Signaling from the embryo conditions Vp1-mediated repression of alpha-amylase genes in the aleurone of developing maize seeds.

The VP1 transcription factor functions as both a repressor and an activator of gene expression in the developing aleurone. Vp1 activation of the anthocyanin pathway exhibits strict cell autonomy in aleurone. In contrast, Vp1-mediated repression of hydrolase genes in aleurone cells during seed development is determined by a combination of cell autonomous and cell non-autonomous signals. To analyze signaling between the embryo and aleurone during seed development, a T-B3La chromosome translocation was used to create seed that has non-concordant embryo and endosperm genotypes. We show that de-repression of an Amy-GUS reporter gene in developing vp1 mutant aleurone cells strongly depends on the presence of a viviparous embryo. Genetic ablation of the developing embryo in vp1 mutant and Vp1 seeds through the introduction of an early embryo mutation caused a similar enhancement of Amy-GUS expression in the aleurone, suggesting that the quiescent embryo present in normal seed is a critical source of inhibitory signals. Analysis of an ABA deficient vp1 vp5 double mutant indicates that ABA synthesized in the embyro interacts additively with Vp1 to prevent precocious induction of alpha-amylase genes in the aleurone of the developing seed. A lack of ABA synthesis, however, does not account for the strongly synergistic interaction between a viviparous vp1 embryo and mutant aleurone suggesting that a quiescent embyro is a source of other inhibitory signals.

The quiescent/colorless alleles of viviparous1 show that the conserved B3 domain of VP1 is not essential for ABA-regulated gene expression in the seed.

A series of vp1 alleles distinguish at least two classes of maturation-related genes that are regulated by the VP1 factor and abscisic acid (ABA). The intermediate vp1-c821708 and vp1-McW alleles have quiescent (non-viviparous) anthocyanin-deficient phenotypes while maintaining significant levels of maturation-specific gene expression in the developing embryo. However, expression of the C1 regulatory gene of the anthocyanin pathway is not detected in these mutants. Reduced steady-state levels of structurally altered VP1 proteins are detected in quiescent mutant embryos. The VP1-McW protein sequence lacks the highly conserved region encoded by exons 3-5 of the Vp1 gene. A sensitive RT-PCR assay was used to rule out significant amounts of intact transcripts in the vp1-McW mutant that could account for the quiescent phenotype. In transient expression assays, the VP1-McW protein and other mutants with a truncated B3 domain of VP1 retained a strong capacity to synergistically enhance ABA-regulation of the Em-GUS reporter gene; whereas transactivation of both Em-GUS and C1-sh-GUS genes in the absence of hormone was strongly inhibited. These results indicate that the largest conserved region in VP1 homologs (B3) is critical for gene activation at low or insignificant ABA dosages; whereas the N-terminal domain provides a key interface with ABA signaling pathways in the developing seed.

Integration and expression of the high-molecular-weight glutenin subunit 1Ax1 gene into wheat.

The unique bread-making characteristic of wheat flour is closely related to the elasticity and extensibility of the gluten proteins stored in the starchy endosperm, particularly the high-molecular-weight glutenin subunits (HMW-GS), which are important in determining gluten and dough elasticity. The quality of wheat cultivars depends on the number and composition of the HMW-GS present. We have introduced the HMW-GS 1Ax1 gene, known to be associated with good bread-making quality, into the Bob White cultivar of wheat (Triticum aestivum L.), in which it is not present in nature, by the biolistic bombardment of cultured immature embryos. Of the 21 independent transformed lines selected, 20 expressed the selectable bar gene, and nine the 1Ax1 gene. The amount of HMW-GS 1Ax1 protein produced in the different transgenic lines varied from 0.6% to 2.3% of the total protein, resulting in an increase of up to 71% in total HMW-GS proteins. The transgenic plants were normal, fertile, and showed Mendelian segregation of the transgenes. The accumulation of HMW-GS 1Ax1 was consistent and stable up to the R3 seed generation. These results demonstrate that it is possible to manipulate both the quantity and quality of HMW-GS, which influence the bread-making quality of wheat.

