Robert van der Heijden

Geraniol 10-hydroxylase1, a cytochrome P450 enzyme involved in terpenoid indole alkaloid biosynthesis

Geraniol 10‐hydroxylase (G10H) is a cytochrome P450 monooxygenase involved in the biosynthesis of iridoid monoterpenoids and several classes of monoterpenoid alkaloids found in a diverse range of plant species. Catharanthus roseus (Madagascar periwinkle) contains monoterpenoid indole alkaloids, several of which are pharmaceutically important. Vinblastine and vincristine, for example, find widespread use as anti‐cancer drugs. G10H is thought to play a key regulatory role in terpenoid indole alkaloid biosynthesis. We purified G10H from C. roseus cells. Using degenerate PCR primers based on amino acid sequence information we cloned the corresponding cDNA. The encoded CYP76B6 protein has G10H activity when expressed in C. roseus and yeast cells. The stress hormone methyljasmonate strongly induced G10h gene expression coordinately with other terpenoid indole alkaloid biosynthesis genes in a C. roseus cell culture.

Effects of over-expression of strictosidine synthase and tryptophan decarboxylase on alkaloid production by cell cultures of Catharanthus roseus

Abstract. Cells of Catharanthus roseus (L.) G. Don were genetically engineered to over-express the enzymes strictosidine synthase (STR; EC 4.3.3.2) and tryptophan decarboxylase (TDC; EC 4.1.1.28), which catalyze key steps in the biosynthesis of terpenoid indole alkaloids (TIAs). The cultures established after Agrobacterium-mediated transformation showed wide phenotypic diversity, reflecting the complexity of the biosynthetic pathway. Cultures transgenic for Str consistently showed tenfold higher STR activity than wild-type cultures, which favored biosynthetic activity through the pathway. Two such lines accumulated over 200 mg · L−1 of the glucoalkaloid strictosidine and/or strictosidine-derived TIAs, including ajmalicine, catharanthine, serpentine, and tabersonine, while maintaining wild-type levels of TDC activity. Alkaloid accumulation by highly productive transgenic lines showed considerable instability and was strongly influenced by culture conditions, such as the hormonal composition of the medium and the availability of precursors. High transgene-encoded TDC activity was not only unnecessary for increased productivity, but also detrimental to the normal growth of the cultures. In contrast, high STR activity was tolerated by the cultures and appeared to be necessary, albeit not sufficient, to sustain high rates of alkaloid biosynthesis. We conclude that constitutive over-expression of Str is highly desirable for increased TIA production. However, given its complexity, limited intervention in the TIA pathway will yield positive results only in the presence of a favorable epigenetic environment.

Cell and tissue cultures of Catharanthus roseus: A literature survey

The literature concerning the regulation and the biosynthesis of secondary metabolites in cell and tissue cultures of Catharanthus roseus is reviewed. The aim of this review is to summarise the progress achieved since the previous review of this subject from 1988 to December 1993. Several factors influencing the production of indole alkaloids are discussed. Special attention is given to large-scale cultivation methods. Some economic considerations on the production of ajmalicine are also discussed.

The iridoid glucoside secologanin is derived from the novel triose phosphate/pyruvate pathway in a Catharanthus roseus cell culture

Secologanin is the iridoid building block of the majority of the terpenoid indole alkaloids. In the biosynthesis of secologanin, mevalonate was considered to be the exclusive precursor of isopentenyl diphosphate. After [1‐13C]glucose feeding to a cell culture of Catharanthus roseus, its incorporation into secologanin was studied by 13C NMR spectroscopy. The data showed that the novel triose phosphate/pyruvate and not the mevalonate pathway was the major route for the biosynthesis of secologanin.

Cell and tissue cultures ofCatharanthus roseus (L.) G. Don: a literature survey

The literature concerning the formation of secondary metabolites in cell and tissue cultures ofCatharanthus roseus has been reviewed. Several aspects involved in the formation of secondary metabolites are discussed; e.g. regulation of secondary metabolism, environmental factors influencing secondary metabolism, biosynthesis and enzymology of the products, analysis of product formation, immobilization of cultured cells and stability of cell lines. Some economical aspects of production processes are discussed.

Biosynthesis of anthraquinones in cell cultures of the Rubiaceae

Plants and their derived cell and tissue cultures in the family Rubiaceae accumulate a number of anthraquinones. There are two main biosynthetic pathways leading to anthraquinones in higher plants: the polyketide pathway and the chorismate/o-succinylbenzoic acid pathway. The latter occurs in the Rubiaceae for the biosynthesis of Rubia type anthraquinones. In this pathway, ring A and B of the Rubia type anthraquinones are derived from shikimic acid, α-ketoglutarate via o-succinylbenzoate, whereas ring C is derived from isopentenyl diphosphate, a universal building block for all isoprenoids. At present, it is known that isopentenyl diphosphate is formed via the mevalonic acid pathway or the 2-C-methyl-D-erythritol 4-phosphate pathway. Recent findings demonstrate that the 2-C-methyl-D-erythritol 4-phosphate pathway, not the mevalonic acid pathway, is involved in the formation of isopentenyl diphosphate, which constitutes ring C of anthraquinones in the Rubiaceae. This review summarizes the latest results of studies on the biosynthetic pathways, the enzymology and regulation of anthraquinone biosynthesis, as well as aspects of the metabolic engineering. Furthermore, biochemical and molecular approaches in functional genomics, which facilitate elucidation of anthraquinone biosynthetic pathways, are briefly described.

