Summary
Sexual and aposporously apomictic plants of buffelgrass (Cenchrus ciliaris L.) form megaspore tetrads. In sexual plants the chalazal megaspore develops into a single Polygonum type embryo sac. In aposporous plants the megaspores degenerate, and one or more un-reduced nucellar cells form Panicum type embryo sacs. Apospory is conditioned by gene A; the dominant allele of gene B is epistatic to A and preserves sexual reproduction. We recently observed that heavy application of (NH4)2SO4 to the soil induced multiple embryo sacs in a sexual line. Therefore we tested the effect of salt stress on embryo sac formation in sexual and aposporous genotypes. One molar solutions of CaCl2, NaCl, (NH4)2SO4, NH4Cl, NaNO3, or Na2SO4 were applied to the soil of greenhouse plants every day or two starting at the archespore stage. Some of the pistils in salt-treated plants of sexual genotypes AaBb, aaBb, and aabb showed features not seen in untreated controls: (1) multiple Polygonum type embryo sacs in 1%–7% of pistils depending upon the salt; (2) embryo sacs without antipodals (0%–7%); (3) embryo sacs protruding through the micropyle (1%–16%). Some pistils of salt-treated obligately aposporous lines, but not controls, developed Polygonum type embryo sacs (4%–13%) and protruding embryo sacs (0%–6%). There was no ion specificity for induction of abnormal features. We postulate that salt stress suppresses the developmental priority of nucellar embryo sacs over megaspores in aposporous lines and of the chalazal megaspore over other megaspores in all lines. This may permit megaspores of aposporous plants to form reduced Polygonum type gametophytes, and permit more than one megaspore to form reduced embryo sacs in all lines. Protrusion of sacs and failure of antipodal formation in reduced embryo sacs may be the consequence of uncoordinated expansion of the embryo sacs and surrounding tissue.
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Joint contribution of the Department of Biology, The Pennsylvania State University, and USDA-ARS, U.S. Regional Pasture Research Laboratory. Names of products are included for the benefit of the reader and do not imply endorsement or preferential treatment by USDA
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Gounaris, E.K., Sherwood, R.T., Gounaris, I. et al. Inorganic salts modify embryo sac development in sexual and aposporous Cenchrus ciliaris . Sexual Plant Reprod 4, 188–192 (1991). https://doi.org/10.1007/BF00190003
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DOI: https://doi.org/10.1007/BF00190003