Abstract
Six to seven week old red clover plants (Trifolium pratense L. cv Merviot) were used to investigate the time-course of root senescence following complete and permanent excision from the shoot. Plants were grown in sand culture watered with nutrient solution. After excision of the shoots, roots were left in situ and sampled over a period of up to 42 days. Respiration rate began to decrease immediately after excision, reaching 50% of its initial value after 24 h. The decline involved a reduction in the capacity of the respiratory pathways as measured in the presence of an uncoupler (FCCP) and exogenous glucose. The reduction in respiration could be prevented by supplying 100 mM sucrose to excised roots incubated in nutrient solution at the time of excision, but not 4–5 days after excision. There was a steady reduction in the protein and soluble sugar concentrations from the time of excision and a smaller reduction in starch. Free amino acid concentrations increased immediately after excision, but the temporal dynamics differed between individual amino acids. The total concentration of free amino acids rose to a maximum value 6–13 days after excision, before declining. Under these conditions roots survived for a remarkably long period of time. Depending on the experiment, cell viability, measured as the percentage of cells with positive turgor, was unchanged for at least 20 days, and complete loss of viability was not observed until 34–42 days after excision. There was no appreciable loss of N from the roots until cell viability declined significantly. The potential implications of these results for modelling and management of N cycling in cropping systems is discussed briefly.
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References
Berry PM, Stockdale EA, Sylvester-Bradley R, Philipps L, Smith KA, Lord EI, Watson CA, Fortune S (2003) N, P and K budgets for crop rotations on nine organic farms in the UK. Soil Use Manage 19:112–118
Bingham IJ (2007) Quantifying the presence and absence of turgor for the spatial characterisation of cortical senescence in wheat roots. Am J Bot 94:2054–2058
Bingham IJ, Farrar JF (1988) Regulation of respiration in roots of barley. Physiol Plant 73:278–285
Bingham IJ, Stevenson EA (1993) Control of root growth: effects of carbohydrates on the extension, branching and rate of respiration of different fractions of wheat roots. Physiol Plant 88:49–158
Bradford MM (1976) A rapid and sensitive method for the quantification of microgram quantities of proteins utilizing the principle of protein-dye binding. Anal Biochem 72:248–254
Brophy LS, Heichel GH (1989) Nitrogen release from roots of alfalfa and soybean grown in sand culture. Plant Soil 116:77–84
Brouquisse R, James F, Raymond P, Pradet A (1991) Study of glucose starvation in excised maize root tips. Plant Physiol 96:619–626
Brouquisse R, James F, Pradet A, Raymond P (1992) Asparagine metabolism and nitrogen distribution during protein degradation in sugar-starved maize root tips. Plant 188:384–395
Brouquisse R, Gaudillère JP, Raymond P (1998) Induction of a carbon-starvation-related proteolysis in whole maize plants submitted to light/dark cycles and to extended darkness. Plant Physiol 117:1281–1291
Comas LH, Eissenstat DM, Lakso AN (2000) Assessing root death and root system dynamics in a study of grape canopy pruning. New Phytol 147:171–178
Contento AL, Kim SJ, Bassham DC (2004) Transcriptome profiling of the response of Arabidopsis suspension culture cells to Suc starvation. Plant Physiol 135:2330–2347
Devaux C, Baldet P, Joubès J, Dieuaide-Noubhani M, Just D, Chevalier C, Raymond P (2003) Physiological, biochemical and molecular analysis of sugar-starvation responses in tomato roots. J Exp Bot 54:1143–1151
Dubois M, Gilles KA, Hamilton JK, Rebus PA, Smith F (1956) Colorimetric method for the determination of sugars and related substances. Anal Chem 28:350–356
