Sophia Biemelt

Impact of Altered Gibberellin Metabolism on Biomass Accumulation, Lignin Biosynthesis, and Photosynthesis in Transgenic Tobacco Plants

Gibberellins (GAs) are involved in regulation of many aspects during plant development. To investigate the impact of altered GA levels on plant growth and metabolism, transgenic tobacco (Nicotiana tabacum) plants have been engineered to express either a GA20-oxidase (AtGA20-ox) or a GA2-oxidase (AtGA2-ox) gene from Arabidopsis under control of the cauliflower mosaic virus 35S promoter. Resulting plants were characterized by elongated or stunted shoot growth, respectively, indicating changes in the content of bioactive GAs. In accordance with the effect on plant growth, biomass production was increased or decreased in AtGA20-ox or AtGA2-ox plants, respectively, and was found to be positively correlated with the rate of photosynthesis as determined at the whole plant level. Differences in dry matter accumulation were most likely due to changes in lignin deposition as indicated by histochemical staining and quantitative measurements. Altered lignification of transgenic plants was paralleled by up- or down-regulation of the expression of lignin biosynthetic genes. Short-term GA3 feeding of excised petioles induced lignin formation in the absence of a transcriptional activation of pathway-specific genes. Thus, short-term GA treatment mediates lignin deposition most likely by polymerization of preformed monomers, whereas long-term effects on lignification involve elevated production of precursors by transcriptional stimulation of the biosynthetic pathway. Interestingly, analysis of stem cross sections revealed a differential effect of GA on the formation of xylem and pith cells. The number of lignified vessels was increased in AtGA20-ox plants pointing to a stimulation of xylem formation while the number of pith cells declined indicating a negative regulation.

Production of Human Papillomavirus Type 16 Virus-Like Particles in Transgenic Plants

ABSTRACT Cervical cancer is linked to infection with human papillomaviruses (HPV) and is the third most common cancer among women worldwide. There is a strong demand for the development of an HPV preventive vaccine. Transgenic plants expressing the HPV major capsid protein L1 could be a system to produce virus-like particles for prophylactic vaccination or could even be used as edible vaccines to induce an L1-specific prophylactic immune response. Here, we describe the generation of transgenic tobacco and potato plants carrying the HPV type 16 major structural gene L1 under the control of the cauliflower mosaic virus 35S promoter. All attempts to express either the original, unmodified L1 gene or an L1 gene with a codon usage optimized for expression in plants failed. Surprisingly, small amounts of the protein were detected using an L1 gene optimized for expression in human cells. However, Northern blot analysis revealed that most of the L1 transcripts were degraded. Introduction of the translational enhancer Ω derived from the tobacco mosaic virus strongly increased transcript stability and resulted in accumulation of L1 protein to approximately 0.5 to 0.2% of total soluble protein in transgenic tobacco and potato plants, respectively. The plant-derived L1 protein displayed conformation-specific epitopes and assembled into virus-like particles. Furthermore, we did not find any indications of protein modification of the L1 protein produced in plants. Plant-derived L1 was as immunogenic as L1 expressed in baculovirus-infected insect cells. Feeding of tubers from transgenic potatoes to mice induced an anti-L1 antibody response in 3 out of 24 mice, although this response was only transient in two of the mice. Our data, however, indicate that an anti-L1 response was primed in about half of the 24 animals.

Comparative analysis of abscisic acid content and starch degradation during storage of tubers harvested from different potato varieties

SummarySeveral lines of evidence suggest a prominent role of abscisic acid in controlling the length of the dormancy period of potato tubers. The ABA content was measured in tubers of six different potato varieties during storage. Consistent with previous publications a continuous decline in ABA content during storage was evident. However, this decline of ABA did not correlate with the sprouting behaviour of the tubers, ruling out that ABA is responsible for the break of dormancy. Activities of starch degrading and glycolytic enzymes were determined to investigate whether changes in their activities would correlate with the break of dormancy. Most of the enzymes investigated did not change significantly during storage. After the onset of sprouting activity of beta-amylase increased two-fold and alpha-amylase activity was stimulated by approximately 30%. The increase in beta-amylase activity was due to transcriptional activation, as shown by northern analysis. Since no change of starch degrading enzymes could be detected prior visible sprout growth, starch degradation is not a prerequisite for the initiation of sprouting.

Sucrose synthase activity does not restrict glycolysis in roots of transgenic potato plants under hypoxic conditions

Abstract. The effect of hypoxia on root development and carbon metabolism was studied using potato (Solanum tuberosum L.) plants as a model system. Hypoxia led to a cessation of root elongation, and finally to the death of meristematic cells. These changes were accompanied by a 4- to 5-fold accumulation of hexoses, suggesting that insufficient carbohydrate supply was not the cause of cell death. In addition, prolonged hypoxia (96 h) resulted in a 50% increase in activity of most glycolytic enzymes studied and the accumulation of glycerate-3-phosphate and phosphoenolpyruvate. This indicates that endproduct utilisation may restrict metabolic flux through glycolysis. As expected, the activities of alcohol dehydrogenase (EC 1.1.1.1) and pyruvate decarboxylase (EC 4.1.1.17) increased during hypoxia. Apart from the enzymes of ethanolic fermentation the activity of sucrose synthase (SuSy; EC 2.4.1.13) was enhanced. To investigate the in-vivo significance of this increase, transgenic plants with reduced SuSy activity were analysed. Compared to untransformed controls, transgenic plants showed a reduced ability to resume growth after re-aeration, emphasising the crucial role of SuSy in the toleration of hypoxia. Surprisingly, analysis of glycolytic intermediates in root extracts from SuSy antisense plants revealed no change as compared to wildtype plants. Therefore, limitation of glycolysis is most likely not responsible for the observed decreased ability for recovery after prolonged oxygen starvation. We assume that the function of SuSy during hypoxia might be to channel excess carbohydrates into cell wall polymers for later consumption rather than fuelling glycolysis.

Characterisation of the ATP-dependent phosphofructokinase gene family from Arabidopsis thaliana

Plants possess two different types of phosphofructokinases, an ATP‐dependent (PFK) and a pyrophosphate‐dependent form (PFP). While plant PFPs have been investigated in detail, cDNA clones coding for PFK have not been identified in Arabidopsis thaliana. Searching the A. thaliana genome revealed 11 putative members of a phosphofructokinase gene family. Among those, four sequences showed high homology to the alpha‐ or beta‐subunits of plant PFPs. Seven cDNAs resulted in elevated PFK, but not PFP activity after transient expression in tobacco leaves suggesting that they encode Arabidopsis PFKs. RT‐PCR revealed different tissue‐specific expression of the individual forms. Furthermore, analysis of GFP fusion proteins indicated their presence in different sub‐cellular compartments.