Abstract
We demonstrate temporal-, spatial- and temperature-dependent expression of five host microRNAs and target mRNAs in potato leaves after potato virus Y (PVY) inoculation. A novel gene, Ny-DG, conferring resistance to PVY was mapped on chromosome IX in the diploid potato clone DG 81-68. At 20 °C, the PVYNTN strain was localized in the inoculated leaves without symptoms. At 28 °C, necrotic lesions were observed in both the inoculated leaves and the non-inoculated upper leaves and the virus spread systemically, which indicates overcoming the resistance. At 0.5 h post-inoculation and 3-day post-inoculation (dpi), PVY led to significant changes in the levels of the tested miRNAs and their targets only in a small number of cases. At 6 dpi, in the inoculated leaves at 28 °C, the increased expression of stu-miR162, stu-miR168a and stu-miR482 (PotatoMir1005353123_x15854) promoted the downregulation of their targets DCL1, AGO1-2 and Cc-nbs-lrr, respectively. The expression of stu-miR482 (PotatoMir1005658171_x16170) and stu-miR172e remained unchanged, whereas their targets Gpa2 and TOE3 were downregulated. However, in the inoculated leaves at 20 °C, all five tested miRNAs and their targets showed parallel downregulation. In the non-inoculated upper leaves, changes in gene expression levels, namely downregulation, were only detected for the tested five miRNAs at 28 °C. We conclude that the expression patterns of the tested miRNAs and targets were altered differently not only at different time points post-inoculation but also in the inoculated and upper leaves, and their accumulation levels were related to the type of reaction, which in turn was dependent on temperature.
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Introduction
The hypersensitive response (HR) and extreme resistance (ER) are the most common defence mechanisms against viral infections in plants. HR-mediated resistance is a programmed cell death response, which leads to effective pathogen restriction in the infected cells or cells adjacent to them and is associated with necrotic lesion generation at the infection sites. ER fails in virus replication at the individual cell level and plants remain symptomless (Kang et al. 2005; de Ronde et al. 2014). The phenomenon of cells dying can also be observed in compatible plant-pathogen interactions and is known as necrosis (Hinrichs-Berger et al. 1999). HR is often temperature-dependent (Zhu et al. 2010). In the leaves of Xanthi-nc tobacco (Nicotiana tabacum L.) of plants possessing the N gene, HR was induced after tobacco mosaic virus (TMV) infection at 20 °C. At 28 °C, the resistance was overcome and tissue necrosis did not develop (Király et al. 2008). The HR-type resistance elicited in the leaves of Nicotiana species by oat dwarf virus (ODV) was suppressed at temperatures above 30 °C (Qian et al. 2016). The HR to the potato virus Y (PVY) strain PVYN in Solanum sparsipilum and Solanum sucrense as well as the HR against the strain PVYO in the potato (Solanum tuberosum L.) cultivar Pito was efficiently expressed at temperatures from 6 to18 °C as indicated by the development of necrosis at the infection sites and/or systemically (Valkonen 1997). However, at higher temperatures (19/24 °C), only leaf drop and mosaic symptoms developed (Valkonen 1997). The temperature-dependent HR to PVYO was also observed in potato cv. Exploits (Nie et al. 2015). The mechanism by which temperature influences the outcome of HR remains to be elucidated (Valkonen 2015).
We previously reported the first temperature-dependent hypersensitivity gene, Ny-1, in potato cv. Rywal. This gene confers HR to both PVYO and PVYN strains of PVY at 20 °C; however, the resistance was overcome at 28 °C and the plants were systemically infected but no symptoms were observed (Szajko et al. 2008). In another study from our group, a temperature-independent but strain type–dependent HR was demonstrated in potato cv. Etola, whereas HR resistance to PVYNTN isolate PVY-3202 and necrotic reaction to PVYZ-NTN isolate PVY-3303 and PVYN-Wi isolate PVY-3411 were observed at temperatures ranging from 20 to 28 °C (Yin et al. 2017). Recently, in a preliminary study from our group, we found a different type of temperature-dependent potato-PVY interaction in a diploid potato clone DG 81-68. At the phenotype level, in contrast to the cv. Rywal, it exhibits a symptomless resistance to PVYNTN at 20 °C and overcomes the resistance and development of necrotic lesions in both the inoculated leaves and the non-inoculated upper leaves at 28 °C. At the genotype level, DG 81-68 represents the temperature-dependent resistance to PVY, which we have found in other potato cultivars besides cv. Rywal, for example, the genes Ny-1A and Ny-1S in cvs. Albatros and Sekwana, respectively (Szajko et al. 2014). In our study, we suggested the putative resistance gene might be carried by DG 81-68 as Ny-DG. Given its novel reaction type towards PVY, we have chosen this diploid potato clone DG 81-68 for further research, for example, in respect to miRNA expression study.
