A method to construct cDNA library of the entomopathogenic fungus, <Emphasis Type="Italic">Metarhizium anisopliae</Emphasis>, in the hemolymph of the infected locust

A method was developed to construct cDNA library of pathogenic fungus in the blood of the infected insect for cloning the fungal genes expressed in the host. This method is designed to take advantage of the obvious difference between the cell structures and components of the pathogen cells and that of the host cells. The host blood cells only have cell membrane, which can be disrupted by using SDS/proteinase K (PK). The fungal cells grown in the animal blood have cell wall, which can protect the fungal cell from the disruption of SDS/proteinase K (PK). By this method, the blood cells were disrupted by SDS/proteinase K (PK) and then the released animal RNA and DNA were digested completely with RNase and DNase. Therefore, the fungi grown in the blood were harvested without any contamination of host RNA and DNA. The pure fungi harvested from the infected blood can be used for mRNA extraction and cDNA library construction. The purity of the fungal mRNA was confirmed by PCR and RT-PCR with specific primer pairs for the host and specific primer pairs for the fungus, respectively, and the clones of cDNA library constructed by using the fungal mRNA was also analyzed. The results showed that there was no detectable contaminated insect DNA or RNA existing in the fungal mRNA. Randomly selected cDNA clones from cDNA library were sequenced and analyzed against GenBank using Blastx; no selected sequences had significant similarity with insects’ genes in comparison with the data of GenBank. The results further confirmed that the method to purify the pathogenic fungus from the host animal is reliable and the mRNA extracted from the fungus is eligible for cDNA library construction, and other molecular analysis including RT-PCR. This method may be applied to other pathogenic fungi and their host animals.     

Induction of thaumatin‐like proteins (TLPs) in Rhizoctonia solani‐infected rice and characterization of two new cDNA clones

Thaumatin‐like proteins (TLPs) were shown to be induced in rice plants (cv. IR58) that were infected with the sheath blight fungus, Rhizoctonia solani . Western blot analysis revealed the presence of two TLPs with sizes of 25 and 24 kDa which are different from a previously reported TLP with a size of 15.6 kDa from rice plants infiltrated with the non‐pathogenic bacterium, Pseudomonas syringae pv. syringae . By probing a cDNA expression library prepared from RNA isolated from R. solani ‐infected rice plants with a TLP antibody, several putative TLP cDNA clones were isolated and sequenced. The cDNA clones appeared to be derived from two different genes which shared only 77% sequence identity with each other and a lower percentage of sequence identity with the previously reported TLP cDNA clone. Southern blot analysis with the two TLP cDNAs revealed different rice genomic DNA fragments. Northern blot analysis also confirmed that a 1.1‐kb RNA detectable by the TLP cDNA inserts was induced by fungal infection. Thus rice TLPs are encoded by a family of at least three genes which are differentially expressed in responses to bacterial or fungal pathogens.     

Identification of Alternaria brassicicola genes expressed in planta during pathogenesis of Arabidopsis thaliana

Alternaria brassicicola is a necrotrophic fungal pathogen that causes black spot disease on cruciferous plants including economically important Brassica species. The purpose of this study was to identify fungal genes expressed during infection of Arabidopsis. In order to identify candidate genes involved in pathogenicity, we employed suppression subtractive hybridization (SSH) between RNA isolated from A. brassicicola spores incubated in water and on the leaf surface of the Arabidopsis ecotype Landsberg. Two populations of cDNA were created from total RNA extracted after 24h when approximately 80% of the spores had germinated either on the leaf surface or in water. Following SSH, expression of clones was examined using dot-blot macro-arrays and virtual Northern blots. 47 cDNA clones differentially expressed between Alternaria infected Arabidopsis leaves and spore germination in water were selected for sequencing. Seventy-seven percent (36) of the cDNAs had significant homology to fungal sequences from databases examined, including available fungal genomes, while 13% (11) had no homology to sequences in the databases. All 36 genes had significant matches with genes of fungal origin, while 11 genes did not have significant hits in the databases examined. Five sequences were expressed on the plant leaf surface but not during spore germination in water according to virtual Northern blots. These five cDNAs were predicted to encode a cyanide hydratase, arsenic ATPase, formate dehydrogenase, major Alternaria allergen, and one unknown. RT-PCR was used to examine the expression of these five genes during infection of Brassica oleraceae var. capitata (cabbage), in vitro growth in nutrient rich media, and infection of Arabidopsis thaliana. Four of these genes are expressed in the nutrient rich medium, while the unknown gene P3F2 was only expressed during plant infection. The results of this study provide the first insight into genes expressed during A. brassicicola infection of Brassica species that may be involved in fungal pathogenesis.     

