Effects of Plant Nutrition on Susceptibility of Potato Leaves to Phytophthora infestans

A complete NPK fertilizer applied at planting, but not at later times, influenced the resistance of potato leaves to infection by Phytophthora infestans and the subsequent growth of lesions. Lesion size (7 days after inoculation) and lesion growth rate (between 7 and 9 days after inoculation) increased linearly with increasing fertilizer rates. Increasing rates of phosphate or potash, applied separately, did not significantly affect the development of blight lesions but a linear increase in lesion size was associated with increasing application rates of nitrogen.     

Susceptibility of potato tubers to infection by Phytophthora infestans

Phytophthora infestans infects King Edward potato tubers more readily through inoculated eyes than through lenticels, but more lenticels than eyes became infected when whole tubers were sprayed with inoculum. The resistance of lenticels but not of eyes increased as tubers aged. The spores did not infect through intact periderm. The likelihood of tubers on plants grown in pots becoming infected by sporangial suspension poured on to the soil increased the nearer the tubers were to the soil surface, the stem, or the side of the pot. Naturally infected tubers, and those sprayed with sporangial suspension, had most eyes infected at the rose end, and most lenticels infected on the middle region of the tuber. Of naturally infected tubers, on which the site of infection could be identified, most were infected through eyes at the rose end.     

The Plant Membrane-Associated REMORIN1.3 Accumulates in Discrete Perihaustorial Domains and Enhances Susceptibility to Phytophthora infestans