Two cold-inducible genes encoding lipid transfer protein LTP4 from barley show differential responses to bacterial pathogens.

The barley genes HvLtp4.2 and HvLtp4.3 both encode the lipid transfer protein LTP4 and are less than 1 kb apart in tail-to-tail orientation. They differ in their non-coding regions from each other and from the gene corresponding to a previously reported Ltp4 cDNA (now Ltp4.1). Southern blot analysis indicated the existence of three or more Ltp4 genes per haploid genome and showed considerable polymorphism among barley cultivars. We have investigated the transient expression of genes HvLtp4.2 and HvLtp4.3 following transformation by particle bombardment, using promoter fusions to the beta-glucuronidase reporter sequence. In leaves, activities of the two promoters were of the same order as those of the sucrose synthase (Ss1) and cauliflower mosaic virus 35S promoters used as controls. Their expression patterns were similar, except that Ltp4.2 was more active than Ltp4.3 in endosperm, and Ltp4.3 was active in roots, while Ltp4.2 was not. The promoters of both genes were induced by low temperature, both in winter and spring barley cultivars. Northern blot analysis, using the Ltp4-specific probe, indicated that Xanthomonas campestris pv. translucens induced an increase over basal levels of Ltp4 mRNA, while Pseudomonas syringae pv. japonica caused a decrease. The Ltp4.3-Gus promoter fusion also responded in opposite ways to these two compatible bacterial pathogens, whereas the Ltp4.2-Gus construction did not respond to infection.

Localization and interaction of the cis-acting elements for abscisic acid, VIVIPAROUS1, and light activation of the C1 gene of maize.

The C1 regulatory gene of the maize anthocyanin pathway is regulated by a combination of developmental and environmental signals that include the Viviparous1 (Vp1) gene, abscisic acid (ABA), and light. Using protoplast electroporation and particle bombardment assays, we have defined c/s-acting elements that are necessary and sufficient for the activation of C1 by ABA, VP1, and light, respectively. The sequence from positions -142 to -132 (CGTCCATGCAT) is essential for VP1 activation, whereas a larger overlapping element from -147 to -132 (CGTGTCGTCCATGCAT) is necessary and sufficient for activation by ABA. A separate light (blue and red)-responsive c/s element is located between positions -116 and -59. Light interacts synergistically with the ABA and VP1 responses in transient expression assays, suggesting that combinatorial interaction between modules plays a role in integrating these signals in the developing seed.

Molecular characterization of the fate of transgenes in transformed wheat (Triticum aestivum L.).

Molecular analysis of the transgenes bar and gus was carried out over successive generations in six independent transgenic lines of wheat, until the plants attained homozygosity. Data on expression and integration of the transgenes is presented. Five of the lines were found to be stably transformed, duly transferring the transgenes to the next generation. The copy number of the transgenes varied from one to five in the different lines. One line was unstable, first losing expression of and then eliminating both the transgenes in R3 plants. Although the gus gene was detected in all the lines, GUS expression had been lost in R2 plants of all but one line. Rearrangement of transgene sequences was observed, but it had no effect on gene expression. All the stable lines were found to segregate for transgene activity in a Mendelian fashion.

Accelerated production of transgenic wheat (Triticum aestivum L.) plants.

We have developed a method for the accelerated production of fertile transgenic wheat (Triticum aestivum L.) that yields rooted plants ready for transfer to soil in 8-9 weeks (56-66 days) after the initiation of cultures. This was made possible by improvements in the procedures used for culture, bombardment, and selection. Cultured immature embryos were given a 4-6 h pre-and 16 h post-bombardment osmotic treatment. The most consistent and satisfactory results were obtained with 30 µg of gold particles/bombardment. No clear correlation was found between the frequencies of transient expression and stable transformation. The highest rates of regeneration and transformation were obtained when callus formation after bombardment was limited to two weeks in the dark, with or without selection, followed by selection during regeneration under light. Selection with bialaphos, and not phosphinothricin, yielded more vigorously growing transformed plantlets. The elongation of dark green plantlets in the presence of 4-5 mg/l bialaphos was found to be reliable for identifying transformed plants. Eighty independent transgenic wheat lines were produced in this study. Under optimum conditions, 32 transformed wheat plants were obtained from 2100 immature embryos in 56-66 days, making it possible to obtain R3 homozygous plants in less than a year.