Variability of gene expression profiles in human blood and lymphoblastoid cell lines

Background

Infection of plants by pathogens and the subsequent disease development involves substantial changes in the biochemistry and physiology of both partners. Analysis of genes that are expressed during these interactions represents a powerful strategy to obtain insights into the molecular events underlying these changes. We have employed expressed sequence tag (EST) analysis to identify rice genes involved in defense responses against infection by the blast fungus Magnaporthe oryzae and fungal genes involved in infectious growth within the host during a compatible interaction.

Results

A cDNA library was constructed with RNA from rice leaves (Oryza sativa cv. Hwacheong) infected with M. oryzae strain KJ201. To enrich for fungal genes, subtraction library using PCR-based suppression subtractive hybridization was constructed with RNA from infected rice leaves as a tester and that from uninfected rice leaves as the driver. A total of 4,148 clones from two libraries were sequenced to generate 2,302 non-redundant ESTs. Of these, 712 and 1,562 ESTs could be identified to encode fungal and rice genes, respectively. To predict gene function, Gene Ontology (GO) analysis was applied, with 31% and 32% of rice and fungal ESTs being assigned to GO terms, respectively. One hundred uniESTs were found to be specific to fungal infection EST. More than 80 full-length fungal cDNA sequences were used to validate ab initio annotated gene model of M. oryzae genome sequence.

Conclusion

This study shows the power of ESTs to refine genome annotation and functional characterization. Results of this work have advanced our understanding of the molecular mechanisms underpinning fungal-plant interactions and formed the basis for new hypothesis.     

木屑处理迷宫栓孔菌Zn(II)-Cys(6)转录因子差异表达分析

Zn(II)-Cys(6)蛋白是一类仅存在于真菌中的锌指转录因子,其在迷宫栓孔菌(曾用名“偏肿革裥菌”) Trametes gibbosa中的相关研究较少。本研究对木屑处理后的迷宫栓孔菌进行转录组测序分析,以期挖掘到差异表达的Zn(II)-Cys(6)转录因子,为后续进一步对其功能的分析提供支持。首先,对在木屑处理下的T. gibbosa木质素降解酶进行了酶活检测,确认迷宫栓孔菌能有效降解木质素。之后,用木屑分别处理迷宫栓孔菌0、3、5、7和11 d,提取菌丝总RNA,利用高通量测序技术对这5个菌丝样本进行了转录组测序分析。通过COG、GO、Pfam和Swiss等数据库进行功能注释分析,鉴定出迷宫栓孔菌中全部的Zn(II)-Cys(6)家族转录因子基因,并进一步筛选出7个差异表达基因。进一步又对这7个差异基因的表达及蛋白结构进行了分析,绘制表达趋势热图,同时也对其理化性质,二、三级结构,疏水性等生物学特性进行了预测。通过构建系统发育树、预测Motif序列等初步分析了它们的进化关系及特性。最后,对这7个基因又利用RT-qPCR技术,进一步验证了转录组测序的结果。本研究从转录水平分析并鉴定出在木屑处理条件下迷宫栓孔菌中7个差异表达的Zn(II)-Cys(6)转录因子,研究结果将对后续研究迷宫栓孔菌中Zn(II)-Cys(6)转录因子的功能和表达调控机制有重要的参考价值。     

Infection structures of biotrophic and hemibiotrophic fungal plant pathogens

Biotrophic plant pathogenic fungi are one of the major causes of crop losses. The infection processes they exhibit are typified by infected host plant cells remaining alive for several days. This requires the development of specialized infection structures such as haustoria which are produced by obligate biotrophs, and intracellular hyphae which are produced by many hemibiotrophs. These infection hyphae are surrounded by the host plant plasma membrane, and in the case of haustoria the extrahaustorial membrane differs biochemically and structurally from the normal membrane. An interfacial matrix separates haustoria and intracellular hyphae from the invaginated membrane and this seems to be characteristic of biotrophic interactions. There is clear evidence for molecular differentiation of the haustorial plasma membrane in powdery mildews and rusts in comparison with the other fungal membranes. Relatively few pathogenicity genes related to biotrophy, and the switch from biotrophy to necrotrophy in hemibiotrophs, have been identified.     

