity is spatially controlled by inductive signals at gastrulation. Development 122 (1996) 2873-2883
67. Rand H.W. Wound closure in actinian tentacles with reference to the problem of organization. Dev. Genes Evol. 41 (1915) 159-214
68. Ren R., Nagel M., Tahinci E., Winklbauer R., and Symes K. Migrating anterior mesoderm cells and intercalating trunk mesoderm cells have distinct responses to Rho and Rac during Xenopus gastrulation. Dev. Dyn. 235 (2006) 1090-1099
69. Sasai Y., Lu B., Steinbeisser H., Geissert D., Gont L.K., and Robertis E.M.D. Xenopus chordin: A novel dorsalizing factor activated by organizer-specific homeobox genes. Cell 79 (1994) 779-790
70. Sawhney R.K., and Howard J. Slow local movements of collagen fibers by fibroblasts drive the rapid global self-organization of collagen gels. J. Cell Biol. 157 (2002) 1083-1091
71. Schroeder T.E. Neurulation in Xenopus laevis. An analysis and model based upon light and electron microscopy. J. Embryol. Exp. Morphol. 23 (1970) 427-462
72. Shih J., and Keller R. Cell motility driving mediolateral intercalation in explants of Xenopus laevis. Development 116 (1992) 901-914
73. Shih J., and Keller R. Patterns of cell motility in the organizer and dorsal mesoderm of Xenopus laevis. Development 116 (1992) 915-930
74. Shook D.R., Majer C., and Keller R. Urodeles remove mesoderm from the superficial layer by subduction through a bilateral primitive streak. Dev. Biol. 248 (2002) 220-239
75. Shook D.R., Majer C., and Keller R. Pattern and morphogenesis of presumptive superficial mesoderm in two closely related species, Xenopus laevis and Xenopus tropicalis. Dev. Biol. 270 (2004) 163-185
76. Sivakumar P., Czirok A., Rongish B.J., Divakara V.P., Wang Y.P., and Dallas S.L. New insights into extracellular matrix assembly and reorganization from dynamic imaging of extracellular matrix proteins in living osteoblasts. J. Cell Sci. 119 (2006) 1350-1360
77. Sive H.L., Grainger R.M., and Harland R.M. Early Development of Xenopus laevis: A Laboratory Manual (2000), Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY p. 338
78. Skoglund P., and Keller R. Xenopus fibrillin regulates directed convergence and extension. Dev. Biol. 301 (2007) 404-416
79. Skoglund P., Dzamba B., Coffman C.R., Harris W.A., and Keller R. Xenopus fibrillin is expressed in the organizer and is the earliest component of matrix at the developing notochord-somite boundary. Dev. Dyn. 235 (2006) 1974-1983
80. Steinberg M.S., and Gilbert S.F. Townes and Holtfreter (1955): Directed movements and selective adhesion of embryonic amphibian cells. J. Exp. Zoolog. A Comp. Exp. Biol. 301 (2004) 701-706
81. Stern C.D. Gastrulation: From Cells to Embryo (2004), Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
82. Stopak D., and Harris A.K. Connective tissue morphogenesis by fibroblast traction. I. Tissue culture observations. Dev. Biol. 90 (1982) 383-398
83. Trinkaus J.P. Cells into Organs: The Forces that Shape the Embryo (1984), Prentice-Hall Inc., Englewood Cliffs
84. Wacker S., Grimm K., Joos T., and Winklbauer R. Development and control of tissue separation at gastrulation in Xenopus. Dev. Biol. 224 (2000) 428-439
85. Wallingford J.B., Fraser S.E., and Harland R.M. Convergent extension: The molecular control of polarized cell movement during embryonic development. Dev. Cell 2 (2002) 695-706
86. Wardle F.C., and Smith J.C. Transcriptional regulation of mesendoderm formation in Xenopus. Semin. Cell Dev. Biol. 17 (2006) 99-109
87. Weliky M., Minsuk S., Keller R., and Oster G. Notochord morphogenesis in Xenopus laevis: Simulation of cell behavior underlying tissue convergence and extension. Development 113 (1991) 1231-1244
88. Winklbauer R. Conditions for fibronectin fibril formation in the early Xenopus embryo. Dev. Dyn. 212 (1998) 335-345
89. Winklbauer R., and Schurfeld M. Vegetal rotation, a new gastrulation movement involved in the internalization of the mesoderm and endoderm in Xenopus. Development 126 (1999) 3703-3713
90. Winklbauer R., Selchow A., Nagel M., Stoltz C., and Angres B. Mesoderm cell migration in the Xenopus gastrula. In: Keller R., Clark W., and Griffin F. (Eds). Gastrulation: Movements, Patterns, and Molecules (1991), Plenum Press, New York/London 147-168
91. Winklbauer R., Nagel M., Selchow A., and Wacker S. Mesoderm migration in the Xenopus gastrula. Int. J. Dev. Biol. 40 (1996) 305-311
92. Winklbauer R., Medina A., Swain R.K., and Steinbeisser H. Frizzled-7 signaling controls tissue separation during Xenopus gastrulation. Nature 413 (2001) 856-860
93. Zajac M., Jones G.L., and Glazier J.A. Simulating convergent extension by way of anisotropic differential adhesion. J. Theor. Biol. 222 (2003) 247-259
94. Zhong C., Chrzanowska-Wodnicka M., Brown J., Shaub A., Belkin A.M., and Burridge K. Rho-mediated contractility exposes a cryptic site in fibronectin and induces fibronectin matrix assembly. J. Cell Biol. 141 (1998) 539-551
95. Zhong Y., Brieher W.M., and Gumbiner B.M. Analysis of C-cadherin regulation during tissue morphogenesis with an activating antibody. J. Cell Biol. 144 (1999) 351-359