Evans PS (1973) The effect of repeated defoliation to three different levels on root growth of five pasture species. N Z J Agric Res 16:31–34
Farrar JF (1993) Carbon partitioning. In: Hall DO, Scurlock JMO, Bolhar-Nordenkampf HR, Leegood RC, Long SP (eds) Photosynthesis and production in a changing environment: a field and laboratory manual. Chapman and Hall, London, pp 232–246
Henry CM, Deacon JW (1981) Natural (non-pathogenic) death of the cortex of wheat and barley seminal roots, as evidenced by nuclear staining with acridine orange. Plant Soil 60:255–274
Høgh-Jensen H, Schjoerring JK (1997) Interactions between white clover and ryegrass under contrasting nitrogen availability: N2 fixation, N fertilizer recovery, N transfer and water use efficiency. Plant Soil 197:187–199
Høgh-Jensen H, Schjoerring JK (2000) Below-ground nitrogen transfer between different grassland species: direct quantification by 15N leaf feeding compared with indirect dilution of soil 15N. Plant Soil 227:171–183
James F, Brouquisse R, Pradet A, Raymond P (1993) Changes in proteolytic activities in glucose-starved maize root tips. Regulation by sugars. Plant Physiol Biochem 31:845–856
Journet EP, Bligny R, Douce R (1986) Is the availability of substrate for the tricarboxylicacid cycle a limiting factor for uncoupled respiration in sycamore (Acer pseudoplatanus) cells. Biochem J 233: 571–576
Kuzyakov Y, Domanski G (2000) Carbon input by plants into the soil. A review. J Plant Nutr 163:421–431
Lascaris D, Deacon JW (1991) Relationship between root cortical senescence and growth of wheat as influenced by mineral nutrition, Idriella bolleyi (Sprague) von Arx and pruning of leaves. New Phytol 118:391–396
Martin RC, Voldeng HD, Smith DL (1991) Nitrogen transfer from nodulating soybean [Glycine max (L.) Merr.] to corn (Zea mays L.) and non-nodulating soybean in intercrops: direct 15N labelling methods. New Phytol 117:233–241
McNeill AM, Zhu C, Fillery IRP (1997) Use of in situ 15N-labelling to estimate the total below-ground nitrogen of pasture legumes in intact soil–plant systems. Aus J Agric Res 48:295–304
Moriyasu Y, Ohsumi Y (1996) Autophagy in tobacco suspension-cultured cells in response to sucrose starvation. Plant Physiol 111:1233–1241
Murray PJ, Hatch DJ (1994) Sitona weevils (Coleptera; Curculionidae) as agents for rapid transfer of nitrogen from white clover (Trifolium repens L.) to perennial ryegrass (Lolium perenne L.). Ann Appl Biol 125:29–33
Paterson E (2003) Importance of rhizodeposition in the coupling of plant and microbial productivity. Eur J Soil Sci 54:741–750
Paterson E, Hodge A, Thornton B, Millard P, Killham K (1999) Carbon partitioning and rhizosphere C-flow in Lolium perenne as affected by CO2 concentration, irradiance and below-ground conditions. Global Change Biol 5:669–678
Paynel F, Murray PJ, Cliquet JB (2001) Root exudates: a pathway for short-term N transfer from clover and ryegrass. Plant Soil 229:235–243
Rovira AD (1969) Plant root exudates. Bot Rev 35:35–57
Yemm EW, Cocking EC (1955) The determination of amino-acids with ninhydrin. Analyst 80:209–213
Yu SM (1999) Cellular and genetic responses of plants to sugar starvation. Plant Physiol 121:687–693
Acknowledgements
We are grateful to Jacqui Blackwood, Eddie Stevenson and John Parker for technical assistance and to Karl Oparka for the loan of the pressure probe. SAC receives financial support from the Scottish Executive Environment and Rural Affairs Department.
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Bingham, I., Rees, R. Senescence and N release from clover roots following permanent excision of the shoot. Plant Soil 303, 229–240 (2008). https://doi.org/10.1007/s11104-007-9501-4
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DOI: https://doi.org/10.1007/s11104-007-9501-4