Summary
One of the primary avenues of improving the biological efficiency of crop plants is through the improvement of the leaf and canopy photosynthetic rates. However, the question whether the superiority of hybrids in respect of productivity potential could be traced, in retrospective fashion, to the photosynthetic parameters should be answered first. Once established and standardized, such indices could be streamlined in innovative breeding to predict the heterotic combinations for final yield formation. To answer this question, the photosynthetic rate and other components of photosynthetic efficiency were monitored among eight inbred stocks of maize (selected for variable photosynthetic rate from a previous study) and their all possible one-way crosses. The results demonstrated extensive heterosis in respect of photosynthetic rate and other photosynthetic indices which, in turn, was also realized in terms of higher biomass productivity and yield. Nonetheless, high leaf photosynthesis alone did not result in higher grain yield. On the contrary, component interaction among the photosynthetic indices like photosynthetic rate, leaf area/plant, number of leaves and chlorophyll content on one hand and the complementary gene action on the other, could be held responsible for higher yields in hybrids. Since the components of photosynthetic efficiency can predict heterosis for biomass and grain yield upto a reasonable extent, judicious incorporation of such indices in selection parameters for applied genetic protocols can add yet another dimension to the strategies for future yield improvements.
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References
Albergoni, F.G., B. Basso, E. Pe & E. Ottaviano, 1983. Photosynthetic rate in maize. Inheritance and correlation with morphological traits. Maydica 28: 439–448.
Arnon, D.J., 1949. Copper enzymes in isolated chloroplasts. Polyphenol oxidase in Beta vulgaris. Plant Physiol. 24: 1–15.
Austin, R.B., 1989. Genetic variation in photosynthesis, review. J. Agric. Sci. Camb. 112: 287–294.
Crosbie, T.M., R.B. Pearce & J.J. Mock, 1978a. Relationship among CO2-exchange rate and plant traits in Iowa Stiff Stalk Synthetic maize population. Crop Sci. 18: 87–90.
Crosbie, T.M., J.J. Mock & R.B. Pearce, 1978b. Inheritance of photosynthesis in a diallel among eight maize inbred lines from Iowa Stiff Stalk Synthetic. Euphytica 27: 657–664.
Crosbie, T.M., R.B. Pearce & J.J. Mock, 1981. Selection for high CO2 exchange rate among inbred lines of maize. Crop Sci. 21: 629–631.
Crosbie, T.M. & R.B. Pearce, 1982. Effects of recurrent phenotypic selection for high and low photosynthesis on agronomic traits in two maize populations. Crop Sci. 22: 809–813.
van de Dijk, S.J., 1987. Inheritance of net photosynthesis, dark respiration, stomatal resistance and related characters in tomato (Lycopersicon esculentum Mill.) under low energy conditions. Euphytica 36: 193–203.
Dornescu, A., 1980. The expression of vegetative heterosis in HT 180. Lucrari Stutifice Institut Agronomic Ion Ionescu de la Brad, Agronomie 24: 37–38.
Duarte, R. & M.W. Adams, 1963. Component interaction in relation to expression of a complete trait in field bean cross. Crop Sci. 3: 185–186.
Dwyer, L.M. & M. Tollenaar, 1989. Genetic improvement in photosynthetic response of hybrid maize cultivars, 1959 to 1988. Can. J. Plant Sci. 69: 81–91.
Dwyer, L.M., M. Tollenaar & D.W. Stewart, 1991. Changes in plant density dependence of leaf photosynthesis of maize (Zea mays L.) hybrids, 1959 to 1988. Can. J. Plant Sci. 71: 1–11.
Fousova, S. & N. Avratovscukova, 1967. Hybrid vigour and photosynthetic rate of leaf discs in Zea mays L. Photosynthetica 1: 3–12.
Fousova, S. & N. Avratovscukova, 1973. Non-additive components of genetic variance in rate of photosynthesis of leaf discs and ways of detecting them. Acta Univ. Agric. Bino, A. 21: 251–261.
Gaudry, M.J.F., E. Carrayol, S. Wuilleme, F. Moutot, M.E. Deroche & E. Jolivit, 1984. Heterosis and photosynthesis in maize (Zea mays L.). In: C. Sybesma (Ed.), Advances in Photosynthesis Research, Vol. IV 2, pp. 157–160, Martin Nijhoff Publishers, The Hague.
