The characteristics of CO2 assimilation of photosynthesis and chlorophyll fluorescence in transgenic PEPC rice

Qiu, G. X., The photosynthetic efficiency in plants, Plant Physiology and Molecular Biology (ed. Yu, S. W.) (in Chinese), Beijing: Science Press, 1992, 236–243.

Jiao, D. M., The genetic improvement for physiological characteristics of photosynthesis and breeding approaches to high-yield in rice, Rice Abstract, 1993, 12(4): 1.

Brown, R. H., Bassett, C. L., Cameron, R. G. et al., Photosynthesis of F1 hybrids between C4 and C3–C4 species ofFlaveria, Plant Physiol., 1986, 82:211.

Rikishi, K., Oquro, H., Samejima, M. et al., C4-like plants derived from a crossAtriplex rosea(C4)×Atriplex. Putula(C3)×Atriplex. rosea, Jap. J. Breed., 1988, 38: 397.

Ku, M. S. B., Sakae Agarie, Mika, N. et al., High-level expression of maize phosphoenolpyruvate carboxylase in transgenic rice plants, Nature Biotechnology, 1999, 17: 76.

Gonzalez, D. H., Iglesias, A. A., Andeo, C. S., On the regulation of phosphoenolpyruvate carboxylase activity from maize leaves by L-malate: Effect of pH, J. Plant Physiol., 1984, 116: 425.

Hatch, M. D., Slack, C. R., Pyruvate, Pi Dikinase from leaves, Methods in Enzymology (ed. Wood, W. A.), New York: Academic Press, Inc., 1975, 42:212–219.

Chen, J. Z., Chen, D. L., Wu, M. X. et al., Comparison of some characteristics of NADP-malic enzyme from sorghum and wheat leaves, Acta Photophysiological Sinica (in Chinese), 1981, 4: 345.

Li, B., Chen, D. L., Shi, J. N., Purification and molecular properties of NADP dependent malate dehydrogenase from sorghum leaves, Acta Photophysiological Sinica (in Chinese), 1987, 13: 113.

Wei, J. C., Wang, R. L., Chen, G. Y., Studies on the kinetic properties of Ribulose-1,5-diphosphate Carboxylase from F1 hybrid rice, Acta Photophysiological Sinica (in Chinese), 1994, 20(1): 55.

Kung, S. D., Chollet, R., Marsho, T. V., Crystallization and assay procedures of tobacco riibulose 1,5-bisphosphate carboxylaseoxygenase, Methods in Enzymology (ed. Wood, W. A.), New York: Academic Press, Inc., 1980, 69: 326.

Guo, M. L., Gao, Y. Z., Wang, Z., Determination of plant carbonic anhydrase activity with pH-meter, Plant Physiol. Commun. (in Chinese), 1988, 6: 59.

Xu, D. Q., Phytosynthesis, Modern Plant Physiology—A Laboratory Manual (in Chinese), Beijing: Science Press, 1999, 83–94.

Jiao, D. M., Ku, M. S. B., The characteristics of photosynthetic CO2 exchange of the F1 hybrids between C3–C4 intermediate and C4 species inFlaveria, Acta Photophysiological Sinica (in Chinese), 1991, 17(3): 225.

Schreiber, U., Schliwa, W., Bilger, U., Continuous recording of photochemical and nonphotochemical chlorophyll fluorescence quenching with a new type of modulation fluoremeter, Photosynthesis Research, 1986, 10: 51.

Genty, B., Briantais, J. M., Baker, N. R., The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence, Biochim. Biophys. Acta, 1989, 990: 87.

Lin, Z. F., Peng, C. L., Lin, G. Z., Diurnal changes of chlorophyll fluorescence quenching and the response to photooxidation in leaves of C3 and C4 plants, Acta Agron. Sin. (in Chinese), 1999, 25: 284.

Magnin, N. C., Cooley, C. A., Reiskind, J. B. et al., Regulation and localization of key enzymes during the induction of kranz-less, C4-type photosynthesis inHydrilla Nerticillata, Plant Physiol, 1997, 115: 1681.

Aoyaki, K., Bassham, J. A., Appearance and accumulation of C4 carbon pathway enzymes in developing wheat leaves, Plant Physiol., 1986, 80: 334.

Austin, R. B., Genetic constraints on photosynthesis and yield in wheat, Advanced Photosynthesis Research, 1984, 4: 103.

Ku, M. S. B., Kano-Murakami, Y., Matsuoka, M., Evolution and expression of C4photosynthesis genes, Plant Physiol., 1996, 111: 949.

Edwards, G., Tuning up crop photosynthesis, Nature Biotechnology, 2000, 1: 22.