Selective obstruction of the mTORC2 complex by a naturally occurring cholestane saponin (OSW-1) for inhibiting prostate cancer cell growth.

Ornithogalum caudatum Ait (OCA) is a natural product used in Chinese traditional medicine. The cholestane saponin OSW-1 is isolated from plant OCA and has recently been shown to have potent cytotoxic effects against different types of cancers. The therapeutic efficacy of OSW-1 on prostate cancer and its underlying mechanism are yet to be established. OSW-1 inhibited the growth of prostate cancer cells by interrupting the interaction between mTOR and Rictor/mTORC2. This mechanism showed a better therapeutic outcome than that of the conventional inhibition of mTOR and provided a basis for as sisting modern prostate cancer treatment strategies.

Glycodiversifying Testosterone with a Promiscuous Glycosyltransferase OsSGT2 from Ornithogalum saundersiae.

The diversity expansion of testosterone17-O-ß-glycosides (TGs) will increase the probability of screening more active molecules from their acetylated derivatives with anticancer activities. Glycosyltransferases (GTs) responsible for the increased diversity of TGs, however, were seldom documented. Herein, a glycosyltransferase OsSGT2 with testosterone glycodiversification capacity was identified from Ornithogalum saundersiae through transcriptome-wide mining. Specifically, OsSGT2 was demonstrated to be reactive with testosterone and eight donors. OsSGT2 displayed both sugar-aglycon and sugar-sugar GT activities. OsSGT2-catalyzed testosterone glycodiversification could be achieved, generating testosterone monoglycosides and disglycosides with varied percentage conversions. Among the eight donors, the conversion of UDP-Glc was the highest, approaching 90%, while the percentage conversions of UDP-GlcNAc, UDP-Gal, helicin, and UDP-Rha were less than 10%. Protein engineering toward F395 was thus performed to improve the conversion of UDP-GlcNAc. Eight variants displayed increased conversions and the mutant F395C got the highest conversion of 72.11 ± 7.82%, eight times more than that of the wild-type. This study provides a promising alternative for diversity expansion of TGs, also significant insights into the molecular basis for the conversion improvement of sugar donors.

Characterization of two flavonol synthases with iron-independent flavanone 3-hydroxylase activity from Ornithogalum caudatum Jacq.

BACKGROUND: Flavonol synthase (FLS) is the key enzyme responsible for the biosynthesis of flavonols, the most abundant flavonoids, which have diverse pharmaceutical effects. Flavonol synthase has been previously found in other species, but not yet in Ornithogalum caudatum. RESULTS: The transcriptome-wide mining and functional characterisation of a flavonol synthase gene family from O. caudatum were reported. Specifically, a small FLS gene family harbouring two members, OcFLS1 and OcFLS2, was isolated from O. caudatum based on transcriptome-wide mining. Phylogenetic analysis suggested that the two proteins showed the closest relationship with FLS proteins. In vitro enzymatic assays indicated OcFLS1 and OcFLS2 were flavonol synthases, catalysing the conversion of dihydroflavonols to flavonols in an iron-dependent fashion. In addition, the two proteins were found to display flavanone 3ß-hydroxylase (F3H) activity, hydroxylating flavanones to form dihydroflavonols. Unlike single F3H enzymes, the F3H activity of OcFLS1 and OcFLS2 did not absolutely require iron. However, the presence of sufficient Fe2+ was demonstrated to be conducive to successive catalysis of flavanones to flavonols. The qRT-PCR analysis demonstrated that both genes were expressed in the leaves, bulbs, and flowers, with particularly high expression in the leaves. Moreover, their expression was regulated by developmental and environmental conditions. CONCLUSIONS: OcFLS1 and OcFLS2 from O. caudatum were demonstrated to be flavonol synthases with iron-independent flavanone 3-hydroxylase activity.

Functional analyses of OcRhS1 and OcUER1 involved in UDP-L-rhamnose biosynthesis in Ornithogalum caudatum.

