Development and applicationof loop-mediated isothermal of Plasmopara viticola

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Xiangjiu Kong,*, Wentao Qin,*, Xiaoqing Huang, Fanfang Kong, Cor D. Schoen, Jie Feng, ZhongyueWang & Hao Zhang

basis of the ITS sequence of P. viticola P. viticola

latent infection of grape leaves by P. viticola level of sporangia released in the air in a certain period. This assay should make disease forecasting

Grape downy mildew, caused by Plasmopara viticola, is one of the most important diseases of grapes worldwide. During the growing season, the pathogen can infect all green parts of the vine whenever the weather is warm and wet. Aer years of extremely favorable environmental conditions, a yield reduction as much as 80% may be observed in vineyards if control procedures are not implemented1. Currently, the disease has caused a large bottleneck restricting the development of the grape industry2,3.

At present, chemical control is the most eective remedy for grape downy mildew. Vine growers usually prevent the disease by spraying fungicide any time they foresee favorable meteorological conditions for pathogen outbreak. Forecasting models have contributed to the abandonment of calendar-based spraying. However, these simulators oen alert growers to treat vines in the absence of infection, thus leading to the overuse of chemicals, environment pollution and a decrease in grape quality. Rapid and sensitive detection techniques for monitoring the presence and severity of infection would help growers to accept or disregard the alert of forecasting models and to apply chemicals with more accuracy and at a higher efficiency, without the risk of crop loss. Therefore, a rapid and low-cost detection method would be of great signicance to the scientic management of grape downy mildew.

Loop-mediated isothermal amplication (LAMP) is a novel molecular biological detection technology, that specically detects genomic DNA by using a set of six oligonucleotide primers specic to dierent regions of a target gene. This method has been widely applied in many elds for on-site detection because of its low cost, high specicity, efficiency, simplicity of operation, rapidness, and ability to be used in broad applications, such as disease diagnosis and food safety testing4.

Several applications of LAMP for the detection of fungal pathogens have been described to date. The detection of Fusarium graminearum has been described by Niessen and Vogela5. Tomlinson et al.6 have published a

State Key Laboratory for Biology of Plant Diseases and Insect Pests, Institute of Plant Protection, Chinese Academy of Agriculture Sciences, Beijing, China. * authors contributed equally to this work. Correspondence and requests for materials should be addressed to Z.W.

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Figure 1. Optimization of LAMP primers. (A) The assessment of primer sets was based on gel electrophoresis analysis of the LAMP products. (B) The position and orientation of the selected LAMP primers within the nucleotide sequence of the ITS region of P. viticola (GenBank accession no. DQ665668.1).

LAMP-based assay for the detection of the oomycete Phytophthora ramorum, which can cause sudden oak death disease. Most recently, Lu et al.7 have established a LAMP assay for the detection and identication of Fusarium oxysporum from soybeans. However, thus far, no attempt has been made to use LAMP for the detection of P. viticola.

In this study, we describe the development and application of a LAMP-based assay for the specic detection

of P. viticola in infected leaves and the airborne sporangia collected from a spore trap. The use of the visual colorimetric indicator hydroxy naphthol blue for the in-tube detection of DNA amplication as well as simplied methods for the preparation of ampliable target DNA is demonstrated and may widely improve disease management in the grape industry by allowing the pathogen to be monitored and making analyses easier and more cost eective.

Results

The P. viticola ITS sequence (DQ665668.1) was chosen as the target region for the LAMP primers. Its full length is 2,337 bp, and it has an overall GC content of 43.3%. The 565-bp fragment (position 694 to 1258) of P. viticola was selected as the target sequence for LAMP primer design. Primer design was performed by using the online tool Primer Explorer version 4.0 (http://primerexplorer.jp/ elamp4.0.0/index.html). All of the parameters were set by default. Twelve primer sets were screened, and two of them showed typical ladder-like DNA fragments on an agarose gel (Fig.1A). For primer set 12, a loop primer was developed to accelerate the LAMP reaction. The positions of the primers within the ITS sequence are shown in Fig.1B. On the basis of the alignment of the cox2 gene of Plasmopara viticola (DQ365760), Plasmopara halstedii (EU743813), Plasmopara obducens (DQ365757), Peronospora belbahrii (FJ394342) and Peronospora elsholtziae (FJ527435), a specic primer pair for P. viticola was developed; the predicted size of the PCR product was 591bp. The sequence of the LAMP and conventional PCR primers are listed in Table1.