Filamentous pathogens such as the oomycete Phytophthora infestans infect plants by developing specialized structures termed haustoria inside the host cells. Haustoria are thought to enable the secretion of effector proteins into the plant cells. Haustorium biogenesis, therefore, is critical for pathogen accommodation in the host tissue. Haustoria are enveloped by a specialized host-derived membrane, the extrahaustorial membrane (EHM), which is distinct from the plant plasma membrane. The mechanisms underlying the biogenesis of the EHM are unknown. Remarkably, several plasma membrane-localized proteins are excluded from the EHM, but the remorin REM1.3 accumulates around P. infestans haustoria. Here, we used overexpression, colocalization with reporter proteins, and superresolution microscopy in cells infected by P. infestans to reveal discrete EHM domains labeled by REM1.3 and the P. infestans effector AVRblb2. Moreover, SYNAPTOTAGMIN1, another previously identified perihaustorial protein, localized to subdomains that are mainly not labeled by REM1.3 and AVRblb2. Functional characterization of REM1.3 revealed that it is a susceptibility factor that promotes infection by P. infestans. This activity, and REM1.3 recruitment to the EHM, require the REM1.3 membrane-binding domain. Our results implicate REM1.3 membrane microdomains in plant susceptibility to an oomycete pathogen.Filamentous plant pathogens, including oomycetes of the genus Phytophthora, downy mildews and white rusts, as well as powdery mildews and rust fungi, are among the most devastating plant pathogens. These biotrophic parasites associate closely with plant cells through specialized infection structures called haustoria. Haustoria are specialized pathogen hyphal structures formed within host cells and enveloped by a perimicrobial membrane called the extrahaustorial membrane (EHM), a key interface between plant pathogens and the host cell. Haustoria are critical for successful parasitic infection by many filamentous plant pathogens and are a signature of the biotrophic lifestyle. In fungi, haustoria function as feeding structures (Voegele et al., 2001). In addition, haustoria are thought to enable the delivery of host-translocated virulence proteins, known as effectors, by both fungal and oomycete pathogens (Catanzariti et al., 2006; Whisson et al., 2007). However, little is known about the molecular mechanisms underlying the biogenesis and function of haustoria and EHM (Kemen and Jones, 2012; Lu et al., 2012).The EHM is thought to be continuous with the host plasma membrane (PM), yet it is a highly specialized membrane compartment that develops only in plant cells that accommodate haustoria (haustoriated cells; Coffey and Wilson, 1983). On the plant side, all eight PM proteins tested by Koh et al. (2005) were excluded from the EHM in Arabidopsis (Arabidopsis thaliana) cells infected with the powdery mildew fungus Golovinomyces cichoracearum. Conversely, the atypical Arabidopsis resistance protein Resistance to Powdery Mildew8.2 (RPW8.2) exclusively localizes to the EHM in this interaction (Wang et al., 2009). Ultrastructure analyses of the Golovinomyces orontii powdery mildew pathosystem revealed that the EHM is asymmetric, thicker and more electron opaque than the PM, and can be highly convoluted around mature haustoria (Micali et al., 2011). More recently, a survey of Arabidopsis and Nicotiana benthamiana plants infected by the oomycete pathogens Hyaloperonospora arabidopsidis and Phytophthora infestans, respectively, revealed that several integral host PM proteins are excluded from the EHM (Lu et al., 2012). Nevertheless, the remorin REM1.3 and the SYNAPTOTAGMIN1 (SYT1) peripheral membrane proteins localized to undetermined subcellular compartments around haustoria in P. infestans-plant interactions (Lu et al., 2012). Whether the differential accumulation of membrane proteins at the EHM is due to interference with the lateral diffusion of proteins from the PM or targeted secretion of specialized vesicles remains unclear (Lu et al., 2012).The subcellular distribution of effectors inside plant cells provides valuable clues about the host cell compartments they modify to promote disease, and effectors have emerged as useful molecular probes for plant cell biology (Whisson et al., 2007; Bozkurt et al., 2012). Heterologous expression of fluorescently tagged effectors in plant cells has been used to determine their subcellular localization in uninfected and infected tissue. This approach has been successful with the RXLR and CRINKLER (CRN) effectors, the two major classes of cytoplasmic (host-translocated) oomycete effectors (Bozkurt et al., 2012). The 49 H. arabidopsidis RXLR effectors studied by Caillaud et al. (2012) localized to the nucleus, the cytoplasm, or various plant membrane compartments. In contrast, CRN effectors from several oomycete species exclusively accumulate in the plant cell nucleus (Schornack et al., 2010; Stam et al., 2013). The P. infestans effectors AVRblb2 and AVR2 accumulate around haustoria when expressed in infected N. benthamiana cells, highlighting the PM and the EHM as important sites for effector activity (Bozkurt et al., 2011; Saunders et al., 2012). These effectors, therefore, can serve as useful probes for plant cell biology to dissect vesicular trafficking and focal immunity, processes that have proved difficult to study using standard genetic approaches (Bozkurt et al., 2011; Win et al., 2012).REM1.3 is one of two plant membrane-associated proteins detected around haustoria during the interaction between P. infestans and the model plant N. benthamiana (Lu et al., 2012). Therefore, we hypothesized that studying REM1.3 should prove useful for understanding the mechanisms governing the function and formation of perihaustorial membranes. REM1.3 belongs to a diverse family of plant-specific proteins containing a Remorin_C domain (PF03763) and has known orthologs in potato (Solanum tuberosum; StREM1.3), tomato (Solanum lycopersicum; SlREM1.2), tobacco (Nicotiana tabacum; NtREM1.2), and Arabidopsis (AtREM1.1–AtREM1.4; Raffaele et al., 2007). Several proteins from the remorin family, including REM1.3, are preferentially associated with membrane rafts, nanometric sterol- and sphingolipid-rich domains in PMs (Pike, 2006; Simons and Gerl, 2010). Indeed, StREM1.3 and NtREM1.2 are highly enriched in detergent-insoluble membranes (DIMs) and form sterol-dependent domains of approximately 75 nm in purified PMs (Mongrand et al., 2004; Shahollari et al., 2004; Raffaele et al., 2009). StREM1.3 directly binds to the cytoplasmic leaflet of the PM through a C-terminal anchor domain (RemCA) that folds into a hairpin of aliphatic α-helices in polar environments (Raffaele et al., 2009; Perraki et al., 2012). StREM1.3 is differentially phosphorylated upon the perception of polygalacturonic acid (Reymond et al., 1996). AtREM1.3 is differentially recruited to DIMs and differentially phosphorylated upon flg22 (for flagellin) peptide perception (Benschop et al., 2007; Keinath et al., 2010; Marín et al., 2012), suggesting a role in plant defense signaling. StREM1.3 and SlREM1.2 prevent Potato virus X spreading by interacting with the Triple Gene Block protein1 (TGBp1) viral movement protein, presumably in plasmodesmata or at the PM (Raffaele et al., 2009; Perraki et al., 2012). AtREM1.2 belongs to protein complexes formed by a negative regulator of immune responses, Resistance to Pseudomonas syringae pv maculicola1 (RPM1)-INTERACTING PROTEIN4, at the PM (Liu et al., 2009). Furthermore, Medicago truncatula MtSYMREM1 is enriched in root cell DIMs (Lefebvre et al., 2007) and localizes to patches at the peribacteroid membrane during symbiosis with Sinorhizobium meliloti (Lefebvre et al., 2010). MtSYMREM1 is important for nodule formation and interacts with the Lysin motif domain–containing receptor-like kinase3 (LYK3) symbiotic receptor (Lefebvre et al., 2010). Multiple lines of evidence, therefore, implicate several remorins in cell surface signaling and the accommodation of microbes during plant-microbe interactions (Raffaele et al., 2007; Jarsch and Ott, 2011; Urbanus and Ott, 2012). Nevertheless, little is known about REM1.3’s molecular function, and its role in immunity against filamentous plant pathogens has not been reported to date.In this study, we analyzed in detail the localization and function of REM1.3 during host colonization by P. infestans. We found that REM1.3 localizes exclusively to the vicinity of the PM and the EHM around noncallosic haustoria. Furthermore, our results suggest that the EHM is likely formed by multiple microdomains. REM1.3 silencing and overexpression experiments demonstrated that it promotes susceptibility to P. infestans in N. benthamiana and tomato. We also show that the REM1.3 membrane anchor domain is required for its localization at the EHM and for the promotion of susceptibility to P. infestans. This work demonstrates the importance of the dynamic reorganization of the PM in response to haustoria-forming pathogens. Our study also revealed that the effector AVRblb2 localizes to remorin-containing host membrane domains at the host-pathogen interface, possibly as a pathogen strategy to facilitate the accommodation of infection structures inside plant cells.     