Plant miRNAs are small endogenous non-coding RNAs that post-transcriptionally regulate gene expression by targeting specific mRNA for cleavage or translational inhibition (Bartel 2004; Voinnet 2009); they play essential roles in plant development and responses to biotic and abiotic stresses (Ruiz-Ferrer and Voinnet 2009; Khraiwesh et al. 2012; Ramesh et al. 2014; Yin et al. 2014). Certain miRNAs are involved in antiviral immunity by regulating resistance (R) genes that encode proteins containing nucleotide binding (NB) and leucine-rich repeat (LRR) domains (Li et al. 2012; Shivaprasad et al. 2012; Permar et al. 2014; Chen et al. 2016a, b). Previously, we showed that a set of potato miRNAs and targets was altered in cv. Etola plants displaying partial HR and severe symptoms after infection with the PVYN-Wi isolate but not in plants presenting HR resistance to the PVYNTN isolate or in plants displaying partial HR and necrosis to PVYZ-NTN (Yin et al. 2017). Later on, these three PVY isolates were used to inoculate tobacco (cv. Samsun) plants and to study miRNA expression in PVY-tobacco interaction (Yin et al. 2019). The abundance of the majority of tested tobacco miRNAs and targets was increased upon infection by PVYNTN and PVYN-Wi isolates, which induced severe symptoms (Yin et al. 2019). Our findings indicated that the tested potato and tobacco miRNAs and their targets responded to PVY challenge (Yin et al. 2017, 2019); and the alteration patterns of these PVY-responsive miRNAs were host- and strain-dependent and may relate to symptom severity in PVY-host interaction.
In this study, we have two objectives. First, it is to demonstrate the chromosome location of the putative gene Ny-DG in the diploid potato clone DG 81-68, which exhibits a symptomless resistance to PVYNTN at 20 °C and overcomes the resistance and development of necrotic lesions in both the inoculated leaves and the non-inoculated upper leaves at 28 °C. Second, it is to test how the selected PVY-responsive potato miRNAs (i.e. stu-miR162, stu-miR168a, stu-miR172e and two members of stu-miR482) and their putative target mRNAs (i.e. DCL1, AGO1-2, TOE3, Gpa2 and Cc-nbs-lrr) would express in the DG 81-68 plants showing temperature-dependent response to PVY. We report for the first time the accumulation of miRNAs and target mRNAs in both the inoculated leaves and the non-inoculated upper leaves of a diploid potato inoculated with PVYNTN in temperature-dependent reactions. The expression of five miRNAs and the corresponding putative target mRNAs were analysed based on their predicted function according to Xie et al. (2011) and Zhang et al. (2013). Amongst them, stu-miR162, stu-miR168a and their targets are supposed to be involved in miRNA biogenesis, plant development and stress responses. Stu-miR172e and its target TOE3 are supposed to be involved in the development, defence response to virus, fungus and bacterium and response to heat. Stu-miR482 and its targets have been shown to be involved in defence response, incompatible interaction and plant-type HR. In addition, these five pairs were chosen because they are PVY-responsive and their expression was altered in potato cv. Etola challenged by PVY as shown in our previous work (Yin et al. 2017).
Materials and Methods
Plant Material
Diploid potato (Solanum tuberosum L., 2n = 2x = 24) parental clones DG 81-68 and DW 83-3121 were crossed. The progeny consisted of 114 F1 individuals. The female parent DG 81-68 was resistant to PVY and had the pedigree described in Zimnoch-Guzowska et al. (2000). The PVY-susceptible male parent DW 83-3121 was derived from inter-crossing S. tuberosum with wild potato species. Potato breeding clone PW 363 and potato cv. Rywal were used as controls carrying the gene Ry-fsto for ER resistance (Flis et al. 2005) and Ny-1 for HR resistance (Szajko et al. 2008) to PVY inoculation, respectively.
PVY Inoculation at 20 and 28 °C and Collection of Leaf Samples
The PVYNTN isolate 12-94 (GenBank: AJ889866.1) obtained from the IHAR-PIB Młochów virus collection was used. A sap extract (using autoclaved distilled water as the extraction buffer) from the plants of tobacco cv. Samsun infected with PVYNTN was used as the inoculum. Plants of the diploid potato clone DG 81-68 in the 6–7 leaf stage were used for mechanical inoculation. For each plant, infectious leaf sap was applied to the lower three leaves and lightly sprinkled with carborundum powder; these lower three leaves were referred to as the inoculated leaves in this study. The leaves above these three inoculated leaves were referred to as the non-inoculated upper leaves. For each plant, small pieces of the three inoculated leaves, as well as small pieces of the three non-inoculated upper leaves, were sampled at 0.5 h post-inoculation (hpi) and at 3- and 6-day post-inoculation (dpi). Samples were stored at − 80 °C for RNA extraction.
The mechanically inoculated potato plants were divided into two groups; one group was incubated at 20 °C, the other at 28 °C, in the growth chambers under controlled environmental conditions (16 h light at 100 mol/s/m2, 8 h dark). Mock-inoculated (inoculation with water) plants were used as controls. Experiments were repeated three times using three plants in each test.
