An allelic series of the novel argonaute mutant (ago1-1 to ago1-6) of the herbaceous plant Arabidopsis thaliana has been isolated. The ago1 mutation pleotropically affects general plant architecture. The apical shoot meristem generates rosette leaves and a single stem, but axillary meristems rarely develop. Rosette leaves lack a leaf blade but still show adaxial/abaxial differentiation. Instead of cauline leaves, filamentous structures without adaxial/abaxial differentiation develop along the stem and an abnormal inflorescence bearing infertile flowers with filamentous organs is produced. Two independent T-DNA insertions into the AGO1 locus led to the isolation of two corresponding genomic sequences as well as a complete cDNA. The AGO1 locus was mapped close to the marker mi291a on chromosome 1. Antisense expression of the cDNA resulted in a partial mutant phenotype. Sense expression caused some transgenic lines to develop goblet-like leaves and petals. The cDNA encodes a putative 115 kDa protein with sequence similarity to translation products of a novel gene family present in nematodes as well as humans. No specific function has been assigned to these genes. Similar proteins are not encoded by the genomes of yeast or bacteria, suggesting that AGO1 belongs to a novel class of genes with a function specific to multicellular organisms.
Transgenic Arabidopsis thaliana (L.) Heynh. plants expressing the three enzymes encoding the biosynthetic route to polyhydroxybutyrate (PHB) are described. These plants accumulated more than 4% of their fresh weight (approximately 40% of their dry weight) in the form of PHB in leaf chloroplasts. These very high producers were obtained and identified following a novel strategy consisting of a rapid GC-MS analysis of a large number of transgenic Arabidopsis plants generated using a triple construct, thus allowing the parallel transfer of all three genes necessary for PHB synthesis in a single transformation event. The level of PHB produced was 4-fold greater than previously published values, thus demonstrating the large potential of plants to produce this renewable resource. However, the high levels of the polymer produced had severe effects on both plant development and metabolism. Stunted growth and a loss of fertility were observed in the high-producing lines. Analysis of the metabolite composition of these lines using a GC-MS method that we have newly developed showed that the accumulation of high levels of PHB was not accompanied by an appreciable change in either the composition or the amount of fatty acids. Substantial changes were, however, observed in the levels of various organic acids, amino acids, sugars and sugar alcohols.
Polyhydroxybutyrate (PHB) is a member of a class of thermoelastic polymers called polyhydroxyalkanoates that serve many bacteria as intracellular storage molecules for carbon and energy. Transgenic plants provide a potential means of producing this polymer cost-effectively. To date, however, few reports of the successful production of this polymer have been published, with the exception of work with transgenic Arabidopsis. Using a variety of chimeric constructs, we have determined that the constitutive, chloroplast-localized expression of one of the genes involved in PHB production-the -ketothiolase (phbA) gene-is detrimental to the efficient production of transgenic PHB. The alternate use of either inducible or somatically activated promoters allowed the construction of transgenic PHB-producing potato (Solanum tuberosum) and tobacco (Nicotiana tabacum) plants, although the amount of PHB formed was still rather low. Taking advantage of an inducible promoter, the maximal amount of PHB produced in transgenic potato was 0.09 mg g Ϫ1 dry weight. In transgenic tobacco using a somatically activated promoter, up to 3.2 mg g Ϫ1 dry weight was accumulated. In Arabidopsis, the formation of high levels of PHB had previously been shown to be accompanied by severe negative effects on growth and development of the plant. Phasins are proteins known from PHB-producing bacteria speculated to serve as protectants against the highly hydrophobic surface of the PHB granules in the bacterial intracellular milieu. Co-expression of the phasin gene in parallel with the PHB synthesis genes, however, did not lead to reduced symptom development.The use of transgenic plants for the production of novel compounds represents one important aspect of plant biotechnology. Whereas multiple examples exist with respect to the production of novel compounds to be used in food and feed, much less work has been done with respect to the use of transgenic plants for production of compounds for non-food purposes. Polyhydroxyalkanoates (PHAs) are polymers that serve many bacteria as intracellular storage molecules for carbon and energy. These molecules occur alone or together with triacylglycerols (Alvarez et al., 2000). The homopolymer poly(3-hydroxybutyrate) (PHB) is the most common type of PHA, although many other PHAs are known (Steinbü chel and Valentin, 1995). Starting from acetylCoA, PHB is synthesized in bacteria by the consecutive action of three genes: -ketothiolase (phbA), acetoacetyl CoA reductase (phbB), and PHB synthase (phbC). Thermoelastic polymers such as PHB have a number of advantages over polymers derived from oil: They are biodegradable, their production is essentially neutral with respect to carbon dioxide balance, and they are biologically renewable and are, therefore, in line with the goal of sustainable development (Steinbü chel and Fü chtenbusch, 1998).The use of recombinant micro-organisms to efficiently produce PHB and PHAs has been described extensively. The main disadvantage of this production route is its high cost (Choi and...
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