Join for Free!
122497 members

table of contents table of contents

Home » Biology Articles » Agriculture » Grain yields with limited water » References

- Grain yields with limited water


Agricultural Statistics. 1999. Washington DC: United States Department of Agriculture.

Andersen MN, Asch F, Wu Y, Jensen CR, Naested H, Mogensen VO, Koch KE. 2002. Soluble invertase expression is an early target of drought stress during the critical, abortion-sensitive phase of young ovary development in maize. Plant Physiology 130, 591–604.

ap Rees T. 1984. Sucrose metabolism. In: Lewis DH, ed. Storage carbohydrates in vascular plants. London: Cambridge University Press, 53–73.

Bassetti P, Westgate ME. 1993. Water deficit affects receptivity of maize silks. Crop Science 33, 279–282.

Bate NJ, Niu X, Wang Y, Reimann KS, Helentjaris TG. 2004. An invertase inhibitor from maize localizes to the embryo surrounding region during early kernel development. Plant Physiology 134, 1–9.

Boyer JS. 1982. Plant productivity and environment. Science 218, 443–448.

Boyer JS, McPherson HG. 1975. Physiology of water deficits in cereal crops. Advances in Agronomy 27, 1–23.

Boyle MG, Boyer JS, Morgan PW. 1991. Stem infusion of liquid culture medium prevents reproductive failure of maize at low water potential. Crop Science 31, 1246–1252.

Cheng W-H, Taliercio EW, Chourey PS. 1996. The Miniature1 seed locus of maize encodes a cell wall invertase required for normal development of endosperm and maternal cells in the pedicel. The Plant Cell 8, 971–983.

Davies WJ, Zhang J. 1991. Root signals and the regulation of growth and development of plants in drying soil. Annual Review of Plant Physiology and Plant Molecular Biology 42, 55–76.

Dembinska O, Lalonde S, Saini HS. 1992. Evidence against the regulation of grain set by spikelet abscisic acid levels in water-stressed wheat. Plant Physiology 100, 1599–1602.

Doehlert DC, Felker FC. 1987. Characterization and distribution of invertase activity in developing maize (Zea mays) kernels. Physiologia Plantarum 70, 51–57.

Dorion S, Lalonde S, Saini HS. 1996. Induction of male sterility in wheat by meiotic-stage water deficit is preceded by a decline in invertase and changes in carbohydrate metabolism in anthers. Plant Physiology 111, 137–145.

Edmeades GO, Bolaños J, Hernandez M, Bello S. 1993. Causes for silk delay in a lowland tropical maize population. Crop Science 33, 1029–1035.

Felker FC, Shannon JC. 1980. Movement of 14C-labelled assimilates into kernels of Zea mays L. An anatomical examination and microautoradiographic study of assimilate transfer. Plant Physiology 65, 864–870.

Fellows RJ, Boyer JS. 1976. Structure and activity of chloroplasts of sunflower leaves having various water potentials. Planta 132, 229–239.

Fellows RJ, Boyer JS. 1978. Altered ultrastructure of cells of sunflower leaves having low water potentials. Protoplasma 93, 381–395.

Finkelstein R, Gibson SI. 2002. ABA and sugar interactions regulating development: cross-talk or voices in a crowd? Current Opinion in Plant Biology 5, 26–32.

Gengenbach BG. 1977. Development of maize caryopses resulting from in-vitro pollination. Planta 134, 91–93.

Griffith SM, Jones RJ, Brenner ML. 1987. In vitro sugar transport in Zea mays L. kernels. 1. Characteristics of sugar absorption and metabolism by developing maize endosperm. Plant Physiology 84, 467–471.

Herrero MP, Johnson RR. 1981. Drought stress and its effect on maize reproductive systems. Crop Science 21, 105–110.

Huang CY, Boyer JS, Vanderhoef LN. 1975. Limitation of acetylene reduction (nitrogen fixation) by photosynthesis in soybean having low water potentials. Plant Physiology 56, 228–232.

Jaynes TA, Nelson OE. 1971. An invertase inactivator in maize endosperm and factors affecting inactivation. Plant Physiology 47, 629–634.

Jurgens SK, Johnson RR, Boyer JS. 1978. Dry matter production and translocation in maize subjected to drought during grain fill. Agronomy Journal 70, 678–682.

Kaiser WM. 1987. Effects of water deficit on photosynthetic capacity. Physiologia Plantarum 71, 142–149.

Kim J-Y, Mahé A, Brangeon J, Prioul J-L. 2000. A maize vacuolar invertase, IVR2, is induced by water stress: organ/tissue specificity and diurnal modulation of expression. Plant Physiology 124, 71–84.