Mapping of the Locus Ny-DG
The mapping population DG 81-68 × DW 83-3121 was used to find the chromosomal localization of the gene Ny-DG. In the mapping experiments, the presence of PVY was assayed in the parental clones and the F1 individuals which were grown at 20 °C by an ELISA using PVY monoclonal cocktail Bioreba AG kit (Reinach, Switzerland) as described previously (Szajko et al. 2014). The inoculated leaves and the non-inoculated upper leaves were tested by ELISA at 1 and 4 weeks post-inoculation, respectively. At 28 °C, the F1 progeny plants were evaluated for the appearance of necrotic symptoms in both the inoculated leaves and the non-inoculated upper leaves following PVY inoculation at 9 dpi. In addition, 2–4 tubers were collected from each plant inoculated at 20 °C and subsequently planted to examine PVY resistance of tuber progeny plants. The linkage group IX of parent DG 81-68 was constructed by scoring markers SC895 (Szajko et al. 2008) and TG591 (Szajko et al. 2014) linked to the gene Ny-1. Genetic distance between the marker loci and the locus Ny-DG was calculated as fraction of recombinants.
RNA Extraction, Reverse Transcription and Real-Time qPCR
RNA extraction and real-time RT-qPCR were conducted essentially according to Yin et al. (2017). Briefly, leaf samples were collected at 0.5 hpi and at 3 and 6 dpi from PVY- and mock-inoculated (i.e. mechanical inoculation with water) plants of DG 81-68. Total RNA was extracted using the mirVana miRNA Isolation Kit (Ambion) in combination with DNase I digestion (DNA-free Kit, Ambion). RNA concentration and quality were measured with a spectrophotometer (Eppendorf BioSpectrometer).
Reverse transcription was conducted using 1 μg of total RNA with the TaqMan microRNA Reverse Transcription Kit (Applied Biosystems) according to the manufacturer’s instructions. The reverse transcription was conducted with the same condition and reagents for miRNA and mRNA. Real-time qPCR was conducted using SYBR Select Master Mix (Applied Biosystems) with a LightCycler480 real-time PCR instrument (Roche Diagnostics). The same reference gene, namely potato β-tubulin encoding gene (TUB, accession number Z33402), was used for the relative quantification of miRNA as well as for mRNA according to Yin et al. (2017).
In this study, the term quantification cycle (Cq) is used to indicate the fractional qPCR cycle used for quantification as used in Yin et al. (2017). The Cq is defined as the number of cycles at which the fluorescence signal exceeds a specific threshold level of detection. The raw Cq values for each gene in each sample were normalised to that of the reference gene (potato TUB gene) using the Advanced Relative Quantification method of the LIGHTCYCLER 480 software package. The software automatically calculates the relative expression levels (RELs) for each assay and displays it as 2−∆Cq. All ΔCq values were calculated as Cq(analysed gene)−Cq(reference gene). The REL (2−∆Cq) for each gene represented the mean of three biological replicates, where each replicate represented a mean of three technical replicates. Differences in the RELs (2−∆Cq) of each gene between the PVY-inoculated and the mock-inoculated (inoculation with water) control samples were analysed by one-way ANOVA and multiple range test using Statgraphics Plus software. Expression change is shown as the ratio of 2−∆Cq(PVY-inoculated sample)/2−∆Cq(mock-inoculated sample) at each time point.
The expression levels of five potato miRNAs, namely stu-miR162, stu-miR168a, stu-miR172e, stu-miR482 (PotatoMir1005658171_x16170) and stu-miR482 (PotatoMir1005353123_x15854), were quantified by real-time stem-loop RT-qPCR, a method that allows two miRNAs with only a single nucleotide change to be differentiated using specific stem-loop primers (Chen et al. 2005). Their mRNA targets, namely DCL1, AGO1-2, TOE3, Gpa2 and Cc-nbs-lrr, respectively, and the viral RNA PVY HC-Pro were tested by real-time RT-qPCR. Determination of the mRNA targets of the tested miRNAs was according to previous methods (Xie et al. 2011; Zhang et al. 2013). The predicted functions of the selected miRNAs/mRNA targets were defined in reference to Yin et al. (2017). The stem-loop primers specific for miRNAs, the primers specific for the mRNA targets and the primers for PVY HC-Pro RNA were chosen according to Yin et al. (2017).
Results
Reaction of DG 81-68 to Infection with PVYNTN at 20 and 28 °C
The temperature-dependent development of symptoms and accumulation of the viral RNA in the leaves of the diploid potato clone DG 81-68 were observed. At 20 °C, no symptoms were observed in the inoculated leaves that were mechanically inoculated with PVYNTN or in the non-inoculated upper leaves. At 28 °C, necrotic lesions were observed in the inoculated leaves of DG 81-68 plants at 4–6 dpi (Fig. 1), and at 7 to 9 dpi, the necrotic symptoms were visualised in the non-inoculated upper leaves. When the plants of DG 81-68 that were inoculated and kept at 20 °C for 14 days were transferred to 28 °C, the appearance of necrotic lesions and the systemic spread of PVY occurred.