Expressed sequence tags from the flower pathogen Claviceps purpurea

The ascomycete Claviceps purpurea (ergot) is a biotrophic flower pathogen of rye and other grasses. The deleterious toxic effects of infected rye seeds on humans and grazing animals have been known since the Middle Ages. To gain further insight into the molecular basis of this disease, we generated about 10 000 expressed sequence tags (ESTs)—about 25% originating from axenic fungal culture and about 75% from tissues collected 6–20 days after infection of rye spikes. The pattern of axenic vs. in planta gene expression was compared. About 200 putative plant genes were identified within the in planta library. A high percentage of these were predicted to function in plant defence against the ergot fungus and other pathogens, for example pathogenesis-related proteins. Potential fungal pathogenicity and virulence genes were found via comparison with the pathogen–host interaction database (PHI-base; http://www.phi-base.org ) and with genes known to be highly expressed in the haustoria of the bean rust fungus. Comparative analysis of Claviceps and two other fungal flower pathogens (necrotrophic Fusarium graminearum and biotrophic Ustilago maydis ) highlighted similarities and differences in their lifestyles, for example all three fungi have signalling components and cell wall-degrading enzymes in their arsenal. In summary, the analysis of axenic and in planta ESTs yielded a collection of candidate genes to be evaluated for functional roles in this plant–microbe interaction.     

羊种布鲁氏菌侵染HPT-8细胞cDNA文库的构建及EST序列分析

拟建立羊种布鲁氏菌侵染HPT-8细胞的cDNA文库。分别提取布鲁氏菌侵染20min、1h、2h、3h、4h后HPT-8细胞总RNA,逆转录合成cDNA,同源重组法构建布鲁氏菌侵染HPT-8细胞的cDNA文库,测定其库容量和重组率,对文库63个克隆进行测序分析,采用BLASTx和BLASTn进行序列同源性比对,并将63个基因进行了功能分类。结果得到的羊种布鲁氏菌侵染人胚胎滋养层细胞HPT-8cDNA文库的库容为1.43×106,重组率是96.92%,插入片段大小为0.2-5.0kb。在63个基因中,与转录、能量代谢、运输及细胞因子相关的基因所占比例较高。构建的羊种布鲁氏菌侵染HPT-8细胞的cDNA文库,为研究宿主细胞受体和布鲁氏菌入侵途径,进一步了解布鲁氏菌的致病机理奠定了基础。     

Evidence that the role of plant defensins in radish defense responses is independent of salicylic acid

Radish leaves contain two homologous 5-kDa plant defensins which accumulate systemically upon infection by fungal pathogens (F.R.G. Terras et al., 1995, Plant Cell 7: 573–588). Here we report on the molecular cloning of the cDNAs encoding the two pathogen-inducible plant defensin isoforms from radish (Raphanus sativus L.) leaves. Tissue-print and whole-leaf electroblot immunostaining showed that the plant defensin peptides not only accumulate at high levels at or immediately around the infection sites in leaves inoculated with Alternariabrassicicola, but also accumulate in healthy tissue further away from the infection sites and in non-infected leaves from infected plants. Gel blot analysis of RNA confirmed that expression of plant defensin genes is systemically triggered upon fungal infection whereas radish PR-1 gene expression is only activated locally. In contrast to the radish PR-1 gene(s), expression of the radish plant defensin genes was not induced by external application of salicylic acid. Activation of the plant defensin genes, but not that of PR-1 genes, occurred upon treatment with methyl jasmonate, ethylene and paraquat. Received: 3 December 1997 / Accepted: 3 March 1998