Sodium Transport and Compartmentation in <i>Spergularia marina</i>

Lazof, Dennis B.; Cheeseman, John M.

doi:10.1104/pp.81.3.742

Cited by 34 publications

(30 citation statements)

References 22 publications

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“…Lazof and Cheeseman (1986) suggested that a small and labile symplastic pool that was involved in the upward transport of Na+. Based on the fact that membrane-impermeable tracers, such as La3+ ), raffinose (Perry and Greenway 1973), and PTS (Hanson et al 1985;Moon et al 1986;Yeo et al 1987), could be detected in the shoots or xylem exudate when the tracers were applied to intact roots, the occurrence of long-distance transport which bypasses membranes had been demonstrated.…”

Section: Discussionmentioning

confidence: 99%

Characterization of the Na⁺delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants

Ochiai

Matoh

2002

Soil Science and Plant Nutrition

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Section: Discussionmentioning

confidence: 99%

Characterization of the Na⁺delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants

Ochiai

Matoh

2002

Soil Science and Plant Nutrition

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“…The second factor is the efficiency of the rinsing procedure in removing apoplastic "5N with minimal loss of symplastic "5N. Similar rinsing procedures have previously been shown to effectively remove cationic radiotracers from the free space without significant loss of label from membrane-bound pools (10). Loss of internal NO3-was tested in preliminary studies, exposing intact seedlings to 0.1 mM [5N]NO3-for 3 d, rinsing roots in 8 mm CaSO4 at 0°C for 2 min to remove free space NO3-, and then rinsing in a large volume of 8 mm CaSO4 at 0°C (5 I/plant) for 30 min.…”

Section: Localization Of Nitrate Absorption and Translocationmentioning

confidence: 99%

“…Results from short-term time courses of uptake by intact roots indicate that symplastic ion transport across the root to the xylem can occur within a few minutes (e.g. 10,12,15,21), so that considerable interregional transport is likely to occur with exposure to labeled nutrients for 30 min or more.…”

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confidence: 99%

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Localization of Nitrate Absorption and Translocation within Morphological Regions of the Corn Root

Lazof¹,

Rufty²,

Redinbaugh³

1992

Plant Physiol.

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The absorption of N03-was characterized in six regions of a 7-d-old corn root (Zea mays L. cv W64A x W182E) growing in a complete nutrient solution. Based on changing rates of '5N accumulation during 15-min time courses, translocation of the concurrently absorbed N through each region of the intact root was calculated and distinguished from direct absorption from the medium. Of the 15N accumulated in the 5-mm root tip after 15 min, less than 15 and 35% had been absorbed directly from the external solution at 0.1 and 10 mm N03-concentration of the external solution, respectively. The characterization of the apical portion of the primary root as a sink for concurrently absorbed N was conconfirmed in a pulse-chase experiment that showed an 81% increase of 15N in the 5-mm root tip during a 12-min chase (subsequent to a 6-min labeling period). The lateral roots alone accounted for 60% of root influx and 70% of 15-min whole root "5N accumulation at either 0.1 or 10 mm. NO3-concentration of the external solution. Because relatively steady rates of 15N accumulation in the shoot were reached after 6 min, the rapidly exchanging pools in lateral roots must have been involved in supplying 15N to the shoot. The laterals and the basal primary root also showed large decreases (24 and 17%) in 15N during the chase experiment, confirming their role in rapid translocation.The plant root, as a well-organized collection of cells differing in both developmental stage and cell type, has long been known to exhibit regional differences in nutrient absorption, translocation, and assimilation processes. Accordingly, the description of root function as an average of the entire root is likely to lead to erroneous interpretations of regional transport and assimilation characteristics (1). In studies that have attempted to define transport characteristics within distinct root regions, however, difficulties are encountered in interpreting results quantitatively.Two general methodological approaches have allowed some assessment of absorption and translocation capacities of defined root region: (a) Use of a chambered system to isolate a single root zone, which can be bathed in labeled nutrient solution (25), and (b) exposure of an entire root system to labeled solution, followed by rapid separation of the regions (2). The first approach has been employed using perspex chambers, latex diaphragms, or plastic tubing for isolation of regions (e.g. 5, 7, 14, 20, 25 There have been two studies of N03-absorption along the root (5, 26). In the one study of NO3-absorption by root regions using the method of isolating regions after labeling, Yoneyama et al. (26) reported a high rate of [15N]NO3-absorption in two regions of intact low-salt corn roots, located 6 to 8.5 and 59 to 61 mm basal to the tip. The first time point in their study was 1 h. Neither of the two previous studies of NO3 uptake in root regions attempted to estimate unidirectional influx or translocation through regions.In this study, we attempt to define the N transport capacities...

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“…This exacerbates the energy problem; it is not simply a problem at the plasmamembrane. Clearly, there is still something critical we are missing about the status of Na + in cells (Lazof and Cheeseman 1986). …”

Section: Transportersmentioning

confidence: 99%

The integration of activity in saline environments: problems and perspectives

Cheeseman

2013

Functional Plant Biol.

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Abstract. The successful integration of activity in saline environments requires flexibility of responses at all levels, from genes to life cycles. Because plants are complex systems, there is no 'best' or 'optimal' solution and with respect to salt, glycophytes and halophytes are only the ends of a continuum of responses and possibilities. In this review, I briefly examine seven major aspects of plant function and their responses to salinity including transporters, secondary stresses, carbon acquisition and allocation, water and transpiration, growth and development, reproduction, and cytosolic function and 'integrity'. I conclude that new approaches are needed to move towards understanding either organismal integration or 'salt tolerance', especially cessation of protocols dependent on sudden, often lethal, shock treatments and the embracing of systems level resources. Some of the tools needed to understand the integration of activity and even 'salt stress' are already in hand, such as those for whole-transcriptome analysis. Others, ranging from discovery studies of the nature of the cytosol to expanded tool kits for proteomic, metabolomic and epigenomic studies, still need to be further developed. After resurrecting the distinction between applied stress and the resultant strain and noting that with respect to salinity, the strain is manifest in changes at all -omic levels, I conclude that it should be possible to model and quantify stress responses.

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Sodium Transport and Compartmentation in Spergularia marina

Cited by 34 publications

References 22 publications

Characterization of the Na⁺delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants

Characterization of the Na⁺delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants

Localization of Nitrate Absorption and Translocation within Morphological Regions of the Corn Root

The integration of activity in saline environments: problems and perspectives

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Sodium Transport and Compartmentation in Spergularia marina

Cited by 34 publications

References 22 publications

Characterization of the Na+delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants

Characterization of the Na+delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants

Localization of Nitrate Absorption and Translocation within Morphological Regions of the Corn Root

The integration of activity in saline environments: problems and perspectives

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Product

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Characterization of the Na⁺delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants

Characterization of the Na⁺delivery from roots to shoots in rice under saline stress: Excessive salt enhances apoplastic transport in rice plants