Notes on the esterase variation in Swedish Dactylorhiza incarnata s. l. (Orchidaceae)

Swedish material of Dactylorhiza incarnara s. l. shows little variation at commonly investigated allozyme loci. However, interpretable variation was found at one esterase locus. All plants investigated of D. incarnata var. cruenta from southern Sweden (with spotted leaves) were homozygous for allele a at this locus, whereas all plants investigated of D. incarnata var. ochroleuca were fixed for allele b. In D. incarnata var. incarnata , both alleles were found, although the b allele dominated. In northern Swedish material of D. incarnata s. l., only allele b was found, regardless whether the material had spotted leaves (sometimes referred to as var. cruenta ), or had unspotted leaves.
These results indicate that there is restricted gene flow between var. cruenta and the other varieties in southern Sweden, although they often grow in mixed populations. The northern Swedish material with spotted leaves appears not to be related to the southern var. cruenta .     

Metabolism of chiral ionylideneacetic acids on the abscisic acid biosynthetic pathway in Cercospora

A Chiralcel OJ column was used to determine the absolute configuration of naturally occurring alpha-ionylideneacetic acid from Cercospora rosicola and gamma-ionylideneacetic acid from C. cruenta as (R) enantiomers in accordance with their biosynthetic product, (S)-ABA. Both enantiomers of [1, 2-(13)C2]-alpha and gamma-ionylideneacetic acids were prepared and fed to C. rosicola and C. cruenta. Six combinations of feeding experiments comparatively and unequivocally demonstrated stereoselectivity in the biosynthetic conversions, including stepwise hydroxylation at C-1' and 4'. Enzymatic isomerization from the gamma to alpha-intermediate was suggested not to be involved in ABA biosynthesis in C. rosicola.     

Biosynthesis of abscisic acid by the direct pathway via ionylideneethane in a fungus, Cercospora cruenta

We examined the biosynthetic pathway of abscisic acid (ABA) after isopentenyl diphosphate in a fungus, Cercospora cruenta. All oxygen atoms at C-1, -1, -1', and -4' of ABA produced by this fungus were labeled with (18)O from (18)O(2). The fungus did not produce the 9Z-carotenoid possessing gamma-ring that is likely a precursor for the carotenoid pathway, but produced new sesquiterpenoids, 2E,4E-gamma-ionylideneethane and 2Z,4E-gamma-ionylideneethane, along with 2E,4E,6E-allofarnesene. The fungus converted these sesquiterpenoids labeled with (13)C to ABA, and the incorporation ratio of 2Z,4E-gamma-ionylideneethane was higher than that of 2E,4E-gamma-ionylideneethane. From these results, we concluded that C. cruenta biosynthesized ABA by the direct pathway via oxidation of ionylideneethane with molecular oxygen following cyclization of allofarnesene. This direct pathway via ionylideneethane in the fungus is consistent with that in Botrytis cinerea, except for the positions of double bonds in the rings of biosynthetic intermediates, suggesting that the pathway is common among ABA-producing fungi.     

Anthrasesamones from roots of Sesamum indicum

Three anthraquinones, named anthrasesamones A, B and C, were isolated from the roots of Sesamum indicum, and their respective structures were determined to be 1-hydroxy-2-(4-methylpent-3-enyl)anthraquinone, 1,4-dihydroxy-2-(4-methylpent-3-enyl)anthraquinone and 2-chloro-1,4-dihydroxy-3-(4-methylpent-3-enyl)anthraquinone on the basis of spectroscopic evidence. Two known anthraquinones were also isolated for the first time from S. indicum roots and characterized as 2-(4-methylpent-3-enyl)anthraquinone and (E)-2-(4-methylpenta-1,3-dienyl)anthraquinone. Anthrasesamone C is a rare chlorinated anthraquinone in higher plants.     

