References
- Belda, R. M., J. S. Fenlon, and L. C. Ho. 1996. Salinity effects on the xylem vessels in tomato fruit among cultivars with different susceptibilities to blossom-end rot. The Journal of Horticultural Science 71: 173–179.
- Bhalla, P. L., and R. M. S. Mulwa. 2003. Tissue culture and macadamia propagation. Acta Horticulturae 616: 343–346.
- Björkman, T., and R. E. Cleland. 1991. The role of extracellular free-calcium gradients in gravitropic signaling in maize roots. Planta 185: 379–384.
- Busse, J S., S. Ozgen, and J. P. Palta. 2008. Influence of root zone calcium on subapical necrosis in potato shoot cultures: Localization of injury at the tissue and cellular levels. Journal of the American Society for Horticultural Science 133: 653–662.
- Dodd, A. N., J. Kudla, and D. Sanders. 2010. The language of calcium signaling. Annual Review of Plant Biology 61: 593–620.
- Ferguson, I. B., and D. T. Clarkson. 1975. Ion transport and endodermal suberization in the roots of Zea mays. New Phytologist 75: 69–79.
- Grichar, W. J., B. A. Besler, and K. D. Brewer. 2002. Comparison of agricultural and power plant by-product gypsum for South Texas peanut production. Texas Journal of Agriculture and Natural Resources 15: 44–50.
- Grigoriadou, K., N. Leventakis, and M. Vasilakakis. 2000. Effects of various culture conditions on proliferation and shoot tip necrosis in the pear cultivars ‘William's’ and ‘Highland’ grown in vitro. Acta Horticulturae 520: 103–108.
- Halperin, S. J., L. V. Kochian, and J. P. Lynch. 1997. Salinity stress inhibits calcium loading into the xylem of excised barley (Hordeum vulgare) roots. New Phytologist 135: 419–427.
- Hepler, P. K. 2005. Calcium: A central regulator of plant growth and development. The Plant Cell 17: 2142–2155.
- Ho, L. C., P. Adams, X. Z. Li, H. Shen, J. Andrews, and Z. H. Xu. 1995. Responses of Ca-efficient and Ca-inefficient tomato cultivars to salinity in plant growth, calcium accumulation and blossom-end rot. The Journal of Horticultural Science 70: 909–918.
- Ho, L. C., R. Belda, M. Brown, J. Andrews, and P. Adams. 1993. Uptake and transport of calcium and the possible causes of blossom-end rot in tomato. Journal of Experimental Botany 44: 509–518.
- Hodge, A. J., D. Stewart, B. Robinson, S. Griffiths and A. H. Fitter. 2000. Competition between roots and soil micro-organisms for nutrients from nitrogen-rich patches of varying complexity. Journal of Ecology 88: 150–164.
- Horst, W. J., C. Currle, and A. H. Wissemeier. 1992. Differences in calcium efficiency between cowpea [Vigna unguiculata (L.) Walp.] cultivars. Plant and Soil 146: 45–54.
- Huang, J., J. E. Shaff, D. L. Grunes, and L. V. Kochian. 1992. Aluminum effects on calcium fluxes at the root apex of aluminum-tolerant and aluminum-sensitive wheat cultivars. Plant Physiology 98: 230–237.
- Kirkby, E. A. 1979. Maximizing calcium uptake by plants. Communications in Soil Science and Plant Analysis 10: 89–113.
- Li, S., J. Yu, M. Zhu, F Zhao, and S. Luan. 2012. Cadmium impairs ion homeostasis by altering K+ and Ca2+ channel activities in rice root hair cells. Plant, Cell & Environment 35: 1998–2013.
- Marcelis, L. F. M., and L. C. Ho. 1999. Blossom-end rot in relation to growth rate and calcium content in fruits of sweet pepper (Capsicum annuum L.). Journal of Experimental Botany 50: 357–363.
- Marschner, H. 1995. Mineral Nutrition of Higher Plants. New York: Academic Press. McAinsh, M. R., and Pittman, J. K. 2009. Shaping the calcium signature. New Phytologist 181: 275–294.
- McCown, B. H., and J. C. Sellmer. 1987. General media and vessels suitable for woody plant cultures. In: Tissue Culture in Forestry–General Principles and Biotechnology, eds. J. M. Bonga and D. J. Durzan, pp. 4–6. Dordrecht, the Netherlands: Martinus, Nijhoff, Mengel, K., and E. A. Kirkby. 1987. Principles of Plant Nutrition, 4th ed. New York: Springer.
