Mechanics and control of the cytoskeleton in Amoeba proteus.

Many models of the cytoskeletal motility of Amoeba proteus can be formulated in terms of the theory of reactive interpenetrating flow (Dembo and Harlow, 1986). We have devised numerical methodology for testing such models against the phenomenon of steady axisymmetric fountain flow. The simplest workable scheme revealed by such tests (the minimal model) is the main preoccupation of this study. All parameters of the minimal model are determined from available data. Using these parameters the model quantitatively accounts for the self assembly of the cytoskeleton of A. proteus: for the formation and detailed morphology of the endoplasmic channel, the ectoplasmic tube, the uropod, the plasma gel sheet, and the hyaline cap. The model accounts for the kinematics of the cytoskeleton: the detailed velocity field of the forward flow of the endoplasm, the contraction of the ectoplasmic tube, and the inversion of the flow in the fountain zone. The model also gives a satisfactory account of measurements of pressure gradients, measurements of heat dissipation, and measurements of the output of useful work by amoeba. Finally, the model suggests a very promising (but still hypothetical) continuum formulation of the free boundary problem of amoeboid motion. by balancing normal forces on the plasma membrane as closely as possible, the minimal model is able to predict the turgor pressure and surface tension of A. proteus. Several dynamical factors are crucial to the success of the minimal model and are likely to be general features of cytoskeletal mechanics and control in amoeboid cells. These are: a constitutive law for the viscosity of the contractile network that includes an automatic process of gelation as the network density gets large; a very vigorous cycle of network polymerization and depolymerization (in the case of A. proteus, the time constant for this reaction is approximately 12 s); control of network contractility by a diffusible factor (probably calcium ion); and control of the adhesive interaction between the cytoskeleton and the inner surface of the plasma membrane.

[1]  R. Allen The consistency of ameba cytoplasm and its bearing on the mechanism of ameboid movement. II. The effects of centrifugal acceleration observed in the centrifuge microscope. , 1960, The Journal of biophysical and biochemical cytology.

[2]  A. Pigon,et al.  Diffusion and active transport of water in amoeba Chaos chaos l. , 1952, Comptes rendus des travaux du Laboratoire Carlsberg. Serie chimique.

[3]  T. Jahn Relative Motion in Amoeba proteus 1 , 1964 .

[4]  A. Grębecki Supramolecular aspects of amoeboid movement , 1982 .

[5]  The molecular basis of amoeboid movement. , 1975, Society of General Physiologists series.

[6]  F. Harlow,et al.  Cell motion, contractile networks, and the physics of interpenetrating reactive flow. , 1986, Biophysical journal.

[7]  William E. Pracht,et al.  A numerical method for calculating transient creep flows , 1971 .

[8]  R. Skalak,et al.  Passive deformation analysis of human leukocytes. , 1988, Journal of biomechanical engineering.

[9]  P. Åstrand,et al.  Textbook of Work Physiology , 1970 .

[10]  R. D. ALLEN,et al.  Streaming in Cytoplasm Dissociated from the Giant Amœba, Chaos Chaos , 1960, Nature.

[11]  M. Dembo The mechanics of motility in dissociated cytoplasm. , 1986, Biophysical journal.

[12]  Josef Stoer,et al.  Solution of Large Linear Systems of Equations by Conjugate Gradient Type Methods , 1982, ISMP.

[13]  Louis A. Hageman,et al.  Iterative Solution of Large Linear Systems. , 1971 .

[14]  R. D. Allen,et al.  THE CONTRACTILE BASIS OF AMOEBOID MOVEMENT , 1973, The Journal of cell biology.

[15]  D. Taylor,et al.  Mobility of cytoplasmic and membrane-associated actin in living cells. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[16]  D. Taylor,et al.  Subcellular compartmentalization by local differentiation of cytoplasmic structure. , 1988, Cell motility and the cytoskeleton.

[17]  T. Pollard,et al.  Cytoplasmic filaments of Amoeba proteus. I. The role of filaments in consistency changes and movement. , 1970 .

[18]  J. Happel,et al.  Low Reynolds number hydrodynamics , 1965 .