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Freeze fracture evidence for lateral phase separations in the plasmalemma of chilling-injured avocado fruit (1987)

Platt-Aloia, K. A. ; Thomson, W. W.

Springer

Protoplasma 136 (1987), S. 71-80

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ISSN: 1615-6102

Keywords: Avocado ; Chilling injury ; Freeze-fracture ; Gel-phase lipid ; Membranes ; Phase separations

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Unripe avocado fruit (Persea americana Mill. cv Hass) were held at 6 °C either in air or in an atmosphere with 100 PPM ethylene and were assessed for chilling injury after one and two weeks. Injury did not occur in any fruit after one week. After two weeks, the fruit in air were still uninjured, but the fruit subjected to ethylene exhibited chilling injury. When the uninjured fruit (both air-treated for one and two weeks and ethylene-treated for one week) were allowed to warm to room temperature before freezing for freeze fracture electron microscopy, replicas revealed membranes with a randomly dispersed pattern of intramembranous particles (IMPs). However, when these uninjured fruit were frozen for freeze fracture without warming, particle-free domains were visible in the plasmalemma. The membranes of the ethylene-treated, chilling-injured (2 weeks) fruit, on the other hand, contained particle-depleted regions in the plasmalemma of fruit frozen not only from 6 °C but also in those allowed to warm to room temperature before freezing for freeze fracture. These particle depleted microdomains were not seen in fruit kept continuously at room temperature (20 °C), even in the presence of high levels of endogenous ethylene which is produced during normal ripening. We suggest these particle-depleted microdomains formed in the fruit frozen for freeze fracture from low temperatures and in the chilling-injured fruit to be due to lateral phase separations of the membrane components, possibly due to an increase in the viscosity of some membrane lipids, leading to the formation of microdomains of gel phase lipid in the plane of the membrane. These phase separations appear to be initially reversible by raising the temperature, however, this reversibility is apparently lost after injury has occurred. With regard to the cause of chilling injury in avocados, we suggest that some secondary effect is involved due to the long term presence of gel phase lipids in the membrane.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01276356

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The vacuolar-tubular continuum in living trichomes of chickpea (Cicer arietinum) provides a rapid means of solute delivery from base to tip (1996)

Lazzaro, M. D. ; Thomson, W. W.

Springer

Protoplasma 193 (1996), S. 181-190

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ISSN: 1615-6102

Keywords: Cicer arietinum ; Confocal microscopy ; Lucifer yellow CH ; Plasmodesmata ; Trichomes ; Vacuoles

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary A vacuolar continuum exists from base to tip in the secretory trichomes of chickpea (Cicer arietinum). This continuum is seen in living trichomes which have been labeled with Lucifer yellow CH and examined with confocal microscopy. It encompasses the large vacuole of the lower stalk cell, the vacuoles and tubules of the central stalk cell, the thin tubules of the upper stalk cell, and the tubules and vacuoles of the secretory head cells. The vacuolar-tubular system is structurally distinct within each cell, forming a gradient of large vacuoles in the lower stalk cell, thick tubules in the central stalk cell, and thin anastamozing tubules in the upper stalk cell. This membrane system appears to be continuous between trichome cells, as thin tubules emanate from plasmodesmata between stalk cells and between the upper stalk and lower head cell. In the upper stalk cell, the thin tubules of this continuum are streaming up and down the long axis of the cell at 0.67 μm/s. The larger vacuolar-tubular system in the central and lower stalk cells is also slowly moving, with apparent peristalsis occurring in the central cell. The vacuolar-tubular system of the secretory head cells is completely labeled with Lucifer yellow when the dye has only partly diffused up the long walls of the trichome, indicating that the streaming tubular system delivers solute through the stalk cells to the secretory head cells faster than diffusion through the trichome walls. In the lower head cells, tubules emanate from the plasmodesmata connecting to the upper stalk cell, and these tubules are continuous with the head cell vacuoles. In addition, another layer of thin tubules forms along the edges of the secretory head cells, at the site of exocytotic secretion. We propose that the continuous vacuolar-tubular system in these trichomes functions to rapidly deliver solute from the base of the trichome to the secretory head cells. This system provides a pathway for the transport of secretory material.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01276644

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