To validate the expected amplication products, LAMP products were digested with the restriction enzyme Hinf I or Ase I. The restriction sites for Hinf I and Ase I, as well as the sizes of the restriction fragments, are shown in Fig.2A. Aer Ase I digestion, only one band was observed because of the similar sizes of the two fragments (135bp and 138bp). For Hinf I digestion, the anticipated 177bp and 96bp bands were clearly observed on an agarose gel (Fig.2B). To further conrm the specicity of the LAMP products, the plasmid pMD228 was sequenced, and the results showed that the 228-bp target fragment was 100% homologous to the ITS sequence used for the primer design. These results indicated that the LAMP products were specically amplied from the ITS target region in P. viticola.

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Primer Sequence (53)

LAMP

FIP GAAGCCAACCATACCGCAAATCGGCGACCAATTTATTTGCTGTTG BIP GAATCGGTGAACCGTAGCTATATGTAAGCTGCCACTCTACTTCG F3 GTTTGTCTATTGTGGCCAGTCB3 CCAAATGGATCGACCCTCGLB GACTATGCTTTCAATCAGTTT

PCR Pv-cox2F CAAGATCCAGCAACTCCAGTTATGGA

Pv-cox2R ACATTGTCCATAAAAAACACCTTCTC

Table 1. Sequences of LAMP and conventional PCR primers for P. viticola.

Figure 2. Restriction enzyme digestion of the positive LAMP products. (A) Schematic representation of the anticipated restricted DNA products. B+, B, F+, F,+ and-in the rst row represent the same regions described by Notomi (Notomi et al.4). (B) LAMP products were digested with Ase I and Hinf I, and the fragments were observed by 2.0% agarose gel electrophoresis.

P. viticola. The specicity of the LAMP primer set for the detection of P. viticola was analyzed by using DNA from the 38 strains listed in Table2. The strains tested belonged to 25 genera, including 8 species within Peronosporales and 9 common grape pathogens. A positive sample was indicated by a sky-blue color and a ladder-like pattern on an agarose gel, whereas a negative sample remained a violet color. The sky-blue color and ladder-like pattern of bands were generated solely with the DNA of P. viticola. Neither species within Plasmopara nor those from other genera showed positive results under the same conditions (Fig.3). This result indicated that the primer set can be used to specically detect P. viticola. Conventional PCR with specic primers (Pv-cox2 F/R) also showed good specicity, and the target fragment was amplied with only the DNA of P. viticola.

P. viticola. Ten-fold serial dilutions of puried genomic DNA were used to evaluate the sensitivity of the method. The ladder-like pattern of bands and sky-blue color were observed from 3.3ng to 33 fg per reaction, indicating that the detection limit was 33 fg of genomic DNA. For conventional PCR, a weak 591-bp fragment was amplied when the template DNA was diluted to 3.3 pg (Fig.4). Thus, for puried DNA, LAMP was at least 100 fold more sensitive than conventional PCR.

Sensitivity was also tested on articially inoculated grape leaves. The pathogen could be detected at 4 dpi using the LAMP assay. However, for conventional PCR, positive results were not observed until 6 dpi. These ndings indicated that our LAMP assay is able to detect latent infection 2 days earlier than conventional PCR under the culture conditions in a laboratory setting.