马铃薯种质资源的晚疫病抗性鉴定

采用离体叶片接种法,对43份马铃薯种质资源进行晚疫病抗性鉴定、比较和评价。以接种5 d后的感病品种‘Désirée’和抗病品种‘加湘1号’叶片症状为对照,鉴定出5份表现为高抗的种质资源,其中包含3个Solanum phurejia和2个S. tuberosum ssp. andigena材料。另外,还鉴定出14份中抗材料(No. 7～20)。结果表明,野生种和安第斯山栽培亚种马铃薯资源的抗性材料较为丰富,可作为晚疫病抗病育种的亲本。     

A Histological Evaluation of Induced Resistance to Phytophthora infestans (Mont.) de Bary in Potato Leaves

Systemically induced resistance against Phytophthora infestans in the potato cultivar ‘Bintje’ was studied histologically at the light microscopy level on the leaf surface, in the epidermis and in the mesophyll of challenged potato leaves. Systemic disease resistance was induced by a local pre-infection with the same fungus. On the leaf surface of induced plants, the germination of cysts was enhanced. In the epidermis of induced plants, papilla deposition increased and penetration decreased, whereas in the mesophyll of induced plants the spread of hyphae was reduced. It is suggested that the reduction of disease severity in induced plants is the result of the combined action of several successive defence reactions.     

Creation of a Metabolic Sink for Tryptophan Alters the Phenylpropanoid Pathway and the Susceptibility of Potato to Phytophthora infestans

