Endosperm cell division in maize kernels cultured at three levels of water potential

The influence of osmoticum treatments on early kernel development of maize (Zea mays L.) was studied using an in vitro culture method. Kernels with subtending cob sections were placed in culture at 5 days after pollination. Sucrose (0.29, 0.44, or 0.58 molar) and sorbitol (0, 0.15, or 0.29 molar) were used to obtain six media with water potentials of −1.1, −1.6, or −2.0 megapascals. Kernel water potential declined in correspondence with the water potential of the medium; however, fresh weight growth was not significantly inhibited from 5 to 12 days after pollination. In stress treatments with media water potentials of −1.6 or −2.0 megapascals, endosperm tissue accumulated water and solutes from 10 and 12 days after pollination at a rate similar to or greater than that of the control (−1.1 megapascals). In contrast, endosperm cell division was inhibited in all treatments relative to control. At 10 days after pollination, endosperm sucrose concentration was greater in two of the −2.0 megapascal treatments with 0.44 or 0.58 molar media sucrose compared to control kernels cultured in 0.29 molar sucrose at −1.1 megapascals. Significant increases in abscisic acid content per gram of fresh weight were detected in two −2.0 megapascal treatments (0.29 molar sucrose plus 0.29 molar sorbitol and 0.58 molar sucrose) at 10 days after pollination. We conclude that in cultured maize kernels, endosperm cell division was more responsive than fresh weight accumulation to low water potential treatments. Data were consistent with mechanisms involving abscisic acid or lowered tissue water potential, or an interaction of the two factors.     

Abscisic acid catabolism in maize kernels in response to water deficit at early endosperm development

To further our understanding of the greater susceptibility of apical kernels in maize inflorescences to water stress, abscisic acid (ABA) catabolism activity was evaluated in developing kernels with chirally separated (+)-[(3)H]ABA. The predominant pathway of ABA catabolism was via 8'-hydroxylase to form phaseic acid, while conjugation to glucose was minor. In response to water deficit imposed on whole plants during kernel development, ABA accumulated to higher concentrations in apical than basal kernels, while both returned to control levels after rewatering. ABA catabolism activity per gram fresh weight increased about three-fold in response to water stress, but was about the same in apical and basal kernels on a fresh weight basis. ABA catabolism activity was three to four-fold higher in placenta than endosperm, and activity was higher in apical than basal kernels. In vitro incubation tests indicated that glucose did not affect ABA catabolism. We conclude that placenta tissue plays an important role in ABA catabolism, and together with ABA influx and compartmentation, determine the rate of ABA transport into endosperms.     

Ultrastructural characterization of maize (Zea mays L.) kernels exposed to high temperature during endosperm cell division

This study reports the ultrastructural changes in maize endosperm that result from exposure to high temperature during cell division. Kernels were grown in vitro at 25 ºC continuously (control) and at 5 d after pollination (DAP) subsamples were transferred to continuous 35 ºC for either 4 or 6 d. The 4 d treatment reduced kernel mass by 40% and increased kernel abortion three-fold. The 6-d high-temperature treatment resulted in a 77% reduction in kernel mass and a 12-fold increase in kernel abortion. Evaluation of the kernels at 11 DAP using scanning and transmission electron microscopy revealed that the reduced kernel mass and/or abortion was associated with the disruption of cell division and amyloplast biogenesis in the periphery of the endosperm. This was further confirmed by the presence of an irregular-shaped nucleus, altered size of the nucleolus, highly dense nucleoplasm, and a decrease in the number of proplastids and amyloplasts. Thus, the endosperm cavity was not filled, the total number of endosperm cells was reduced by 35 and 70%, and the number of starch granules was decreased by 45 and 80% after exposure to 4 and 6 d of high-temperature treatments, respectively. This also resulted in a 35–70% reduction in total starch accumulation. KI/I₂ staining and light microscopy revealed that starch accumulation in the peripheral endosperm cells was reduced more severely than in the central zones. However, the scanning electron micrographs of cells from the central endosperm showed that the number and the size of apparently viable amyloplasts were reduced and isolated granules were smaller and/or showed enhanced pitting. These ultrastructural data support the hypothesis that high temperature during endosperm cell division reduces kernel sink potential and subsequently mature kernel mass, mainly by disrupting cell division and amyloplast biogenesis in the peripheral and central endosperm.     