Integrated control of seed maturation and germination programs by activator and repressor functions of Viviparous-1 of maize.

The Viviparous-1 (VP1) transcriptional activator of maize is required for abscisic acid induction of maturation-specific genes late in seed development leading to acquisition of desiccation tolerance and arrest in embryo growth. Here, we show that VP1 also inhibits induction of the germination-specific alpha-amylase genes in aleurone cells of the developing seed and thereby appears to be involved in preventing precocious hydrolyzation of storage compounds accumulating in the endosperm. In developing seeds of the somatically instable vp1-m2 mutant, hydrolase activity was derepressed specifically in endosperm sectors underlying vp1 mutant aleurone. A barley alpha-amylase promoter-GUS reporter construct (Amy-GUS) was induced in developing vp1 mutant aleurone cells but not in wild-type aleurone cells. Moreover, transient expression of recombinant VP1 and vp1 mutant aleurone cells strongly inhibited expression of Amy-GUS and thus effectively complemented this aspect of the mutant phenotype. VP1 specifically repressed induction of Amy-GUS by the hormone gibberellic acid in aleurone of germinating barley seeds. Deletion of the acidic transcriptional activation domain of VP1 did not affect the inhibitory activity, indicating that VP1 has a discrete repressor function. Hence, physically combining activator and repressor functions in one protein may provide a mechanism to integrate the control of two normally consecutive developmental programs, seed maturation and seed germination.

Overlap of Viviparous1 (VP1) and abscisic acid response elements in the Em promoter: G-box elements are sufficient but not necessary for VP1 transactivation.

The relationship between promoter sequences that mediate Viviparous1 (VP1) transactivation and regulation by abscisic acid (ABA) in the wheat Em promoter was investigated using deletion analysis and directed mutagenesis. The Em1a G-box is strongly coupled to VP1 transactivation as well as to ABA regulation; however, the Em promoter includes additional components that can support VP1 transactivation without ABA responsiveness or synergism. Oligonucleotide tetramers of several G-box sequences, including Em1a, Em1b, and the dyad G-box element from the UV light-regulated parsley chalcone synthase gene, were sufficient to confer VP1 transactivation and the synergistic interaction with ABA to the -45 cauliflower mosaic virus 35S core promoter. These data suggest that VP1 can activate transcription through at least two classes of cis-acting sequences, including the G-box elements and the Sph regulatory motif found in the C1 promoter. The contrasting roles of these motifs in the Em and C1 promoters suggest a basis for the differential regulation of the corresponding genes by VP1.

Molecular analysis of plants regenerated from embryogenic cultures of wheat (Triticum aestivum L.).

Total DNAs of plants regenerated from immature embryo-derived 2-month-old embryogenic calli of wheat (cultivars Florida 302, Chris, Pavon, RH770019) were probed with six maize mitochondrial genes (atpA, atp6, apt9, coxI, coxII, rrn18-rrn5), three hypervariable wheat mitochondrial clones (K', K3, X2), five random pearl millet mitochondrial clones (4A9, 4D1, 4D12, 4E1, 4E11) and the often-used wheat Nor locus probe (pTA71), in order to assess the molecular changes induced in vitro. In addition, protoplast-derived plants, and 24-month-old embryogenic and non-embryogenic calli and cell suspension cultures of Florida 302 were also analyzed. No variation was revealed by the wheat or millet mitochondrial clones. Qualitative variation was detected in the nonembryogenic suspension culture by three maize mitochondrial genes (coxI, rrn18-rrn5, atp6). A callus-specific 3.8-kb Hind III fragment was detected in all four cultivars after hybridization with the coxI gene. The organization of the Nor locus of the plants regenerated from Florida 302 and Chris was stable when compared to their respective control plants and calli. The Nor locus in regenerants of Pavon and RH, on the other hand, was found to be variable. However, Nor locus variability was not observed in 14 individual seed-derived control plants from either Pavon or RH sources. In Pavon, a 3.6-kb Taq I or a 5.6-kb Bam HI+ Eco RI fragment was lost after regeneration. In one of the RH regenerants, which lost a fragment, an additional fragment was observed.