UDP-L-rhamnose (UDP-Rha) is an important sugar donor for the synthesis of rhamnose-containing compounds in plants. However, only a few enzymes and their encoding genes involved in UDP-Rha biosynthesis are available in plants. Here, two genes encoding rhamnose synthase (RhS) and bi-functional UDP-4-keto-6-deoxy-D-glucose (UDP-4K6DG) 3, 5-epimerase/UDP-4-keto-L-rhamnose (UDP-4KR) 4-keto-reductase (UER) were isolated from Ornithogalum caudatum based on the RNA-Seq data. The OcRhS1 gene has an ORF (open reading frame) of 2019 bp encoding a tri-functional RhS enzyme. In vitro enzymatic assays revealed OcRhS1 can really convert UDP-D-glucose (UDP-Glc) into UDP-Rha via three consecutive reactions. Biochemical evidences indicated that the recombinant OcRhS1 was active in the pH range of 5-11 and over the temperature range of 0-60 °C. The Km value of OcRhS1 for UDP-Glc was determined to be 1.52 × 10-4 M. OcRhS1 is a multi-domain protein with two sets of cofactor-binding motifs. The cofactors dependent properties of OcRhS1 were thus characterized in this research. Moreover, the N-terminal portion of OcRhS1 (OcRhS1-N) was observed to metabolize UDP-Glc to form intermediate UDP-4K6DG. OcUER1 contains an ORF of 906 bp encoding a polypeptide of 301 aa. OcUER1 shared high similarity with the carboxy-terminal domain of OcRhS1 (OcRhS1-C), suggesting its intrinsic ability of converting UDP-4K6DG into UDP-Rha. It was thus reasonably inferred that UDP-Glc could be bio-transformed into UDP-Rha under the collaborating action of OcRhS1-N and OcUER1. The subsequently biochemical assay verified this notion. Importantly, expression profiles of OcRhS1 and OcUER1 revealed their possible involvement in the biosynthesis of rhamnose-containing polysaccharides in O. caudatum.

Expression levels of antimicrobial peptide tachyplesin I in transgenic Ornithogalum lines affect the resistance to Pectobacterium infection.

The genus Ornithogalum includes several ornamental species that suffer substantial losses from bacterial soft rot caused by Pectobacteria. The absence of effective control measures for use against soft rot bacteria led to the initiation of a project in which a small antimicrobial peptide from an Asian horseshoe crab, tachyplesin (tpnI), was introduced into two commercial cultivars: O. dubium and O. thyrsoides. Disease severity and bacterial colonization were examined in transgenic lines expressing this peptide. Disease resistance was evaluated in six lines of each species by measuring bacterial proliferation in the plant tissue. Three transgenic lines of each species were subjected to further analysis in which the expression level of the transgene was evaluated using RT-PCR and qRT-PCR. The development of disease symptoms and bacterial colonization of the plant tissue were also examined using GFP-expressing strain of P. carotovorum subsp. brasiliense Pcb3. Confocal-microscopy imaging revealed significantly reduced quantities of bacterial cells in the transgenic plant lines that had been challenged with the bacterium. The results clearly demonstrate that tpnI expression reduces bacterial proliferation, colonization and disease symptom (reduced by 95-100%) in the transgenic plant tissues. The quantity of tpnI transcripts, as measured by qRT-PCR, was negatively correlated with the protection afforded to the plants, as measured by the reduced severity of disease symptoms in the tissue.

Lipotubuloids in ovary epidermis of Ornithogalum umbellatum act as metabolons: suggestion of the name 'lipotubuloid metabolon'.

A metabolon is a temporary, structural-functional complex formed between sequential metabolic enzymes and cellular elements. Cytoplasmic domains called lipotubuloids are present in Ornithogalum umbellatum ovary epidermis. They consist of numerous lipid bodies entwined with microtubules, polysomes, rough endoplasmic reticulum (RER), and actin filaments connected to microtubules through myosin and kinesin. A few mitochondria, Golgi structures, and microbodies are also observed and also, at later development stages, autolytic vacuoles. Each lipotubuloid is surrounded by a tonoplast as it invaginates into a vacuole. These structures appear in young cells, which grow intensively reaching 30-fold enlargement but do not divide. They also become larger due to an increasing number of lipid bodies formed in the RER by the accumulation of lipids between leaflets of the phospholipid bilayer. When a cell ceases to grow, the lipotubuloids disintegrate into individual structures. Light and electron microscope studies using filming techniques, autoradiography with [(3)H]palmitic acid, immunogold labelling with antibodies against DGAT2, phospholipase D1 and lipase, and double immunogold labelling with antibodies against myosin and kinesin, as well as experiments with propyzamide, a microtubule activity inhibitor, have shown that lipotubuloids are functionally and structurally integrated metabolons [here termed lipotubuloid metabolons (LMs)] occurring temporarily in growing cells. They synthesize lipids in lipid bodies in cooperation with microtubules. Some of these lipids are metabolized and used by the cell as nutrients, and others are transformed into cuticle whose formation is mediated by cutinsomes. The latter were discovered in planta using specific anti-cutinsome antibodies visualized by gold labelling. Moreover, LMs are able to rotate autonomously due to the interaction of microtubules, actin filaments, and motor proteins, which influence microtubules by changing their diameter.

