Differentiating Penicillium species by detection of indole metabolites using a filter paper method

The indole secondary metabolites chaetoglobosin C, cyclopiazonic acid, isofumigaclavine A and rugulovasine A and B produced by several Penicillium species growing on Czapek yeast autolysate agar were detected directly in the culture using filter paper wetted with Ehrlich reagent dissolved in ethanol. The filter paper was placed on the mycelial side of an agar plug and the metabolites were visualized as a violet zone on the paper within 10 min. It was shown that the combined characters of the violet reaction on filter paper and the ability to grow on creatine sucrose agar occurred in 5 out of 16 species of Penicillium examined. A few additional simple morphological and physiological criteria were then sufficient for identification of P. camemberti, P. commune, P. discolor, P. expansum and P. roqueforti var. roqueforti.     

Diagnostic characterization of Penicillium palitans, P. commune and P. solitum

A total of 98 isolates of Penicillium commune and P. solitum were analysed and it was shown that these isolates produced three unique combinations of secondary metabolites. Penicillium commune produced cyclopiazonic acid, cyclopaldic acid and rugulovasine A and B; P. solitum produced compactin and a new group including the ex-type culture of P. palitans produced cyclopiazonic acid and fumigaclavine A. Isolates in all three groups were able to produce cyclopenin, cyclopenol and viridicatin. An optimal thin layer chromatography system to detect the secondary metabolites from P. commune, P. palitans and P. solitum was developed using an agar plug method. The results were confirmed by high performance liquid chromatography with diode array detection. The chemotaxonomic allocations were backed up by differences in conidial colour on Czapek yeast autolysate agar, reverse colour on yeast extract sucrose agar and origin of the isolates. Even though P. palitans previously has been considered synonymous with P. commune or P. solitum it was concluded that P. palitans is a distinct species.     

Penicilliopsis pseudocordyceps, the holomorph of Pseudocordyceps seminicola, and notes on Penicilliopsis clavariaeformis

Penicilliopsis pseudocordyceps was collected from seeds of Diospyros discolor and is described as new. The anamorph produced in culture is Pseudocordyceps seminicola. The teleomorph was produced on oatmeal agar in 6 wk. Penicilliopsis clavariaeformis was also collected from the same seeds, yielding its Sarophorum palmicola anamorph in culture.     

蔷薇亚科4属4种植物幼苗形态结构及其系统演化分析

通过对蔷薇亚科蛇莓属的蛇莓[Duchesnea indica(Andrews)Focke]、委陵菜属的翻白草(Potentilla dis-colorBunge)、水杨梅属的水杨梅(Geum aleppicumJacq.)和地榆属的地榆(Sanguisorba officinalisL.)4种植物幼苗形态特征以及初生维管系统的结构研究表明:蛇莓、翻白草子叶脉序中主脉与两侧二级脉呈原始的二叉分支状,蛇莓脉序中无二级间脉,翻白草中为简单型的二级间脉;水杨梅、地榆的主脉与两侧二级脉呈进化的对生分支状,二者的二级间脉为复合型.蛇莓属幼苗子叶节区下部的中柱为原始的中始式二原型圆形单中柱,委陵菜属为较进化的外始式二原型圆形单中柱,水杨梅属为外始式二原型双钩型的单中柱,而地榆属的外始式二原型双扇型的单中柱则最为进化,并且地榆的后生木质部发达,也是进化的表现.综合叶脉数量和级数以及子叶节区下部的中柱类型分析,认为4属的演化趋势为:蛇莓属最原始,其次为委陵菜属和水杨梅属,地榆属最为进化.     