Proteomics in plant biotechnology and secondary metabolism research.

Proteomics, the systematic analysis of (differentially) expressed proteins, is a tool for the identification of proteins involved in cellular processes. Proteomics has already been used for many different applications in plant sciences, including the study of proteins of biosynthetic pathways leading to secondary metabolites. In secondary metabolism, many enzymes are involved, often working in close collaboration to catalyse cascades of reactions. Besides the enzymes, transport and regulatory proteins are also involved, which makes the proteome an essential topic for studying metabolic pathways. Proteomics technology is based on high-throughput techniques for the separation and identification of proteins, allowing an integral study of many proteins at the same time. For the separation of protein mixtures the most powerful technique available is two-dimensional polyacrylamide gel electrophoresis: after separation, proteins can be subsequently identified by mass spectrometry (MS). The increasing amount of genome sequence data has to be followed by deciphering the function of the genes and proteins. Studying differential expression by proteomics is a complementary tool for functional analysis. In this review practical aspects and applications of proteomics in plant sciences, with particular emphasis on secondary metabolism, are discussed. Copyright

Effect of precursor feeding on alkaloid accumulation by a tryptophan decarboxylase over-expressing transgenic cell line T22 of Catharanthus roseus.

To obtain more insight into the regulation of terpenoid indole alkaloid (TIA) biosynthesis in Catharanthus roseus (L.) G. Don cell cultures and particularly to identify possible rate limiting steps, a transgenic cell line over-expressing tryptophan decarboxylase (Tdc), and thus having a high level of tryptamine, was fed with various amounts of precursors (tryptophan, tryptamine, loganin and secologanin) in different time schedules and analyzed for TIA production. When these precursors were added to this culture it was found that the optimal time for supplying the precursors was at inoculation of the cells into the production medium. Alkaloid accumulation by line T22 was enhanced by addition of loganin or secologanin; however, the secologanin feeding was less effective. Tryptamine or tryptophan alone had no effect on TIA accumulation. The over-expression of Tdc causes this cell line to produce quite large quantities of alkaloids after feeding loganin or secologanin. However, in combination with tryptophan or tryptamine, feeding of these precursors resulted in an even further increase of alkaloid accumulation and under optimal conditions line T22 accumulated around 1200 micromol l(-1) of TIAs whereas the control cultures accumulated less than 10 micromol l(-1) TIAs.

Sequential solubilization of proteins precipitated with trichloroacetic acid in acetone from cultured Catharanthus roseus cells yields 52% more spots after two‐dimensional electrophoresis

Sample preparation is still the most critical step in two‐dimensional gel electrophoresis (2‐DE), and needs to be optimized for each type of sample. To analyze the proteome of the medicinal plant Catharanthus roseus, we developed and evaluated a sequential solubilization procedure for the solubilization of proteins after precipitation in trichloroacetic acid and acetone. The procedure includes solubilization with a conventional urea buffer followed by a stronger solubilizing buffer containing thiourea. The sequential solubilization of the precipitated proteins results in very different spot patterns following 2‐DE. The number of protein spots which could be detected in both samples of the sequential solubilization was only about 10% of the total number of spots. Compared to solubilization in a single step, the total number of spots that could be detected in the sequential solubilization procedure was increased by 52%. The method described is simple and is applicable to different types of plant tissue.

Assay of strictosidine synthase from plant cell cultures by high-performance liquid chromatography

An HPLC assay is described for the enzyme strictosidine synthase in which the formation of strictosidine and the decrease of tryptamine can be followed at the same time. In cell cultures of Catharanthus roseus significant amounts of strictosidine glucosidase activity were detected. In crude preparations, the strictosidine synthase reaction is therefore best measured by the secologanin-dependent decrease of tryptamine. In this way, the specific synthase activity in a cell free extract was found to be 56 pkat/mg of protein. Inclusion of 100 mM D(+)-gluconic acid-delta-lactone in the incubation mixture inhibited 75% of the glucosidase activity, without inhibiting the synthase activity. The synthase activity was readily separated from the glucosidase activity by gel filtration on Sephadex G-75 or Ultrogel AcA-44. Cell cultures of Tabernaemontana orientalis did not contain measurable amounts of strictosidine glucosidine activity. The specific strictosidine synthase activity was 130-200 pkat/mg of protein during the growth of this cell culture. Strictosidine synthase is stable at -20 degrees C for at least 2 months.