Nematode-Induced Syncytium--A Multinucleate Transfer Cell

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Submitted on November 25, 1971

Nematode-Induced Syncytium--A Multinucleate Transfer Cell

M. G. K. JONES ¹ and D. H. NORTHCOTE ¹

¹ Department of Biochemistry, University of Cambridge, Cambridge CB2 1 QW, England

The formation and structure of a syncytium induced by the potatocyst-nematode (Heterodera rostochiensis Woll.) in potato rootsis described.

At the permanent feeding site of the nematodelarva, usually in the root cortex, the larva pierces a cellwith its mouth stylet and injects saliva. Cell wall dissolutionoccurs to incorporate neighbouring cells into a syncytium. Acolumn of cells is incorporated towards the vascular tissue.Centripetal advance is limited by the lignifled xylem, thensyncytial spread continues laterally along xylem parenchymaand pericycle cells.

Wall protuberances form on syncytial wallsadjacent to conducting elements. This indicates the syncytiumis a multinucleate transfer cell, and by ingesting syncytialcontents the larva is the nutrient sink. As syncytial expansionoccurs, sieve elements are crushed and probably cease to function,hence protuberance development continues only against xylemelements.

Cell alterations on incorporation into the syncytiuminvolve expansion, loss of cell vacuole, nuclear hypertrophyand a proliferation of cytoplasmic organelles free to move throughwall gaps into the communal cytoplasm.

‘Boundary formations’and microtubules are associated with the growing ends of protuberances, and appear to be involved in their synthesis. Fibrillarmaterial, possibly cellulose microfibrils, occurs between theplasrnalemma and the membrane of the ‘boundary formation’,and the forming protuberance.

To induce the formation of thesyncytium, the larva controls the differentiation of unspecializedcells to cells with a specific physiological function. The occurrenceof wall protuberances suggests that transfer cells form as aresponse to solute flow.

Submitted on November 25, 1971

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