Using real-time RT-qPCR for PVY HC-Pro RNA according to Yin et al. (2017), low levels of the viral RNA were detected in the inoculated leaves at 0.5 hpi and 3 dpi at both 20 and 28 °C; PVY was not detected in the upper non-inoculated leaves in the corresponding experiments. At 6 dpi, high levels of HC-Pro RNA were detected in both the inoculated and the non-inoculated upper leaves at 28 °C, whereas the viral RNA was not detected in DG 81-68 at 20 °C (Fig. 1).
Location of the Gene Ny-DG on Potato Chromosome IX
An ELISA assay was used for the detection of PVY in mapping experiments at 20 °C. The PVY resistant parent DG 81-68 had very low (A405 ˂ 0.05) and the susceptible parent DW 83-3121 had very high (A405 ˃ 1.4) absorbance values according to ELISA tests in both the inoculated leaves and in the non-inoculated upper leaves of plants grown at 20 °C after 1 and 4 weeks post-inoculation, respectively.
In the corresponding tests for the mapping population of DG 81-68 × DW 83-3121, out of the 114 F1 individuals, 51 plants were resistant (group A, having A405 ˂ 0.05) and 63 were susceptible (group B, with A405 ranging from 0.15 to 1.6) to PVYNTN. In the secondary infection assay for the plants from group A, PVY was not detected in all tuber progeny plants. In addition, at 28 °C, necrotic symptoms were observed in group A at 9 dpi, which confirmed the similar reaction type as the resistant parental clone DG 81-68.
In the mapping population DG 81-68 × DW 83-3121, the 1:1 segregation ratio of resistance versus susceptibility (χ2 = 1.26, P = 0.26) indicates the presence of a single, dominant gene present in the heterozygous state in the resistant parent DG 81-68. The two markers SC895 and TG591 were positioned 2.6 cM from the locus Ny-DG. This result confirms the location of Ny-DG on the long arm of potato chromosome IX.
Expression Changes of the miRNAs and Their Targeting mRNAs in the Leaves of DG81-68
In total, five miRNA/mRNA target pairs, namely stu-miR162/DCL1, stu-miR168a/AGO1-2, stu-miR172e/TOE3, stu-miR482 (PotatoMir1005658171_x16170)/Gpa2 and stu-miR482 (PotatoMir1005353123_x15854)/Cc-nbs-lrr, were tested by real-time (stem-loop) RT-qPCR. The raw Cq values for each gene were normalised to that of the reference gene (potato TUB gene). The use of TUB as the reference gene for normalisation is according to Yin et al. (2017), and its expression stability in the tested tissue of the mock- and PVY-infected plants was assessed amongst 12 putative reference genes (Z. Yin, unpublished data). Differences in the REL of each gene between the PVY-inoculated and the mock-inoculated (inoculation with water) control samples were analysed by one-way ANOVA and multiple range test using Statgraphics Plus software. Expression change is shown as the ratio of REL of the PVY-inoculated sample and that of the mock-inoculated one for each gene at each time point at each temperature, and the results are presented in Fig. 2.
In a small number of cases, PVY infection led to significant changes in the expression levels of the tested miRNAs and their mRNA targets at 0.5 hpi (Fig. 2a–d) and 3 dpi (Fig. 2e–h). In the inoculated leaves at 0.5 hpi, downregulation of stu-miR168a (0.4-fold) and Gpa2 (0.3-fold) was observed at 20 °C, and downregulation of all of the tested miRNAs and mRNAs was observed at 28 °C with the exception of stu-miR482 (PotatoMir1005658171_x16170), which was upregulated 3.76-fold (Fig. 2a, c). In the non-inoculated upper leaves at 0.5 hpi, downregulation of AGO1-2 (0.5-fold) and TOE3 (0.24-fold) was detected at 20 °C (Fig. 2d). At 3 dpi, upregulation of stu-miR168a (1.74-fold) and downregulation of Gpa2 (0.13-fold) in the inoculated leaves were observed at 28 °C (Fig. 2e, g). In the non-inoculated upper leaves, downregulation of miR162 (0.3-fold), stu-miR482 (PotatoMir1005353123_x15854) (0.3-fold) and miR172e (0.5-fold) was detected at 3 dpi at 28 °C (Fig. 2f).
