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http://dx.doi.org/10.5010/JPB.2004.31.2.169

The Induction Time of Sucrose Active Transport System during the Phloem Cell Development in Suspension Cultures of Streptantus tortus Cotyledon  

Cho, Bong-Heuy (수원대학교 자연과학대학 생명과학과 기능성생명소재연구소)
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Journal of Plant Biotechnology / v.31, no.2, 2004 , pp. 169-173 More about this Journal
Abstract
Parenchyma cells of Streptanthus tortus suspension cultures possessed the different transport system for aldose-formed D-glucose and for ketose-formed D-fructose. $K_{m}$ value for D-glucose and D-fructose were 0.28mM and 15.02mM, respectively. $K_{m}$ value of D-mannose was 0.44 mM which is similar to the D-glucose transport system, but D-mannose was transported also through its own special uptake system. Parenchyma cells possessed the transport system of L-glucose, but the function of L-glucose was not known at all. Protoplast of parenchyma cells possessed only the monosugars transport system, but didn't possess the disugars, sucrose transport system. Early developing phloem protoplasts possessed glucose and sucrose transport system at the same time. On the contrary, in the complete developed phloem cells disappeared preexisted glucose transport system in the parenchyma cells, only new induced sucrose transport system existed.ted.
Keywords
Cotyledon; phloem; sucrose active transport; suspension;
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1 Cho BH (1987) Analysis of the low affinity system of the uptake of fructose in suspensison culture cells. Kor J Bot 30: 277-285
2 Cho BH (1996) Phoem differentiation of cell culture of Streptanthus. Kor J Plant Tiss Cult 23: 107-111
3 Cho BH (1998) Isolation of phloem cell and active transport of sucrose by isolated phloem and parenchyma cells of Streptanthus tortus suspension culture. Kor J Plant Tiss Cult 25: 109-112
4 Cho BH (2000) Effect of sugar starvation on the sugar transport system in suspension cultures of Streptanthus tortus. Kor J Biotechnol 27: 47-50
5 Cho BH (1983) Mechanism of proline uptake by Chlorella. Planta 162: 23-39   DOI   ScienceOn
6 Oxender DL (1972) Membrane transport. Annu Rev Biochem 4: 777-814
7 Robinson SD, Beevers H (1981) Amino acid transport in germinating castor been seedlings. Plant Physiol 68: 560-566   DOI   ScienceOn
8 Tanner W (1969) Light driven active uptake of 3-0-methyl glucose via an inducible hexose uptake system of Chlorella. Biochem Biophys Res Commu 36: 278-283   DOI   ScienceOn
9 Wyse RE and Komor E (1984) Mechanism of amino acid uptake by sugarcane suspension cells. Plant Physiol 76: 865-870   DOI   ScienceOn
10 Cho BH, Komor E (1985) Comparison of suspension cells and cotyledons of Ricinus with respects to sugar uptake. J Plant Physiol 118: 381-390   DOI
11 Cho BH, Sauer N, Komor E, Tanner W (1981) Glucose induced two amino acid transport system in Chlorella. Proc Natl Acad Sci USA 78: 3591-3594   DOI   ScienceOn
12 Humphreys T, Echeverria E (1984) Invertase and maltase in the free space of the maize scutellum. Phytochemistry 19: 189-193   DOI   ScienceOn
13 Komor E (1973) Proton coupled hexose transport in Chlorella vulgaris. FEBS Lett 38: 16-18   DOI   ScienceOn
14 Komor E (1977) Sucrose uptake by cotyledon of Ricinus communis L.: Characterization, mechanism and regulation. Planta 47: 1498-1502
15 Murashige RD, Skoog E (1962) A revised medium for rapid growth and bioassay with tabacco tissue cultures. Physiol Plant 161: 109-417
16 Nissen P (1978) Multiphasic uptake of amino acid by barley roots. Physiol Plant 43: 181-188   DOI