Inducible overexpression of oat arginine decarboxylase in transgenic tobacco plants.

To test the possible interaction of polyamines in plant growth responses, transgenic tobacco plants containing the Avena sativa L. (oat) arginine decarboxylase (ADC) gene under the control of a tetracycline-inducible promoter were generated. Inducible overexpression of oat ADC in transgenic tobacco led to an accumulation of ADC mRNA, increased ADC activity and changes in polyamine levels. Transgenic lines, induced during vegetative stage, displayed different degrees of an altered phenotype, the severity of which was correlated with putrescine content. These phenotypic changes were characterized by short internodes, thin stems and leaves, leaf chlorosis and necrosis, as well as reduced root growth. This is the first report to show altered phenotypes as a consequence of polyamine changes under tetracycline-induction in in vivo conditions. Interestingly, overexpression of oat ADC in tobacco resulted in similar detrimental effects to those observed by ADC activation induced by osmotic stress in the homologous oat leaf system. In the context of the role of specific polyamines in plant growth and development, the present results indicate that activation of the ADC pathway leading to high levels of endogenous putrescine (or its catabolytes) is toxic for the vegetative growth of the plant. In contrast, no visible phenotypic effects were observed in flowering plants following tetracycline induction. Further characterization of the different transgenic lines may shed light on the action of specific polyamines in different plant developmental processes.

Arginine Decarboxylase Is Localized in Chloroplasts.

Plants, unlike animals, can use either ornithine decarboxylase or arginine decarboxylase (ADC) to produce the polyamine precursor putrescine. Lack of knowledge of the exact cellular and subcellular location of these enzymes has been one of the main obstacles to our understanding of the biological role of polyamines in plants. We have generated polyclonal antibodies to oat (Avena sativa L.) ADC to study the spatial distribution and subcellular localization of ADC protein in different oat tissues. By immunoblotting and immunocytochemistry, we show that ADC is organ specific. By cell fractionation and immunoblotting, we show that ADC is localized in chloroplasts associated with the thylakoid membrane. The results also show that increased levels of ADC protein are correlated with high levels of ADC activity and putrescine in osmotically stressed oat leaves. A model of compartmentalization for the arginine pathway and putrescine biosynthesis in active photosynthetic tissues has been proposed. In the context of endosymbiote-driven metabolic evolution in plants, the location of ADC in the chloroplast compartment may have major evolutionary significance, since it explains (a) why plants can use two alternative pathways for putrescine biosynthesis and (b) why animals do not possess ADC.

Slow-growth phenotype of transgenic tomato expressing apoplastic invertase.

The growth of transgenic tomato (Lycopersicon esculentum) plants that express in their apoplast yeast invertase under the control of the cauliflower mosaic virus 35S promoter is severely inhibited. The higher the level of invertase, the greater the inhibition of growth. A second phenotypic characteristic of these transgenic plants is the development of yellow and necrotic spots on the leaves, and leaf curling. Again the severity of the symptoms is correlated with the level of invertase. These symptoms do not develop in shaded leaves indicating the need for photosynthesis. Keeping the plants in the dark for a prolonged period (24 hours) results in the disappearance of leaf starch from the control plants, but not from the plants with apoplastic invertase. These results are consistent with the interpretation that apoplastic invertase prevents photosynthate export from source leaves and that phloem loading includes an apoplastic step.

Tobacco Plants Transformed with the Bean alphaai Gene Express an Inhibitor of Insect alpha-Amylase in Their Seeds.

Bean (Phaseolus vulgaris L.) seeds contain a putative plant defense protein that inhibits insect and mammalian but not plant alpha-amylases. We recently (J Moreno, MJ Chrispeels [1989] Proc Natl Acad Sci USA 86:7885-7889) presented strong circumstantial evidence that this alpha-amylase inhibitor (alphaAI) is encoded by an already-identified lectin gene whose product is referred to as lectin-like-protein (LLP). We have now made a chimeric gene consisting of the coding sequence of the lectin gene that encodes LLP and the 5' and 3' flanking sequences of the lectin gene that encodes phytohemagglutinin-L. When this chimeric gene was expressed in transgenic tobacco (Nicotiana tabacum), we observed in the seeds a series of polypeptides (M(r) 10,000-18,000) that cross-react with antibodies to the bean alpha-amylase inhibitor. Most of these polypeptides bind to a pig pancreas alpha-amylase affinity column. An extract of the seeds of the transformed tobacco plants inhibits pig pancreas alpha-amylase activity as well as the alpha-amylase present in the midgut of Tenebrio molitor. We suggest that introduction of this lectin gene (to be called alphaai) into other leguminous plants may be a strategy to protect the seeds from the seed-eating larvae of Coleoptera.

Characterization of alpha-Amylase-Inhibitor, a Lectin-Like Protein in the Seeds of Phaseolus vulgaris.

The common bean, Phaseolus vulgaris, contains a glycoprotein that inhibits the activity of mammalian and insect alpha-amylases, but not of plant alpha-amylases. It is therefore classified as an antifeedant or seed defense protein. In P. vulgaris cv Greensleeves, alpha-amylase inhibitor (alphaAl) is present in embryonic axes and cotyledons, but not in other organs of the plant. The protein is synthesized during the same time period that phaseolin and phytohemagglutinin are made and also accumulates in the protein storage vacuoles (protein bodies). Purified alphaAl can be resolved by SDS-PAGE into five bands (M(r) 15,000-19,000), four of which have covalently attached glycans. These bands represent glycoforms of two different polypeptides. All the glycoforms have complex glycans that are resistant to removal by endoglycosidase H, indicating transport of the protein through the Golgi apparatus. The two different polypeptides correspond to the N-terminal and C-terminal halves of a lectin-like protein encoded by an already identified gene or a gene closely related to it (LM Hoffman [1984] J Mol Appl Genet 2: 447-453; J Moreno, MJ Chrispeels [1989] Proc Natl Acad Sci USA 86:7885-7889). The primary translation product of alphaAl is a polypeptide of M(r) 28,000. Immunologically cross-reacting glycopolypeptides of M(r) 30,000 to 35,000 are present in the endoplasmic reticulum, while the smaller polypeptides (M(r) 15,000-19,000) accumulate in protein storage vacuoles (protein bodies). Together these data indicate that alphaAl is a typical bean lectin-type protein that is synthesized on the rough endoplasmlc reticulum, modified in the Golgi, and transported to the protein storage vacuoles.