Koch KE. 1996. Carbohydrate-modulated gene expression in plants. Annual Review of Plant Physiology and Plant Molecular Biology 47, 509–540.

Kramer PJ, Boyer JS. 1995. Water relations of plants and soils. San Diego: Academic Press.

Lalonde S, Beebe DU, Saini HS. 1997. Early signs of disruption of wheat anther development associated with the induction of male sterility by meiotic-stage water deficit. Sexual Plant Reproduction 10, 40–48.

León P, Sheen J. 2003. Sugar and hormone connections. Trends in Plant Science 8, 110–116.

Lonnquist JH, Jugenheimer RW. 1943. Factors affecting the success of pollination in corn. Journal of the American Society of Agronomy 35, 923–933.

McLaughlin JE, Boyer JS. 2004. Glucose localization in maize ovaries when kernel number decreases at low water potential and sucrose is fed to the stems. Annals of Botany 94, 75–86.

McPherson HG, Boyer JS. 1977. Regulation of grain yield by photosynthesis in maize subjected to a water deficiency. Agronomy Journal 69, 714–718.

Miller ME, Chourey PS. 1992. The maize invertase-deficient miniature-1 seed mutation is associated with aberrant pedicel and endosperm development. The Plant Cell 4, 297–305.

Moss GI, Downey LA. 1971. Influence of drought stress on female gametophyte development in corn (Zea mays L.) and subsequent grain yield. Crop Science 11, 368–372.

Pankhurst CE, Sprent JI. 1975. Effects of water stress on the respiratory and nitrogen-fixing activity of soybean root nodules. Journal of Experimental Botany 26, 287–304.

Pelleschi S, Rocher J-P, Prioul J-L. 1997. Effect of water restriction on carbohydrate metabolism and photosynthesis in mature maize leaves. Plant, Cell and Environment 20, 493–503.

Porter GA, Knievel DP, Shannon JC. 1987. Assimilate unloading from maize (Zea mays L.) pedicel tissues. Plant Physiology 83, 131–136.

Potter JR, Boyer JS. 1973. Chloroplast response to low leaf water potentials. II. Role of osmotic potential. Plant Physiology 51, 993–997.

Pressey R. 1967. Invertase inhibitors from potatoes: purification, characterization and reactivity with plant invertases. Plant Physiology 42, 1780–1786.

Saini HS, Westgate ME. 2000. Reproductive development in grain crops during drought. Advances in Agronomy 68, 59–96.

Salter PJ, Goode JE. 1967. Crop responses to water at different stages of growth. Farnham Royal, Buckinghamshire, UK: Commonwealth Agricultural Bureaux.

Schoper JB, Lambert RJ, Vasilas BL, Westgate ME. 1987. Plant factors controlling seed set in maize: the influence of silk, pollen, and ear-leaf water status and tassel heat treatment at pollination. Plant Physiology 83, 121–125.

Schussler JR, Westgate ME. 1991. Maize kernel set at low water potential. 1. Sensitivity to reduced assimilates during early kernel growth. Crop Science 31, 1189–1195.

Schussler JR, Westgate ME. 1994. Increasing assimilate reserves does not prevent kernel abortion at low water potential in maize. Crop Science 34, 1569–1576.

Schussler JR, Westgate ME. 1995. Assimilate flux determines kernel set at low water potential in maize. Crop Science 35, 1074–1080.

Seki M, Narusaka M, Ishida J, et al. 2002. Monitoring the expression profiles of 7000 Arabidopsis genes under drought, cold and high-salinity stresses using a full-length cDNA microarray. The Plant Journal 31, 279–292.

Setter TL, Flannigan BA. 2001. Water deficit inhibits cell division and expression of transcripts involved in cell proliferation and endoreduplication in maize endosperm. Journal of Experimental Botany 52, 1401–1408.

Setter TL, Flannigan BA, Melkonian J. 2001. Loss of kernel set due to water deficit and shade in maize: carbohydrate supplies, abscisic acid, and cytokinins. Crop Science 41, 1530–1540.

Shaner DL, Boyer JS. 1976. Nitrate reductase activity in maize (Zea mays L.) leaves. II. Regulation by nitrate flux at low leaf water potentials. Plant Physiology 58, 505–509.

Shannon JC. 1968. Carbon-14 distribution in carbohydrates of immature Zea mays kernels following 14CO2 treatment of intact plants. Plant Physiology 43, 1215–1220.