Classification of terverticillate penicillia based on profiles of mycotoxins and other secondary metabolites

Strains of available terverticillate penicillium species and varieties were analyzed for profiles of known mycotoxins and other secondary metabolites produced on Czapek yeast autolysate agar (intracellular metabolites) and yeast extract-sucrose agar (extracellular metabolites) by using simple thin-layer chromatography screening techniques. These strains (2,473 in all) could be classified into 29 groups based on profiles of secondary metabolites. Most of these profiles of secondary metabolites were distinct, containing several biosynthetically different mycotoxins and unknown metabolites characterized by distinct colors and retardation factors on thin-layer chromatography plates. Some species (P. italicum and P. atramentosum) only produced one or two metabolites by the simple screening methods. The 29 groups based on profiles of secondary metabolites were known species or subgroups thereof. These species and subgroups were independently identifiable by using morphological and physiological criteria. The species accepted, the number of isolates in each species investigated, and the mycotoxins they produced were: P. atramentosum, 4; P. aurantiogriseum, 510 (group I: penicillic acid and S-toxin and group II: penicillic acid, penitrem A [low frequency], terrestric acid [low frequency], viomellein, and xanthomegnin); P. brevicompactum, 81 (brevianamid A and mycophenolic acid); P. camembertii group I, 38, and group II, 114 (cyclopiazonic acid); P. chrysogenum, 87 (penicillin, roquefortine C, and PR-toxin); P. claviforme, 4 (patulin and roquefortine C); P. clavigerum, 4 (penitrem A); P. concentricum group I, 10 (griseofulvin and roquefortine C), and group II, 3 (patulin and roquefortine C); P. crustosum, 123 (penitrem A, roquefortine C, and terrestric acid); P. echinulatum, 13; P. expansum, 91 (citrinin, patulin, and roquefortine C); P. granulatum, 6 (patulin, penitrem A, and roquefortine C [traces]); P. griseofulvum, 21 (cyclopiazonic acid, griseofulvin, patulin, and roquefortine C); P. hirsutum, 100 (group I: terrestric acid; group II: citrinin, penicillic acid , roquefortine C, and terrestric acid; and group III: roquefortine C and terrestric acid), P. hirsutum group IV, 2 (chaetoglobosin C); P. isariiforme, 1; P. italicum, 41; P. mali, 104; P. roquefortii, 78 (group I: mycophenolic acid, PR-toxin, and roquefortine C and group II: mycophenolic acid, patulin, penicillic acid [low frequency], and roquefortine C); P. viridicatum group I, 634 (brevianamid A [low frequency], penicillic acid, viomellein, and xanthomegnin), P. viridicatum group II and III, 494 (citrinin and ochratoxin A), P. viridicatum group IV, 12 (griseofulvin and viridicatumtoxin). It is proposed that profiles of secondary metabolites be strongly emphasized in any future revision of the penicillia.     

一株类芽孢杆菌的分离鉴定及其抗革兰氏阴性菌活性测定

【背景】随着碳青霉烯类和多粘菌素类可转移耐药基因的发现及扩散,多重耐药革兰氏阴性细菌感染更加难以治疗。【目的】筛选有效拮抗革兰氏阴性菌的菌株,为新型抗生素的发掘奠定基础。【方法】利用胰蛋白胨大豆琼脂培养基筛选土壤源细菌,通过16S rRNA基因序列鉴定其种属;通过全基因组测序,antiSMASH比对分析菌株产抗生素潜能,双层琼脂平板法验证其抗菌活性;通过甲醇萃取其次级代谢产物,高效液相色谱串联质谱(HPLC-MS/MS)进行次级代谢产物分析。【结果】从北京周边土壤样品中分离到一株类芽孢杆菌CAU136 (Paenibacillus pabuli CAU136),经过生物信息学分析和antiSMASH比对,表明该菌株有较强合成次级代谢产物的潜能,双层琼脂平板法验证其能抑制多株革兰氏阴性菌生长,HPLC-MS/MS检测结果显示其可能分泌多粘菌素E。【结论】类芽孢杆菌CAU136可能分泌多粘菌素E,能有效拮抗革兰氏阴性菌。     

Biochemical characterization of ochratoxin A-producing strains of the genus Penicillium

