Cutinsomes and cuticle enzymes GPAT6 and DGAT2 seem to travel together from a lipotubuloid metabolon (LM) to extracellular matrix of O. umbellatum ovary epidermis.

In the ovary epidermis of O. umbellatum there are lipotubuloid metabolons (LMs), in which synthesis of lipids takes place. This process partly provides nourishment, and partly cuticle building blocks, transformed, among others, with the participation of cutinsomes. The cutinsomes are cutin-building structures, 40-200nm in size, which are formed as a result of self-assembly and self-esterification of hydroxy fatty acids. The cutinsomes, by binding to the cuticle, introduce into it nonlinear, amorphous and cross-linked polymers. Double-immunogold EM observations revealed that enzymes producing elements of cutin (GPAT6) and waxes (WS/DGAT) were found not only as free cytoplasmic molecules but also in many cases they were bound to carboxylate-carboxylic shell of cuntinsomes. Hence, we suppose that these enzymes can move alone or together with the cutinsomes through cytoplasm (pH 6.8-7.0), plasmalemma and the polysaccharide layer of a cell wall to the site of their functioning i.e. to the cuticle (pH 5.0).

[Physiological and biochemical change of Paris seed in after-ripening during variable temperature stratification].

In order to explore the dormancy physiological and biochemical mechanism of Paris seeds, the seed embryo growth courses, and the dynamic change of 5 enzymes, include SOD, POD, CAT, MDH, G-6-PDH were measured during variable temperature stratification. The results indicated that Paris seeds embryo grew quickly after 40 d in warm-stratification (18 ± 1) °C, at the meantime the metabolic activity was significantly strengthened. These facts showed that Paris seeds turned into physiological after-ripening process. After 60-80 d, the morphological embryo after-ripping process basically completed, and the following cold-stratification (4 ± 1) °C furthered Paris seed to finish physiological after-ripening. After 40 d, the activity of MDH decreased while G-6-PDH increased significantly. This showed that the main respiratory pathway of seed changed from TCA to PPP, which benifited breaking seed dormancy. In the whole period of stratification process, the activity variation of SOD and CAT was insignificantly and the activity of POD was enhanced significantly after shifting the seed in cold stratification process. This showed that SOD, CAT had no direct effects on breaking Paris seed dormancy but keeping the seed vigor, while the POD might involve in the process of Paris seed dormancy breaking.

Metabolic fate of cardiac glycosides and flavonoids upon fermentation of aqueous sea squill (Drimia maritima L.) extracts.

Sea squill (Drimia maritima L.) extracts have been used for centuries for the medical treatment of heart diseases. A procedure for the preparation of Drimia extracts applied for such purposes comprising a fermentation step is described in the German Homoeopathic Pharmacopoeia (GHP). However, little is known about the secondary metabolite profile of such extracts and the fate of these components upon processing and storage. Thus, in the present study sea squill extracts were monitored during fermentation and storage by HPLC-DAD-MS(n) and GC-MS to characterise and quantitate individual cardiac glycosides and phenolic compounds. For this purpose, a previously established HPLC method for the separation and quantitation of pharmacologically relevant cardiac glycosides (bufadienolides) was validated. Within 12 months of storage, total bufadienolide contents decreased by about 50%, which was attributed to microbial and plant enzyme activities. The metabolisation and degradation rates of individual bufadienolide glycosides significantly differed, which was attributed to differing structures of the aglycones. Further degradation of bufadienolide aglycones was also observed. Besides reactions well known from human metabolism studies, dehydration of individual compounds was monitored. Quantitatively predominating flavonoids were also metabolised throughout the fermentation process. The present study provides valuable information about the profile and stability of individual cardiac glycosides and phenolic compounds in fermented Drimia extracts prepared for medical applications, and expands the knowledge of cardiac glycoside conversion upon microbial fermentation.

Cloning and characterization of 3-hydroxy-3-methylglutaryl-CoA reductase (HMGR) gene from Paris fargesii Franch.

