Mari Murai scite author profile

Water transport in plants is greatly dependent on the expression and activity of water transport channels, called aquaporins. Here, we have clarified the tissue- and cell-specific localization of aquaporins in rice plants by immunoblotting and immunocytochemistry using seven isoform-specific aquaporin antibodies. We also examined water transport activities of typical aquaporin family members using a yeast expression system in combination with a stopped-flow spectrophotometry assay. OsPIP1 members, OsPIP2;1, OsTIP1;1 and OsTIP2;2 were expressed in both leaf blades and roots, while OsPIP2;3, OsPIP2;5 and OsTIP2;1 were expressed only in roots. In roots, large amounts of aquaporins accumulated in the region adjacent to the root tip (around 1.5-4 mm from the root tip). In this region, cell-specific localization of the various aquaporin members was observed. OsPIP1 members and OsTIP2;2 accumulated predominantly in the endodermis and the central cylinder, respectively. OsTIP1;1 showed specific localization in the rhizodermis and exodermis. OsPIP2;1, OsPIP2;3 and OsPIP2;5 accumulated in all root cells, but they showed higher levels of accumulation in endodermis than other cells. In the region at 35 mm from the root tip, where aerenchyma develops, aquaporins accumulated at low levels. In leaf blades, OsPIP1 members and OsPIP2;1 were localized mainly in mesophyll cells. OsPIP2;1, OsPIP2;3, OsPIP2;5 and OsTIP2;2 expressed in yeast showed high water transport activities. These results suggest that rice aquaporins with various water transport activities may play distinct roles in facilitating water flux and maintaining the water potential in different tissues and cells.

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Differences in Aquaporin Levels among Cell Types of Radish and Measurement of Osmotic Water Permeability of Individual Protoplasts

Suga

Murai

Kuwagata

et al. 2003

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;We investigated tissue-and cell-specific accumulation of radish aquaporin isoforms by immunocytochemical analysis. In taproots, the plasma membrane aquaporins (RsPIP1 and RsPIP2) were accumulated at high levels in the cambium, while the tonoplast aquaporin (RsTIP) was distributed in all tissues. The three isoforms were highly accumulated in the central cylinder of seedling roots and hypocotyls, and rich in the vascular tissue of the petiole of mature plants. The results suggest that RsPIP1 and RsPIP2 are abundant in the cells surrounding the sieve tube of the radish plant. The swelling rate of protoplasts in a hypotonic solution was determined individually by a newly established method to compare the osmotic water permeability of different cell types. All cells of the cortex and endodermis in seedlings showed a high water permeability of more than 300 mm s -1 . There was no marked difference in the values between the root endodermis and cortex protoplasts, although the RsPIP level was lower in the cortex than in the endodermis. This inconsistency suggests two possibilities: (1) a low level of aquaporin is enough for high water permeability and (2) the water channel activity of aquaporin in the tissues is regulated individually. The uneven distribution of aquaporins in tissues is discussed along with their physiological roles.

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Evidence for the Cell Wall Involvement in Temporal Changes in Freezing Tolerance of Jerusalem Artichoke {Helianthus tuberosus L.) Tubers during Cold Acclimation

Murai

Yoshida

1998

Plant and Cell Physiology

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We studied the mechanism of cold acclimation of Jerusalem artichoke (Helianthus tuberosus L.) tubers with special reference to the role of the cell wall. During the cold-acclimation process from September to January, the freezing tolerance of tubers increased from -2.8 degrees C to -8.4 degrees C (LT50). By contrast, the isolated protoplasts constitutively showed a consistent high level of freezing tolerance (LT50; below -25 degrees C) throughout the period. In tuber tissues, freezing injury was effectively protected by the external addition of isotonic solutions. Cryomicroscopic observations revealed that tissue cells mounted in isotonic solutions plasmolyzed upon freezing; tissue cells mounted in water collapsed with a tight attachment of plasma membrane to the cell wall. Upon freezing of intact tissues in water to temperatures below the critical range, the cytoplasm was irreversibly acidified as revealed by a fluorescence pH-ratiometry, suggesting that occurrence of detrimental cellular events leading to permanent cell injury. The freeze-induced acidification of cytoplasm was also effectively prevented by the external addition of isotonic solutions. These results suggest that the tight attachment of the plasma membrane to the cell wall during freezing may have a harmful effect on cells, in particular on the plasma membrane, possibly due to mechanical or some sort of chemical/ physico-chemical interaction with the cell wall.

