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Control of Cell Elongation in Nitella by Endogenous Cell Wall pH Gradients

MULTIAXIAL EXTENSIBILITY AND GROWTH STUDIES ¹

Division of Natural Sciences, Thimann Laboratories, University of California, Santa Cruz, California 95064

The multiaxial stress of turgor pressure was stimulated in vitro by inflating isolated Nitella cell walls with mercury. The initial in vitro extension at pH 6.5, 5 atmospheres pressure, returned the wall approximately to the in vivo stressed length, and did not induce any additional extension during a 15-minute period. Upon release of pressure, a plastic deformation was observed which did not correlate with cell growth rates until the final stages of cell maturation. Since wall plasticity does not correlate with growth rate, a metabolic factor(s) is implicated. Walls at all stages of development exhibited a primary yield stress between 0 and 2 atmospheres, while rapidly growing cells (1-3% per hour) exhibited a secondary yield stress of 4 to 5 atmospheres. The creep rate and plastic deformation of young walls were markedly enhanced by acid buffers (10 millimolar, pH 5.3).

Nitella cells produce acid and base "bands" along their length due to localized excretion of protons and hydroxyl ions. Marking experiments showed that growth is largely restricted to the acid regions. Growth in the acid bands was inhibited by alkaline buffers, and growth in the base bands was stimulated by acidic buffers. The two zones have similar mechanical properties. When the proton-binding capacity of the wall was taken into account, the pH of the solution in contact with inner wall surface in the acid band was estimated to be about 4.3, well within the threshold of acid-enhanced creep. Since the inner 25% of the wall controls extensibility, we conclude that growth in the acid band is caused by the action of protons on the wall.

³ Present address: Department of Biological Sciences, University of the Pacific, Stockton, California 95211.

⁴ To whom reprint requests should be addressed.

¹ This research was supported by National Science Foundation Grant PCM77-25216 and by a grant from the Faculty Research Committee, University of California, Santa Cruz, to L. T.

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