At 6 dpi, different expression patterns in the tested miRNAs and their targets were detected not only at different temperatures in plants showing symptomless or necrotic reaction but also at the same temperatures in the inoculated leaves compared with the non-inoculated upper leaves. In the inoculated leaves at 6 dpi at 20 °C, parallel downregulation occurred in all five tested miRNAs and their targets (Fig. 2i, k). At 6 dpi at 28 °C, the inoculated leaves, which possessed high amounts of the viral HC-Pro RNA (Fig. 1a), presented antagonistic expression of stu-miR162, stu-miR168a and stu-miR482 (PotatoMir1005353123_x15854) with their targets; thus, the increased expression of these miRNAs promoted the downregulation of their targets. Stu-miR162, stu-miR168a and stu-miR482 (PotatoMir1005353123_x15854) were highly upregulated and presented levels 1.9-, 2.0- and 1.9-fold compared with the levels observed in the mock-inoculated controls, respectively (Fig. 2i). In addition, the corresponding target mRNAs, DCL1, AGO1-2 and Cc-nbs-lrr, were decreased by 0.35-, 0.40- and 0.46-fold compared with the controls, respectively (Fig. 2k). For stu-miR482 (PotatoMir1005658171_x16170) and stu-miR172e, although their levels were downregulated at 20 °C, their expression remained unchanged at 28 °C at 6 dpi, and downregulation of their target mRNAs Gpa2 (0.4-fold) and TOE3 (0.3-fold) occurred at 28 °C at 6 dpi in the inoculated leaves (Fig. 2i, k). At 6 dpi at 20 °C, the non-inoculated upper leaves, which contained no detectable viral HC-Pro RNA, did not show changes in the expression levels of the tested miRNAs or their targets (Fig. 2j, l). In the corresponding experiments at 28 °C, the downregulation of all five miRNAs was correlated with high levels of the viral HC-Pro RNA in the non-inoculated upper leaves at 6 dpi, whereas the expression levels of their targets remained unchanged (Fig. 2j, l).
Discussion
Early findings have demonstrated variants of temperature-dependent HRs in potato. The hypersensitivity gene Ny-1 confers resistance to PVY in potato cv. Rywal. The virus was localised via HR when the plants were grown at 20 °C, whereas the plants were systemically infected but no symptoms were observed at 28 °C (Szajko et al. 2008). Similar results were obtained in the potato cvs. Albatros and Sekwana, which possess the genes Ny-1A and Ny-1S, respectively (Szajko et al. 2014). However, the potato cv. Sárpo Mira showed HR to PVY at both 20 and 28 °C (Tomczyńska et al. 2014). In this study, the potato diploid clone DG 81-68 exhibited necrotic lesions in both the inoculated leaves and the non-inoculated upper leaves to PVY infection at 28 °C. At 20 °C, the virus was localised in the inoculated leaves without symptoms, such as in PW 363 plants possessing Ry-fsto which is the gene for the ER response. Compared with the observations in PW 363 (Flis et al. 2005), the systemic spread of PVY in DG 81-68 occurred when the plants that were inoculated and kept at 20 °C for 14 days were transferred to 28 °C. The temperature-dependent reaction observed in DG 81-68 was different from that observed in potato cv. Rywal possessing the temperature-dependent HR resistance gene Ny-1 to PVY. In cv. Rywal, necrotic lesions were observed in the inoculated leaves and no symptoms in the non-inoculated upper leaves, and the virus was localised when plants were grown at 20 °C, whereas at 28 °C, plants were systemically infected but no symptoms were observed in both the inoculated leaves and the non-inoculated upper leaves (Szajko et al. 2008). In the plants of DG 81-68 following PVYNTN inoculation at 20 °C, no symptoms were observed and no viral RNAs were detected in the non-inoculated upper leaves, which indicates DG 81-68 displays symptomless resistance to PVYNTN. However, at 28 °C, the necrosis observed in both the inoculated leaves and the non-inoculated upper leaves and systemic spreading of viral RNA indicate overcoming the resistance. Ny-DG is the first reported R gene for PVY resistance of its type in potato. The genes Ny-1, Ny-1A and Ny-1S were mapped on the long arm of the potato chromosome IX (Szajko et al. 2008, 2014), and their genetic positions correspond to the location of Ny-Smira in the potato cv. Sárpo Mira (Tomczyńska et al. 2014). The locus Ny-DG was also mapped to this chromosome region. It is likely that all of these resistance genes belong to the same R gene cluster and represent different alleles at the same locus.
We analysed the expression levels of five host miRNAs and their targets in DG 81-68 plants showing symptomless resistance at 20 °C and necrotic lesions at 28 °C after PVYNTN inoculation. The results obtained indicated that the expression patterns of the tested miRNAs and target mRNAs were altered differently not only at different time points post-inoculation but also in the inoculated and upper leaves, and their accumulation levels were related to the type of reaction, which in turn was dependent on temperature.
Alteration in the expression levels of the miRNAs and their targets seen in this study was also observed in other plant species upon virus infection. Stu-miR482 has been suggested to be involved in the regulation of NB-LRR-type disease-resistance R genes in plants (Shivaprasad et al. 2012; de Vries et al. 2015). The downregulation of miR482 and upregulation of NB-LRR transcripts at the infection sites were observed in tomato plants infected with turnip crinkle virus (TCV), cucumber mosaic virus (CMV) and tobacco rattle virus (TRV) (Shivaprasad et al. 2012) and in cowpea (Vigna unguiculata (L.) Walp.) plants infected with groundnut bud necrosis virus (GBNV) (Permar et al. 2014). Previous studies have indicated that miR172 might be linked to leaf curl disease in tomato caused by tomato leaf curl New Delhi virus infection (Naqvi et al. 2010). In N. tabacum plants, TMV infection causes the downregulation of miR172 at an early stage and upregulation at a later stage (Bazzini et al. 2007, 2011). Plant DCL1 and AGO1 represent two key enzymes in the miRNA biogenesis pathway, and they are regulated by miR162 and miR168, respectively (Xie et al. 2003; Vaucheret et al. 2004; Voinnet 2009). Induction of miR168 and its target AGO1 mRNA is commonly observed in plant-virus interactions (Yin et al. 2014). In soybean genotype PI96983 carrying the strain-specific resistance gene Rsv1, highly elevated levels of miR168 and AGO1 mRNA were detected only in G7-infected Rsv1 plants showing a lethal systemic hypersensitive response (LSHR). However, in the Rsv1 plants resistant to strain G2, no significant difference was found in expression of miR168 compared to the mock-inoculated control (Chen et al. 2015).