In order to explore the biochemical scope of ochratoxin A-producing penicillia, we screened 48 Penicillium verrucosum isolates for the production of secondary metabolites. Fungal metabolites were analyzed by high-pressure liquid or gas chromatography coupled to diode array detection or mass spectrometry. The following metabolites were identified: ochratoxins A and B, citrinin, verrucolones, verrucines, anacines, sclerotigenin, lumpidin, fumiquinazolines, alantrypinones, daldinin D, dipodazine, penigequinolines A and B, 2-pentanone, and 2-methyl-isoborneol. By use of average linking clustering based on binary (nonvolatile) metabolite data, the 48 isolates could be grouped into two large and clearly separated groups and a small outlying group of four non-ochratoxin-producing isolates. The largest group, containing 24 isolates, mainly originating from plant sources, included the type culture of P. verrucosum. These isolates produced ochratoxin A, verrucolones, citrinin, and verrucines and had a characteristic dark brown reverse color on yeast extract-sucrose agar medium. Almost all of a group of 20 isolates mainly originating from cheese and meat products had a pale cream reverse color on yeast extract-sucrose agar medium and produced ochratoxin A, verrucolones, anacines, and sclerotigenin. This group included the former type culture of P. nordicum. We also found that P. verrucosum isolates and three P. nordicum isolates incorporated phenylalanine into verrucine and lumpidin metabolites, a finding which could explain why those isolates produced relatively lower levels of ochratoxins than did most isolates of P. nordicum.     

Identification of NephrotoxicPenicillium Species from Cereal Grains

A system is described for identifying grain-inhabiting nephrotoxicPenicillium spp. based on their colony characters on Czapek yeast extract agar, yeast extract sucrose agar, and malt extract agar media, and their secondary metabolite profiles on thin layer chromatography plates. Using this system, the identity of 11Penicillium species, or their chemotypes, producing nephrotoxic metabolites could be confirmed. The species areP. verrucosum chemotype I, P.verrucosum chemotype II,P. expansum, P. citrinum, P. aurantiogriseum, P. freii, P. tricolor, P. polonicum, P. viridicatum, P. cyclopium, and P. melanoconldlum. Other non-nephrotoxicPenicillium species present on stored grains were separated from nephrotoxic species by their colony characters and metabolite profiles.     

Identification of cheese-associated fungi using selected ion monitoring of volatile terpenes

The cheese-associated fungi Penicillium commune , P. roqueforti , P. solitum , P. discolor and Aspergillus versicolor have been investigated for production of volatile terpenes for chemical identification, when grown on yeast extract agar. Volatiles were collected by headspace solid-phase microextraction. Selected ion monitoring of four to seven of the most characteristic ions of mainly sesquiterpenes made it possible to identify the fungi to species level within 2 d. In a mixed culture of P. roqueforti and P. commune , inoculated in a ratio of 1000 : 1, volatiles from both fungi could be detected within 3 d, making identification possible.     

Taxonomy ofPenicillium nalgiovense isolates from mould-fermented sausages

A large number ofPenicillium nalgiovense isolates from mould fermented sausages and the ex type culture were examined for characters of morphology, physiology and production of secondary metabolites. To separate biotypes within theP. nalgiovense species, the data obtained were evaluated using multivariate statistical methods. The macromorphological characters of the ex type culture and isolates from meat products appeared to be distinctive. The ex type culture is characterized by a brown reverse on both Czapek yeast extract and malt extract agar while the isolates from meat products have a yellow to orange reverse. Proteolytic and/or lipolytic activity was demonstrated by 75% of the examined cultures and all of them demonstrated ability to utilize lactate as sole carbon source. Growth on creatine sucrose agar was very inhibited and acid production was absent or very weak. TLC analysis showed production of three unknown secondary metabolites that constituted the characteristic profile. HPLC analysis showed production of only three known secondary metabolites; chrysogine (96%), nalgiolaxin and nalgiovensin (9%). The ex type culture produced nalgiolaxin and nalgiovensin but not chrysogine. The chemometric evaluation showed thatP. nalgiovense isolates from meat products from a homogenous species, which can not be divided into biotypes. The only indication of grouping, beside a separation of the ex type culture, was related to the conidium colour (white, turquoise or grey green). The examinedP. nalgiovense isolates showed some resemblance (morphologically and chemically) toP. chrysogenum.     

