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Transport of [3H]IAA label in gravistimulated primary roots of maize

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Abstract

The curvature of roots in response to gravity is attributed to the development of a differential concentration gradient of IAA in the top and bottom of the elongation region of roots. The development of the IAA gradient has been attributed to the redistribution of IAA from the stele to cortical tissues in the elongation region. The gravistimulated redistribution of IAA was investigated by applying [3H]IAA to the cut surface of 5 mm apical primary root segments. The movement of label from the stele-associated [3H]IAA into the root, tip, root cap, and cortical tissues on the top and bottom of the elongation region was determined in vertically growing roots and gravistimulated roots. Label from the stele moved into the region of cell differentiation (root tip) prior to accumulating in the elongation region. Little label was observed in the root cap. Gravistimulation did not increase the amount of label moving from the stele; but gravistimulation did increase the amount of label accumulating in cortical tissues on the lower side of the elongation region, and decreased the amount of label accumulating in cortical tissues on the upper side of the elongation region. Removal of the cap prior to or immediately following gravity stimulation rendered the roots partially insensitive to gravity and also prevented gravity-induced asymmetric redistribution of label. However, removal of the root cap following 30 min of gravistimulation did not alter root curvature or the establishment of an IAA asymmetry across the region of root elongation. These results suggest that a signal originating in the root cap directs auxin redistribution in tissues behind the root cap, leading to the development of an asymmetry of IAA concentration in the elongation region that in turn causes the differential growth rate in the elongation region of a graviresponding root.

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References

  1. Davies PJ and Mitchell EK (1972) Transport of indoleacetic acid in intact roots of Phaseolus coccineus. Planta 105: 139–154

    Google Scholar 

  2. Evans ML, Moore R and Hasenstein KH (1986) How roots respond to gravity. Sci Am 254: 112–119

    Google Scholar 

  3. Hasenstein KH and Evans ML (1988) Effects of cations on hormone transport in primary roots of Zea mays. Plant Physiol 86: 890–894

    Google Scholar 

  4. Hasenstein KH, Evans ML, Stinemetz CL, Moore R, Fondren WM, Koon EC, Higby MA and Smucker A (1987) Comparative effectiveness of metal ions in inducing curvature of primary roots of Zea mays. Plant Physiol 86: 885–889

    Google Scholar 

  5. Fondren WM, Stinemetz CL and Evans ML (1988) IAA transport and sensitivity in maize roots NASA Space Biology Meetings, Annual Symposia 5: S72

  6. Ishikawa H and Evans ML (1992) Calcium-induced curvature in maize roots. Plant Physiol 99: S60

    Google Scholar 

  7. Konings H (1967) On the mechanism of the transverse distribution of auxin in geotropically exposed pea roots. Acta Bot Neerl 16: 161–176

    Google Scholar 

  8. Konings H (1968) The significance of root cap for geotropism. Acta Bot Neerl 17: 203–211

    Google Scholar 

  9. Mitchell EK and Davies PJ (1975) Evidence for three different systems of movement of indoleacetic acid in intact roots of Phaseolus coccineus. Physiol Plant 33: 290–294

    Google Scholar 

  10. Nelson A and Evans ML (1986) Analysis of growth patterns during gravitropic curvature in roots of Zea mays using a computer-based video digitizer. Plant Growth Regul 5: 73–83

    Google Scholar 

  11. Owaki T and Tsurumi S (1976) Auxin transport and growth in intact roots of Vicia faba. Plant Cell Physiol 17: 1329–1342

    Google Scholar 

  12. Pilet P-E and Meuwly P (1986) Local application of indole-3- acetic acid by resin beads to intact growing maize roots Planta 169:16–22

    Google Scholar 

  13. Scott TK and Wilkins MB (1968) Auxin transport in roots. II. Polar flux of IAA in Zea roots. Planta 83: 323–334

    Google Scholar 

  14. Scott TK and Wilkins (1969) Auxin transport in roots. IV. Effects of light on IAA movement and geotropic responsiveness in Zea roots. Planta 87: 249–258

    Google Scholar 

  15. Shaw S and Wilkins MB (1974) Auxin transport in roots. X. Relative movement of radioactivity from IAA in the stele and cortex of Zea root segments. J Exp Bot 25: 199–207

    Google Scholar 

  16. Tsurumi S and Ohwaki Y (1978) Transport of 14C-labeled indoleacetic acid in Vicia root segments. Plant Cell Physiol 19: 1195–1206

    Google Scholar 

  17. Young LM, Evans ML and Hertel R (1990) Correlations between gravitropic curvature and auxin movement across gravistimulated roots of Zea mays. Plant Physiol 92: 792–796

    Google Scholar 

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Authors and Affiliations

  1. Biology Department, Rhodes College, 38112, Memphis, TN, USA

    Charles L. Stinemetz

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  1. Charles L. Stinemetz
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Stinemetz, C.L. Transport of [3H]IAA label in gravistimulated primary roots of maize. Plant Growth Regul 16, 83–92 (1995). https://doi.org/10.1007/BF00040511

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  • DOI: https://doi.org/10.1007/BF00040511

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