Summary
We describe the spatial and temporal immunohistological distributions of the two sucrose synthases, SS1 and SS2, encoded by the Sh and Sus genes, respectively, in different parts of the maize plant. The two similar isozymes were differentially localized in developing endosperm cells through the combined uses of a shrunken (sh) mutant lacking the SS1 protein and the SS1 and SS2 antisera. The accumulation of SS1 protein always coincided with starch deposition in the Sh endosperm cells, whereas in the sh endosperm, the centrally located cells were lost at or during the most critical phase of starch biosynthesis. The SS2 specific cells, including aleurone layer and the basal endosperm transfer cells in both genotypes, were not associated with detectable starch deposition. Such heterogeneity was indicative of two cell types separable by gene expression, and of differential in vivo roles of the two isozymes in the endosperm. In young roots, the expression of both SS encoding genes was predominantly in the vascular cylinder region. These data fulfill a previous prediction, based on the genetic analyses, that the expression of the SS genes is spatially and/or temporally separated in endosperm cells but not in root cells.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Chourey PS (1981) Genetic control of sucrose synthetase in maize endosperm. Mol Gen Genet 184:372–376
Chourey PS, Nelson OE (1976) The enzymatic deficiency conditioned by the shrunken-1 mutations in maize. Biochem Genet 14:1041–1055
Chourey PS, Nelson OE (1979) Interallelic complementation at the sh locus in maize at the enzyme level. Genetics 91:317–325
Chourey PS, Latham MD, Still PE (1986) Expression of two sucrose synthetase genes in endosperm and seedling cells of maize: evidence of tissue-specific polymerization of protomers. Mol Gen Genet 203:251–255
Chourey PS, DeRobertis GA, Still PE (1988) Altered tissue specificity of the revertant shrunken allele upon dissociation (Ds) excision is associated with loss of expression and molecular rearrangement at the corresponding non-allelic isozyme locus in maize. Mol Gen Genet 214:300–306
Clark JK, Sheridan WF (1986) Developmental profiles of the maize embryo-lethal mutants dek22 and dek23. J Hered 77:83–92
Echt CS, Chourey PS (1985) A comparison of two sucrose synthetase isozymes from normal and shrunken-1 maize. Plant Physiol 79:530–536
Giaquinta RT (1980) Translocation of sucrose and oligosaccharides. In: Press J (ed) The biochemistry of plants — A comprehensive treatise. Academic Press, New York, pp 271–315
Gupta M, Chourey PS, Burr B, Still PE (1988) cDNAs of two non-allelic sucrose synthase genes in maize: cloning, expression, characterization and molecular mapping of the sucrose synthase-2 gene. Plant Mol Biol 10:215–224
Kiesselbach TA (1949) The structure and reproduction of corn. Nebr Agric Exp Stn Res Bull 161:1–96
Kowles RV, Phillips RL (1985) DNA amplification patterns in maize endosperm nuclei during kernel development. Proc Natl Acad Sci USA 82:7010–7014
Kyle DJ, Styles ED (1977) Development of aleurone and sub-aleurone layers in maize. Planta 137:185–193
McCarty DR, Shaw JR, Hannah LC (1986) The cloning, genetic mapping, and expression of the constitutive sucrose synthase locus of maize. Proc Natl Acad Sci USA 83:9099–9103
McClintock B (1978) Development of the maize endosperm as revealed by clones. In: Subtelny S, Sussex I (eds) 36th Symp Soc Devel Biol. Academic Press, New York, pp 217–237
McElfresh KC, Chourey PS (1988) Anaerobiosis induces transcription but not translation of sucrose synthase in maize. Plant Physiol 87:542–546
Phillips RL, Kowles RF, McMullen JD, Enomoto S, Rubenstein I (1985) Developmentally timed changes in maize endosperm DNA. In: Freeling M (ed) Plant genetics. Alan R Liss, New York, pp 739–754
Sass JE (1945) Schedules for sectioning maize kernels. Stain Technol 20:93–98
Schwartz D (1960) Electrophoretic and immunochemical studies with endosperm proteins of maize mutants. Genetics 45:1419–1427
Shannon JC (1972) Movement of 14C-labelled assimilates into kernels of Zea mays L. Plant Physiol 49:198–202
Shannon JC, Porter GA, Knievel DP (1986) Phloem unloading and transfer of sugars into developing corn endosperm. In: Cronshaw J, Lucas WJ, Giaquinta RT (eds) Phloem transport. Alan R Liss, New York, pp 265–277
Springer B, Werr W, Starlinger P (1985) Regulation of the sucrose synthase genes. Maize Genet Coop Newslett 59:32
Springer B, Werr W, Starlinger P, Bennett DC, Zokolica M, Freeling M (1986) The Shrunken gene on chromosome 9 of Zea mays L. is expressed in various plant tissue and encodes an anaerobic protein. Mol Gen Genet 205:461–468
Su JC, Preiss J (1978) Purification and properties of sucrose synthase from maize kernels. Plant Physol 61:389–393
Tsaftaris AS, Scandalios JG (1986) Spatial pattern of catalase (Cat2) gene activation in scutella during postgerminative development in maize. Proc Natl Acad Sci USA 83:5549–5553
Tsai CY, Salamini F, Nelson OE (1970) Enzymes of carbohydrate metabolism in the developing endosperm of maize. Plant Physiol 46:299–306
Werr W, Frommer WB, Maas C, Starlinger P (1985) Structure of the sucrose synthase gene on chromosome 9 of Zea mays L. EMBO J 4:1373–1380
Author information
Authors and Affiliations
Additional information
Communicated by P. L. Pfahler
Rights and permissions
About this article
Cite this article
Chen, Y.C., Chourey, P.S. Spatial and temporal expression of the two sucrose synthase genes in maize: immunohistological evidence. Theoret. Appl. Genetics 78, 553–559 (1989). https://doi.org/10.1007/BF00290842
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00290842