The relationship between transgenerational acquired resistance and global DNA methylation in Arabidopsis.

Progeny of heavily diseased plants develop transgenerational acquired resistance (TAR). In Arabidopsis, TAR can be transmitted over one stress-free generation. Although DNA methylation has been implicated in the regulation of TAR, the relationship between TAR and global DNA methylation remains unknown. Here, we characterised the methylome of TAR-expressing Arabidopsis at different generations after disease exposure. Global clustering of cytosine methylation revealed TAR-related patterns in the F3 generation, but not in the F1 generation. The majority of differentially methylated positions (DMPs) occurred at CG context in gene bodies. TAR in F3 progeny after one initial generation of disease, followed by two stress-free generations, was lower than TAR in F3 progeny after three successive generations of disease. This difference in TAR effectiveness was proportional to the intensity of differential methylation at a sub-set of cytosine positions. Comparison of TAR-related DMPs with previously characterised cytosine methylation in mutation accumulation lines revealed that ancestral disease stress preferentially acts on methylation-labile cytosine positions, but also extends to methylation-stable positions. Thus, the TAR-related impact of ancestral disease extends beyond stochastic variation in DNA methylation. Our study has shown that the Arabidopsis epigenome responds globally to disease in previous generations and we discuss its contribution to TAR.

Development and Evaluation of a Real-Time PCR Multiplex Assay for the Detection of Allergenic Peanut Using Chloroplast DNA Markers.

Peanut is one of the most commonly consumed allergy-causing foods in the United States. Prevention of accidental consumption by allergic individuals is assisted by methods that effectively identify the presence of peanut in food, even at trace levels. This study presents a multiplex real-time polymerase chain reaction (PCR) assay that uses chloroplast markers ( matK, rpl16, and trnH-psbA) to specifically detect peanut in three types of foods: baked goods, chocolate, and tomato sauces. Food matrices were spiked with raw peanut at concentrations ranging from 0.1 to 105 ppm. The assay was evaluated with respect to linear range and reaction efficiency. High reaction efficiencies were generally obtained across 6-7 orders of magnitude. Limits of detection were between 0.1 and 1 ppm, and reaction efficiencies were mostly within the preferred range of 100 ± 10%. Our results indicate that real-time PCR assays using chloroplast markers can be a valuable tool for peanut detection.

Extracellular DNA: the tip of root defenses?

This review discusses how extracellular DNA (exDNA) might function in plant defense, and at what level(s) of innate immunity this process might operate. A new role for extracellular factors in mammalian defense has been described in a series of studies. These studies reveal that cells including neutrophils, eosinophils, and mast cells produce 'extracellular traps' (ETs) consisting of histone-linked exDNA. When pathogens are attracted to such ETs, they are trapped and killed. When the exDNA component of ETs is degraded, trapping is impaired and resistance against invasion is reduced. Conversely, mutation of microbial genes encoding exDNases that degrade exDNA results in loss of virulence. This discovery that exDNases are virulence factors opens new avenues for disease control. In plants, exDNA is required for defense of the root tip. Innate immunity-related proteins are among a group of >100 proteins secreted from the root cap and root border cell populations. Direct tests revealed that exDNA also is rapidly synthesized and exported from the root tip. When this exDNA is degraded by the endonuclease DNase 1, root tip resistance to fungal infection is lost; when the polymeric structure is degraded more slowly, by the exonuclease BAL31, loss of resistance to fungal infection is delayed accordingly. The results suggest that root border cells may function in a manner analogous to that which occurs in mammalian cells.

Decreased suppression of immune stimulatory CpG motifs in plant DNA.

