PATHWAYS OF CELLULAR MORPHOGENESIS: A Diversity in Nitella

doi:10.1083/jcb.27.2.343

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ARTICLE

PATHWAYS OF CELLULAR MORPHOGENESIS : A Diversity in Nitella

Paul B. Green ¹

¹ From the Department of Cytology, Dartmouth Medical School, and Department of Biological Sciences, Dartmouth College, Hanover, New Hampshire.

Dr. Green's present address is Department of Biology, University of Pennsylvania, Philadelphia

Evidence is presented to show that a given change in cell formor size may generally be brought about by a variety of patternsof local surface distortion and expansion. Structural and chemicalfeatures of the cell which are important in morphogenesis maythus be expected to relate not to form per se but to the kineticsof surface behavior which establish form. These kinetics evaluateboth the rate at which local regions of cell surface expandand the directed character (anisotropy) of this expansion. Thesevariables have been studied in model systems and, through markingexperiments, in growing cells of various shapes in Phycomyces,Clypeaster, and particularly Nitella. In the latter plant, prominent"giant internodes" display a well defined longitudinal anisotropicexpansion devoid of sizeable gradients in expansion rate. Thesecells have their origin, however, in apical cells which havea pronounced gradient in area expansion rate (maximal at thetip). The great part of the expansion in the apical cell isapparently isotropic (equal in all directions), but the basalregion often shows predominant expansion laterally. This transversestretching in the apical cell could align cell wall textureand possibly fibrous cytoplasmic constituents, such as microtubules,into configurations significant in later morphogenetic stages,including the elongation of the internodes.

Submitted on May 13, 1965

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