P. viticola-infected grape leaves. LAMP and conventional PCR were performed on 150 grape leaf samples including the main varieties and grape-producing areas in China. LAMP and PCR were both positive for samples No. 1~78, on which white mildew was observed (Table S1). However, for the leaves without visible symptoms (No. 79~150), LAMP (47/72, 65.2%) scored signicantly more samples positive compared with conventional PCR (16/72, 22.2%) (Fig.5, Table S1), thus indicating that LAMP is more

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Number Latin name Host Source LAMP PCR

1 Plasmopara viticola Grape China + +2 Plasmopara halstedii Sunower Germany 3 Plasmopara sp. Creeper Germany 4 Plasmopara halstedii Sunower France 5 Plasmopara angustiterminalis Cocklebur China 6 Peronospora farinosa Goosefoot China 7 Phytophthora capsici Chili China 8 Phytophthora boehmeriae Cotton China 9 Pythium sp. Asparagus China 10 Coniella diplodiella Grape China 11 Botrytis cinerea Grape China 12 Botryosphaeria rhodina Grape China 13 Botryosphaeria dothidea Grape China 14 Uncinula necator Grape China 15 Colletotrichum gloeosporioides Grape China 16 Pestalotia mangiferae Grape China 17 Guignaridia bidwellii Grape China 18 Cryptosporella viticola Grape China 19 Alternaria alternata Tobacco China 20 Phyricularia grisea Rice China 21 Fusarium oxysporum Cotton China 22 Fulvia fulva Tomato China 23 Exserohilum turcicum Maize China 24 Bipolaris maydis Maize China 25 Fusarium graminearum Wheat China 26 Botryospuaeria berengeriana Apple China 27 Botrytis cinerea Tomato China 28 Valsa mali Apple China 29 Puccinia striiformis Wheat China 30 Botryosphaeria ribis Poplar China 31 Rhizoctonia solani Cotton China 32 Fusarium sp. Apple China 33 Blumeria graminis Wheat China 34 Ceratobasidium cornigerum Wheat China 35 Puccinia triticina Wheat China 36 Botrytis cinerea Berry China 37 Phaeosphaeria nodorum Wheat China 38 Penicillium digitatum Orange China

Table 2. Strains used for the specicity validation of LAMP and conventional PCR primers.

sensitive than conventional PCR for the detection of the latent infection of P. viticola in grape leaves. All of the non-infected samples tested showed negative results.

We investigated both the daily airborne sporangia and the increased numbers of diseased leaves for 40 consecutive days. P. viticola sporangia were rst detected on July 6, and the number increased slowly until August 5, when a sharp increase was observed aer the third rainfall period. The number of diseased leaves, monitored daily, showed a similar trend (Fig.6). The LAMP assay was performed on all of the air samples. When the amount of sporangia was less than 20 (14 samples), only one sample was positive (7.1%). When the number was between 20 and 100, more positive samples were scored (66.7%; 8/12). All of the samples with more than 100 sporangia were positive. For conventional PCR, only the samples with more than 100 sporangia were scored positive, thus indicating that PCR is less sensitive than LAMP.

Discussion

The specic detection of pathogens is very important for disease prediction and control. Many rapid molecular detection methods for plant pathogens have been reported. For example, Zeng et al.8 have developed a nested PCR method to detect the latent infection of wheat leaves by Blumeria graminis f. sp. tritici. Luminex technology is available to detect more than 20 Fusarium species that cause Fusarium head blight of wheat and barley9. However, no species-specic detection method for P. viticola has been reported previously. Valsesia et al.1 have developed a quantitative real-time PCR assay to detect the amount of P. viticola DNA in leaves treated with potential antagonists and infected with the pathogen. Whether this test can be used for the detection of P. viticola under eld conditions is

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Figure 3. Specicity of LAMP detection vs. conventional PCR. The number of isolates is identical to that in Table2, and No. 39 is the negative control.