Lipid body biogenesis and the role of microtubules in lipid synthesis in Ornithogalum umbellatum lipotubuloids.

Lipid bodies present in lipotubuloids of Ornithogalum umbellatum ovary epidermis take the form of a lens between leaflets of ER (endoplasmic reticulum) membrane filled with a highly osmiophilic substance. The two enzymes, DGAT1 [DAG (diacylglycerol) acyltransferase 1] and DGAT2 (DAG acyltransferase 2), involved in this process are synthesized on rough ER and localized in the ER near a monolayer surrounding entities like lipid bodies. After reaching the appropriate size, newly formed lipid bodies transform into mature spherical lipid bodies filled with less osmiophilic content. They appear to be surrounded by a half-unit membrane, with numerous microtubules running adjacently in different directions. The ER, no longer continuous with lipid bodies, makes contact with them through microtubules. At this stage, lipid synthesis takes place at the periphery of lipid bodies. This presumption, and a hypothesis that microtubules are involved in lipid synthesis delivering necessary components to lipid bodies, is based on strong arguments: (i) silver grains first appear over microtubules after a short [3H]palmitic acid incubation and before they are observed over lipid bodies; (ii) blockade of [3H]palmitic acid incorporation into lipotubuloids by propyzamide, an inhibitor of microtubule function; and (iii) the presence of gold grains above the microtubules after DGAT1 and DGAT2 reactions, as also near microtubules after an immunogold method that identifies phospholipase D1.

Accumulation of apocarotenoids in mycorrhizal roots of Ornithogalum umbellatum.

Colonization of roots of Ornithogalum umbellatum by the arbuscular mycorrhizal fungus Glomus intraradices induced the accumulation of different types of apocarotenoids. In addition to the mycorrhiza-specific occurrence of cyclohexenone derivatives and the "yellow pigment" described earlier, free mycorradicin and numerous mycorradicin derivatives were detected in a complex apocarotenoid mixture for the first time. From the accumulation pattern of the mycorradicin derivatives their possible integration into the continuously accumulating "yellow pigment" is suggested. Structure analyses of the cyclohexenone derivatives by MS and NMR revealed that they are mono-, di- and branched triglycosides of blumenol C, 13-hydroxyblumenol C, and 13-nor-5-carboxy-blumenol C, some of which contain terminal rhamnose as sugar moiety.

Actin filaments connected with the microtubules of lipotubuloids, cytoplasmic domains rich in lipid bodies and microtubules.

Lipotubuloids, i.e., cytoplasmic domains containing an agglomeration of lipid bodies surrounded by half-unit membrane, entwined and held together by a system of microtubules, have been found in the ovary epidermis of Ornithogalum umbellatum. Ultrastructural studies demonstrated thin filaments in lipotubuloids that are probably actin filaments arranged parallel to microtubules. It is suggested that interaction of actin filaments with the microtubules determines the driving force for the rotary motion characteristic of lipotubuloids, as this movement is sensitive to cytochalasin B.

Nonmuscle caldesmon: its distribution and involvement in various cellular processes. Review article.

Smooth muscle caldesmon is a thin-filament constituent which takes part in the Ca2+-dependent regulation of actomyosin motor activity which converts chemical energy of ATP into force. The molecular anatomy of its counterpart found in a variety of nonmuscle cells is similar. Both contain about 20 nm long terminal domains responsible for functionally important multisite interactions with filamentous actin, tropomyosin, Ca2+/calmodulin, and myosin and differ by a 35 nm long central, alpha-helical fragment which is lacking in nonmuscle caldesmon. The different structural organisation of nonmuscle cells and thus distinct distribution of caldesmon implicates its different physiological functions. Due to direct interaction with globular and filamentous actin as well as with tropomyosin, nonmuscle caldesmon is involved in the assembly, dynamics, or stability of microfilaments, whereas the indirect inhibitory effect on interaction of the microfilaments with myosin causes its participation in the regulation of cell contraction and intracellular motional processes. These functions of nonmuscle caldesmon of vertebrates are controlled by Ca2+/calmodulin (or other Ca2+-binding proteins) or caldesmon phosphorylation catalysed by various protein kinases. Examples of nonmuscle caldesmon involvement in functions of higher and lower eukaryote, animal and plant cells are presented.