Genetic transformation of green bean callus via Agrobacterium mediated DNA transfer

Summary Kanamycin resistant callus was produced from leaf disc or hypocotyl expiants of green bean (Phaseolus vulgaris L.) when cultured on a defined medium containing 50 mg/l kanamycin after 4 days of co-cultivation with Agrobacterium tumefaciens strain EHA101 containing the binary vector pKYLX71GUS. The presence of neomycin phosphotransferase II (NPT-II) in crude cellular extracts from the kanamycin resistant callus was confirmed by ELISA. The expression of the ß-glucuronidase (GUS) reporter gene was confirmed by histochemical and fluorimetric analyses. Southern blot border analysis confirmed the integration of the foreign DNA. In addition to the evidence obtained from Southern analysis, the absence of Agrobacterium in the transformed callus cultures was confirmed by microscopic observation and through test cultures. Using the above protocol, bean callus cultures were also transformed with a bean chalcone synthase promoter-GUS fusion. These cultures, when treated with the elicitor glutathione, showed higher levels of GUS expression than the unelicited callus clumps.     

Transformation of antisense constructs of the chalcone synthase gene superfamily into Gerbera hybrida: differential effect on the expression of family members

Suppression of gene expression using antisense technology has been successful in various applications. In this paper we report differential inhibition of gene expression of the chalcone synthase (chs) gene superfamily members in transgenic Gerbera hybrida (Asteraceae) plants. We have transformed two different cDNAs of the chs gene family, gchs 1 [4] and gchs2, in antisense orientation under control of the CaMV 35S promoter into gerbera. Gchs1 codes for an enzyme with chalcone synthase activity while gchs2 is a more diverged member of the gene family having distinct structure and expression pattern. Furthermore, gchs2 is evidently not involved in anthocyanin synthesis and encodes an enzyme with novel catalytic properties. In both cases effective blocking of the resident sense gene expression was detected. In addition, the transformation affected differentially the expression of other members of the chs gene family. The degree of inhibition appeared to depend on the sequence homology between the antisense and the target genes. In the unevenly coloured inflorescences detected among anti-gchs1 transformants during their growth, relaxation of the antisense effect was here shown to start from the most distant member of the gene family, further demonstrating the influence of sequence homology in the stability of antisense inhibition.     

Inhibition of flower pigmentation by antisense CHS genes: promoter and minimal sequence requirements for the antisense effect

Introduction of a constitutive antisense full-length chalcone synthase (CHS) cDNA gene in petunia can result in an inhibition of flower pigmentation. We have evaluated some of the factors which may be important for the effectiveness of an antisense CHS gene.Antisense CHS genes encoding half-length or quarter-length RNA complementary to the 3 half of CHS mRNA are able to affect flower pigmentation, while a gene encoding RNA complementary to the 5 half of CHS mRNA did not show phenotypic effects in transgenic petunia plants. We demonstrate that the RNA encoded by the latter gene has a much lower average steady-state level in leaf tissue than the RNAs encoded by the other antisense gene constructs. We have compared the CaMV 35S and endogenous CHS promoter strengths and intrinsic stabilities of sense and antisense CHS RNAs. From the data we conclude that the constitutive antisense CHS genes are not likely to provide an excess of antisense RNA compared to the CHS mRNA derived from the endogenous genes.Effective inhibition of flower pigmentation is also observed when the antisense CHS gene is under control of the homologous CHS promoter. The results indicate that the mechanism of antisense inhibition cannot solely operate via RNA duplex formation between sense and antisense RNA.     

Distribution of the chalcone,isosalipurposide, in the onagraceae

Isosalipurposide was present in 13 species and absent from 27 other species of the Onagraceae.     

Enlarging the family of ferrocenylphosphine dinuclear rhodium complexes: synthesis and X-ray structure of a novel “A-frame”-type trimetallic Rh/Fe/Rh complex

The symmetrically substituted ligand 1,1^′-bis[di(5-methyl-2-furyl)phosphino]ferrocene (1) has been obtained from the bromophosphine BrP(Fu^Me)₂ and the dilithioferrocene/TMEDA adduct. The quantitative addition of this ferrocene derivative to the tetracarbonyl dimer [(CO)₄Rh₂{μ-(S^tBu)₂}] leads, through decarbonylation, to the dinuclear rhodium complex [(CO)₂Rh₂{μ-(S^tBu)₂}{μ-P,P-Fc[P(Fu^Me)₂]₂}] (2) in high yield. A X-ray structure [orthorhombic, space group P2₁2₁2₁; a=11.2982(2) Å, b=13.3165(3) Å, c=27.2687(7) Å] and the solution multinuclear NMR characterization are reported, which show that the rare “quasi-closed bridging” A-frame structure of the complex is rather similar to the one reported for [(CO)₂Rh₂{μ-(S^tBu)₂}{μ-P,P-dppf}] in solid state. However, in solution the furyl-containing ferrocenylphosphine complex presents a greater fluxionality, together with an electronic environment at phosphorus very different from the dppf analogue (δ_P=−10 and 27 ppm, respectively).     