Water deficit in developing endosperm of maize: cell division and nuclear DMA endoreduplication

Water deficit severely decreases maize (Zea mays L.) kernel growth; the effect is most pronounced in apical regions of ears. The capacity for accumulation of storage material in endosperms is thought to he partially determined by the extent of cell division and endoreduplication (post-mitotic nuclear DNA synthesis). To gain a better understanding of the regulatory mechanisms involved, we have examined the effect of water deficit on cellular development during the post-fertilization period. Greenhouse-grown maize was subjected to water-limited treatments during rapid cell division [from 1 to 10days after pollination (DAP)] or rapid endoreduplication (9 to 15 DAP). The number of nuclei and the nuclear DNA content were determined with flow cytometry. Water deficit from 1 to 10 DAP substantially decreased the rate of endosperm cell division in apical-region kernels, but had little effect on middle-region endosperms. Rewatcring did not allow cell division to recover in apical-region endosperms. Water deficit from 9 to 15 DAP also decreased cell division in apical-region endosperms. Endoreduplication was not affected by the late treatment in either region of the car, but was inhibited by the early treatment in the apical region. In particular, the proportion of nuclei entering higher DN A-content size classes was reduced. We conclude that cell division is highly responsive to water deficit, whereas endoreduplication is less so. We also conclude that the reduced proportion of nuclei entering higher DNA-content size classes during endoreduplication is indicative of multiple control points in the mitotic and endoreduplication cycles.     

Inhibition of maize endosperm cell division and endoreduplication by exogenously applied abscisic acid

Abscisic acid (ABA) is thought to play a role in inhibiting or aborting kernel growth during water deficit. To test the responsiveness of early endosperm development to ABA concentrations, cylinders containing (±)ABA in a buffered agar medium were applied to the apical pericarp surface of kernels on intact, well‐watered maize ( Zea mays L. cv. Pioneer Brand 3925) plants from 5 to 11 days after pollination (DAP). Endosperm nuclei were analyzed by flow cytometry to assess effects on cell division and endoreduplication. ABA treatments of ≥ 100 µM substantially decreased endosperm cell numbers and fresh weight accumulation, but did not affect average cell size. ABA at ≥ 300 µM decreased the proportion of nuclei in the size classes ≥ 12C, indicating that the rate of transition to endoreduplication status was inhibited, and decreased the progressive advance from 12C to 24C to 48C, indicating that the rate of S‐phase cycling of endoreduplicating cells was inhibited. We conclude that cell division was more responsive to ABA concentrations than were endoreduplication or cell expansion growth.     

Characteristics of an Acid protease from maize endosperm

An assay has been developed to measure protease activity in endosperm extracts of maize seeds. With hemoglobin as substrate, the enzyme(s) has a pH optimum of 3.8 and a temperature optimum of 46 C. It also degrades gliadin, edestin, bovine serum albumin, and partially hydrolyzed zein and glutelin under standard assay conditions. The enzyme(s) has endopeptidase activity with all substrates tested. When undenatured zein and glutelin are suspended in an agar gel, both are efficiently degraded. Using this assay, the protease activity increases from day 3 to day 8 after inhibition and then declines.     

Abscisic acid-regulated Glb1 transient expression in cultured maize P3377 cells

In a study of the 5′-flanking sequence of the Zea mays L. (maize) Glb1 gene in vitro, serial promoter deletions were generated and linked with the β-glucuronidase (GUS) reporter gene. The promoter deletion-GUS fusions were introduced into the maize P3377 cell line by particle bombardment. GUS assays indicated that treatment of the maize cultured cells with abscisic acid (ABA) was required for Glb1-driven GUS transient expression, and that the –272-bp sequence of the Glb1 promoter was sufficient for ABA-regulated expression of GUS. The longest undeleted sequence used, –1391 GUS, showed relatively low expression which could be indicative of an upstream silencer element in the Glb1 promoter between –1391 and –805. Further studies show that the Glb1-driven GUS activity of bombarded maize P3377 cells increases with increasing ABA concentration (up to 100–300 μm). Site-directed mutagenesis of a putative ABA response element, Em1a, abolished GUS expression in P3377 cells. This observation indicated that the Em1a sequence in the Glb1 5′ regulatory region is responsible for the positive ABA regulation of gene expression. Received: 9 May 1997 / Revision received: 9 November 1997 / Accepted: 8 December 1997     