3-Hydroxy-3-methylglutaryl-coenzyme A reductase (HMGR) plays an important role in catalyzing the first committed step of isoprenoids biosynthesis in mevalonic acid (MVA) pathway. Here, we cloned a full-length transcript of Paris fargesii Franch. The full-length cDNA of P. fargesii HMGR (Pf-HMGR, GenBank accession no. JX508638) was 1,973 bp and contained a 1,728 bp ORF encoding 576 amino acids. Sequence analysis revealed that the deduced Pf-HMGR had high similarity with HMGRs from other plants, including Ricinus communis (77%), Litchi chinensis (76%), Michelia chapensis (75%) and Panax quinquefolius (72%). It had a calculated molecular mass of about 62.13 kDa and an isoelectric point (pI) of 8.47. It contained two transmembrane domains, two putative HMGR binding sites and two NADP(H)-binding sites. The predicted 3-D structure revealed that Pf-HMGR had a similar spatial structure with other plant HMGRs. Three catalytic regions, including L-domain, N-domain and S-domain were detected by structural modeling of HMGR. Tissue expression analysis revealed that Pf-HMGR was strongly expressed in roots and stems than in leaves. Taken together, our data laid a foundation for further investigation of HMGR's functions and regulatory mechanisms in plants.

Molecular cloning and characterization of a novel adenylyl cyclase gene, HpAC1, involved in stress signaling in Hippeastrum x hybridum.

Adenylyl cyclases (ACs) are enzymes that generate cyclic AMP, which is involved in different physiological and developmental processes in a number of organisms. Here, we report the cloning and characterization of a new plant adenylyl cyclases (AC) gene, designated HpAC1, from Hippeastrum x hybridum. This gene encodes a protein of 206 amino acids with a calculated molecular mass of 23 kD and an isoelectric point of 5.07. The predicted amino acid sequence contains all the typical features of and shows high identity with putative plant ACs. The purified, recombinant HpAC1 is able to convert ATP to cAMP. The complementation test that was performed to analyze the ability of HpAC1 to compensate for the AC deficiency in the Escherichia coli SP850 strain revealed that HpAC1 functions as an adenylyl cyclase and produces cyclic AMP. Moreover, it was shown that the transcript level of HpAC1 and cyclic AMP concentration changed during certain stress conditions. Both mechanical damage and Phoma narcissi infection lead to two sharp increases in HpAC1 mRNA levels during a 72-h test cycle. Changes in intracellular cAMP level were also observed. These results may indicate the participation of a cAMP-dependent pathway both in rapid and systemic reactions induced after disruption of symplast and apoplast continuity.

[Molecular cloning of squalene synthase gene form Paris polyphylla and its expression in Escherichia coli].

OBJECTIVE: To clone the cDNA sequence of squalene synthase gene from Paris polyphylla, and characterize the biological features of the obtained SQS. METHOD: Using homology cloning and RACE technique, a full-length cDNA sequence of PpSQS gene was isolated from P. polyphylla. The obtained sequence was analyzed by bioinformatics softwares. A plasmid [named pET-30b (+)-PpSQS] was constructed for prokaryotic expression the recombinant PpSQS. RESULT: The full-length cDNA of PpSQS gene is 1 498 bp, which contains a 1 212 bp ORF. Sequence analysis indicated that PpSQS encoded 403 amino acids residues with a calculated molecular weight (MW) of 46.36 kDa and an isoelectric point (pI) of 6.83. SDS-PAGE results showed that the recombinant PpSQS was expressed in Escherichia coli BL21 (DE3) by inducing with 1 mmol x L(-1) IPTG. CONCLUSION: The full-length cDNA sequence of PpSQS gene was obtained from P. polyphylla, and its molecular features were consisted with classic SQS in plant. The recombinant PpSQS was successfully expressed in E. coli.

Dissecting the stress metabolic alterations in in vitro Cyrtanthus regenerants.