Identification of 2,3-dihydro-gamma-ionylideneethanol in Cercospora cruenta

During our scrutiny of GC-EI-MS date for C15 alcohols as putative intermediates on the ABA biosynthetic pathway in Cercospora cruenta, a trace amount of 5-[2',2'-dimethyl-6'-methylene-1'-cyclohexyl]-3-methyl-4-penten-1-ol (2,3-dihydro-gamma-ionylideneethanol) was identified. Feeding experiments indicated that this compound was not an intermediate to ABA, but a catabolite that originated from gamma-ionylideneacetaldehyde. The stereochemistry of 2,3-dihydro-gamma-ionylideneethanol was deduced to be (3R,1'S) from a comparison with an authentic specimen prepared via baker's yeast asymmetric reduction.     

蒽醌衍生物结构及其对小麦白粉病菌生物活性的关系研究

蒽醌衍生物是植物产生的一类次生代谢产物,对植物病原真菌具有明显的活性。为明确蒽醌衍生物结构与其生物活性之间的关系,以小麦白粉病菌为研究对象,测定了蒽醌及16种蒽醌衍生物对该病菌的活性。结果表明,蒽醌衍生物对小麦白粉病菌的活性明显大于葸醌的活性;甲氧基的位置与活性关系密切,6位是决定活性的关键,活性顺序为5、6位〉1、6位〉6位〉8位。     

Identification of Anthraquinone-Degrading Bacteria in Soil Contaminated with Polycyclic Aromatic Hydrocarbons

Quinones and other oxygenated polycyclic aromatic hydrocarbons (oxy-PAHs) are toxic and/or genotoxic compounds observed to be cocontaminants at PAH-contaminated sites, but their formation and fate in contaminated environmental systems have not been well studied. Anthracene-9,10-dione (anthraquinone) has been found in most PAH-contaminated soils and sediments that have been analyzed for oxy-PAHs. However, little is known about the biodegradation of oxy-PAHs, and no bacterial isolates have been described that are capable of growing on or degrading anthraquinone. PAH-degrading Mycobacterium spp. are the only organisms that have been investigated to date for metabolism of a PAH quinone, 4,5-pyrenequinone. We utilized DNA-based stable-isotope probing (SIP) with [U-¹³C]anthraquinone to identify bacteria associated with anthraquinone degradation in PAH-contaminated soil from a former manufactured-gas plant site both before and after treatment in a laboratory-scale bioreactor. SIP with [U-¹³C]anthracene was also performed to assess whether bacteria capable of growing on anthracene are the same as those identified to grow on anthraquinone. Organisms closely related to Sphingomonas were the most predominant among the organisms associated with anthraquinone degradation in bioreactor-treated soil, while organisms in the genus Phenylobacterium comprised the majority of anthraquinone degraders in the untreated soil. Bacteria associated with anthracene degradation differed from those responsible for anthraquinone degradation. These results suggest that Sphingomonas and Phenylobacterium species are associated with anthraquinone degradation and that anthracene-degrading organisms may not possess mechanisms to grow on anthraquinone.     

Resistance of Hibiscus esculentus L. and Vigna sinensis (L.) Endl. to Pseudocercospora and plant peroxidase activity in relation to infection

Five cultivars of Hibiscus esculentus L. and six cultivars of Vigna sinensis (L.) Endl. were tested for their relative resistance to Pseudocercospora spp. Differences in susceptibility to the leaf spot pathogen were observed in both host and non-host interactions. The H. esculentus cv. South Sea and V. sinensis cv. Purple Mart were most susceptible to Pseudocercospora abelmoschi and P. cruenta, respectively. The H. esculentus cv. Pure Luck was most tolerant to P. abelmoschi while the V. sinensis cv. KY Bush was highly resistant to P. cruenta. A distinct host-specific interaction was observed among the different species of Pseudocercospora. Cultivar specific interactions were most pronounced between V. sinensis and P. cruenta. A direct correlation was observed between the variation in peroxidase activity in the soluble fraction of inoculated leaves and resistance to infection in H. esculentus and V. sinensis cultivars. The soluble fraction of inoculated leaves had higher peroxidase activity than either mitochondrial or chloroplast extracts.     

