A set of MADS-box genes in flowering plants encode transcription factors that control both flower meristem formation and organ identity in the developing flower. In this report we present the first documentation of the presence of MADS-box genes in a non-flowering seed plant, and indeed from a plant bearing truly unisexual reproductive axes. A MADS-box-specific screening of a cDNA library from immature female strobili of the conifer Norway spruce, Picea abies (L.) Karst, resulted in cDNA clones that correspond to three different deficiens-agamous-like (dal) genes, dal1, dal2 and dal3. In addition to the MADS box, the spruce genes contain a second sequence element conserved among angiosperm genes, the K box, which is located downstream to the MADS box. A phylogenetic analysis of the nucleotide sequences confirms common ancestry of the gene superfamily. dal1 is related to agl2, agl4 and agl6 from Arabidopsis thaliana, all genes with unknown functions, and is expressed in vegetative as well as reproductive shoots on the adult spruce tree. dal2 is sister to angiosperm genes that control the identity of sexual organs, and is expressed only in the developing male and female strobili. dal3 is related to the vegetatively expressed tomato gene tm3 and is transcribed in both vegetative and reproductive shoots. These results strongly suggest that the functional and structural complexity within the MADS-box superfamily of reproduction-control genes is an ancestral property of seed plants and not a novelty in the angiosperm lineage.
A pulse treatment of embryos of Norway spruce with cytokinin suppresses germinative development and induces the coordinate formation of adventitious buds from subepidermal cell layers. To analyse the patterns of gene expression associated with germination and the alterations induced by the bud induction treatment, we have isolated cDNA clones corresponding to genes that are differentially expressed in cytokinin-treated and untreated in vitro germinating embryos. One category of 14 clones hybridized to transcripts that were abundant specifically during germination. The expression of 8 of these genes was reduced by the bud induction treatment. Four clones, including one identified as a histone H2A gene, recognized transcripts that showed an increased abundance in bud-induced versus in vitro germinating embryos. A second category of 13 clones hybridized to transcripts that increased in abundance during post-germinative development of the seedling. Among these a subset of 8 clones, including an alpha-tubulin clone, corresponds to genes suppressed by the bud induction treatment, whereas 5 clones, including a gene with sequence similarity to polyubiquitin, were unaffected by the treatment. One clone hybridized to a message abundant in the seed, during early germination as well as in the vegetative bud, and showed 60% partial sequence identity to a barley (1----3)-beta-glucanase gene. Genes expressed exclusively in bud-induced or in vitro germinating embryos were not found. The results show that a major difference in gene expression between treated and untreated embryos is related to the shift from extensive cell proliferation to elongation and differentiation that occurs at the transition from germination to post-germinative development, and which is suppressed in the bud-induced embryos.
A pulse treatment of Norway spruce (Picea abies (L.) Karst) embryos with the cytokinin N(6)-benzyladenine induces the formation of adventitious buds from subepidermal cells in the hypocotyl and cotyledons. In addition the treatment also inhibits elongation growth, a key process during germination. In this report we demonstrate that these effects on development of the plant are associated with a suppression of the accumulation of several major chloroplast proteins during germination. These proteins include the large subunit of ribulose bisphosphate/carboxylase oxygenase, two subunits of the chloroplast ATPase, protochlorophyllide reductase and a 23000-Mr component of photosystem II. For two nuclear-encoded proteins, the small subunit of ribulose bisphosphate carboxylase/oxygenase and the light-harvesting chlorophyll a/b-binding protein, a corresponding suppression of the increase in the steady-state amounts of mRNA is recorded. The suppression of chloroplast protein synthesis is consistant with the previously documented delay in greening that results from cytokinin treatment, but the effect is opposite to that found in other plants, where cytokinins promote the synthesis of chloroplast proteins, and stimulate chloroplast biogenesis. We believe that this difference is explained by the cytokinin primarily suppressing organ development, and a strict dependance of chloroplast biogenesis on the developmental state of the organs.
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