The creation of artificial metabolic sinks in plants by genetic engineering of key branch points may have serious consequences for the metabolic pathways being modified. The introduction into potato of a gene encoding tryptophan decarboxylase (TDC) isolated from Catharanthus roseus drastically altered the balance of key substrate and product pools involved in the shikimate and phenylpropanoid pathways. Transgenic potato tubers expressing the TDC gene accumulated tryptamine, the immediate decarboxylation product of the TDC reaction. The redirection of tryptophan into tryptamine also resulted in a dramatic decrease in the levels of tryptophan, phenylalanine, and phenylalanine-derived phenolic compounds in transgenic tubers compared with nontransformed controls. In particular, wound-induced accumulation of chlorogenic acid, the major soluble phenolic ester in potato tubers, was found to be two- to threefold lower in transgenic tubers. Thus, the synthesis of polyphenolic compounds, such as lignin, was reduced due to the limited availability of phenolic monomers. Treatment of tuber discs with arachidonic acid, an elicitor of the defense response, led to a dramatic accumulation of soluble and cell wall-bound phenolics in tubers of untransformed potato plants but not in transgenic tubers. The transgenic tubers were also more susceptible to infection after inoculation with zoospores of Phytophthora infestans, which could be attributed to the modified cell wall of these plants. This study provides strong evidence that the synthesis and accumulation of phenolic compounds, including lignin, could be regulated by altering substrate availability through the introduction of a single gene outside the pathway involved in substrate supply. This study also indicates that phenolics, such as chlorogenic acid, play a critical role in defense responses of plants to fungal attack.     

Postinfectional Changes of Lipid Metabolism in Potato Tuber Resistant and Susceptible to Phytophthora infestans

The effect of Phytophthora infestans on the lipid content and composition as well as lipid acyl hydrolase activity in the potato tuber of two cultivars, Nysa – horizontal resistant and Bintje –susceptible were investigated. In the susceptible cultivar the infection resulted in: a qualitative changes in aminolipids, an increase in steroid content, an inconsiderable decrease in amount of glycolipids and a slight drop in FFA, no significant changes in composition of total, FA and slight loss in acyl hydrolase activity. The following changes were observed in the resistant cultivar: a considerable enhancement of steroid content (reached in about 400 %), a slight increase in amount of glycolipid, a rapid drop of acyl hydrolase activity and FFA content and a considerable increase in oleic acid level in total FA. In the response to both infection and aging in both cultivars no significant quantitative changes in lipid-phosphorus and sulfolipids were noted.     

Inoculation of Transgenic Resistant Potato by Phytophthora infestans Affects Host Plant Choice of a Generalist Moth

Pathogen attack and the plant’s response to this attack affect herbivore oviposition preference and larval performance. Introduction of major resistance genes against Phytophthora infestans (Rpi-genes), the cause of the devastating late blight disease, from wild Solanum species into potato changes the plant-pathogen interaction dynamics completely, but little is known about the effects on non-target organisms. Thus, we examined the effect of P. infestans itself and introduction of an Rpi-gene into the crop on host plant preference of the generalist insect herbivore, Spodoptera littoralis (Lepidoptera: Noctuidae). In two choice bioassays, S. littoralis preferred to oviposit on P. infestans-inoculated plants of both the susceptible potato (cv. Desiree) and an isogenic resistant clone (A01-22: cv. Desiree transformed with Rpi-blb1), when compared to uninoculated plants of the same genotype. Both cv. Desiree and clone A01-22 were equally preferred for oviposition by S. littoralis when uninoculated plants were used, while cv. Desiree received more eggs compared to the resistant clone when both were inoculated with the pathogen. No significant difference in larval and pupal weight was found between S. littoralis larvae reared on leaves of the susceptible potato plants inoculated or uninoculated with P. infestans. Thus, the herbivore’s host plant preference in this system was not directly associated with larval performance. The results indicate that the Rpi-blb1 based resistance in itself does not influence insect behavior, but that herbivore oviposition preference is affected by a change in the plant-microbe interaction.     

Tuber Blight Development in Potato Cultivars in Response to Different Genotypes of Phytophthora infestans

Migrations or introduction of new genotypes of Phytophthora infestans to a specific region imposes a different perspective for potato production. During 2009–2010, a late blight epidemic affected the Northeastern United States, which quickly spread through several states. The epidemic was characterized by the appearance of a new genotype of P. infestans designated US‐22, which was isolated from tomato and potato. Potato tubers are an essential component of late blight epidemics where the pathogen cannot overwinter on Solanaceous plants. Six potato cultivars were inoculated with 12 isolates of P. infestans (five different genotypes), including isolates of the genotype US‐22. Tuber blight development was characterized in terms of tissue darkening expressed as area under the disease progress curve values and lenticel infection. The responses indicated that US‐8 was more aggressive than US‐22, but US‐22 isolates obtained from potato were more aggressive on potato than those acquired from tomato. Tuber periderm responses to infection were limited, yet US‐8 isolates infected the periderm more often than US‐22 isolates. There were significant differences among the cultivars tested but cv. Jacqueline Lee was the most resistant overall. Although isolates of P. infestans genotype US‐22 were less aggressive in comparison with US‐8 isolates, US‐22 isolates still infected potato tubers and were as aggressive us US‐8 isolates on some cultivars. Management of late blight caused by isolates of US‐22 through host resistance may be feasible but imposes a different set of criteria for consideration from those that US‐8 imposed.     