虎杖营养器官蒽醌类化合物含量的季节变化

采用差示分光光度法测定虎杖营养器官中蒽醌类化合物的含量.该法以醋酸镁甲醇液为显色剂,以大黄素作标准对照品.其回归方程y=0.0576x+0.0012,r=0.9962.结果表明,在一个生长期中,各营养器官总蒽醌的变化不明显,蒽醌类化合物在各营养器官中含量的顺序依次为根>叶>茎;三年生的根高于一年生根;幼嫩茎叶的含量高于成熟的茎叶.在三年生根中游离蒽醌的含量在7月和9月出现两个峰值,8月降至最低;一年生根、幼叶、幼茎和老茎中游离蒽醌的含量在7月左右最高;除根外,幼叶的蒽醌类化合物的含量较其它营养器官高,且其生物量大,因此幼叶具有一定的开发前景.     

Anthrasesamones D and E from Sesamum indicum roots

Two anthraquinone derivatives, named anthrasesamones D and E, were isolated from the roots of Sesamum indicum. Their respective structures were determined to be 1,2,4-trihydroxy-3-(4-methylpent-3-enyl)anthraquinone and 1,2-dihydroxy-3-(4-methylpent-3-enyl)anthraquinone on the basis of spectroscopic evidence.     

Anthrasesamones D and E from Sesamum indicum Roots

Two anthraquinone derivatives, named anthrasesamones D and E, were isolated from the roots of Sesamum indicum. Their respective structures were determined to be 1,2,4-trihydroxy-3-(4-methylpent-3-enyl)anthraquinone and 1,2-dihydroxy-3-(4-methylpent-3-enyl)anthraquinone on the basis of spectroscopic evidence.     

Synthesis of Okicamelliaside,a Glucoside of Ellagic Acid with Potent Anti-Degranulation Activity

During our scrutiny of GC-EI-MS date for C₁₅ alcohols as putative intermediates on the ABA biosynthetic pathway in Cercospora cruenta, a trace amount of 5-[2',2'-dimenthyl-6'-methylene-1'-cyclohexyl]-3-methyl-4-penten-1-ol (2,3-dihydro-γ-ionylideneethanol) was identified. Feeding experiments indicated that this compound was not an intermediate to ABA, but a catabolite that originated from γ-ionylideneacetaldehyde. The stereochemistry of 2,3-dihydro-γ-ionylideneethanol was deduced to be (3R,1'S) from a comparison with an authentic specimen prepared via baker’s yeast asymmetric reduction.     

Separation procedures for the pharmacologically active components of rhubarb

Rhubarb, as an important Chinese medicine, has many functions owing to containing anthraquinone derivatives. The analysis of anthraquinone derivatives in Chinese rhubarb is reviewed. The analytical techniques include high performance liquid chromatography, capillary electrophoresis, thin-layer chromatography and so on. The main operation parameters in every technique were given. The structures of anthraquinone derivatives and the classification of Chinese rhubarb were summarized too.     

Early biosynthetic pathway to abscisic acid in Cercospora cruenta

A new biosynthetic intermediate of ABA, (2Z,4E)-gamma-ionylideneacetaldehyde, was isolated from young mycelia of Cercospora cruenta. Under an (18)O2 atmosphere, an oxygen atom of this endogenous aldehyde was exclusively labeled. Similarly, three (18)O atoms were incorporated into the ABA molecule recovered after prolonged incubation; selectively labeled were one of the carboxyl oxygen atoms and the two on the ring portion of ABA. A feeding experiment with [1-(13)C]glucose proved the exclusive operation of the mevalonate pathway for the formation of both ABA and beta-carotene. These results suggest that (2Z,4E)-gamma-ionylideneacetaldehyde can be a key ABA biosynthetic intermediate formed by the oxidative cleavage of a carotenoid precursor.     

Isolation and photoisomerization of a new anthraquinone from hairy root cultures of Sesamum indicum

An unstable anthraquinone was isolated from hairy root cultures of Sesamum indicum after preventing light throughout all experimental procedures. The structure of the (Z)-isomer of a previously isolated anthraquinone was determined to be 2-[(Z)-4-methylpenta-1,3-dien-1-yl]anthraquinone by spectroscopic methods. This compound was readily isomerized to the known (E)-isomer under light.     