Gordon, A.J., J.D. Hesketh & D.B. Peters, 1982. Soybean leaf photosynthesis in relation to maturity classification and stage of growth. Photosynth. Res. 3(2): 81–93.
Heichel, G.H. & R.B. Musgrave, 1969. Varietal differences in net photosynthesis of Zea mays L. Crop Sci. 9: 483–486.
Jain, H.K., 1986. Eight years of post-Mendelian breeding for crop yield. Nature of selection pressure and future potentials. Indian J. Genet. 46 (Suppl.): 1–19.
Khanna-Chopra, R., 1982. Photosynthesis, photosynthetic enzymes and leaf area development in relation to hybrid vigour in Sorghum vulgare L. Photosynth. Res. 3: 113–122.
Korz, B.V., 1980. Photosynthesis and photorespiration in heterotic maize hybrids at different temperatures. Tr. Prikl. Bot. Genet. Selekts. 67(2): 83–87.
Mehta, H., K.R. Sarkar & N.N. Singh, 1989. Variability and heritability studies for photosynthetic efficiency in some inbred stocks of maize. Ann. Agric. Res. 10: 73–78.
Mehta, H., K.R. Sarkar & S.K. Sharma, 1992. Genetic analysis of photosynthesis and productivity in corn. Theor. Appl. Genet. (In press).
Milica, C.I., I. Ifusoaie & A. Airinei, 1986. Relationship between photosynthetic yield and yield formation in different maize hybrids. Lucrari Stutifice, Institut Agronomic Ion Ionescu de la Brad, Agronomie, 28: 37–40.
Monma, E. & S. Tsunoda, 1979. Photosynthetic heterosis in maize. Jap. J. Breed. 29(2): 159–165.
Nayyar, H., C.P. Malik, P. Singh, U. Parmar, M. Grewal & S. Kawa, 1990. Diurnal variations in photosynthetic parameters in peanut. Photosynthetica 24(2): 276–297.
Nelson, C.J., 1988. Genetic associations between photosynthetic characteristics and yield: review of the evidence. Plant Physiol. Biochem. 26: 543–554.
Peng, S., D.R. Krieg & F.S. Girma, 1991. Leaf photosynthetic rate is correlated with biomass and grain production in grain sorghum lines. Photosynth. Res. 28(1): 1–8.
Sinha, S.K. & R. Khanna-Chopra, 1975. Physiological, biochemical and genetic basis of heterosis. Adv. Agron. 27: 123–170.
Sinha, S.K., V. Balasubramanian, R. Khanna-Chopra & P. Shantakumari, 1976. Growth analysis and photosynthesis system in relation to hybrid vigour in maize. Indian J. Exptl. Biol. 14: 459–462.
Swaminathan, M.S., 1986. Integration of the tools of Mendelian and molecular genetics in crop improvement. Indian J. Genet. 46 (Suppl.): 12–29.
Tollenaar, M., 1989. Genetic improvement in grain yield of commercial maize hybrids grown in Ontario from 1959 to 1988. Crop Sci. 29: 1365–1371.
Tollenaar, M., 1991. Physiological basis of genetic improvement of maize in Ontario hybrids from 1959 to 1988. Crop Sci. 31: 119–124.
Torres-Kalt, W., P.S. Kerr, H. Usuda & S.C. Huber, 1987. Diurnal changes in maize leaf photosynthesis. I. Carbon exchange rate, assimilation export rate and enzyme activities. Plant Physiol. 83: 283–288.
Wilson, D. & J.P. Cooper, 1969. Diallel analysis of photosynthetic rate and related leaf characters among contrasting genotypes of Lolium perenne L. Heredity 24: 633–649.
Xu Da-quaan, De-yao Li, Yun gang Shen & Guo-an Liang, 1984. On midday depression of photosynthesis of wheat leaf under field conditions. Acta Phytophysiol. Sin. 10: 269–276.
Zelitch, I., 1982. The close relationship between net photosynthesis and crop yield. Bioscience 32(10): 796–802.
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Mehta, H., Sarkar, K.R. Heterosis for leaf photosynthesis, grain yield and yield components in maize. Euphytica 61, 161–168 (1992). https://doi.org/10.1007/BF00026807
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DOI: https://doi.org/10.1007/BF00026807