Abscisic Acid accelerates adaptation of cultured tobacco cells to salt

Adaptation of tobacco (Nicotiana tabacum L. var Wisconsin 38) cells to NaCl was accelerated by (±) abscisic acid (ABA). In medium with 10 grams per liter NaCl, ABA stimulated the growth of cells not grown in medium with NaCl (unadapted, S-0) with an increasing response from 10⁻⁸ to 10⁻⁴ molar. ABA (10⁻⁵ molar) enhanced the growth of unadapted cells in medium with 6 to 22 grams per liter NaCl but did not increase the growth of cells previously adapted to either 10 (S-10) or 25 (S-25) grams per liter NaCl unless the cells were inoculated into medium with a level of NaCl higher than the level to which the cells were adapted. The growth of unadapted cells in medium with Na₂SO₄ (85.5 millimolar), KCl (85.5 or 171 millimolar), K₂SO₄ (85.5 millimolar) was also stimulated by ABA. ABA (10⁻⁸-10⁻⁴ molar) did not accelerate the growth of unadapted cells exposed to water deficits induced by polyethylene glycol (molecular weight 8000) (5-20 grams per 100 milliliters), sorbitol (342 millimolar), mannitol (342 millimolar) or sucrose (342 millimolar). These results suggest that ABA is involved in adaptation of cells to salts, and is not effective in promoting adaptation to water deficits elicited by nonionic osmotic solutes.     

Abscisic Acid and the developmental regulation of embryo storage proteins in maize

The relationship of abscisic acid (ABA) inhibition of precocious germination and ABA-induced storage protein accumulation was examined over the course of embryogenesis in wild-type and viviparous mutants of maize (Zea mays L.). We show that a high level of embryo ABA and the product of the Viviparous-1 gene are both required in early maturation phase for germination suppression and the accumulation of storage globulins encoded by the gene Glb1. Suppressing precocious germination with a high osmoticum is not sufficient to initiate Glb1 protein synthesis, although continued accumulation is contingent upon this inhibition; germination of immature or mature embryos leads to a decline in synthesis and the degradation of stored globulins. Late in embryogenesis, fragments of Glb1 protein accumulate, coinciding with the loss of ABA sensitivity. These results suggest that ABA influences storage globulin accumulation by initiating synthesis, suppressing degradation, and inhibiting precocious germination.     

Water deficit induces abscisic Acid accumulation in endosperm of maize viviparous mutants

To determine whether abscisic acid (ABA) accumulation in endosperms of water-limited maize (Zea mays L.) plants is from synthesis in maternal plant organs or from intraendosperm synthesis, plants heterozygous for viviparous (vp) genes were self-pollinated to create endosperm genotypes capable (+/−/−; +/+/−; +/+/+) or incapable (−/−/−) of carotenoid and ABA synthesis. The mutants vp2, vp5, and vp7, each in W22 inbred background, were utilized. Both in wild-type endosperms capable of ABA synthesis and in mutants incapable of ABA synthesis, ABA concentrations at 15 days after pollination were substantially increased in response to plant water deficit. We conclude that ABA synthesis in maternal organs was the source of ABA that accumulated in endosperms in response to plant water deficit.     

Abscisic acid switches cell division modes of asymmetric cell division and symmetric cell division in stem cells of protonemal filaments in the moss Physcomitrium patens

Multicellular organisms regulate cell numbers and cell fate by using asymmetric cell division (ACD) and symmetric cell division (SCD) during their development and to adapt to unfavorable environmental conditions. A stem cell self-renews and generates differentiated cells. In plants, various types of cells are produced by ACD or SCD; however, the molecular mechanisms of ACD or SCD and the cell division mode switch are largely unknown. The moss Physcomitrium (Physcomitrella) patens is a suitable model to study plant stem cells due to its simple anatomy. Here, we report the cell division mode switch induced by abscisic acid (ABA) in P. patens. ABA is synthesized in response to abiotic stresses and induces round-shape cells, called brood cells, from cylindrical protonemal cells. Although two daughter cells with distinct sizes were produced by ACD in a protonemal stem cell on ABA-free media, the sizes of two daughter cells became similar with ABA treatment. Actin microfilaments were spatially localized on the apices of apical stem cells in protonemata on ABA-free media, but the polar accumulation was lost under the condition of ABA treatment. Moreover, ABA treatment conferred an identical cell fate to the daughter cells in terms of cell division activity. Collectively, the results indicate ABA may suppress the ACD characteristics but evoke SCD in cells. We also noticed that ABA-induced brood cells not only self-renewed but regenerated protonemal cells when ABA was removed from the media, suggesting that brood cells are novel stem cells that are induced by environmental signals in P. patens.     

