FOOD VACUOLE MEMBRANE GROWTH WITH MICROTUBULE-ASSOCIATED MEMBRANE TRANSPORT IN PARAMECIUM

doi:10.1083/jcb.63.3.904

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ARTICLE

FOOD VACUOLE MEMBRANE GROWTH WITH MICROTUBULE-ASSOCIATED MEMBRANE TRANSPORT IN PARAMECIUM

Richard D. Allen ¹

¹ From the Pacific Biomedical Research Center and Department of Microbiology, University of Hawaii, Honolulu, Hawaii 96822

Evidence from a morphological study of the oral apparatus ofParamecium caudatum using electron microscope techniques haveshown the existence of an elaborate structural system whichis apparently designed to recycle digestive-vacuole membrane.Disk-shaped vesicles are filtered out of the cytoplasm by agroup of microtubular ribbons. The vesicles, after being transportedto the cytostome-cytopharynx region in association with theseribbons, accumulate next to the cytopharynx before they becomefused with the cytopharyngeal membrane. This fusion allows thenascent food vacuole to grow and increase its membrane surfacearea. The morphology of this cytostome-cytopharynx region isdescribed in detail and illustrated with a three-dimensionaldrawing of a portion of this region and a clay sculpture ofthe oral apparatus of Paramecium. Evidence from the literaturefor the transformation of food vacuole membrane into disk-shapedvesicles both from condensing food vacuoles in the endoplasmand from egested food vacuoles at the cytoproct is presented.This transformation would complete a system of digestive vacuolemembrane recycling.

Submitted on June 10, 1974
Revised on August 29, 1974

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