Development and structure of the seed-coat of Lannea discolor (Sonder) Engl. (Anacardiaceae)

VON TEICHMAN, I., 1988. The development and structure of the seed-coat of Lannea discolor (Sonder) Engl. (Anacardiaceae). The bitegmic, anatropous ovule contains a group of nucellar cells with slightly thickened and intensively staining cell walls. Besides this hypostase sensu stricto, the nucellus cells in the chalaza become tanniniferous. This tanniniferous chalazal-nucellar tissue is intially plate-like. It is referred to as the hypostase sensu lato. The latter and the chalaza enlarge significantly. The raphe, extensive chalaza and well-developed cup-like hypostase sensu lato play an important role in the development of the seed-coat. The inner, tanniniferous epidermis of the inner integument persists in parts of the mature seed-coat. The outer, distinctly tanniniferous epidermis of the outer integument shows in the mature seed-coat a degree of secondary wall thickening. This undifferentiated type of seed-coat of L. discolor (tribe Spondieae) is remarkably similar to that of Camnosperma minor (tribe Rhoideae), both also showing tendency towards the exotestal type. In the Rhoideae the endotestal, i.e. differentiated type, of seed-coat is also present. The exalbuminous seed of L. discolor represents a derived and advanced type.     

Effect of aposymbiotic conditions on colony growth and secondary metabolite production in the lichen-forming fungus Ramalina dilacerata

The production of secondary metabolites by aposymbiotic lichen-forming fungi in culture is thought to be influenced by environmental conditions. The effects of the environment may be studied by culturing fungi under defined growing parameters to provide a better understanding of the role of the large number of polyketide synthase (PKS) gene paralogs detected in the genomes of many fungi. The objectives of this study were to examine the effects of culture conditions (media composition and pH level) on the colony growth, the numbers of secondary products, and the expression of two PKS genes by the lichen-forming fungus Ramalina dilacerata. Four types of growth media at four different pH levels were prepared to culture spore isolates of R. dilacerata. Colony diameter and texture were recorded. The number of secondary compounds were determined by thin layer chromatography (TLC) and high performance liquid chromatography (HPLC). Expression of two PKS genes (non-reducing (NR) and 6-MSAS-type PKS) were compared with expression of an internal control mitochondrial small subunit gene (mtSSU). The results showed that media containing yeast extracts produced the largest colony diameters and the fewest number of secondary metabolites. Colony growth rates also varied with different media conditions, and a significant negative relationship occurred between colony diameter and number of secondary metabolites. Expression of the NR PKS gene was significantly higher at pH 6.5 on the glucose malt agar than any other media, and expression of the 6-MSAS-type (partially-reducing) PKS gene was significantly higher at pH 8.5 on (malt agar) malt agar than on the other types of agar. Gene expression was correlated with the pH level and media conditions that induced the production of the larger number of secondary substances. This is the first study to examine secondary metabolite production in R. dilacerata by comparing the number of polyketides detected with quantitative polymerase chain reaction (qPCR) of two PKS genes under different culture conditions.     

Biochemical Characterization of Ochratoxin A-Producing Strains of the Genus Penicillium

In order to explore the biochemical scope of ochratoxin A-producing penicillia, we screened 48 Penicillium verrucosum isolates for the production of secondary metabolites. Fungal metabolites were analyzed by high-pressure liquid or gas chromatography coupled to diode array detection or mass spectrometry. The following metabolites were identified: ochratoxins A and B, citrinin, verrucolones, verrucines, anacines, sclerotigenin, lumpidin, fumiquinazolines, alantrypinones, daldinin D, dipodazine, penigequinolines A and B, 2-pentanone, and 2-methyl-isoborneol. By use of average linking clustering based on binary (nonvolatile) metabolite data, the 48 isolates could be grouped into two large and clearly separated groups and a small outlying group of four non-ochratoxin-producing isolates. The largest group, containing 24 isolates, mainly originating from plant sources, included the type culture of P. verrucosum. These isolates produced ochratoxin A, verrucolones, citrinin, and verrucines and had a characteristic dark brown reverse color on yeast extract-sucrose agar medium. Almost all of a group of 20 isolates mainly originating from cheese and meat products had a pale cream reverse color on yeast extract-sucrose agar medium and produced ochratoxin A, verrucolones, anacines, and sclerotigenin. This group included the former type culture of P. nordicum. We also found that P. verrucosum isolates and three P. nordicum isolates incorporated phenylalanine into verrucine and lumpidin metabolites, a finding which could explain why those isolates produced relatively lower levels of ochratoxins than did most isolates of P. nordicum.     