Molecular analysis of plants regenerated from embryogenic cultures of hybrid sugarcane cultivars (Saccharum spp.).

The genomic stability of tissue culture regenerants of sugarcane (Saccharum spp. hybrids, cvs 'CP721210', 'CP68-1067' and 'B43-62') was analyzed by DNA restriction fragment length polymorphism (RFLP). Plants regenerated from calli, cell suspensions, cryopreserved cell suspensions and protoplasts were used. Total DNA isolated from 19 different sources was digested with EcoRI, HindIII, BamHI, BamHI, EcoRI and PstI and probed with six known maize mitochondrial genes (coxI, coxII, atpA, atp6, atp9 and rrn18-rrn5), three random maize mitochondrial cosmid clones, two random maize chloroplast cosmid clones and a wheat Nor locus clone. Hybridization patterns indicated that the variation observed was minor and appeared only in the secondcycle regenerants. No differences were observed among the three cultivars and the regenerants from calli, suspension culture, cryopreserved suspension culture and protoplasts. Mitochondrial DNA (mtDNA) isolated from 'CP72-1210' plants and its embryogenic cell suspensions, and bulk samples from all 'CP72-1210' regenerants pooled together were digested with EcoRI, HindIII, PstI, BamHI and SalI and probed with three recombinationally active wheat mtDNA clones, K', K3 and X2. No variation in the mtDNA restriction patterns was observed between the 'CP72-1210' plants and its regenerants. However, restriction pattern variation was observed only from EcoRI digestion, and hybridization patterns of K3, K' and X2 revealed minor variations in the mtDNA of cell suspensions when compared with the DNA of the 'CP72-1210' plant. Except for a qualitative variation detected by the X2 probe and minor stoichiometric variations detected by the K3 probe, sugarcane DNAs were found to be stable after plant regeneration.

Enhanced GUS gene expression in cereal/grass cell suspensions and immature embryos using the maize uhiquitin-based plasmid pAHC25.

Transient GUS (ß-glucuronidase) expression was visualized in cell suspensions of Triticum aestivum, Zea mays, Pennisetum glaucum, Saccharum officinarum, Pennisetum purpureum and Panicum maximum after microprojectile bombardment with pBARGUS and pAHC25 plasmid DNAs. pBARGUS contains the GUS (UidA) gene coding region driven by the Adh1 promoter and the Adh1 intron 1, as well as the BAR gene coding region driven by the CaMV 35S promoter and the Adh1 intron 1. pAHC25 contains the GUS and BAR gene coding regions driven by the maize ubiquitin promoter, first exon and first intron (Ubi1). The effectiveness of the constructs was first compared in cell suspension cultures by counting blue expression units (b.e.u.). The expression of construct pAHC25 ranged from 3 to 50 fold greater than pBARGUS in different species. In addition, the two plasmids were quantitatively compared in Triticum aestivum and Zea mays by using the more sensitive GUS fluorometric assay to determine the amount of methylumbellyferride (MU) produced. There was more than a 30 fold increase in MU production with pAHC25 than with pBARGUS in the wheat suspension, while the maize suspension showed only a 2.5 fold increase with the pAHC25 construct. Transient GUS expression was also visualized in immature embryos of Pennisetum glaucum following bombardment with pBARGUS and pAHC25 DNA. Expression of plasmid pAHC25 was twice as high as pBARGUS. A comparison of two DNA/gold preparation methods, as well as repeated sonications of the DNA/gold mixture, had no effect on the number of b.e.u.

Multiple ocs-like elements required for efficient transcription of the mannopine synthase gene of T-DNA in maize protoplasts.