In potato, in our previous study, the expression of the same group of miRNAs and targets has been analysed in cv. Etola showing strain-specific HR resistance to PVY. In the non-inoculated upper leaves of the plants of cv. Etola, parallel increases in the expression levels of stu-miR168, stu-miR162, stu-miR172e and two members of stu-miR482, together with their targets AGO1-2, DCL1, TOE3, Gpa2 and Cc-nbs-lrr, respectively, were observed in PVYN-Wi-infected plants showing necrotic reaction and severe symptoms. However, changes were not observed in the levels of the same set of miRNAs and their targets in PVYNTN-inoculated plants showing HR resistance or in PVYZ-NTN-infected Etola showing necrotic reaction and mild symptoms (Yin et al. 2017). In another example, potato cv. Rywal carrying Ny-1 gene exhibited temperature-dependent HR resistance to PVY at 20 °C (Szajko et al. 2008). The transcriptional reprogramming was pronounced in the inoculated leaves of the plants of cv. Rywal following PVY inoculation at 1 and 3 dpi at 20 °C, including the downregulation of genes related to RNA silencing, for example, AGO1 transcript (Baebler et al. 2014). Regulation of immune receptor transcripts by miR6022 as well as upregulation of miR164, miR167, miR169, miR171, miR319, miR390 and miR393 in potato cv. Désirée showing tolerant response to PVYNTN revealed similarities to responses observed in mutualistic symbiotic interactions (Križnik et al. 2017).
In this study, in the non-inoculated upper leaves of potato DG 81-68 plants following PVYNTN inoculation at 6 dpi, the downregulation of the tested miRNAs was detected at 28 °C in plants showing necrosis in the inoculated leaves but not at 20 °C in plants showing symptomless resistance. Their corresponding targets remained unchanged at both temperatures. Moreover, in the inoculated leaves of potato DG 81-68 plants following PVYNTN inoculation at 6 dpi, parallel downregulation of the tested miRNAs and their targets were observed at 20 °C in plants showing symptomless resistance. However, the increased expression of the tested miRNAs was detected, and the levels of their target transcripts were decreased at 28 °C in plants showing necrotic lesions. The downregulation of miRNAs in the non-inoculated upper leaves observed in this study shares similarities with the pattern of alterations in a group of biotic and abiotic stress-responsive miRNAs in the early stage of TMV infection in tobacco as demonstrated by Bazzini et al. (2011). The authors inferred that the basal defence and the signals of viral-associated molecular pattern (VAMPs) might play a role in the early stages of miRNA alteration (Bazzini et al. 2011). As for the upregulation of miRNAs in the inoculated leaves observed in this study (3 and 6 dpi), it is similar to that observed in Désirée-PVYNTN tolerant response (Križnik et al. 2017). The authors demonstrated the downregulation of gibberellin signalling at 3 dpi in the inoculated leaves before viral multiplication could be detected and it might be linked to the reduced disease severity. Moreover, the discordance between miRNA and mRNA expression patterns observed in the non-inoculated upper leaves of DG 81-68 may indicate that additional miRNAs may regulate the same target transcript. For example, TOE3 is targeted by stu-miR172a and stu-miR1533a in addition to stu-miR172e, and AGO1-2 is targeted by stu-miR1522c besides stu-miR168a (Zhang et al. 2013). The alteration of the tested potato miRNAs and their targets was strain-dependent and related to symptom severity in the PVY-Etola interactions. In the PVY-DG 81-68 interactions, changes in the same tested set of potato miRNAs and their targets expression levels were temperature-dependent and related to the reaction type and differed between the inoculated leaves and the non-inoculated upper leaves.
In summary, a few miRNAs and their targets were tested in DG 81-68-PVYNTN interaction. However, the alteration patterns of their expression showed a clear tendency of depending on the site of infection and temperature. This data will lay the foundation for our further study on the role of miRNA in potato-PVY interaction at large scale and at genome level. It might also be useful information for researchers interested in similar subjects in other plant species.
