A freeze-fracture study on the differentiation of Golgi and plasma membranes in plant cells.

Dictyosomes, Golgi vesicles, and plasma membranes were investigated after freeze-fracture in cells from growing root tips of cress (Lepidium sativum L.), that are distinguishable by different cellulose content of the cell wall, into (i) meristematic cells during early formation of the cell plate, (ii) statocytes of the root cap, and (iii) cortex cells of the differentiation zone. The results of this study show that the number of intramembrane particles (imps) is high in dictyosome cisternae, but low in membranes of budding or dictyosome-derived vesicles. Imps are disperse in the vesicle membranes of meristematic cells (i), but are often grouped into clusters in vesicle membranes of statocytes (ii), and of cortex cells (iii). For the number of particle aggregates in vesicle membranes, the following relation holds: (i) < (ii) < (iii). The number of particles on both fracture faces (PF and EF) of the plasma membrane differs widely between the cell types investigated. There are approximately 250, 1400, and 3100 imps microns-2 on the PF and 50, 500, and 300 on the EF of (i), (ii), and (iii), respectively. The structural complexity of the plasma membrane as judged by the degree of particle aggregations on the PF and the number of cellulose microfibrils in the cell wall show the same relationship: (i) < (ii) < (iii). Thus, the strong correlation between the distribution of imps in vesicle membranes, the structural complexity of the plasma membrane, and the content of cellulose microfibrils indicate that selection of imps during vesicle formation at dictyosome cisternae is an integral component of biogenesis and structural differentiation of plant plasma membranes.