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J. Brachet (1960)
International Series of Monographs in pure and applied Biology. Vol.2
C.P. Raven (1961)
Oogenesis: The storage of developmental information
G. Reverberi, A. Minganti (1946)
Fenomeni di evocazione nelle sviluppo dell'uovo di AscidiePubl. Staz. Zool. Napoli, 20
C. Waddington (1966)
Fields and Gradients
Mc Carthy (1966)
Information. A Scientific American book
G. Reverberi (1970)
The ultrastructure of the ripe oocyte of Dentalium.Acta embryologiae experimentalis, 3
J. Lash (1963)
Tissue Interaction and Specific Metabolic Responses: Chondrogenic Induction and Differentiation
L. Saxén, O. Koskimies, A. Lahti, H. Miettinen, J. Rapola, J. Wartiovaara (1968)
Differentiation of kidney mesenchyme in an experimental model system.Advances in morphogenesis, 7
T. Yamada (1967)
Cell differentiation
G. Czihak (1977)
Kinetics of RNA synthesis in the 16-cell stage of the sea-urchin Paracentrotus lividusRoux Arch. EntwMech. Organ., 182
Ede Da (1971)
Control of form and pattern in the vertebrate limb.Symposia of the Society for Experimental Biology, 25
P.D. Nieuwkoop (1977)
Current topics in developmental Biology 11
C.H. Waddington (1940)
Organizers and genes
G. Ortolani (1958)
Cleavage and development of egg fragments in ascidiansActa Embryol. Morphol. exp., 1
Par Guerrier (1970)
Les caractères de la segmentation et la détermination de la polarité dorsoventrale dans le développement de quelques Spiralia: I. Les formes à premier clivage égalDevelopment, 23
S.J. Counce (1973)
Developmental systems: Insects, 2
M. Apter, L. Wolpert (1965)
Cybernetics and development. I. Information theory.Journal of theoretical biology, 8 2
A. Dalcq (1960)
A comparison of the various types of egg organization
G. Lopashov, O. Stroeva (1964)
Development of the eye : experimental studies
E.K. Boon-Niermeijer (1975)
The effect of puromycin on the early cleavage cycles and morphogenesis of the Pond Snail Lymnaea stagnalisRoux Arch. EntwMech. Organ., 177
J. Devriès (1976)
(Autoradiographie à l'uracile 3Activité génétique au cours de l'embryogenèse de l'oligochète Eisenia foetidaH et traitement à l'actinomycine D)J. Embrvol. exp. Moroh., 35
C. Waddington (1966)
Cybernetics and developmentJournal of the Operational Research Society, 17
P. Brien (1968)
Blastogenesis and morphogenesis.Advances in morphogenesis, 7
C.F. Graham, S.J. Kelly (1977)
Cell interactions in differentiation
W.R. Ashby (1958)
Requisite variety and its implication for the control of complex systemsCybernetica, 1
J. Pasteels (1938)
Recherches sur les facteurs initiaux de la morphogenèse chez les amphibiens anouresArch. Biol., 49
G. Reverberi (1968)
La mánique du développement de l'oeuf des AscidiesAnnée biol., 7
B. Brandhorst (1976)
Two-dimensional gel patterns of protein synthesis before and after fertilization of sea urchin eggs.Developmental biology, 52 2
(1973)
The causal analysis of insect embryogenesis
G. Czihak (1965)
Evidences for inductive properties of the micromeres RNA in seaurchin embryosNaturwissenschaften, 52
G.R. Martin (1975)
Teratocarcinoma as model system for the study of embryogenesis and neoplasia. A reviewCell, 5
E. Parisi, S. Filosa, B. Petrocellis, A. Monroy (1978)
The pattern of cell division in the early development of the sea urchin. Paracentrotus lividus.Developmental biology, 65 1
C. Graham, S. Kelly (1977)
Interactions between Embryonic Cells during the Early Development of the Mouse
G. Reverberi (1961)
The Embryology of Ascidians, 1
J. Pasteels (1964)
THE MORPHOGENETIC ROLE OF THE CORTEX OF THE AMPHIBIAN EGG.Advances in morphogenesis, 4
J. Devriès (1973)
Détermination précoce du dévelopment embryonnaire chez le lombricien Eisenia foetidaBull. Soc. Zool. Fr., 98
J. Ebert, M. Kaighn, M. Locke (1966)
The keys to change: factors regulating differentiation.