References
Baebler Š, Witek K, Petek M, Stare K, Tušek-Žnidarič M, Pompe-Novak M, Renaut J, Szajko K, Strzelczyk-Żyta D, Marczewski W, Morgiewicz K, Gruden K, Hennig J (2014) Salicylic acid is an indispensable component of the Ny-1 resistance-gene-mediated response against Potato virus Y infection in potato. J Exp Bot 65:1095–1109
Bartel DP (2004) MicroRNAs: genomics, biogenesis, mechanism, and function. Cell 116:281–297
Bazzini AA, Hopp HE, Beachy RN, Asurmendi S (2007) Infection and coaccumulation of Tobacco mosaic virus proteins alter microRNA levels, correlating with symptom and plant development. PNAS 104(29):12157–12162
Bazzini AA, Manacorda CA, Tohge T, Conti G, Rodriguez MC, Nunes-Nesi A, Villanueva S, Fernie AR, Carrari F, Asurmendi S (2011) Metabolic and miRNA profiling of TMV infected plants reveals biphasic temporal changes. PLoS One 6:e28466
Chen C, Ridzon DA, Broomer AJ, Zhou Z, Lee DH, Nguyen JT, Barbisin M, Xu NL, Mahuvakar VR, Andersen MR, Lao KQ, Livak KJ, Guegler KJ (2005) Real-time quantification of microRNAs by stem-loop RT-PCR. Nucleic Acids Res 33:e179
Chen H, Arsovski AA, Yu K, Wang A (2016a) Genome-wide investigation using sRNA-seq, degradome-seq and transcriptome-seq reveals regulatory networks of microRNAs and their target genes in soybean during Soybean mosaic virus infection. PLoS One 11:e0150582. https://doi.org/10.1371/journal.pone.0150582
Chen H, Arsovski AA, Yu K, Wang A (2016b) Deep sequencing leads to the identification of eukaryotic translation initiation factor 5a as a key element in Rsv1-mediated lethal systemic hypersensitive response to Soybean mosaic virus infection in soybean. Mol Plant Pathol 18:391–404. https://doi.org/10.1111/mpp.12407
Chen H, Zhang L, Yu K, Wang A (2015) Pathogenesis of Soybean mosaic virus in soybean carrying Rsv1 gene is associated with miRNA and siRNA pathways, and breakdown of AGO1 homeostasis. Virology 476:395–404
de Ronde D, Butterbach P, Kormelink R (2014) Dominant resistance against plant viruses. Front Plant Sci 5. https://doi.org/10.3389/fpls.2014.00307
de Vries S, Kloesges T, Rose LE (2015) Evolutionarily dynamic, but robust, targeting of resistance genes by the miR482/2118 gene family in the Solanaceae. Genome Biol Evol 7:3307–3321
Flis B, Hennig J, Strzelczyk-Żyta D, Gebhardt C, Marczewski W (2005) The Ry-f sto gene from Solanum stoloniferum for extreme resistant to Potato virus Y maps to potato chromosome XII and is diagnosed by PCR marker GP122718 in PVY resistant potato cultivars. Mol Breed 15:95–101
Hinrichs-Berger J, Harfold M, Berger S, Buchenauer H (1999) Cytological responses of susceptible and extremely resistant potato plants to inoculation with potato virus Y. Physiol Mol Plant Pathol 55:143–150
Kang BC, Yeam I, Jahn MM (2005) Genetics of plant virus resistance. Annu Rev Phytopathol 43:581–621
Khraiwesh B, Zhu JK, Zhu J (2012) Role of miRNAs and siRNAs in biotic and abiotic stress responses of plants. Biochim Biophys Acta 1819:137–148
Király L, Hafez YM, Fodor J, Király Z (2008) Suppression of tobacco mosaic virus-induced hypersensitive-type necrotization in tobacco at high temperature is associated with downregulation of NADPH oxidase and superoxide and stimulation of dehydroascorbate reductase. J Gen Virol 89:799–808
Križnik M, Petek M, Dobnik D, Ramšak Ž, Baebler Š, Pollmann S, Kreuze JF, Žel J, Gruden K (2017) Salicylic acid perturbs sRNA-gibberellin regulatory network in immune response of potato to Potato virus Y infection. Front Plant Sci 8: 2192
Li F, Pignatta D, Bendix C, Brunkard JO, Cohn MM, Tung J, Sun H, Kumar P, Baker B (2012) MicroRNA regulation of plant innate immune receptors. PNAS 109:1790–1795
Naqvi AR, Haq QM, Mukherjee SK (2010) MicroRNA profiling of tomato leaf curl New Delhi virus (TOLCNDV) infected tomato leaves indicates that deregulation of mir159/319 and mir172 might be linked with leaf curl disease. Virol J 7:281
Nie X, Liang Z, Nie BH, Murphy A, Singh M (2015) Studies on varietal response to different strains of Potato virus Y (PVY) reveal hypersensitive resistance in exploits to PVYO and extreme resistance in F87084 to all tested strains. Am J Potato Res 92:23–31
Permar V, Singh A, Pandey V, Alatar AA, Faisal M, Jain RK, Praveen S (2014) Tospo viral infection instigates necrosis and premature senescence by micro RNA controlled programmed cell death in Vigna unguiculata. Physiol Mol Plant Pathol 88:77–84
Qian Y, Hou H, Shen Q, Cai X, Sunter G, Zhou X (2016) RepA protein encoded by Oat dwarf virus elicits a temperature-sensitive hypersensitive response-type cell death that involves jasmonic acid-dependent signaling. Mol Plant-Microbe Interact 29:5–21