Shannon JC. 1972. Movement of 14C-labeled assimilates into kernels of Zea mays L. I. Pattern and rate of sugar movement. Plant Physiology 49, 198–202.

Shannon JC, Dougherty CT. 1972. Movement of 14C-labeled assimilates into kernels of Zea mays L. II. Invertase activity of the pedicel and placento-chalazal tissues. Plant Physiology 49, 203–206.

Sheen J, Zhou L, Jang JC. 1999. Sugars as signaling molecules. Current Opinion in Plant Biology 2, 410–418.

Sheoran IS, Saini HS. 1996. Drought-induced sterility in rice: changes in carbohydrate levels and enzyme activities associated with the inhibition of starch accumulation in pollen. Sexual Plant Reproduction 9, 1661–1669.

Sinclair TR. 1990. Relative sensitivity of grain yield and biomass accumulation to drought in field-grown maize. Crop Science 30, 690–693.

Thomas PA, Felker FC, Shannon JC, Crawford CG. 1993. Use of tassel-seed (Ts-5) maize for assimilate transport studies using intact or detached tassel branches. Crop Science 33, 325–328.

Todd GW. 1972. Water deficits and enzymatic activity. In: Kozlowski TT, ed. Water deficits and plant growth, Vol. 3. New York: Academic Press, 177–216.

Trouverie J, Thévenot C, Rocher J-P, Sotta B, Prioul J-L. 2003. The role of abscisic acid in the response of a specific vacuolar invertase to water stress in the adult maize leaf. Journal of Experimental Botany 54, 2177–2186.

Wang Z, Mambelli S, Setter TL. 2002. Abscisic acid catabolism in maize kernels in response to water deficit at early endosperm development. Annals of Botany 90, 623–630.

Weil M, Krausgrill S, Schuster A, Rausch T. 1994. A 17-kDa Nicotiana tabacum cell-wall peptide acts as an in-vitro inhibitor of the cell-wall isoform of acid invertase. Planta 193, 438–445.

Westgate ME. 1994. Water status and development of the maize endosperm and embryo during drought. Crop Science 34, 76–83.

Westgate ME, Boyer JS. 1985. Carbohydrate reserves and reproductive development at low leaf water potentials in maize. Crop Science 25, 762–769.

Westgate ME, Boyer JS. 1986a. Silk and pollen water potentials in maize. Crop Science 26, 947–951.

Westgate ME, Boyer JS. 1986b. Reproduction at low silk and pollen water potentials in maize. Crop Science 26, 951–956.

Westgate ME, Thomson Grant D. 1989. Water deficits and reproduction in maize: response of the reproductive tissues to water deficits at anthesis and mid-grain fill. Plant Physiology 91, 862–867.

Xu J, Pemberton GH, Almira EC, McCarty DR, Koch KE. 1995. The Ivr1 gene for invertase in Zea mays L. Plant Physiology 108, 1293–1294.

Yang J, Zhang J, Wang Z, Zhu Q. 2001a. Activities of starch hydrolytic enzymes and sucrose-phosphate synthase in the stems of rice subjected to water stress during grain filling. Journal of Experimental Botany 52, 2169–2179.

Yang J, Zhang J, Wang Z, Zhu Q, Wang W. 2001b. Remobilization of carbon reserves in response to water-deficit during grain filling of rice. Field Crops Research 71, 47–55.

Yu L, Setter TL. 2003. Comparative transcriptional profiling of placenta and endosperm in developing maize kernels in response to water deficit. Plant Physiology 131, 568–582.

Zinselmeier C. 1991. The role of assimilate supply, partitioning and metabolism in maize kernel development at low water potentials. PhD thesis, University of Minnesota.

Zinselmeier C, Jeong BR, Boyer JS. 1999. Starch and the control of kernel number in maize at low water potentials. Plant Physiology 121, 25–35.

Zinselmeier C, Lauer MJ, Boyer JS. 1995a. Reversing drought-induced losses in grain yield: sucrose maintains embryo growth in maize. Crop Science 35, 1390–1400.

Zinselmeier C, Sun YJ, Helentjaris T, Beatty M, Yang S, Smith H, Habben J. 2002. The use of gene expression profiling to dissect the stress sensitivity of reproductive development in maize. Field Crops Research 75, 111–121.

Zinselmeier C, Westgate ME, Schussler JR, Jones RJ. 1995b. Low water potential disrupts carbohydrate metabolism in maize (Zea mays L.) ovaries. Plant Physiology 107, 385–391.

rating: 5.63 from 16 votes | updated on: 22 Sep 2006 | views: 14375 |

Rate article: