A novel O-methyltransferase Cp4MP-OMT catalyses the final step in the biosynthesis of the volatile 1,4-dimethoxybenzene in pumpkin (Cucurbita pepo) flowers.

BACKGROUND: Floral scents play a crucial role in attracting insect pollinators. Among the compounds attractive to pollinators is 1,4-dimethoxybenzene (1,4-DMB). It is a significant contributor to the scent profile of plants from various genera, including economically important Cucurbita species. Despite its importance, the biosynthetic pathway for the formation of 1,4-DMB was not elucidated so far. RESULTS: In this study we showed the catalysis of 1,4-DMB in the presence of 4-methoxyphenol (4-MP) by protein extract from Styrian oil pumpkin (Cucurbita pepo) flowers. Based on this finding, we identified a novel O-methyltransferase gene, Cp4MP-OMT, whose expression is highly upregulated in the volatile-producing tissue of pumpkin flowers when compared to vegetative tissues. OMT activity was verified by purified recombinant Cp4MP-OMT, illustrating its ability to catalyse the methylation of 4-MP to 1,4-DMB in the presence of cofactor SAM (S-(5'-adenosyl)-L-methionine). CONCLUSIONS: Cp4MP-OMT is a novel O-methyltransferase from C. pepo, responsible for the final step in the biosynthesis of the floral scent compound 1,4-DMB. Considering the significance of 1,4-DMB in attracting insects for pollination and in the further course fruit formation, enhanced understanding of its biosynthetic pathways holds great promise for both ecological insights and advancements in plant breeding initiatives.

The effect of translationally controlled tumour protein (TCTP) on programmed cell death in plants.

BACKGROUND: Translationally controlled tumour protein (TCTP), a well known protein of the animal kingdom, was shown to be a Ca(2+)-binding protein with important functions in many different cellular processes (e.g. protection against stress and apoptosis, cell growth, cell cycle progression, and microtubule organization). However, only little is known about TCTP in plants. Transcript and protein levels of plant TCTPs were shown to be altered by various stress conditions (e.g. cold, salt, draught, aluminium, and pathogen infection), and Arabidopsis thaliana TCTP (AtTCTP) was described as an important regulator of growth. The aim of this study was to further characterize plant TCTP relating to one of its major functions in animals: the protection against cell death. RESULTS: We used two different activators of programmed cell death (PCD) in plants: the mammalian pro-apoptotic protein BAX and tunicamycin, an inhibitor of glycosylation and trigger of unfolded protein response (UPR). Over-expression of AtTCTP significantly decreased cell death in tobacco leaf discs in both studies. A (45)Ca overlay assay showed AtTCTP to be a Ca(2+)-binding protein and localization experiments revealed cytosolic distribution of AtTCTP-GFP in Arabidopsis seedlings. CONCLUSIONS: Our study showed cytoprotective effects of plant TCTP for the first time. Furthermore, we showed the ability of AtTCTP to bind to Ca(2+) and its cytosolic distribution within the cell. If these results are combined, two putative modes of action can be assumed: 1) AtTCTP acts as Ca(2+) sequester, preventing PCD by reducing cytosolic Ca(2+) levels as described for animals. 2) AtTCTP could directly or indirectly interact with other cytosolic or membrane-bound proteins of the cell death machinery, thereby inhibiting cell death progression. As no homologous proteins of the anti-apoptotic machinery of animals were found in plants, and functional homologues still remain to be elucidated, future work will provide more insight.

Investigations on N-rich protein (NRP) of Arabidopsis thaliana under different stress conditions.

Stress response and adaptation are important physiological mechanisms in plants. As plants are not able to avoid stressful environments by moving away, as animals, they have developed diverse mechanisms to respond to stressful situations. One of the genes involved in these mechanisms is NRP (Asparagine-rich protein or N-rich protein). In this study, NRP expression, protein localization and nrp knockout plants were investigated for further understanding of NRP function. NaCl-induced salt stress, oxidative stress (ozone exposure) and mechanical perturbation (touch treatment) were used to induce abiotic stress. NRP expression was up-regulated in the early phase of stress response to all three elicitors. Stressed nrp knockout seedlings revealed a more pronounced growth inhibition compared to wildtype (salt and osmotic stress). Seedlings showed NRP-GFP expression in the apical meristem, leaf veins, central cylinder, root hair zone and root tip. Analyses of NRP-GFP localization in root cells and protoplasts revealed cytosolic distribution under non-stress conditions and translocation of NRP-GFP to mitochondria due to stress response. Summarizing, our findings point to a contribution of NRP in signal transduction of the initial phase of general stress response in Arabidopsis thaliana.

Cloning of Glucuronokinase from Arabidopsis thaliana, the last missing enzyme of the myo-inositol oxygenase pathway to nucleotide sugars.

Nucleotide sugars are building blocks for carbohydrate polymers in plant cell walls. They are synthesized from sugar-1-phosphates or epimerized as nucleotide sugars. The main precursor for primary cell walls is UDP-glucuronic acid, which can be synthesized via two independent pathways. One starts with the ring cleavage of myo-inositol into glucuronic acid, which requires a glucuronokinase and a pyrophosphorylase for activation into UDP-glucuronate. Here we report on the purification of glucuronokinase from Lilium pollen. A 40-kDa protein was purified combining six chromatographic steps and peptides were de novo sequenced. This allowed the cloning of the gene from Arabidopsis thaliana and the expression of the recombinant protein in Escherichia coli for biochemical characterization. Glucuronokinase is a novel member of the GHMP-kinase superfamily having an unique substrate specificity for d-glucuronic acid with a K(m) of 0.7 mm. It requires ATP as phosphate donor (K(m) 0.56 mm). In Arabidopsis, the gene is expressed in all plant tissues with a preference for pollen. Genes for glucuronokinase are present in (all) plants, some algae, and a few bacteria as well as in some lower animals.

Nonradioactive enzyme measurement by high-performance liquid chromatography of partially purified sugar-1-kinase (glucuronokinase) from pollen of Lilium longiflorum.

Here we present a highly sensitive and simple high-performance liquid chromatography (HPLC) method that enables specific quantification of glucuronokinase activity in partially purified extracts from pollen of Lilium longiflorum without radioactive labeled substrates. This assay uses a recombinant UDP-sugar pyrophosphorylase with broad substrate specificity from Pisum sativum (PsUSP) or Arabidopsis thaliana (AtUSP) as a coupling enzyme. Glucuronokinase was partially purified on a DEAE-sepharose column. Kinase activity was measured by a nonradioactive coupled enzyme assay in which glucuronic acid-1-phosphate, produced in this reaction, is used by UDP-sugar pyrophosphorylase and further converted to UDP-glucuronic acid. This UDP-sugar, as well as different by-products, is detected by HPLC with either a strong anion exchange column or a reversed phase C18 column at a wavelength of 260 nm. This assay is adaptive to different kinases and sugars because of the broad substrate specificity of USP. The HPLC method is highly sensitive and allows measurement of kinase activity in the range of pmol min(-1). Furthermore, it can be used for determination of pure kinases as well as crude or partially purified enzyme solutions without any interfering background from ATPases or NADH oxidizing enzymes, known to cause trouble in different photometric assays.