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.     

Cellular differentiation and host invasion by the rice blast fungus Magnaporthe grisea

This review describes current advances in understanding the biology of plant infection by the rice blast fungus Magnaporthe grisea. Development of the specialized infection structure, the appressorium, in M. grisea has recently been shown to be controlled by cell cycle progression and initiation of autophagic, programmed cell death in the fungal spore. Re-cycling of the contents of the fungal spore and peroxisomal fatty acid beta-oxidation are therefore important processes for appressorium function. Following entry to the host plant, new evidence suggests that M. grisea grows biotrophically within rice cells, bounded by the plant plasmalemma, and the fungus moves from cell-to-cell by means of plasmodesmata. Biotrophic proliferation of the fungus is likely to require secretion of effector proteins and suppression of host defences. Consistent with this, a component of the polarized exocytosis machinery of M. grisea is necessary for pathogenicity and also for induction of host defences in an incompatible interaction. Large-scale insertional mutagenesis is now allowing the rapid analysis of gene function in M. grisea, heralding a new approach to the study of this important fungal pathogen.     

Disease resistance against Magnaporthe grisea is enhanced in transgenic rice with suppression of omega-3 fatty acid desaturases

Linolenic acid (18:3) is the most abundant fatty acid in plant membrane lipids and is a source for various oxidized metabolites, called oxylipins. 18:3 and oxylipins play important roles in the induction of defense responses to pathogen infection and wound stress in Arabidopsis. However, in rice, endogenous roles for 18:3 and oxylipins in disease resistance have not been confirmed. We generated 18:3-deficient transgenic rice plants (F78Ri) with co-suppression of two omega-3 fatty acid desaturases, OsFAD7 and OsFAD8. that synthesize 18:3. The F78Ri plants showed enhanced resistance to the phytopathogenic fungus Magnaporthe grisea. A typical 18:3-derived oxylipin, jasmonic acid (JA), acts as a signaling molecule in defense responses to fungal infection in Arabidopsis. However, in F78Ri plants, the expression of JA-responsive pathogenesis-related genes, PBZ1 and PR1b, was induced after inoculation with M. grisea, although the JA-mediated wound response was suppressed. Furthermore, the application of JA methyl ester had no significant effect on the enhanced resistance in F78Ri plants. Taken together, our results indicate that, although suppression of fatty acid desaturases involves the concerted action of varied oxylipins via diverse metabolic pathways, 18:3 or 18:3-derived oxylipins, except for JA, may contribute to signaling on defense responses of rice to M. grisea infection.     

Saccharomyces cerevisiae SSD1 orthologues are essential for host infection by the ascomycete plant pathogens Colletotrichum lagenarium and Magnaporthe grisea

Fungal plant pathogens have evolved diverse strategies to overcome the multilayered plant defence responses that confront them upon host invasion. Here we show that pathogenicity of the cucumber anthracnose fungus, Colletotrichum lagenarium, and the rice blast fungus, Magnaporthe grisea, requires a gene orthologous to Saccharomyces cerevisiae SSD1, a regulator of cell wall assembly. Screening for C. lagenarium insertional mutants deficient in pathogenicity led to the identification of ClaSSD1. Following targeted gene replacement, appressoria of classd1 mutants retained the potential for penetration but were unable to penetrate into host epidermal cells. Transmission electron microscopy suggested that appressorial penetration by classd1 mutants was restricted by plant cell wall-associated defence responses, which were observed less frequently with the wild-type strain. Interestingly, on non-host onion epidermis classd1 mutants induced papilla formation faster and more abundantly than the wild type. Similarly, colonization of rice leaves by M. grisea was severely reduced after deletion of the orthologous MgSSD1 gene and attempted infection by the mutants was accompanied by the accumulation of reactive oxygen species within the host cell. These results suggest that appropriate assembly of the fungal cell wall as regulated by SSD1 allows these pathogens to establish infection by avoiding the induction of host defence responses.     

稻瘟病菌致病性的分子遗传学研究进展

由稻瘟病菌引起的稻瘟病是水稻生产上危害最为严重的真菌病害,对世界粮食生产造成巨大损失。稻瘟病菌成功侵染寄主包括分生孢子萌发、附着胞形成、侵染钉分化和侵染性菌丝扩展等一系列错综复杂的过程,其中每一环节都是由特定基因控制的。稻瘟病菌与水稻的互作符合经典的基因对基因学说,二者的不亲和互作是无毒基因与抗病基因相互作用的结果。近几十年来,世界各国的科学家对稻瘟病菌致病性的生物学及其遗传的分子机制进行了深入的研究。文章就稻瘟病菌致病性的分子遗传学及其遗传变异机制的研究进行了综述,同时对功能基因的研究方法进行了总结。     

Comparative study of genes expressed from rice fungus-resistant and susceptible lines during interactions with Magnaporthe oryzae

Rice blast disease caused by Magnaporthe oryzae is the most important fungal disease of rice. To understand the molecular basis of interaction between the fungus and rice, we constructed a cDNA library from a rice-resistant line inoculated with M. oryzae. One hundred and fifty-three cDNA clones were sequence analyzed, of which 129 exhibited significant nucleotide sequence homology to known genes, 21 were homologous to unknown genes, while three clones did not match to any database. However, these three unmatched clones showed sequence homology at protein level in the protein databases and one of them encoded a disease resistance-related protein kinase and was abundant in the EST collection. Northern analysis showed that this disease resistance-related protein kinase gene was induced by inoculation and only expressed in the rice-resistant, but not susceptible, lines. Southern analysis showed that this gene was present in a single copy in the rice genome and co-segregated with the M. oryzae resistance in the cross of the resistant and susceptible lines. This study illustrates that sequencing of ESTs from inoculated resistant plants can reveal genes responsive to pathogen infection, which could help understand plant defense mechanisms.     

