Gene expression studies on developing kernels of maize sucrose synthase (SuSy) mutants show evidence for a third SuSy gene

Previous studies have identified two tissue- and cell-specific, yet functionally redundant, sucrose synthase (SuSy) genes, Sh1 and Sus1, which encode biochemically similar isozymes, SH1 and SUS1 (previously referred to as SS1 and SS2, respectively). Here we report evidence for a third SuSy gene in maize, Sus3, which is more similar to dicot than to monocot SuSys. RNA and/or protein blot analyses on developing kernels and other tissues show evidence of expression of Sus3, although at the lowest steady-state levels of the three SuSy gene products and without a unique pattern of tissue specificity. Immunoblots of sh1sus1-1 embryos that are either lacking or deficient for the embryo-specific SUS1 protein have shown a protein band which we attribute to the Sus3 gene, and may contribute to the residual enzyme activity seen in embryos of the double mutant. We also studied developing seeds of the double mutant sh1sus1-1, which is missing 99.5% of SuSy enzyme activity, for evidence of co-regulation of several genes of sugar metabolism. We found a significant reduction in the steady-state levels of Miniature-1 encoded cell wall invertase2, and Sucrose transporter (Sut) mRNAs in the double mutant, relative to the lineage-related sh1Sus1 and sh1Sus1 kernels. Down-regulation of the Mn1 gene was also reflected in significant reductions in cell wall invertase activity. Co-regulatory changes were not seen in the expression of Sucrose phosphate synthase, UDP-glucose pyrophosphorylase, and ADP-glucose pyrophosphorylase.     

Accumulation of Japanese cedar pollen allergen,Cry j 1, in the protein body I of transgenic rice seeds using the promoter and signal sequence of glutelin GluB-1 gene

Recombinant Cry j 1, a Japanese cedar pollen allergen, was produced in rice seeds for potential use for oral immunotherapy. Cry j 1 cDNA was divided into two parts, an N-terminal half and a C-terminal half, and each was fused downstream to glutelin GluB-1 gene containing sequences of the promoter, 5 untranslated region and signal peptide. A gene for green fluorescent protein was also fused to the 3 end of the Cry j 1 fragment. Recombinant Cry j 1 of up to 16.6 g per mg total protein of the seeds was expressed in transgenic rice seeds. Although the recombinant Cry j 1 was expected to be accumulated in protein body II because of the employment of glutelin signal peptide, it was demonstrated to be accumulated exclusively in protein body I. The recombinant Cry j 1 was not shown to react with IgE of allergic patients, indicating the reduction of the risk of anaphylactic reaction. These results demonstrate that the transgenic rice seeds with the recombinant Cry j 1 would be useful for the study of oral immunotherapy.     

The Arabidopsis AtEPR1 extensin-like gene is specifically expressed in endosperm during seed germination

Screening of 10 000 Arabidopsis transgenic lines carrying a gene-trap (GUS) construct has been undertaken to identify markers of seed germination. One of these lines showed GUS activity restricted to the endosperm, at the micropylar end of the germinating seed. The genomic DNA flanking the T-DNA insert was cloned by walking PCR and the insertion was shown to be located 70 bp upstream of a 2285 bp open reading frame (AtEPR1) sharing strong similarities with extensins. The AtEPR1 open reading frame consists of 40 proline-rich repeats and is expressed in both wild-type and mutant lines. The expression of the AtEPR1 gene appears to be under positive control of gibberellic acid, but is not downregulated by abscisic acid during seed germination. No expression was detected in organs other than endosperm during seed germination. The putative role of AtEPR1 is discussed in the light of its specific expression in relation to seed germination.     

Phenotypic analysis and molecular cloning of discolored-1 (dsc1), a maize gene required for early kernel development

Recessive mutations in the maize dsc1 locus prevent normal kernel development. Solidification of the endosperm in homozygous dsc1– mutant kernels was undetectable 12 days after pollination, at which time the tissue was apparently completely solidified in wild-type kernels. At later times endosperm did solidify in homozygous dsc1– mutant kernels, but there was a marked reduction in the volume of the tissue. Embryo growth in homozygous dsc1– kernels was delayed compared to wild-type kernels, but proceeded to an apparently normal stage 1 in which the scutellum, coleoptile, and shoot apex were clearly defined. Embryo growth then ceased and the embryonic tissues degraded. Late in kernel development no tissue distinctions were obvious in dsc1– mutant embryos. Immature mutant embryos germinated when transplanted from kernels to tissue culture medium prior to embryonic degeneration, but only coleoptile proliferation was observed. The dsc1 gene was isolated by transposon tagging. Analysis of the two different dsc1– mutations confirmed that transposon insertion into the cloned genomic locus was responsible for the observed phenotype. Dsc1 mRNA was detected specifically in kernels 5–7 days after pollination. These data indicate Dsc1 function is required for progression of embryo development beyond a specific stage, and also is required for endosperm development.     

Development and function of central cell in angiosperm female gametophyte

The central cell characterizes the angiosperm female gametophyte (embryo sac or megagametophyte) in that it directly participates in “double fertilization” to initiate endosperm development, a feature distinguishing angiosperm from all other plant taxa. Polygonum‐type central cell is a binucleate cell that, upon fertilization with one of the two sperm cells, forms triploid endosperm to nourish embryo development. Although the formation and the structure of central cell have well been elucidated, the molecular mechanisms for its specification and development remain largely unknown. The central cell plays a critical role in pollen tube guidance during pollination and in endosperm initiation after fertilization. Recently, a group of mutants affecting specific steps of central cell development and function have been identified, providing some clues in understanding these questions. This review summarizes our current knowledge about central cell development and function, and presents overview about hypotheses for its evolution. genesis 48:466–478, 2010. © 2010 Wiley‐Liss, Inc.