Metabolic plasticity in plants allows for continuous adjustments of defence strategies in suboptimal environments. Proline and other metabolites figure prominently in most stress-mediated responses. This study examined the expression of salinity and osmotic adjustments in the enzymatic activity and accumulation of solutes and metabolites in response to imposed water and salt stress in Cyrtanthus contractus N.E. Br. and Cyrtanthus guthrieae L. Bolus regenerants. In vitro-derived plantlets were cultured on solid Murashige and Skoog (MS) media with three different polyethylene glycol (PEG)-induced osmotic levels and four NaCl stress-induced levels at 25 °C. The levels of proline and phenolic compounds measured at intervals of three, four and five weeks from initial plantlet culture increased in a stress-dependent pattern. The levels of these metabolites also showed a significant increase with an increase in the duration of plantlets under stress conditions. The highest proline concentration (9.98 µmol g(-1) FW) was recorded in C. contractus at 300 µM NaCl after five weeks. A corresponding high level of total phenolic compounds (147 mg GAE g(-1) DW) was also recorded in the same treatment for the same species. The activity of proline dehydrogenase (PDH) (EC 1.5.99.8) was shown to decrease with an increase in proline levels from week three to week five in almost all the stress conditions. The high levels, particularly of phenolic compounds obtained under osmotic and salinity stress conditions in this study present a promising potential of manipulating culture and/or growing conditions for improved secondary compound production and hence medicinal benefits.

Characterization of Squalene synthase gene from Chlorophytum borivilianum (Sant. and Fernand.).

Saponins are important group of secondary metabolites known for their pharmacological properties. Chlorophytum borivilianum contains high amount of saponins and is thus, recognized as an important medicinal plant with aphrodisiac properties. Though the plant is well known for its pharmaceutical properties, there is meager information available about the genes and enzymes responsible for biosynthesis of saponins from this plant. Squalene synthase (SqS) is the key enzyme of saponin biosynthesis pathway and here, we report cloning and characterization of SqS gene from C. borivilianum. A full-length CbSqS cDNA consisting of 1,760 bp was cloned which contained an open reading frame (ORF) of 1,233 bp, encoding a protein of 411 amino acids. Analysis of deduced amino acid sequence of CbSqS predicted the presence of conserved isoprenoid family domain and catalytic sites. Phylogenetic analysis revealed that CbSqS is closer to Glycine max and monocotyledonous plants. 3D structure prediction using various programs showed CbSqS structure to be similar to SqS from other species. C-terminus truncated recombinant squalene synthase (TruncCbSqS) was expressed in E. coli M15 cells with optimum expression induced with 1 mM IPTG at 37 °C. The gene expression level was analyzed through semi-quantitative RT-PCR and was found to be higher in leaves as compared to the roots.

Alkaloids from Chlidanthus fragrans and their acetylcholinesterase, butyrylcholinesterase and prolyl oligopeptidase activities.

Eleven Amaryllidaceae alkaloids (1-11) were isolated from fresh bulbs of Chlidanthus fragrans Herb. The chemical structures were elucidated by MS, and 1D and 2D NMR spectroscopic experiments. Complete NMR assignments were achieved for deoxypretazzetine (1). All compounds were evaluated for their erythrocytic acetylcholinesterase and serum butyrylcholinesterase inhibition activity using Ellman's method. In the prolyl oligopeptidase assay, Z-Gly-Pro-p-nitroanilide was used as substrate. In biological assays, only the crinine type Amaryllidaceae alkaloid undulatine showed promising acetylcholinesterase and prolyl oligopeptidase inhibition activity with IC50 values of 23.0 +/- 1.0 microM and 1.96 +/- 0.12 mM, respectively. Other isolated compounds were considered inactive.

Isolation of an acyl-glucose-dependent anthocyanin 7-O-glucosyltransferase from the monocot Agapanthus africanus.

A cDNA encoding an acyl-glucose-dependent anthocyanin 7-O-glucosyltransferase (AaAA7GT) was isolated from Agapanthus africanus petals; this is the first AAGT identified in a monocot. Peak expression of AaAA7GT in developing A. africanus petals occurred before the flowering stage, and was later than found previously for other anthocyanin biosynthetic genes. Analysis of recombinant proteins showed AaAA7GT had strict substrate preference for anthocyanidin 3-O-glycosides. The AaAA7GT amino acid had high sequence similarity to glycoside hydrolase family 1 (GH1) proteins, which typically act as ß-glycosidases. A phylogenetic analysis of amino acid sequences suggested that AAGTs were derived from glycosidase early in the angiosperm lineage.