Due to differential content of CpG motifs in genomic DNA of organisms like bacteria and mammals, CpG-containing DNA delivers a danger or immunostimulatory signal that is recognized by Toll-like receptor 9 in mammalian cells. Here we show that genomic DNA from several plants promote proliferation and CD69 expression as well as activate NFkappaB and JNK pathways in murine B lymphocytes. Plant DNA synergize with specific antigen in activating B cells in a dose-dependent manner. Using a computational method we compared the usage of CpG motif related sequences in DNA of plants, bacteria, mammals or other species. It was found that the CpG motif suppression is much less significant in plant DNA than in mammalian genomes. These computation results partially explain the immunostimulatory activity of plant DNA observed in biological experiments, and lead to the hypothesis that plants respond to plant pathogens by recognizing CpG motifs in the pathogens' genomic DNA. Collectively this work provides new evidence for further understanding the interactions between plants and the human immune system or homeostasis, and between plants and their pathogens. The hypothesis that CpG dependent immunomodulation is a feature of plant DNA that contributes to plant nutrition or food/pollen allergy is also discussed.

Exploiting the plant secretory pathway to improve the anticancer activity of a plant-derived HPV16 E7 vaccine.

The human papillomavirus 16 (HPV16) E7 oncoprotein can be considered a "tumor-specific antigen", and therefore it represents a promising target for a therapeutic vaccine against HPV-associated tumors. Efficient production of E7 protein with a plant-based transient expression system has been already described and it was demonstrated that E7-containing crude plant extracts confer partial protection against tumor challenge in a mouse model system. Before adopting the plant-based system as a cost-effective method for the production of an E7-based anti-cancer vaccine, some aspects, such as the oncoprotein yield, need further investigation. In the present study, we report the transient expression, mediated by a potato virus X (PVX)-derived vector, of the E7 protein targeted to the secretory system of Nicotiana benthamiana plants by using a plant-derived signal sequence. Targeting the antigen to the secretory pathway enhanced the E7 protein expression levels about five-fold. Mice immunized by s.c. administration with crude foliar extracts containing E7 showed strong stimulation of cell-mediated immune response after five boosters, as detected by ELISPOT. After challenging with the E7-expressing C3 tumor cells, tumor growth was completely inhibited in 80% of the vaccinated animals and a drastic reduction of tumor burden was observed in the remaining tumor-affected mice. These data demonstrate that, by enhancing E7 yield, it is possible to improve the anti-cancer activity of the plant-based experimental vaccine and open the way for a large-scale production of the E7 protein which could be purified or used as in planta formulation, also suitable for oral therapeutic vaccination.

Combination of electron microscopic in situ hybridization and anti-DNA antibody labelling reveals a peculiar arrangement of ribosomal DNA in the fibrillar centres of the plant cell nucleolus.

The fibrillar centres (FCs) in the nucleoli of Allium cepa usually contained compact dense chromatin, which was always surrounded with light fibrous material (LFM). Distribution of 18S ribosomal DNA (rDNA) in the FCs was examined by in situ hybridization at the light and electron microscopic levels and the results were compared with those obtained by immunogold labelling with anti-DNA antibodies. Anti-DNA antibodies heavily labelled the dense chromatin of the FCs but scarcely labelled the LFM. However, electron microscopic in situ hybridization using the 18S rDNA probe showed that the label in the dense chromatin was extremely weak compared with that obtained by the anti-DNA antibody labelling: the specific label with anti-DNA antibodies of the dense chromatin was about 15 times as much as that of the LFM, whereas the specific label with in situ hybridization in the dense chromatin was only about 1.7 times higher than in the LFM. These results suggest that the rDNA encoding rRNA is preferentially released from the dense chromatin and that non-transcribed intergenic spacers remain in the dense chromatin as the anchoring sites of rDNA.

Activation of antigen-presenting cells by immunostimulatory plant DNA: a natural resource for potential adjuvant.

