Developmental biology of the cereal endosperm.

The recent application of immunohistochemistry and molecular techniques has revealed that endosperm development depends on a genetic program that combines an ancient process for cellularization (similar to that seen in late Paleozoic seed ferns) with a mechanism for specifying asymmetric cell fates that has parallels to signaling processes in mammals. Progress has been further accelerated by the recent realization that the conserved nature of nuclear endosperm development extends beyond the grass species, to include dicots, such as Arabidopsis. It is anticipated that these ongoing studies will provide invaluable tools for the improvement of yield and grain quality in cereal crops.

Nucellain, a barley homolog of the dicot vacuolar-processing protease, is localized in nucellar cell walls.

The nucellus is a complex maternal grain tissue that embeds and feeds the developing cereal endosperm and embryo. Differential screening of a barley (Hordeum vulgare) cDNA library from 5-d-old ovaries resulted in the isolation of two cDNA clones encoding nucellus-specific homologs of the vacuolar-processing enzyme of castor bean (Ricinus communis). Based on the sequence of these barley clones, which are called nucellains, a homolog from developing corn (Zea mays) grains was also identified. In dicots the vacuolar-processing enzyme is believed to be involved in the processing of vacuolar storage proteins. RNA-blot and in situ-hybridization analyses detected nucellain transcripts in autolysing nucellus parenchyma cells, in the nucellar projection, and in the nucellar epidermis. No nucellain transcripts were detected in the highly vacuolate endosperm or in the other maternal tissues of developing grains such as the testa or the pericarp. Using an antibody raised against castor bean vacuolar-processing protease, a single polypeptide was recognized in protein extracts from barley grains. Immunogold-labeling experiments with this antibody localized the nucellain epitope not in the vacuoles, but in the cell walls of all nucellar cell types. We propose that nucellain plays a role in processing and/or turnover of cell wall proteins in developing cereal grains.

Isolation of molecular markers from the barley endosperm coenocyte and the surrounding nucellus cell layers.

The cereal endosperm develops from a coenocyte to a cellular storage organ through formation of nucleo-cytoplasmic domains and cell wall deposition in the interzones between these domains. During its early stages, the endosperm develops in close contact with nucellus, the sporophytic tissue which gives rise to the megagametophyte. Owing to the positioning of the two tissues deeply within the ovary, neither cell types have been easily accessible for molecular studies. In this paper we report for the first time the cloning of molecular markers for the barley endosperm coenocyte and the nucellus. The novel END1 and NUC1 cDNAs were isolated by differential screening of a cDNA library from 5 DAP (days after pollination) ovaries using a positive probe from hand-dissected embryo sacs with adhering nucellus and testa cell layers, and a negative probe from pericarp. In situ and northern blot hybridization data show that END1 transcripts are asymmetrically distributed in the endosperm coenocyte limited to an area over the nucellar projection. In the cellular endosperm, END1 transcripts are present in modified aleurone cells and a few layers of ventral starchy endosperm cells. The second clone, NUC1, hybridizes to transcripts in the nucellus before fertilization and in autolyzing nucellus cells after fertilization. At later stages, after the disappearance of nucellus, NUC1 transcripts are present in the nucellar epidermis and in the lateral cells of the nucellar projection. This work provide tools for future elucidation of the genes specifying endosperm histogenesis.

The promoter of the barley aleurone-specific gene encoding a putative 7 kDa lipid transfer protein confers aleurone cell-specific expression in transgenic rice.

This paper describes the aleurone-specific gene Ltp2 from barley, which encodes a putative 7 kDa non-specific lipid transfer protein. As shown by Northern and in situ hybridization analyses, the Ltp2 transcript is present in barley aleurone cells shortly after the initiation of aleurone cell differentiation. The expression of Ltp2 increases until grain mid-maturity, but the mRNA is absent from mature grains. The Ltp2 transcript is undetectable in the embryo and vegetative tissues, confirming the aleurone specificity of the Ltp2 gene. The ability of the isolated 801 bp Ltp2 promoter to direct aleurone-specific expression in immature barley grains is demonstrated by particle bombardment experiments. In these experiments, the activity of the Ltp2 promoter is 5% of the activity of the strong constitutive Actin1 promoter from rice, as quantified by GUS activity measurements. In stably transformed rice plants containing the Ltp2 promoter-Gus construct, the specificity of the Ltp2 promoter is confirmed in vivo by the presence of GUS activity exclusively in the aleurone layer. This study demonstrates the conserved nature of the regulatory signals involved in aleurone-specific gene transcription in cereal grains.

Transcripts encoding an oleosin and a dormancy-related protein are present in both the aleurone layer and the embryo of developing barley (Hordeum vulgare L.) seeds.

In cereal seeds, the aleurone layer and the embryo share several characteristics, including synthesis and accumulation of lipid bodies, desiccation tolerance and dormancy. A number of Balem transcripts present in both the barley aleurone layer and the embryo have been cloned by differential screening of a cDNA library from aleurone layers of immature barley grains. The Balem clones constitute two subgroups, one for which the transcripts are detectable in aleurone layers and embryos of developing seeds only (B23D and B15C), and another for which transcripts are present also in germinating embryos and in maternal tissues (B12D, B14E and B31E). Sequence analysis identified B23D and B15C as the barley homologues of the 18 kDa oleosin of maize embryos (72% amino acid identity) and the dormancy-associated transcript pBS128 from Bromus secalinus (95% identity), respectively. In situ hybridization experiments demonstrate that in the embryo, the B23D transcript is mainly present in the scutellum, whereas the B15C transcript is predominantly present in shoot and root apices. Using anther-derived embryos and embryogenic cell suspensions, it is demonstrated that the B23D and B15C transcripts can be used as molecular markers for somatic embryogenesis. The functions of the transcripts in the second Balem subgroup remain unknown. Further studies on the Balem transcripts may shed light on the molecular basis for the extensive similarities between the embryo and the aleurone layer of the endosperm in the grass family.