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Alterations of Intracellular pH in Response to Low Temperature Stresses

et al. 1999

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In chilling-sensitive plants, the inactivation of the vacuolar H+-ATPase is one of the primary cellular events directly resulting from cold exposure. We demonstrate here that cold-induced inactivation of the proton translocating enzyme is closely linked to the rapid acidification of the cytoplasm and the concomitant alkalization of the vacuoles, suggesting an important role of the enzyme in maintaining homeostasis of the cellular pH in a cold environment. The stability of the vacuolar H+-ATPase to cold both in vivo and in vim is distinctly different between species sensitive and insensitive to cold. These findings provide further insight into the way in which the vacuolar H+-ATPase is involved in cold adaptation of plants. In addition, the temperature reduction and the concentration of the cytoplasm as a consequence of freeze-induced dehydration may also result in changes in the cellular pH. In fact, we demonstrate here that the cytoplasm is markedly acidified upon freezing; in particular, in cells of less hardy plants. Freeze-induced acidification is presumably due to changes in the physicochemical properties of the cytoplasm and the changes in the permeability of the vacuolar membrane both of which result from severe dehydration. The physiological significance of freeze-induced acidification of the cytoplasm is discussed.

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Vacuolar Membrane Lesions Induced by a Freeze-Thaw Cycle in Protoplasts Isolated from Deacclimated Tubers of Jerusalem Artichoke (Helianthus tuberosus L.)

Murai¹,

Yoshida²

1998

Plant and Cell Physiology

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The processes of freezing injury in Jerusalem artichoke (Helianthus tuberosus L.) tubers were studied using protoplasts isolated from cold-acclimated and deacclimated tubers. Prior to freezing, protoplasts were preloaded with 10 microM fluorescein diacetate (FDA) in an isotonic sorbitol solution. After freeze-thawing at various temperatures, cell viability was evaluated under a fluorescence microscope. In cold-acclimated tubers, more than 80% of protoplasts survived freezing to -20 degrees C. By contrast, in deacclimated tubers, the cell survival abruptly declined after freezing to temperatures below -5 degrees C. Thus, freezing tolerance differed significantly between protoplasts isolated from cold-acclimated and deacclimated tubers. Two distinct types of cell injury, which were caused by either damage to plasma membrane (cell-lysis type) or by damage to the vacuolar membrane (abnormal-staining type), were observed, depending on the cold hardiness and freezing temperature. In the cells of the abnormal-staining type, shrinkage of the central vacuolar space and simultaneous acidification of the cytoplasmic space were characteristically observed immediately before complete cell-rehydration during thawing. The decrease in freezing tolerance of protoplasts after deacclimation was suggested to be due mainly to destabilization of the vacuolar membrane by freeze-induced dehydration stress.

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Mari Murai

Tissue and Cell-Specific Localization of Rice Aquaporins and Their Water Transport Activities

Differences in Aquaporin Levels among Cell Types of Radish and Measurement of Osmotic Water Permeability of Individual Protoplasts

Evidence for the Cell Wall Involvement in Temporal Changes in Freezing Tolerance of Jerusalem Artichoke {Helianthus tuberosus L.) Tubers during Cold Acclimation

Alterations of Intracellular pH in Response to Low Temperature Stresses

Vacuolar Membrane Lesions Induced by a Freeze-Thaw Cycle in Protoplasts Isolated from Deacclimated Tubers of Jerusalem Artichoke (Helianthus tuberosus L.)

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