Structure and molecular organization of higher plant coated vesicles

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Submitted on April 8, 1987
Accepted on May 20, 1987

Structure and molecular organization of higher plant coated vesicles

JULIAN COLEMAN ¹, DAVID EVANS ¹, CHRIS HAWES ², DAVID HORSLEY ², and LOUISE COLE ²

¹ Department of Plant Sciences, Oxford University, Smith Parks Road, Oxford OX1 3RA, UK
² Department of Plant Sciences, Oxford University Smith Parks Road, Oxford OX1 3RA, UK

Author for correspondence

Suspension-cultured cells of carrot contain three populationsof coated vesicles, associated with the plasma membrane (84-91nm diameter), Golgi dictyosomes and the partially coated reticulum(61-73 nm diameter). These were observed by thin sectioning,dry-cleaving and rapid-freeze deep-etching of cells. Dissociationof clathrin coats with Tris, released triskelions that weremorphologically identical with those from mammalian tissue.The triskelion arm length of carrot clathrin was greater (61nmversus 44-50 nm), but packaging results in clathrin cages ofpentagons and hexagons of similar size to those from mammaliancells.

SDS-PAGE of Tris-released triskelion preparations revealeda complex of three polypeptides of 190, 60 and 57(x10³)M_r. The190x10³M_r protein is the plant clathrin heavy chain, slightlylarger than the mammalian heavy chain. The 60 and 57(x10³)M_rbands showed the same sensitivities to protease treatment asmammalian light chains. Triskelion preparations containing thesethree proteins reassembled into polyhedral cages.

These resultsare discussed in relation to the structural organization ofcoated vesicles and clathrin cages in other systems.

Key words: carrot suspension cultures, clathrin (plant), coated vesicles, electron microscopy, triskelion

Submitted on April 8, 1987
Accepted on May 20, 1987

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