Genomic DNA sequences (bacteria, insect, nematodes and molluscs) or synthetic oligodeoxynucleotides (ODN) containing unmethylated CpG motifs (CpG-DNA/ODN) are regarded as promising candidates for new medical adjuvants for their ability to stimulate the mammalian immune system and enhance immune responses to specific antigens. Here, we first report the immunostimulatory activity of total genomic DNA from two plants, Brassica chinensis L. and Zea may, the CpG methylation status of which is incomplete compared with E. coli DNA. These plant DNA can activate B cells to proliferate. Plant DNA promotes secretion of IL-12, and increases expression of MHC and costimulatory molecules by bone marrow-derived dendritic cells (BMDC). Plant DNA can also enhance antigen presentation capacity of BMDC and macrophages. When administrated in vivo, plant DNA can inhibit tumor growth in situ or metastasis in tumor-bearing mice. The immunostimulatory activity of plant DNA could be abolished by methylation. Our data showed that plant DNA can activate antigen-presenting cells (APC) including DC, macrophages and B cells, indicating that plant DNA is a new kind of potential adjuvant. Therefore, we conclude that plant DNA is another natural source of CpG-DNA, and that green plants may provide abundant resources for this potential medical adjuvant.

Mutational analysis of the IgE-binding epitopes of P34/Gly m Bd 30K.

BACKGROUND: Peanuts and soybeans are 2 foods that have been shown to be responsible for many atopic disorders. Because of their nutritional benefit, soybean proteins are now being used increasingly in a number of food products. Previous studies have documented multiple allergens in soybean extracts, including glycinin, beta-conglycinin, and the P34/Gly m Bd 30K protein. OBJECTIVE: Our overall goal was to identify soybean-specific allergens to begin to understand molecular and immunochemical characteristics of legume proteins. The specific aim of the current investigation was to identify the essential amino acid residues necessary for IgE binding in the 5 distinct immunodominant epitopes of P34/Gly m Bd 30K. METHODS: Serum IgE from 6 clinically sensitive soybean-allergic individuals was used to identify P34/Gly m Bd 30K in the native and single amino acid substituted peptides with use of the SPOTS peptide synthesis technique to determine critical amino acids required for IgE binding. RESULTS: The intensity of IgE binding and epitope recognition by serum IgE from the individuals varied substantially. With use of serum from 6 clinically soybean-sensitive individuals, 2 of the 5 immunodominant epitopes could be mutagenized to non-IgE binding peptides. CONCLUSIONS: Single-site amino acid substitution of the 5 immunodominant epitopes of Gly m Bd 30K with alanine revealed that IgE binding could be reduced or eliminated in epitopes 6 and 16 in the serum obtained from 6 soybean-sensitive patients.

Subnuclear distribution of the entire complement of linker histone variants in Arabidopsis thaliana.

Linker histones (e.g. H1, H5, H1 degrees ) are thought to exert control on chromatin function by restricting nucleosomal dynamics. All higher eukaryotes possess a diverse family of linker histones, which may exhibit functional specialization. Arabidopsis thaliana apparently contains a minimal complement of linker histone structural variants and therefore is an ideal model for investigating functional differentiation among linker histones. Histones H1-1 and H1-2 are relatively similar proteins that are expressed in a wide variety of tissues and make up the majority of linker histone while H1-3 is a highly divergent minor variant protein that is induced by drought stress. We are interested in determining whether the in vivo distribution of each of these proteins also differs. To this end, we have produced subtype-specific antibodies and have localized each of the three proteins at the intranuclear and DNA sequence levels by indirect immunofluorescence and immunoprecipitation, respectively. Antibodies against linker histones H1-1 and H1-2 decorate nuclei in patterns very similar to 4',6-diamidino-2-phenylindole (DAPI) staining, but different than the staining pattern of total histones. In contrast, antibodies made against two regions of H1-3 bind to chromatin in a diffuse pattern distinct from the DAPI-staining pattern. We also describe a technique to determine the localization of plant linker histone variants along regions of chromatin, employing in vivo chemical DNA-protein cross-linking to preserve native associations followed by immunoprecipitation with subtype-specific antibodies. We use this technique to demonstrate that, in contrast to the major linker histones, H1-3 does not bind the repetitive sequences pAL1 and 5S rDNA. In addition, we show that linker histones are bound to the compacted nucleosomal arrays at the telomere but with reduced stoichiometry. Taken together, our results suggest that plants, as has been shown for animals, possess a variant linker histone that is differentially localized.