Autopolyploidy differentially influences body size in plants, but facilitates enhanced accumulation of secondary metabolites, causing increased cytosine methylation

Whole genome duplication leads to autopolyploidy and brings about an increase in cell size, concentration of secondary metabolites and enhanced cytosine methylation. The increased cell size offers a positive advantage to polyploids for cell-surface-related activities, but there is a differential response to change in body size across species and taxonomic groups. Although polyploidy has been very extensively studied, having genetic, ecological and evolutionary implications, there is no report that underscores the significance of native secondary metabolites vis-à-vis body size with ploidy change. To address this problem we targeted unique diploid-autotetraploid paired sets of eight diverse clones of six species of Cymbopogon- a species complex of aromatic grasses that accumulate qualitatively different monoterpene essential oils (secondary metabolite) in their vegetative biomass. Based on the qualitative composition of essential oils and the plant body size relationship between the diploid versus autotetraploid paired sets, we show that polyploidy brings about enhanced accumulation of secondary metabolites in all cases, but exerts differential effects on body size in various species. It is observed that the accumulation of alcohol-type metabolites (e.g. geraniol) does not inhibit increase in body size with ploidy change from 2× to 4× (r = 0.854, P < 0.01), but aldehyde-type metabolites (e.g. citral) appear to drastically impede body development (r = -0.895). Such a differential response may be correlated to the metabolic steps involved in the synthesis of essential oil components. When changed to tetraploidy, the progenitor diploids requiring longer metabolic steps in production of their secondary metabolites are stressed, and those having shorter metabolite routes better utilize their resources for growth and vigour. In situ immunodetection of 5-methylcytosine sites reveals enhanced DNA methylation in autopolyploids. It is underpinned that the qualitative composition of secondary metabolites found in the vegetative biomass of the progenitor diploid has a decisive bearing on the body size of the derived autotetraploids and brings about an enhancement in genome-wide cytosine methylation.     

Penicillium persicinum, a new griseofulvin, chrysogine and roquefortine C producing species from Qinghai province, China

A unique Penicillium isolate from Chinese soil with terverticillate penicilli and ellipsoidal to cylindrical smooth-walled conidia, produces, in addition to the common metabolite ergosterol, copious amounts of an unknown peach-red pigment and the following secondary metabolites: griseofulvin, dechlorogriseofulvin, lichexanthone, roquefortine C, roquefortine D, chrysogine, 2-pyrovoylaminobenzamide, 2-acetyl-quinazolin-4(3H)-one. This isolate, CBS 111235, is described as Penicillium persicinum sp. nov., which belongs to subgenus Penicillium section Chrysogena but is morphologically similar to P. italicum. On the basis of the production of secondary metabolites it resembles P. griseofulvum and P. coprophilum. Sequence data using part of the beta-tubulin gene showed that it is phylogenetically related to P. chrysogenum and P. aethiopicum in section Chrysogena with which it shares both secondary metabolites and ability to grow at 37 degrees C.     

昆虫对植物次生物质的代谢适应机制及其对昆虫抗药性的意义

植物次生物质(plant secondary metabolites)对昆虫的取食行为、生长发育及繁殖可以产生不利影响,甚至对昆虫可以产生毒杀作用。为了应对植物次生物质的不利影响,昆虫通过对植物次生物质忌避取食、解毒代谢等多种机制,而对寄主植物产生适应性。其中,昆虫的解毒代谢酶包括昆虫细胞色素P450酶系（P450s）及谷胱甘肽硫转移酶（GSTs）等,在昆虫对植物次生物质的解毒代谢及对寄主植物的适应性中发挥了重要作用。昆虫的解毒酶系统不仅可以代谢植物次生物质,还可能代谢化学杀虫剂,因而昆虫对寄主植物的适应性与其对杀虫剂的耐药性甚至抗药性密切相关。昆虫细胞色素P450s和GSTs等代谢解毒酶活性及相关基因的表达可以被植物次生物质影响,这不仅使昆虫对寄主植物的防御产生了适应性,还影响了昆虫对杀虫剂的解毒代谢,因而改变昆虫的耐药性或抗药性。掌握昆虫对植物次生物质的代谢适应机制及其在昆虫抗药性中的作用,对于明确昆虫的抗药性机制具有重要的参考意义。本文综述了植物次生物质对昆虫的影响、昆虫对寄主植物次生物质的代谢机制、昆虫对植物次生物质的代谢适应性对昆虫耐药性及抗药性的影响等方面的研究进展。     

