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Chloroplast Grana Membrane Carboxyl Groups

Their Involvement in Membrane Association ¹

^a Departments of Biochemistry and Biological Sciences, Purdue University, West Lafayette, Indiana, 47905

Chloroplast membrane carboxyl groups were modified by carbodiimide activation followed by glycine methyl ester substitution, leaving the derivatized group uncharged. This charge alteration induced a number of effects similar to addition of salts to control chloroplasts suspended in a low salt medium. These include: (a) restacking or multiple membrane association in low salt-treated chloroplasts that lack grana stacks, (b) protection against polycation inhibition of photosystem I electron transfer, (c) reduction of the amount of polycations bound to the membranes, and (d) increased 90° light scattering due to membrane conformational changes. Carboxyl modification also altered acid-induced conformational changes.

These effects are interpretated as the results of the reduction in the surface negative charge contributed by carboxyl groups. Membrane structure at both a local, polyelectrolyte level and at the level of membrane-membrane interaction (stacking) is controlled in part by these negative, charged groups.