Substrate inhibition of maize endosperm sucrose synthase by fructose and its interaction with glucose inhibition

Sucrose synthase (EC 2.4.1.13) was purified to homogeneity from developing maize (Zea mays L.) endosperm. Substrate saturation and inhibitor kinetics were examined for the sucrose synthase reaction. The K_m-values for fructose and uridine diphosphate glucose (UDPGlc) were estimated to be 7.8 mM and 76 μM, respectively. Fructose concentrations over 20 mM inhibited sucrose synthase in an uncompetitive manner with respect to UDPGlc. Glucose was also found to be an uncompetitive inhibitor with respect to both fructose and UDPGlc. At inhibitory concentrations of fructose, the apparent K_i for glucose increased linearly with increasing fructose concentration. The results suggest an ordered kinetic mechanism for sucrose synthase where UDPGlc binds first and UDP dissociates last. Fructose and glucose both inhibit by binding to the enzyme-UDP complex. Fructose and glucose, which are present in maize endosperm as the products of invertase, could inhibit sucrose synthase, especially in basal regions of the kernel where hexosesmay accumulate.     

Induction of RNase and nuclease activity in cultured maize endosperm cells following sucrose starvation

The activity of RNases and nucleases in plants often increases following exposure to many types of stress, including prolonged exposure to dark or phosphate starvation. In cereals, the activity of RNases and nucleases is also regulated developmentally during late seed development. In this study, we investigated the effect that the absence of sugar or phosphate in culture medium has on the activity of RNases and nucleases expressed in maize endosperm suspension cells. Withdrawal of sugar from the culture medium resulted in a substantial increase in RNase and nuclease activities, whereas deprivation of phosphate during the same period of growth had no detectable effect on either of these activities. The increase in RNase activity was limited to the neutral RNases, demonstrating that the effect of sugar starvation is specific to one class of RNase. Elimination of asparagine from the medium resulted in a transient reduction in nuclease but not in RNase activity. These observations suggest that sugar starvation constitutes a stress to which maize endosperm responds, in part, by increasing neutral RNase and nuclease activity.     

Aleurone cell identity is suppressed following connation in maize kernels

Expression of the cytokinin-synthesizing isopentenyl transferase enzyme under the control of the Arabidopsis (Arabidopsis thaliana) SAG12 senescence-inducible promoter reverses the normal abortion of the lower floret from a maize (Zea mays) spikelet. Following pollination, the upper and lower floret pistils fuse, producing a connated kernel with two genetically distinct embryos and the endosperms fused along their abgerminal face. Therefore, ectopic synthesis of cytokinin was used to position two independent endosperms within a connated kernel to determine how the fused endosperm would affect the development of the two aleurone layers along the fusion plane. Examination of the connated kernel revealed that aleurone cells were present for only a short distance along the fusion plane whereas starchy endosperm cells were present along most of the remainder of the fusion plane, suggesting that aleurone development is suppressed when positioned between independent starchy endosperms. Sporadic aleurone cells along the fusion plane were observed and may have arisen from late or imperfect fusion of the endosperms of the connated kernel, supporting the observation that a peripheral position at the surface of the endosperm and not proximity to maternal tissues such as the testa and pericarp are important for aleurone development. Aleurone mosaicism was observed in the crown region of nonconnated SAG12-isopentenyl transferase kernels, suggesting that cytokinin can also affect aleurone development.     

Regulation of programmed cell death in maize endosperm by abscisic acid

Cereal endosperm undergoes programmed cell death (PCD) during its development, a process that is controlled, in part, by ethylene. Whether other hormones influence endosperm PCD has not been investigated. Abscisic acid (ABA) plays an essential role during late seed development that enables an embryo to survive desiccation. To examine whether ABA is also involved in regulating the onset of PCD during endosperm development, we have used genetic and biochemical means to disrupt ABA biosynthesis or perception during maize kernel development. The onset and progression of cell death, as determined by viability staining and the appearance of internucleosomal DNA fragmentation, was accelerated in developing endosperm of ABA-insensitive vp1 and ABA-deficient vp9 mutants. Ethylene was synthesized in vp1 and vp9 mutant kernels at levels that were 2–4-fold higher than in wild-type kernels. Moreover, the increase and timing of ethylene production correlated with the premature onset and accelerated progression of internucleosomal fragmentation in these mutants. Treatment of developing wild-type endosperm with fluridone, an inhibitor of ABA biosynthesis, recapitulated the increase in ethylene production and accelerated execution of the PCD program that was observed in the ABA mutant kernels. These data suggest that a balance between ABA and ethylene establishes the appropriate onset and progression of programmed cell death during maize endosperm development.