Antimicrobial activity of food-related Penicillium sp. against pathogenic bacteria in laboratory media and a cheese model system

Food-related Penicillium species ( n ep fy1 = rs 34) and Geotrichum candidum ( n = 11) grown on Czapek Dox and brie agar were tested for their ability to suppress growth of pathogenic bacteria. Ten out of 13 P. camemberti showed antagonistic activity while the other species did not interact significantly with the bacterial growth. The order of inhibition was: Gram-negative bacteria and Bacillus cereus > Listeria monocytogenes , Lactococcus sp. > Micrococcus sp. whereas Lactobacillus sp., Staphylococcus aureus and some Micrococcus sp. were unaffected. When Salmonella typhimurium was inoculated together with P. camemberti P25 in brie agar, bacterial growth was inhibited during the first 6 d of incubation whereafter growth started. The inhibition of L. monocytogenes was similar but less pronounced. The antimicrobial activity produced by P. camemberti P25 and L84 was enhanced with increasing amount of sucrose in the medium. The activity was increased at low pH and destroyed at pH above 8. It was detectable at 15°C but not at 37°C indicating that volatile metabolites might be involved. No significant accumulation of organic acids and no secondary metabolites such as mycotoxins were detected. HSGC-MS analysis indicated that acetaldehyde, benzaldehyde, 3-methylbutanal and 1-octen-3-ol were produced by P. camemberti during the period when inhibitory activity was observed. Pure acetaldehyde and benzaldehyde were shown to be inhibitory to L. monocytogenes and Salm. typhimurium when grown at 15°C and pH 5·5 and 7·0.     

Myxobacteria: a source of new antibiotics

Myxobacteria form highly colored macroscopic fruiting bodies on rotting wood and other substrates. The organisms can move by gliding or creeping, for example, across glass and agar surfaces. They also produce a large number of unusual secondary metabolites some of which have considerable potential as antibiotics. The large-scale cultivation of myxobacteria has also, therefore, become of great interest.     

Chemical and physiological characterization of taxa in theFusarium sambucinum complex

Forty-one isolates ofFusarium sambucinum sensu lato were screened for production of secondary metabolites in agar cultures. Of 16 strains ofF. sambucinum sensu stricto all but two strains produced diacetoxyscirpenol and two unidentified metabolites, TB1 and TB2 respectively. The two remainingF. sambucinum strains produced T-2 toxin, TB1 and TB2.Fusarium venenotum (6 strains) produced diacetoxyscirpenol and an unidentified metabolite BB.Fusarium torulosum (8 strains) produced wortmannin and antibiotic Y. The three species could be differentiated by their pattern of identified and unidentified metabolites detected by agar plug TLC combined with chemical data from HPLC-diode array detection of fungal extracts, and data on growth rates on potato sucrose agar and tannin sucrose agar.     

Secondary metabolites as co-markers in the taxonomy of Aspergilli

The production of extracellular and intracellular secondary metabolites by 13 Aspergillus species has been directly detected using the agar plug technique. In addition to several unknown compound A. aculeatus, A. ochraceus and A. terreus were found to be the highest producers of extracellular secondary metabolites, while the lowest producer species were A. tamarii, A. rugulosus in addition to A. oryzae whose secondary metabolites couldn't be detected by this technique. In case of intracellular secondary metabolites, the highest producer species were A. flavus, A. nidulans and A. wentii, while the lowest producers were A. clavatus, A. tamarii and A. violaceous. All the examined species could be distinguished on the basis of their secondary metabolite profiles indicating the potential role of secondary metabolites in the chemotaxonomy of Aspergilli.