Figure 4. Sensitivity of LAMP vs. conventional PCR. (A) Sensitivity on puried DNA of P. viticola. M, 100-bp DNA Ladder; 1, 3.3ng; 2, 330 pg; 3, 33 pg; 4, 3.3 pg; 5, 330 fg; 6, 33 fg; 7, 3.3 fg; 8, negative control. (B) Sensitivity on articially infected grape leaves. M, 100-bp DNA ladder; 1, 1 dpi; 2, 2 dpi; 3, 3 dpi; 4, 4 dpi; 5, 5 dpi; 6, 6 dpi; 7, 7 dpi; 8, 8 dpi; 9, negative control.

unknown because no specicity test of this method on dierent Plasmopara species has been reported. Most rapid and high-throughput detection methods require sensitive and expensive equipment and reagents, such as real-time

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Figure 5. Application of LAMP and conventional PCR on grape leaves without visible symptoms. The number of samples is identical to that in Table S1. N; negative control.

PCR and Luminex. LAMP is a novel nucleic acid amplication technique that amplies with high specicity, sensitivity and speed under isothermal conditions. It does not require expensive instrumentation and is therefore more suitable for local on-site detection. Downy mildew is one of the most important grape diseases worldwide. Because of the wide distribution of vineyards in China, regional disease forecasting based on the amount of pathogen and climate is needed. This work was undertaken by Plant Protection Stations in various counties. However, expensive machines, such as real-time PCR equipment, are not currently available in most counties. Therefore, the low-cost LAMP technique is suitable for eld application in China. In this study, we developed a highly practical and valid method for the detection of P. viticola, which is the causal agent of grape downy mildew. To the best of our knowledge, this is the rst report on the application of the LAMP assay to monitor airborne plant pathogens.

On the basis of the ITS sequence, twelve primer sets were designed and tested. No. 12 was selected because of the high specicity and amplication efficiency. With restriction endonuclease proling and sequencing of the product, we validated the specicity of this primer set for the target region in ITS. In this study, one LoopB primer was developed to accelerate the LAMP reaction described by Nagamine et al.10. The reaction time was signicantly shortened from one hour to half an hour, thereby improving the efficiency of detection.

LAMP is suitable for on-site detection in the eld because of its rapidity and robustness, and it does not require elaborate laboratory equipment. For better visibility of the reaction result, a DNA intercalating dye, such as SYBR green11,12, Picogreen13,14, or propidium iodide11, is added to the solution when the reaction is completed. However, owing to the massive amount of amplication product generated during the reaction, cross contamination with the amplicon from preceding reactions is a major problem that can be circumvented only when the reaction tubes stay unopened aer the reaction is nished. Therefore, during the current study, we used a colorimetric assay for LAMP detection by adding HNB as an indirect indicator. Because HNB does not react with the resulting DNA because the color change is dependent on the chelation of Mg2+ ions by dNTPs, this indicator can be added before the LAMP reaction15. HNB is also superior to calcein, another common pre-added dye16, because it produces a more pronounced color change that does not require uorescence excitation equipment for detection. In the LAMP assay, FIP and BIP primers, which are critical for specicity, hybridize to four binding sites, and the reaction is highly specic. In this study, a set of fungal and oomycete species tested comprised most of the pathogens commonly prevalent on grapes in the eld and the closest species within Plasmopara. The result indicated that this LAMP assay is highly specic for P. viticola and also showed higher sensitivity on both puried DNA and articially infected leaves than that of conventional PCR. This methodology therefore has great potential for the detection of latent infection on leaves and airborne sporangia.

Because of its high sensitivity, LAMP has been widely used for the early detection of latent infection of clinical17,18