The Irish Potato Famine Pathogen Phytophthora infestans Translocates the CRN8 Kinase into Host Plant Cells

Phytopathogenic oomycetes, such as Phytophthora infestans, secrete an arsenal of effector proteins that modulate plant innate immunity to enable infection. We describe CRN8, a host-translocated effector of P. infestans that has kinase activity in planta. CRN8 is a modular protein of the CRN effector family. The C-terminus of CRN8 localizes to the host nucleus and triggers cell death when the protein is expressed in planta. Cell death induction by CRN8 is dependent on its localization to the plant nucleus, which requires a functional nuclear localization signal (NLS). The C-terminal sequence of CRN8 has similarity to a serine/threonine RD kinase domain. We demonstrated that CRN8 is a functional RD kinase and that its auto-phosphorylation is dependent on an intact catalytic site. Co-immunoprecipitation experiments revealed that CRN8 forms a dimer or multimer. Heterologous expression of CRN8 in planta resulted in enhanced virulence by P. infestans. In contrast, in planta expression of the dominant-negative CRN8^R469A;D470A resulted in reduced P. infestans infection, further implicating CRN8 in virulence. Overall, our results indicate that similar to animal parasites, plant pathogens also translocate biochemically active kinase effectors inside host cells.     

Effect of Leaf Age and Nodal Position on Receptivity of Rice Leaves to Infection by Pyricularia grisea

The effect of leaf age and nodal position on leaf receptivity to rice blast, caused by Pyricularia grisea , was studied by inoculating potted Rosemont plants with blast pathogen race IC-17, isolate 92T107. at different growth stages. Regressioti equations were used to describe the effect ofleaf age (degree days > 10 C) and nodal position on lesion density, the relative frequency of lesion appearance, and the lesion area distribtition. The number of sporulating lesions per cm² of inoculated leaf area was highest for leaves inoculated early in their development and progressively lower for leaves inoculated later in their development. The average lesion density for less than 1-day-old leaves at nodal position 6 was about four times the density for 10-day-old leaves of the same nodal position. Lesion density was similar for leaves of less than 1-day-old from the 4th to the 7th nodal position, but dropped sharply from the 7th to the 11 th nodal position. The flag leaf was the least susceptible of all nodal positions. The average lesion density for young leaves of about 1-day-old at nodal position 6 was about 27 times the density for young flag leaves of the same age. The incubation period increased with leaf age. but was not obviously affected by leaf nodal position. Lesion area increased linearly with time, but was not affected by leaf age and nodal position. The results are of use for epidemiological investigations which rely on detailed quantitative leaf susceptibility data for accurate blast forecasts.     

利用抑制差减杂交技术分离马铃薯晚疫病抗性相关基因

以晚疫病病原菌混合小种接种处理48h的马铃薯水平抗性材料(R-gene-free)叶片为目的材料,以未处理材料作为对照,用抑制差减杂交技术构建了一个富集晚疫病抗性相关基因的差减文库。应用反向Northern技术对840个克隆进行斑点杂交筛选,筛选出150个病原诱导后信号明显增强的克隆。26个片段测序结果表明：部分片段基因功能与抗病性明显相关。7个差异表达片段与GenBank EST数据库中已有晚疫病原诱导马铃薯叶片得到的EST有很高同源性(达95％～100％);部分片段核苷酸或氨基酸序列分别与番茄、烟草、拟南芥等的EST序列或氨基酸序列有较高同源性;另有4个基因片段在GenBank EST数据库中未找到明显的同源序列,可能为新发现的基因片段。