Regulatory elements controlling transcriptional activity of the mannopine synthase 2' promoter (mas 2') were defined by analysis of deletion mutants in transient expression assays in maize protoplasts. Deletion of the region between -305 and -290 containing sequence similarity to the octopine synthase (ocs) promoter element reduced activity by 67% compared to wild type activity. Less than 1% of the activity remained in 5' deletions downstream of -153. Inclusion of various heterologous enhancer-like sequences immediately upstream of position -325 increased activity by up to 7.5-fold. Insertion of the -325 to -275 sequence alone, or in combination with heterologous enhancer-like elements, restored activity of some of the 5'-deletion mutants. Restoration of activity was not obtained with mutants deleted past position -127. Our results suggest that a single class of nuclear proteins from maize interact with high affinity at elements designated mas b (-306 to -275; mas 1' element), d (-127 to -108), and e (-82 to -39; mas 2' element) as well as the 20 bp element from the ocs promoter. Although the binding site at mas d only appears to accommodate a single protein, this element has the potential to make a weak, but positive, contribution to the activity of the mas 2' promoter. The binding of nuclear proteins could not be demonstrated at mas a and c, both of which showed limited homology to the ocs element. Mutational evidence suggested that mas a and c may also contribute to mas 2' transcription.

The Viviparous-1 gene and abscisic acid activate the C1 regulatory gene for anthocyanin biosynthesis during seed maturation in maize.

The Viviparous-1 (Vp1) gene is required for expression of the C1 regulatory gene of the anthocyanin pathway in the developing maize seed. We show that VP1 overexpression and the hormone, abscisic acid (ABA), activate a reporter gene driven by the C1 promoter in maize protoplasts. Cis-acting sequences essential for these responses were localized. Mutation of a conserved sequence in the C1 promoter abolishes both ABA regulation and VP1 trans-activation. An adjacent 5-bp deletion blocks ABA regulation but not VP1 trans-activation. The latter mutant reconstructs the promoter of c1-p, an allele that is expressed during seed germination but not during seed maturation. We suggest that VP1 activates C1 specifically during maturation by interacting with one or more ABA-regulated transcription factors.

Biochemical and molecular analysis of plants derived from embryogenic tissue cultures of napier grass (Pennisetum purpureum K. Schum).

We have investigated the extent of biochemical and molecular variation in 63 plants of napier grass (Pennisetum purpureum K. Schum.) regenerated from 3- to 24-week-old embryogenic callus cultures. The calli were derived from cultured basal segments of young leaves and immature inflorescences obtained from a single fieldgrown donor plant. The entire population was analyzed for the activity of 14 isozyme systems, but no qualitative variation was found at any of the loci examined. Similarly, no restriction fragment length polymorphisms (RFLPs) were detected in the mitochondrial, plastid and nuclear genomes in a representative sample of regenerated plants. Our results confirm earlier reports of the genetic uniformity of plants derived from somatic embryos and highlight their value both for clonal propagation and for genetic transformation.

Ultrastructural changes in suspension culture cells of Panicum maximum during cryopreservation.

A Panicum maximum cell suspension was used to study ultrastructural changes during cryopreservation. Pregrowing the cells in mannitol caused reduction in the vacuolar volume by redistribution of the large central vacuole into a number of smaller vesicles. Invaginations were formed in the plasma membrane of the cells, to accommodate the reduced cell volume. Swelling of organelles occurred during different stages of cryopreservation. The cisternae of the endoplasmic reticulum dilated and formed vesicles. Although some damage was apparent, organelles were still recognizable in cells frozen slowly and freeze-fixed at -10°C. The cells were able to repair such damage within two days in culture, and regained their normal appearance. Cells frozen slowly without any cryoprotection, and cells frozen rapidly by direct immersion into liquid nitrogen after cryoprotection, were lethally damaged by destruction of membranous structures. Osmiophilic granules were found along the plasma membrane of lethally damaged cells, indicating that their formation is a consequence of freeze damage, rather than a mechanism to prevent injury.