Starter substrate specificities of wild-type and mutant polyketide synthases from Rutaceae

Chalcone synthases (CHSs) and acridone synthases (ACSs) belong to the superfamily of type III polyketide synthases (PKSs) and condense the starter substrate 4-coumaroyl-CoA or N-methylanthraniloyl-CoA with three malonyl-CoAs to produce flavonoids and acridone alkaloids, respectively. ACSs which have been cloned exclusively from Ruta graveolens share about 75-85% polypeptide sequence homology with CHSs from other plant families, while 90% similarity was observed with CHSs from Rutaceae, i.e., R. graveolens, Citrus sinensis and Dictamnus albus. CHSs cloned from many plants do not accept N-methylanthraniloyl-CoA as a starter substrate, whereas ACSs were shown to possess some side activity with 4-coumaroyl-CoA. The transformation of an ACS to a functional CHS with 10% residual ACS activity was accomplished previously by substitution of three amino acids through the corresponding residues from Ruta-CHS1 (Ser132Thr, Ala133Ser and Val265Phe). Therefore, the reverse triple mutation of Ruta-CHS1 (mutant R2) was generated, which affected only insignificantly the CHS activity and did not confer ACS activity. However, competitive inhibition of CHS activity by N-methylanthraniloyl-CoA was observed for the mutant in contrast to wild-type CHSs. Homology modeling of ACS2 with docking of 1,3-dihydroxy-N-methylacridone suggested that the starter substrates for CHS or ACS reaction are placed in different topographies in the active site pocket. Additional site specific substitutions (Asp205Pro/Thr206Asp/His207Ala or Arg60Thr and Val100Ala/Gly218Ala, respectively) diminished the CHS activity to 75-50% of the wild-type CHS1 without promoting ACS activity. The results suggest that conformational changes in the periphery beyond the active site cavity volumes determine the product formation by ACSs vs. CHSs in R. graveolens. It is likely that ACS has evolved from CHS, but the sole enlargement of the active site pocket as in CHS1 mutant R2 is insufficient to explain this process.     

Biosynthesis of the hyperforin skeleton in Hypericum calycinum cell cultures

Hyperforin is an important antidepressant constituent of Hypericum perforatum (St. John's wort). Cell cultures of the related species H. calycinum were found to contain the homologue adhyperforin and to a low extent hyperforin, when grown in BDS medium in the dark. Adhyperforin formation paralleled cell culture growth. Cell-free extracts from the cell cultures contained isobutyrophenone synthase activity catalyzing the condensation of isobutyryl-CoA with three molecules of malonyl-CoA to give phlorisobutyrophenone, i.e. the hyperforin skeleton. The formation of the hyperforins during cell culture growth was preceded by an increase in isobutyrophenone synthase activity. The cell cultures also contained benzophenone synthase and chalcone synthase activities which are involved in xanthone and flavonoid biosyntheses, respectively. The three type III polyketide synthases were separated by anion exchange chromatography.     

Sulfonamide chalcone as a new class of alpha-glucosidase inhibitors

Chalcones 1-20, a new class of glycosidase inhibitors, were synthesized, and their glycosidase inhibitory activities were investigated. Non-aminochalcones 1-12 had no inhibitory activity, however, aminochalcones 13-20 had strong glycosidase (alpha-glucosidase, alpha-amylase, and beta-amylase) inhibitory activities. In particular, sulfonamide chalcones 17-20 had more potent alpha-glucosidase inhibitory activity than aminated chalcone 13-16. 4'-(p-Toluenesulfonamide)-3,4-dihydroxy chalcone 20 (IC(50)=0.4microM) was the best inhibitor against alpha-glucosidase, and these sulfonamide chalcones showed non-competitive inhibition.     

Synthesis and investigations into the anticancer and antibacterial activity studies of β-carboline chalcones and their bromide salts

A series of sixteen β-carbolines, bearing chalcone moiety at C-1 position, were prepared from easily accessible 1-acetyl-β-carboline and various aldehydes under basic conditions followed by N²-alkylation using different alkyl bromides. The prepared compounds were evaluated for in vitro cytotoxicity against a panel of human tumor cell lines. N²-Alkylated-β-carboline chalcones 13a-i represented the interesting anticancer activities compared to N²-unsubstituted β-carboline chalcones 12a-g. Off the prepared β-carbolines, 13g exhibited broad spectrum of activity with IC₅₀ values lower than 22.5?µM against all the tested cancer cell lines. Further, the N²-alkylated-β-carboline chalcone 13g markedly induced cell death in MDA-MB-231 cells by AO/EB staining assay. The most cytotoxic compound 13g possessed a relatively high drug score of 0.48. Additionally, the prepared β-carboline chalcones displayed moderate antibacterial activities against tested bacterial strains.