Regulation of anthraquinone biosynthesis in cell cultures of Morinda citrifolia

Cell cultures of Morinda citrifolia L. are capable of accumulating substantial amounts of anthraquinones. Chorismate formed by the shikimate pathway is an important precursor of these secondary metabolites. Isochorismate synthase (EC 5.4.99.6), the enzyme that channels chorismate into the direction of the anthraquinones, is involved in the regulation of anthraquinone biosynthesis. Other enzymes of the shikimate pathway such as deoxy-D-arabino-heptulosonate 7-phosphate synthase (EC 4.1.2.15) and chorismate mutase (EC 5.4.99.5) do not play a regulatory role in the process. The accumulation of anthraquinones is correlated with isochorismate synthase activity under a variety of conditions, which indicates that under most circumstances the concentration of the branchpoint metabolite chorismate is not a rate-limiting factor. Anthraquinone biosynthesis in Morinda is strongly inhibited by 2,4-D, but much less by NAA. Both auxins inhibit the activity of isochorismate synthase proportionally to the concomitant reduction in the amount of anthraquinone accumulated. However, the correlation between enzyme activity and rate of biosynthesis is less clear when the activity of the enzyme is very high. In this case, a limiting concentration of precursor may determine the extent of anthraquinone accumulation. Partial inhibition of chorismate biosynthesis by glyphosate leads to less anthraquinone accumulation, but also to a reduction in ICS activity. The complexity of the interference of glyphosate with anthraquinone biosynthesis is illustrated by the effect of the inhibitor in cell cultures of the related species Rubia tinctorum L. in these cells, glyphosate leads to an increase in anthraquinone content and a concomitant rise in ICS activity. All data indicate that the main point of regulation in anthraquinone biosynthesis is located at the entrance of the specific secondary route.     

Effect of chitosan elicitation and media components on the production of anthraquinone colorants in madder (Rubia akane Nakai) cell culture

To increase the production of anthraquinone colorants in madder (Rubia akane Nakai) cell culture, the effects of elicitation on the colorant production were investigated. Chitosan was the best biotic elicitor among nine plant derived and microbial derived polysaccharides. When elicited with 25 mg/L chitosan, the total production was increased approximately two times in a seven-day culture as compared to that in the unelicited cells. Anthraquinone production was increased in proportion to the contact period up to day 3. Maximum anthraquinone colorants were obtained with 3-day treatment of chitosan. During chitosan elicitation, the total production was increased 1.3 times in MS medium containing galactose as compared to that containing sucrose. The degree of deacetylation in chitosan and the use of growth regulator or addition of precursor did not affect the production of anthraquinone colorants. When madder cells were elicited at optimum condition, anthraquinone concentration and specific anthraquinone content increased 1.3 times (0.69 g/L) and 2.2 times (0.32 g/g DCW), respectively.     

In vitro regeneration from leaf explants of Neoregelia cruenta (R. Graham) L.B. Smith,an endemic bromeliad from Eastern Brazil

An efficient plant regeneration system was developed for the induction of direct shoot formation from leaves derived from seedlings of Neoregelia cruenta, an endemic Bromeliaceae of Eastern Brazil. Shoot differentiation occurred directly from the leaf bases. In vitro responses were influenced by seedling age and growth regulator combinations. Highest regeneration rates were obtained from explants excised from 7-week-old seedlings cultured in the presence of 22 μM BA and 2.5 μM NAA. Shoot conversion to whole plants was most effective in shoots formed in response to 4.4 or 8.8 μM BA combined with 2.5 μM NAA. This revised version was published online in June 2006 with corrections to the Cover Date.     

Synthesis and properties of novel antisense oligonucleotides bearing an anthraquinone moiety at an internucleotide linkage.

Antisense oligonucleotides bearing an anthraquinone moiety at an internucleotide linkage were synthesized utilizing the stereoisomers of anthraquinone incorporated T-C dimer phosphoramidite derivatives. Some physicochemical properties of the anthraquinon bearing oligomers were investigated.