- Morley, P., and J. F. Whitfield. 1993. The differentiation inducer, dimethyl sulfoxide, transiently increases the intracellular calcium ion concentration in various cell types. Journal of Cellular Physiology 156: 219–225.
- Murata, M. R., G. E. Zharare, and P. S. Hammes. 2008. pH of the pod-zone affects reproductive growth of groundnut. Journal of Plant Nutrition 31: 69–79.
- Murata, M. R., G. E. Zharare, and P. S. Hammes. 2013. Interactions of pod-zone pH and calcium concentration on fructification of groundnut grown in solution culture. Journal of Plant Nutrition 36: 32–41.
- Newman, I. A. 2001. Ion transport in roots: Measurement of fluxes using ion-selective microelectrodes to characterize transporter function. Plant, Cell & Environment 24: 1–14.
- Ng, C. K. Y., and M. R. McAinsh. 2003. Encoding specificity in plant calcium signaling: Hot-spotting the ups and downs and waves. Annals of Botany 92: 477–485.
- Raychaudhury, M., S. V. Ngachan, S. Raychaudhury, and A. L. Singh. 2003. Yield response of groundnut to dual inoculation and liming of acid hill Ultisol of Manipur. The Indian Journal of Agricultural Science 73: 86–88.
- Ryan, P. R., I. A. Newman, and B. Shields. 1990. Ion fluxes in corn roots measured by microelectrodes with ion-specific liquid membranes. Journal of Membrane Science 53: 59–69.
- Ryan, P. R., J. E. Shaff, and L. V. Kochian. 1992. Aluminum toxicity in roots. Correlation among ionic currents, ion fluxes, and root elongation in aluminum-sensitive and aluminum-tolerant wheat cultivars. Plant Physiology 99: 1193–1200.
- Sha, L., B. H. McCown, and L. A. Peterson. 1985. Occurrence and cause of shoot-tip necrosis in shoot cultures. Journal of American Society of Horticultural Science 110: 631–634.
- Shabala, S., and I. Newman. 2000. Salinity effects on the activity of plasma membrane H+ and Ca2+ transporters in bean leaf mesophyll: Masking role of the cell wall. Annals of Botany 85: 681–686.
- Shabala, S., L. Shabala, and E. V. Volkenburgh. 2003. Effect of calcium on root development and root ion fluxes in salinized barley seedlings. Functional Plant Biology 30: 507–514.
- Simpson, J. R., A. Pinkerton, and J. Lazdovskis. 1977. Effects of subsoil calcium on the root growth of some lucerne genotypes (Medicago sativa L.) in acidic soil profiles. Australian Journal of Agricultural Research 28: 629–638.
- Sun, J., S. L. Chen, S. X. Dai, R. G. Wang, N. Y. Li, X. Shen, X. Y. Zhou, C. F. Lu, X. J. Zheng, Z. M. Hu, Z. K. Zhang, J. Song, and Y. Xu. 2009. NaCl-induced alternations of cellular and tissue ion fluxes in roots of salt-resistant and salt-sensitive poplar species. Plant Physiology 149: 1141–1153.
- Tillman, B. L., M. W. Gomillion, G. Person, and C. L. Mackowiak. 2010. Variation in response to calcium fertilization among four runner-type peanut cultivars. Agronomy Journal 102: 469–474.
- White, P. J. 2001. The pathways of calcium movement to the xylem. Journal of Experimental Botany 52: 891–899.
- White, P. J., and M. R. Broadley. 2003. Calcium in plants. Annal Botany. (Lond.) 92: 487–511.
- Wissuwa, M. 2003. How do plants achieve tolerance to phosphorus deficiency? Small causes with big effects. Plant Physiology 133: 1947–1958.
- Xu, Y., T. Sun, and L. Yin. 2006. Application of non-invasive microsensing system to simultaneously measure both H+ and O2 fluxes around the pollen tube. Journal of Integrative Plant Biology 48: 823–831.
- Zharare, G. E., F. C. Blamey, and C. J. Asher. 2012. Effects of pod-zone calcium supply on dry matter distribution at maturity in two groundnut cultivars grown in solution culture. Journal of Plant Nutrition 35: 1542–1556.
- Zonia, L., S. Cordeiro, J. Tupý, and J. A. Feijó. 2002. Oscillatory chloride efflux at the pollen tube apex has a role in growth and cell volume regulation and is targeted by inositol 3, 4, 5, 6 - tetrakisphosphate. The Plant Cell 14: 2233–2249.