Mass spectra were acquired by a Finnigan™ LCQ™ DECA ion trap inst

Mass spectra were acquired by a Finnigan™ LCQ™ DECA ion trap instrument. An ionization device was used for sample analyses (sheath gas: 80 mL min−1, auxiliary gas: 20 mL min−1, spray voltage: 5 kV, capillary temperature: 300 °C, capillary voltage: 46 kV, and tube lens: −60 kV). The Xcalibur 2.0

SR2 software (copyright Thermo Electron Corporation 1998–2006) was used. Morphological and cultural studies of the most productive isolate containing the ts gene, SBU-16, including conidial morphology, the mechanism learn more of conidia production, and growth characteristics on PDA, potato-carrot agar (PCA), and on the firm base of an alfalfa stem were carried out according to Simmons (2001). The isolate of SBU-16 was grown on the media in a culture chamber under www.selleckchem.com/products/gsk1120212-jtp-74057.html a 10-h photoperiod provided by 56 W cool-white fluorescent lamps (Philips Master, Holand) at 22 °C. Anamorph and telomorph populations were examined at 4–5 days and 2–6 weeks, respectively. The size and morphology of 100 mature conidia and 50 conidiophores

in lactic acid were recorded by light microscopy at 100× magnification and photographed. A total of 25 isolates separated from the inner bark of T. baccata were screened for the presence of the ts gene. Based on the conserved region of the ts gene, the specific primers were designed and synthesised for the amplification of the core DNA fragment of ts from 25 isolated endophytic fungi. Following PCR amplification, a 334-bp product was obtained. Of 25 isolates, 4 (SBU-16, SBU-17, SBU-69 and SBU-71) showed PCR positive for the conserved sequence of the ts gene (Fig. 1). Taxol and 10-DAB III were extracted from culture filtrates and mycelia of the four ts PCR positive fungi and then analyzed Branched chain aminotransferase by HPLC-DAD. Under the same analysis conditions, the samples containing chemical reference substances of 10-DAB III and taxol were also compared with fungal extracts (Fig. 2). Further convincing evidence for the identity of 10-DAB III and taxol was obtained by high-performance

liquid chromatography-mass spectrometry (LC-MS). Characteristically, standard 10-DAB III and taxol yielded both an [M + H]+ peak at a molecular weight of 854 and an [M + Na]+ peak at a molecular weight of 876, respectively (see Fig. 3a and b). By comparison, fungal taxol also produced peaks, [M + H]+ at m/z 854 and [M + Na]+ at m/z 876. The peaks corresponding to taxol exhibited mass-to-charge (m/z) ratios corresponding to the molecular ions (M + H)+ of standard taxol (at 854), confirming the presence of taxol in the fungal extracts. It was evident that taxol was much more complex because its molecular weight (from high-resolution mass spectrometry) was 854, which corresponds to a molecular formula of C47H51NO14 as reported earlier (McClure & Schram, 1992). The results of the quantification analysis among the four ts PCR positive isolates showed that SBU-16, which was isolated for the first time in our laboratory, produces taxol (6.9 ± 0.2 μg L−1) and its intermediate compound, 10-DAB III (2.

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