and agricultural pathogens19. To evaluate the possible application of the LAMP assay on infected grape leaves, we tested this method on a collection from 34 counties in 22 dierent provinces covering all of the main grape-producing areas in China. The crude DNA, including the pathogen, host and other microbes on the surface, was extracted and used as a template. Positive results for all of the leaves from dierent varieties and geographical regions with apparent symptoms revealed that this method can be used under eld conditions. Usually, infection by pathogens does not immediately lead to a disease, and the pathogens can remain latent for a period of time and not produce symptoms until favorable conditions occur. These infected leaves may produce sporangia that serve as an initial inoculum to infect the healthy leaves. However, under unfavorable conditions, such a latent phase can last for a long period of time before symptoms appear. Therefore, an accurate estimation of the levels of latent infection on grape leaves can provide critical information to predict possible disease development in the eld. To evaluate the efficiency of this method in the detection of latent infection in P. viticola, we compared LAMP and conventional PCR on 72 grape leaves without visible symptoms. The results showed that the detection level of LAMP (65.2%) was nearly threefold higher than that of PCR (22.2%). This result revealed that LAMP is more suitable to estimate the latent infection rate of grape leaves by P. viticola. It may be helpful in deciding when the fungicide should be applied and when to reduce the number of fungicide applications to the minimum necessary level. In this study, a rapid and simple method was used to extract crude DNA from the leaf samples within 15minutes. When this method with the LAMP procedure, the total detecting time was shortened to about one hour. The entire detection process requires no equipment other than a water bath, and this method is highly suitable for the on-site detection of latent infection in the eld.

Inoculum levels and weather conditions are usually important factors in disease forecasting20. Regarding the monitoring of airborne spores, inoculum-based forecasting schemes have been developed and applied on cucurbit downy mildew (http://cdm.ipmpipe.org/) and soybean rust (http://www.ces.ncsu.edu/depts/pp/soybeanrust/) in the USA. The current understanding of the epidemiology of P. viticola suggests that there are two infectious stages in the life cycle. Oospores cause primary infections, and the airborne sporangia released from primary infected leaves are thought to be a secondary inoculum. It has been reported that this secondary inoculum of P. viticola is important to the epidemic of grapevine downy mildew21. Several disease-forecasting schemes have

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Figure 6. Application of LAMP in the monitoring of airborne sporangia in the eld. Asterisks on the dierent columns represent the positive results of LAMP. The rst tube and corresponding region in the agarose gel represent the negative control.

been developed to aid in control of grape downy mildew in dierent countries. These schemes are based primarily on weather conditions conducive to oospore formation, infection and sporangia release2224. However, disease would not develop under suitable weather conditions with insufficient inoculum. In this study, we found the disease severity to be strongly associated with airborne sporangia. During this period, there were three rainfall periods recorded, and the number of sporangia in the air increased to a higher level aer each rainfall. The rst two rainfall periods did not lead to a disease epidemic because there were insufficient sporangia (Fig.6). This nding revealed the importance of airborne sporangia in addition to the weather in forecasting grape downy mildew epidemics. Traditionally, tape containing air samples on the surface is analyzed under a microscope, and the particles of interest is identied and counted. However, it is difficult to dierentiate the sporangia of P. viticola from other spores. The LAMP method developed in this study is highly specic to P. viticola and simple to perform. Additionally, many tape samples, representing units of time (days or hours), can be tested at one time by one technician; therefore, the LAMP process is much more efficient than counting tape samples one by one under a microscope. LAMP applied to dierent air samples showed that 66.7% of the samples contained between 20 and 100 sporangia, covering the 21 days before disease outbreak. Before the rst rainfall, all of the daily samples were negative, and between the rst and second rainfall, only one of six samples was positive; disease did not develop on the leaves thereaer. However, between the second and third rainfall, six of twelve days showed positive results corresponding to the amount of sporangia and the sharply daily increased amount of diseased leaves. This result indicates that the high levels of sporangia in the air and high humidity could result in the outbreak of the disease. On the basis of the results above, considering the estimation of airborne sporangia levels, as determined by LAMP, together with weather conditions will be helpful for decision-making in eorts to control grape downy mildew and to apply chemicals more sparingly, without incurring a risk of yield and quality loss.

Strains used in this study. The P. viticola strains were isolated from diseased grape leaves from Langfang, Hebei Province. A single sporangiophore was picked up and placed on the underside of a healthy grape leaf disc (2 cm in diameter), which was surface sterilized with 70% ethanol and washed with double distilled water. The inoculated leaf disc was placed on water-agar medium in a Petri dish to keep the leaf wet, and the leaves were incubated at 21C for 16h in daylight and 8h at night and 100% humidity. When white mildew was observed, the sporangias were transferred to other leaf discs for propagation. Sporangia and sporangiophores were collected from the leaf discs and stored in liquid nitrogen.