MHP1, a Magnaporthe grisea hydrophobin gene, is required for fungal development and plant colonization

Fungal hydrophobins are implicated in cell morphogenesis and pathogenicity in several plant pathogenic fungi including the rice blast fungus Magnaporthe grisea. A cDNA clone encoding a hydrophobin (magnaporin, MHP1) was isolated from a cDNA library constructed from rice leaves infected by M. grisea. The MHP1 codes for a typical fungal hydrophobin of 102 amino acids containing eight cysteine residues spaced in a conserved pattern. Hydropathy analysis of amino acids revealed that MHP1 belongs to the class II group of hydrophobins. The amino acid sequence of MHP1 exhibited about 20% similarity to MPG1, an M. grisea class I hydrophobin. Expression of MHP1 was highly induced during plant colonization and conidiation, but could hardly be detected during mycelial growth. Transformants in which MHP1 was inactivated by targeted gene replacement showed a detergent wettable phenotype, but were not altered in wettability with water. mhp1 mutants also exhibited pleiotropic effects on fungal morphogenesis, including reduction in conidiation, conidial germination, appressorium development and infectious growth in host cells. Furthermore, conidia of mhp1 mutants were defective in their cellular organelles and rapidly lose viability. As a result, mhp1 mutants exhibited a reduced ability to infect and colonize a susceptible rice cultivar. These phenotypes were recovered by re-introduction of an intact copy of MHP1. Taken together, these results indicate that MHP1 has essential roles in surface hydrophobicity and infection-related fungal development, and is required for pathogenicity of M. grisea.     

Molecular analysis of the rice MAP kinase gene family in relation to Magnaporthe grisea infection

Mitogen-activated protein kinase (MAPK) cascades play a crucial role in plant growth and development as well as biotic and abiotic stress responses. In Arabidopsis, 20 MAPKs have been identified and divided into four major groups. In rice, a monocot model and economically important cereal crop, only five MAPKs were characterized, including three related to the host defense response. In this study, we have identified 17 members of the rice MAPK gene (OsMPK) family through an in silico search of rice genome databases. Based on the phylogenetic analysis and pairwise comparison of Arabidopsis and rice MAPKs, we propose that MAPKs can be divided into six groups. Interestingly, the rice genome contains many more MAPKs with the TDY phosphorylation site (11 members) than with the TEY motif (six members). In contrast, the Arabidopsis genome contains more MAPKs with the TEY motif (12 members) than with the TDY motif (eight members). Upon inoculation with the blast fungus (Magnaporthe grisea), nine of 17 OsMPK genes were found to be induced at the mRNA level during either early, late, or both stages of infection. Four of the M. grisea-induced OsMPK genes were associated with host-cell death in the lesion-mimic rice mutant, and eight of them were differentially induced in response to defense signal molecules such as jasmonic acid, salicylic acid, abscisic acid, and ethylene. The genome-wide expression analysis suggests that about half of the rice MAPK genes are associated with pathogen infection and host defense response.     

MGOS: A resource for studying Magnaporthe grisea and Oryza sativa interactions

The MGOS (Magnaporthe grisea Oryza sativa) web-based database contains data from Oryza sativa and Magnaporthe grisea interaction experiments in which M. grisea is the fungal pathogen that causes the rice blast disease. In order to study the interactions, a consortium of fungal and rice geneticists was formed to construct a comprehensive set of experiments that would elucidate information about the gene expression of both rice and M. grisea during the infection cycle. These experiments included constructing and sequencing cDNA and robust long-serial analysis gene expression libraries from both host and pathogen during different stages of infection in both resistant and susceptible interactions, generating >50,000 M. grisea mutants and applying them to susceptible rice strains to test for pathogenicity, and constructing a dual O. sativa-M. grisea microarray. MGOS was developed as a central web-based repository for all the experimental data along with the rice and M. grisea genomic sequence. Community-based annotation is available for the M. grisea genes to aid in the study of the interactions.     