Ramesh SV, Ratnaparkhe MB, Kumawat G, Gupta GK, Husain SM (2014) Plant miRNAome and antiviral resistance: a retrospective view and prospective challenges. Virus Genes 48:1–14
Ruiz-Ferrer V, Voinnet O (2009) Roles of plant small RNAs in biotic stress responses. Annu Rev Plant Biol 60:485–510
Shivaprasad PV, Chen HM, Patel K, Bond DM, Santos BA, Baulcombe DC (2012) A microRNA superfamily regulates nucleotide binding site-leucine-rich repeats and other mRNAs. Plant Cell 24:859–874
Szajko K, Chrzanowska M, Witek K, Strzelczyk-Zyta D, Zagórska H, Gebhardt C, Hennig J, Marczewski W (2008) The novel gene Ny-1 on potato chromosome IX confers hypersensitive resistance to Potato virus Y and is an alternative to Ry genes in potato breeding for PVY resistance. Theor Appl Genet 116:297–303
Szajko K, Strzeczyk-Zyta D, Marczewski W (2014) Ny-1 and Ny-2 genes conferring hypersensitive response to potato virus Y (PVY) in cultivated potatoes: mapping and marker-assisted selection validation for PVY resistance in potato breeding. Mol Breed 34:267–271
Tomczyńska I, Jupe F, Hein I, Marczewski W, Śliwka J (2014) Hypersensitive response to Potato virus Y in potato cultivar Sárpo Mira is conferred by the Ny-Smira gene located on the long arm of chromosome IX. Mol Breed 34:471–480
Valkonen JPT (1997) Novel resistances to four potyviruses in tuber-bearing potato species, and temperature-sensitive expression of hypersensitive resistance to potato virus Y. Ann Appl Biol 130:91–104
Valkonen JPT (2015) Elucidation of virus-host interactions to enhance resistance breeding for control of virus diseases in potato. Breed Sci 65:69–76
Vaucheret H, Vazquez F, Crété P, Bartel DP (2004) The action of ARGONAUTE1 in the miRNA pathway and its regulation by the miRNA pathway are crucial for plant development. Genes Dev 18:1187–1197
Voinnet O (2009) Origin, biogenesis, and activity of plant microRNAs. Cell 136:669–687
Xie Z, Kasschau KD, Carrington JC (2003) Negative feedback regulation of dicer-Like1 in Arabidopsis by microRNA-guided mRNA degradation. Curr Biol 13:784–789
Xie F, Frazier TP, Zhang B (2011) Identification, characterization and expression analysis of microRNAs and their targets in the potato (Solanum tuberosum). Gene 473:8–22
Yin Z, Chrzanowska M, Michalak K, Zimnoch-Guzowska E (2014) Alteration of host-encoded miRNAs in virus infected plants - experimentally verified. In: Guar RK, Hohn T, Sharma P (ed) Plant virus-host interaction. Elsevier, pp17–55
Yin Z, Xie F, Michalak M, Pawełkowicz M, Zhang B, Murawska Z, Lebecka R, Zimnoch-Guzowska E (2017) Potato cultivar Etola exhibits hypersensitive resistance to PVYNTN and partial resistance to PVYZ-NTN and PVYN-Wi strains and strain-specific alterations of certain host miRNAs might correlate with symptom severity. Plant Pathol 66:539–550
Yin Z, Murawska Z, Xie F, Pawełkowicz M, Michalak K, Zhang B, Lebecka R (2019) microRNA response in potato virus Y infected tobacco shows strain-specificity depending on host and symptom severity. Virus Res 260:20–32
Zhang R, Marshall D, Bryan GJ, Hornyik C (2013) Identification and characterization of miRNA transcriptome in potato by high-throughput sequencing. PLoS One 8:e57233
Zhu Y, Qian W, Hua J (2010) Temperature modulates plant defense responses through NB-LRR proteins. PLoS Pathog 6:e1000844. https://doi.org/10.1371/journal.ppat.1000844
Zimnoch-Guzowska E, Marczewska W, Lebecka R, Flis B, Scha¨fer-Pregl R, Salamini F, Gebhardt C (2000) QTL analysis of new sources of resistance to Erwinia carotovora ssp. atroseptica in potato done by AFLP, RFLP, and resistance-gene-like markers. Crop Sci 40:1156–1167
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This study was funded in part by statutory grants 1-3-00-1-01 and 1-3-00-3-04 from the Polish Ministry of Science and Higher Education.
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K.S. carried out phenotyping and performed the genetic and molecular studies. Z.Y. participated in the design of the molecular studies, performed the statistical analysis and co-wrote the paper. W.M. conceived and coordinated the project, and co-wrote the paper. All authors reviewed the manuscript.
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Szajko, K., Yin, Z. & Marczewski, W. Accumulation of miRNA and mRNA Targets in Potato Leaves Displaying Temperature-Dependent Responses to Potato Virus Y. Potato Res. 62, 379–392 (2019). https://doi.org/10.1007/s11540-019-9417-4
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DOI: https://doi.org/10.1007/s11540-019-9417-4