Valonia ventricosa has a coenocytic structure with multiple nuclei and chloroplasts. This organism possesses a large central vacuole which is multilobular in structure. The entire cell contains several cytoplasmic domains with each domain having a nucleus and a few chloroplasts. Cytoplasmic domains are interconnected by cytoplasmic "bridges" that are supported by microtubules. The peripheral cytoplasm, is only about 40 nm thick. Valonia ventricosa typically grow individually, but in rare cases they can grow in groups.
Environment
They appear in tidal zones of tropical and subtropical areas, like the Caribbean, north through Florida, south to Brazil, and in the Indo-Pacific. Overall, they inhabit every ocean throughout the world, often living in coral rubble. The greatest observed depth for viability is approximately.
The single-cell organism has forms ranging from spherical to ovoid, and the color varies from grass green to dark green, although in water they may appear to be silver, teal, or even blackish. This is determined by the quantity of chloroplasts of the specimen. The surface of the cell shines like glass when clean due to being extremely smooth with no texture. The thallus consists of a thin-walled, tough, multinucleate cell with a diameter that ranges typically from although it may achieve a diameter of up to in rarer cases. The "bubble" alga is attached by rhizoids to the substrate fibers. Reproduction occurs by segregative cell division, where the multinucleate parent cell makes child cells, and individual rhizoids form new bubbles, which become separate from the parent cell.
Studies
Valonia ventricosa has been studied particularly because the cells are so unusually large that they provide a convenient subject for studying the transfer of water and water-soluble molecules across biological membranes. It was concluded that the properties of permeability in both osmosis and diffusion were identical, and that urea and formaldehyde molecules did not require any kind of postulated water-filled pores in the membrane to move through it. In studying the cellulose lattice, and its orientation in biological structures, Valonia ventricosa has undergone extensive X-ray analytical procedures. It has also been studied for its electrical properties, due to its unusually high electrical potentialrelative to the seawater that surrounds it.