Another 37 reference strains were also used for the specicity validation of P. viticola LAMP and conventional PCR assay. The reference strains belonged to 25 genera, in which there were 8 species within Peronosporales and 9 common grape pathogens. Detailed information, including geographical origin and hosts, is listed in Table2.

For specicity validation, the pure DNA of P. viticola was isolated. Approximately 20mg of sporangia and sporangiophores were frozen by liquid nitrogen and then were disrupted using a MiniBeadbeater (Biospec, USA). DNA was extracted according to the CTAB protocol described by Mller et al.25.

A rapid and simple DNA extraction method26 was used for DNA preparation from the grape leaf samples. Briey, a small piece of grape leaf with or without symptoms (approximately 50~100 mg) was transferred to a PCR tube, 50L of freshly made buer A (100mM NaOH, 2% Tween 20) was added, the mixture was incubated for 10min at 95 C, 50 L of buer B as added (100 mM Tris-HCl, 2 mM EDTA, pH approximately 2.0), and the samples were mixed at a moderate speed. Finally, 2.5L of the solution was used directly as the DNA template for the LAMP and conventional PCR assay.

The DNA of air samples collected by the spore trap were prepared according to the method described by Rogers et al.27. Sporangia-coated tape sections were placed into 2-mL screw-top tubes, and then 60 L of

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MicroLYSIS (Microzone) combined with 0.1 g of 500-m-diameter glass beads (Biospec, USA) was added and shaken in FastPrep-24 (MP Biomedicals) for 20 s at 4m s1. The liquid was transferred to PCR tubes and placed in a thermal cycler. The cycling prole was 65C for 15min, 96C for 2min, 65C for 4min, 96C for 1min, 65C for 1 min, 96 C for 30 s, and a hold at 20 C. Additionally, 2 mg of polyvinylpyrrolidone and 40 L of TE buer were added, vortexed and centrifuged to remove polysaccharides. A 60-L portion of the supernatant was transferred to a new PCR tube, and an ethanol precipitation step was performed. Aer resuspension of the pellet in 10L of H2O, 2.5L of DNA was used as the template per reaction.

With some small modifications, LAMP of P. viticola DNA was accomplished as described by Tomita et al.16. Briey, 25 L of the LAMP reaction mixture contained 1.4 M each of the FIP and BIP primers, 0.2M each of the F3 and B3 primers, 0.8 M of the LB primer, 8 U of Bst DNA polymerase (New England Biolabs) and 2.5L of 10 ThermoPol Reaction buer (including 20mM MgSO4), 0.8M betaine, 6mM

MgSO4, 1.4 mM each of dNTPs, 120 M hydroxy naphthol blue (HNB) and 2.5 L of template DNA. The same reaction mixture with 2.5L of double distilled water instead of the DNA template was used as the negative control. Reaction tubes were placed in a Veriti 96-Well Thermal Cycler (ABI, USA) operated at a constant temperature of 65C for 30min. The reactions were stopped by heat denaturation of the Bst DNA polymerase for 2min at 80C.

Conventional PCR was performed using the P. viticola-specic primers (Pv-cox2F/R). The reaction mixture (20L) contained 2.5L of DNA template, 0.5M of each primer, 10L of 2 PCR Mix (Guangzhou Dongsheng), and 5.5L of double-distilled water. The thermal cycler (Veriti 96-Well Thermal Cycler, ABI) was programmed as follows: 95C for 5min, followed by 35 cycles of 95C for 30 s, 50C for 30 s and 72C for 40 s, and nally 72C for 7min. The PCR products were electrophoresed on 1% agarose gels.