P. Nieuwkoop (1977)
Origin and establishment of embryonic polar axes in amphibian development.Current topics in developmental biology, 11
S. Hörstadius, J.I. Lorch, J.F. Danielli (1953)
The effect of enucleation on the development of sea-urchin eggs. II. Enucleation of animal and vegetal halvesExp. Cell Res., 4
Rosine Chandebois (1977)
Cell sociology and the problem of position effect: Pattern formation, origin and role of gradientsActa Biotheoretica, 26
R. Lallier (1964)
BIOCHEMICAL ASPECTS OF ANIMALIZATION AND VEGETALIZATION IN THE SEA URCHIN EMBRYO.Advances in morphogenesis, 4
C.H. Waddington (1966)
Major problems in developmental biology
S. Hörstadius (1935)
Ueber die Determination im Verlaufe der Eiachse bei SeeigelnPubl. Staz. Zool. Napoli, 14
B. Levak-Svajger, A. Svajger (1970)
Differentiation in homografts of isolated germ layers of the rat embryoArch. Sci. Biol., 22
P. Devriès (1976)
Activité génétique au cours de l'embryogenèse de l'Oligochète Eisenia fœtida (autoradiographie à l'uracile-3H et traitement à l'actinomycine D)Development, 35
Rosine Chandebois (1976)
Cell sociology: A way of reconsidering the current concepts of morphogenesisActa Biotheoretica, 25
G. Martin (1975)
Teratocarcinomas as a model system for the study of embryogenesis and neoplasiaCell, 5
J. Devriès (1973)
Aspect du déterminisme embryonnaire au cours des premiers stades de la segmentation chez le lombricien Eisenia foetidaAnn. Embryol. Morph., 6
W. Beermann (1966)
Cell differentiation and morphogenesis
J.W. Lash (1963)
Cytodifferentiation and macromolecular synthesis
J. Rossant (1975)
Investigation of the determinative state of the mouse inner cell mass. II. The fate of isolated inner cell masses transferred to the oviduct.Journal of embryology and experimental morphology, 33 4
J. Brachet (1972)
The Biochemistry of DevelopmentArchives of Disease in Childhood, 47
L. Smith, R. Ecker (1970)
Regulatory processes in the maturation and early cleavage of amphibian eggs.Current topics in developmental biology, 5
F.E. Lehmann (1958)
A symposium on the chemical basis of development
P.D. Nieuwkoop (1969)
The formation of the mesodern in urodelean amphibians. I. The induction by the endodermRoux Arch. EntwMech. Organ., 162
G. Freeman (1976)
The role of cleavage in the localization of developmental potential in the ctenophore Mnemiopsis leidyi.Developmental biology, 49 1
Par Guerrier (1970)
Les caractères de la segmentation et la détermination de la polarité dorsoventrale dans le développement de quelques Spiralia: II. Sabellaria alveolata (Annélide polychète)Development, 23
J. Rossant (1975)
Investigation of the determinative state of the mouse inner cell masses transferred to the oviductJ. Embryol. exp. Morph., 33
M. Arbib (1972)
Chapter 3 – AUTOMATA THEORY IN THE CONTEXT OF THEORETICAL EMBRYOLOGY
S. Hörstadius, I. Lorch, J. Danielli (1953)
Enucleation of sea urchin eggs: II. Enucleation of animal or vegetal halvesExperimental Cell Research, 4
G. Reverberi (1946)
Fenomeni di evocazione nello sviluppo dell'uovo di Ascidie. Risultati dell'indagine sperimentale sull'uovo di Ascidiella aspersa e di Ascidia malaca allo stadio di otto blastomeri, 20
J. Pasteels (1934)
Recherches sur le morphogenèse et le dérminisme des segmentations ináles chez les SpiraliaArch. Anat. mocro., 30
T. Elsdale, K. Jones (1963)
The independence and interdependence of cells in the amphibian embryo.Symposia of the Society for Experimental Biology, 17
R. Chandebois (1976)
Morphogénétique des animaux pluricellulaires
S. Counce, D. Ede (1957)
The Effect on Embryogenesis of a Sex-linked Female-Sterility Factor in Drosophila melanogasterDevelopment, 5
C. Waddington (2016)
Principles of Embryology
T. Gustafson (1965)
The biochemistry of animal development, I
P. Guerrier (1970)
Les caractères de la segmentation et la détermination de la polarité dorsoventrale dans le développement de quelques Spiralia. III. Pholas dactylus et Spisula subtruncata (Mollusques Lamellibranches)J. Embryol. exp. Morph., 23
K. Dan (1972)
Modified cleavage pattern after suppression of one mitotic division.Experimental cell research, 72 1
P. Brien (1974)
Propos d'un zoologiste: Le vivant: épigenèse, évolution épigénétique
M.A. Arbib (1972)
Foundations of mathematical biology. Vol. 2: Cellular systems
K. Hara (1977)
The cleavage pattern of the Axolotl egg studied by cinematography and cell countingRoux Arch. EntwMech. Organ., 181
T. Dettlaff (1964)
CELL DIVISIONS, DURATION OF INTERKINETIC STATES AND DIFFERENTIATION IN EARLY STAGES OF EMBRYONIC DEVELOPMENT.Advances in morphogenesis, 4
H. Atlan (1972)
L'organisation biologique et la théorie de l'information. (Actualités scientifiques et industrielles)
L. Stevens (1967)
The biology of teratomas.Advances in morphogenesis, 6
T. Morgan (1934)
Embryology And Genetics
M. Sala (1955)
Distribution of activating and transforming influences in the archenteron roof during the induction of the nervous system in amphibiansProc. Acad. Sci. Amst. Ser.C, 58
L. Wolpert (1969)
Positional information and the spatial pattern of cellular differentiation.Journal of theoretical biology, 25 1
R. Auerbach (1960)
Self-organizing systems
The principles of automation (automatism and programming) in the unfolding of spatio-temporal patterns during animal development are deduced from experimental data reconsidered from the point of view of cell sociology. The developmental programme in the egg is not part of the genetic information but a part of the cytoplasmic information. Throughout development cells store extra-cellular information released by their neighbours in the form of cytoplasmic information. Successive determinations cannot be considered as successive reprogrammings of cells: each one consists of a selection of one specific programme from the total information previously stored. This programme specifies cell interactions in the determined population as a whole; it is very imprecise and is progressively completed during the course of further differentiation by information released by neighbouring cell populations. Complicated patterns may emerge from only two homogeneous populations involved in distinct differentiation pathways and confronting each other. Consequently the ‘egg developmental programme’ provides gene effectors and specific physico-chemical conditions necessary for the starting of at least two distinct differentation pathways. Experimental data suggest that there are two components in this programme. One is a molecular machinery which starts at fertilization in the whole cytoplasm. It yields two programmes of differentiation, typically first an endodermal and then an ectodermal one. The other component of the egg developmental programme, which does not require specific information, allows the interception of the first (endodermal) programme. The application of informatics to developmental automatism is discussed in the latter part of the paper.
Acta Biotheoretica – Springer Journals
Published: Apr 30, 2004
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