Cholic acid, a bile acid elicitor of hypersensitive cell death, pathogenesis-related protein synthesis, and phytoalexin accumulation in rice

When plants interact with certain pathogens, they protect themselves by generating various defense responses. These defense responses are induced by molecules called elicitors. Since long ago, composts fermented by animal feces have been used as a fertilizer in plant cultivation, and recently, have been known to provide suppression of plant disease. Therefore, we hypothesized that the compounds from animal feces may function as elicitors of plant defense responses. As a result of examination of our hypothesis, an elicitor of rice defense responses was isolated from human feces, and its structure was identified as cholic acid (CA), a primary bile acid in animals. Treatment of rice (Oryza sativa) leaves with CA induced the accumulation of antimicrobial compounds (phytoalexins), hypersensitive cell death, pathogenesis-related (PR) protein synthesis, and increased resistance to subsequent infection by virulent pathogens. CA induced these defense responses more rapidly than did fungal cerebroside, a sphingolipid elicitor isolated from the rice pathogenic fungus Magnaporthe grisea. Furthermore, fungal cerebroside induced both types of rice phytoalexins, phytocassanes and momilactones, whereas CA mainly induced phytocassanes, but not momilactones. In the structure-activity relationship analysis, the hydroxyl groups at C-7 and C-12, and the carboxyl group at C-24 of CA contributed to the elicitor activity. These results indicate that CA is specifically recognized by rice and is a different type of elicitor from fungal cerebroside. This report demonstrated that bile acid induced defense responses in plants.     

A putative polyketide synthase/peptide synthetase from Magnaporthe grisea signals pathogen attack to resistant rice

Isolates of the rice blast fungus Magnaporthe grisea that carry the gene encoding Avirulence Conferring Enzyme1 (ACE1) are specifically recognized by rice (Oryza sativa) cultivars carrying the resistance gene Pi33. This recognition enables resistant plants to activate a defense response. ACE1 was isolated by map-based cloning and encodes a putative hybrid between a polyketide synthase and a nonribosomal peptide synthetase, enzymes involved in microbial secondary metabolism. ACE1 is expressed exclusively during fungal penetration of host leaves, the time point at which plant defense reactions are triggered. Ace1 appears to be localized in the cytoplasm of the appressorium. Mutation of the putative catalytic site of the beta-ketoacyl synthase domain of Ace1 abolishes recognition of the fungus by resistant rice. This suggests that Ace1 biosynthetic activity is required for avirulence. Our results are consistent with the hypothesis that the fungal signal recognized by resistant rice plants is the secondary metabolite whose synthesis depends on Ace1.     

Large-scale identification of expressed sequence tags involved in rice and rice blast fungus interaction

To better understand the molecular basis of the defense response against the rice blast fungus (Magnaporthe grisea), a large-scale expressed sequence tag (EST) sequencing approach was used to identify genes involved in the early infection stages in rice (Oryza sativa). Six cDNA libraries were constructed using infected leaf tissues harvested from 6 conditions: resistant, partially resistant, and susceptible reactions at both 6 and 24 h after inoculation. Two additional libraries were constructed using uninoculated leaves and leaves from the lesion mimic mutant spl11. A total of 68,920 ESTs were generated from 8 libraries. Clustering and assembly analyses resulted in 13,570 unique sequences from 10,934 contigs and 2,636 singletons. Gene function classification showed that 42% of the ESTs were predicted to have putative gene function. Comparison of the pathogen-challenged libraries with the uninoculated control library revealed an increase in the percentage of genes in the functional categories of defense and signal transduction mechanisms and cell cycle control, cell division, and chromosome partitioning. In addition, hierarchical clustering analysis grouped the eight libraries based on their disease reactions. A total of 7,748 new and unique ESTs were identified from our collection compared with the KOME full-length cDNA collection. Interestingly, we found that rice ESTs are more closely related to sorghum (Sorghum bicolor) ESTs than to barley (Hordeum vulgare), wheat (Triticum aestivum), and maize (Zea mays) ESTs. The large cataloged collection of rice ESTs in this study provides a solid foundation for further characterization of the rice defense response and is a useful public genomic resource for rice functional genomics studies.     

Effector-mediated suppression of chitin-triggered immunity by magnaporthe oryzae is necessary for rice blast disease

Plants use pattern recognition receptors to defend themselves from microbial pathogens. These receptors recognize pathogen-associated molecular patterns (PAMPs) and activate signaling pathways that lead to immunity. In rice (Oryza sativa), the chitin elicitor binding protein (CEBiP) recognizes chitin oligosaccharides released from the cell walls of fungal pathogens. Here, we show that the rice blast fungus Magnaporthe oryzae overcomes this first line of plant defense by secreting an effector protein, Secreted LysM Protein1 (Slp1), during invasion of new rice cells. We demonstrate that Slp1 accumulates at the interface between the fungal cell wall and the rice plasma membrane, can bind to chitin, and is able to suppress chitin-induced plant immune responses, including generation of reactive oxygen species and plant defense gene expression. Furthermore, we show that Slp1 competes with CEBiP for binding of chitin oligosaccharides. Slp1 is required by M. oryzae for full virulence and exerts a significant effect on tissue invasion and disease lesion expansion. By contrast, gene silencing of CEBiP in rice allows M. oryzae to cause rice blast disease in the absence of Slp1. We propose that Slp1 sequesters chitin oligosaccharides to prevent PAMP-triggered immunity in rice, thereby facilitating rapid spread of the fungus within host tissue.