To conrm that the LAMP products originated from the correct target fragment, restriction enzyme digestion and sequencing were performed. The LAMP products were digested with the restriction enzymes Ase I and Hinf I (New England Biolabs) according to the operating instructions. The digested LAMP products were electrophoresed on a 2% agarose gel. Using the F3 and B3 primers, the 228-bp fragment was amplied by PCR and cloned into pMD19-T (Takara, Japan) to create pMD228 for sequencing.

Aer selection of the optimal primer set, the spec-icity of LAMP was tested with pure genomic DNA of P. viticola and DNA from 37 other reference strains (Table S1). The LAMP and conventional PCR assay were performed and evaluated as described in the previous section.

The specicity of the LAMP reaction was also tested with articially inoculated grape leaves. Fiy microliters of sporangia suspension (104 sporangia mL1) was coated on the water-agar plate. A small piece of water-agar including one sporangia was cut under the microscope and was transferred to a surface-sterilized healthy leaf. The inoculated leaves were placed on water-agar medium in a Petri dish to keep the leaf wet and were incubated at 21C, for 16h in daylight and 8h at night and 100% humidity. Three leaves were sampled daily until eight days post inoculation (The symptoms could be observed at 7 dpi). Crude DNA extractions were performed from these samples and were analyzed with LAMP and conventional PCR.

The sensitivities of the LAMP assay and conventional PCR were compared using ten-fold serial dilutions of the genomic DNA of P. viticola as the template. The initial genomic DNA concentration was 3.3ng/L. The LAMP results were visualized by the HNB staining method and were reconrmed by gel electrophoresis.

P. viticola-infected grape leaves. One hundred y grape leaf samples comprising 35 varieties were collected from 34 counties in 22 provinces covering all of the main grape-producing areas in China. White mildew on the underside of the leaves was observed in seventy-eight samples (No. 1~78), indicating natural infection by P. viticola (Table S1). The other seventy-two samples (No. 79~150) were also collected during the disease period; however, no visible symptoms were observed. To validate the applicable scope of the LAMP assay on naturally infected tissues, LAMP and conventional PCR were both performed on all 150 grape leaf samples, and the results were compared (Table S1). Several leaves with no visible symptoms were placed on water-agar medium and were incubated under the condition mentioned above. Usually, if the leaves were infected by P. viticola, white mildew was observed within 7 days. Therefore, aer 9 days, leaves with no symptoms were regarded as non-infected samples. One sample from each county was selected as the negative control.

Air samples were taken from a 7-day continuously recording spore sampler (Burkard, UK) operating outdoors according to the standard method reported by Lacey & West28. The eld air sampling site was at a vineyard in Changli, Hebei Province with an acreage of 2 ha. The air samples were collected for 40 consecutive days during the period from 1/7/2012 to 9/8/2012. During this period, 100 grape plants were selected randomly, and the number of diseased leaves was investigated and recorded daily. Samples from the operational spore traps were counted daily with a microscope and were used for DNA extraction described above. The DNA was identied by both LAMP and conventional PCR.

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This research project was supported by the special fund for agro-scientific research in the public interest (201203035) and the special fund of the China Agricultural Research System (nycytx-30). We thank the comprehensive test stations of the China Agricultural Research System for providing the eld samples. We also thank Dr. Aleksandra Bulajic, Dr. Renaud IOOS, Dr. Tim Schubert, Dr. Otmar Spring and Professor Li Xinghong for providing reference strains or their DNA.

Conceived and designed the experiments: H.Z., J.F. and Z.W. Performed the experiments: W.Q., X.K., X.H., F.K. and H.Z. Analyzed the data: W.Q., X.K., C.D.S. and H.Z. Wrote the paper: C.D.S. and H.Z. Revised and approved the nal version of the paper: C.S. and H.Z.

Supplementary information accompanies this paper at http://www.nature.com/srep

Competing nancial interests: Co-author Cor D. Schoen is employed by a commercial company (Plant Research International).

How to cite this article: Qin, W. et al. Development and application of loop-mediated isothermal amplication (LAMP) for detection of Plasmopara viticola. Sci. Rep. 6, 28935; doi: 10.1038/srep28935 (2016).

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