Abstract

Downy mildew (Plasmopara viticola) is the main grapevine disease in humid regions. In the present investigation, marker-assisted selection (MAS) was used to develop grapevine lines homozygous in loci Rpv1 and Rpv3 for resistance against P. viticola. The experimental populations UFSC-2013-1 (n = 420) and UFSC-2013-2 (n = 237) were obtained by self-pollination of two 𝐅 𝟏 full-sib plants, originated from a cross between two distinct breeding lines containing the downy mildew resistance loci Rpv1 and Rpv3 in heterozygosity. The two experimental populations were genotyped with four microsatellite markers flanking the two downy mildew resistance loci. Among 637 genotyped plants, 300 (48.2%) were homozygous for at least one resistance locus and 10 (1.57%) were homozygous for both Rpv1 and Rpv3 alleles. These 10 plants challenged with P. viticola inoculum showed a clearly enhanced level of resistance. These plants have a great potential as resistance donors in grapevine breeding.

Key words:
Vitis; disease resistance; gene pyramiding; distorted segregation

INTRODUCTION

The diploid obligate biotrophic oomycete Plasmopara viticola (Berk & Kurt) causes downy mildew, one of the main diseases that reduce grape (Vitis vinifera) production (Caffi et al. 2010Caffi T, Rossi V and Bugiani R (2010) Evaluation of a warning system for controlling primary infections of grapevine downy mildew. Plant Disease 94: 709-716. ). This yield loss is not confined to one season; early leaf death and defoliation caused by the disease weakens the vine and leads to poor harvests in subsequent seasons (Matasci et al. 2008Matasci CL, Gobbin D, Schärer HJ, Tamm L and Gessler C (2008) Selection for fungicide resistance throughout a growing season in populations of Plasmopara viticola. European Journal of Plant Pathology 120: 79-83.). The pathogen was found originally in North America on wild Vitis (Olmo 1986Olmo HP (1986) The potential role of (vinifera x rotundifolia) hybrids in grape variety improvement. Experientia 42: 921-926.); however, it has since spread across the globe to many countries, including Brazil, by introduction of American vines contaminated with the pathogen (Santos-Neto 1955Santos-Neto JRA (1955) Melhoramento da videira. Bragantia 14: 237-267. ). Currently, the pathogen is responsible for extreme damages to vineyards without effective crop protection in South Brazil, where the humid climate is especially amenable for the pathogen’s life cycle and proliferation (Hamada et al. 2008Hamada E, Ghini R, Rossi P, Júnior MJP and Fernandes JL (2008) Climatic risk of grape downy mildew (Plasmopara viticola) for the state of São Paulo, Brazil. Scientia Agricola 65: 60-64. , Peruch and Bruna 2008Peruch LAM and Bruna ED (2008) Relação entre doses de calda bordalesa e de fosfito potássico na intensidade do míldio e na produtividade da videira cv. ‘Goethe’. Ciência Rural 38: 2413-1418. ).

For more than two centuries, V. vinifera and Muscadinia rotundifolia, a donor of resistance genes, have been bred with the objective of combining high-quality fruit production with effective disease resistance (Olmo 1986Olmo HP (1986) The potential role of (vinifera x rotundifolia) hybrids in grape variety improvement. Experientia 42: 921-926., Alleweldt and Possingham 1988Alleweldt G and Possingham JV (1988) Progress in grapevine breeding. Theoretical and Applied Genetics 75: 669-673. ). Nevertheless, high levels of distorted segregation in plants from interspecific crosses led to low survival rates in the progeny, thus hindering breeding efforts (Bouquet 1986Bouquet A (1986) Introduction dans l’espèce Vitis vinífera L. d’un caractère de résistance à l’o (Uncinula necator Schw. Burr.) issu de l’espèce Muscadinia rotundifolia (Michx.) Small. Vignevini 12 (suppl): 141-146., Lu et al. 1998Lu J, Schell L and Ramming DW (1998) Interspecific hybridization between Vitis rotundifolia and Vitis vinifera and evaluation of the hybrids. Acta Horticulturae 528: 479-486.); however, some successful hybridizations were obtained when M. rotundifolia was used as the male parent (Lu et al. 1998).

Grapevine improvement, similar to all perennial species, takes a considerably long time to develop new varieties because maturity often requires several growing seasons before breeding success can be evaluated. However, indirect selection with the assistance of molecular markers, which can be used at any developmental stage of the plant, can reduce this interim time considerably (Töpfer et al. 2011aTöpfer R, Hausmann L, Harst M, Maul E, Zyprian E and Eibach R (2011a) New horizons for grapevine breeding. In Flachowsky H and Hanke MV (eds) Fruit, vegetable and cereal science and biotechnology, vol 5. Methods in temperate fruit breeding. Global Science Books, Isleworth, p.79-100.).

More recently, these markers have allowed the construction of genetic maps, QTL analyses, and implementation of marker-assisted selection (MAS), particularly applied for pyramiding resistance alleles in grapevine (Alzate-Marin et al. 2005Alzate-Marin AL, Cervigni GDL, Moreira MA and Barros EG (2005) Seleção assistida por marcadores moleculares visando ao desenvolvimento de plantas resistentes a doenças, com ênfase em feijoeiro e soja. Fitopatologia Brasileira 30: 333-342. , Eibach et al. 2007Eibach R, Zyprian E, Welter L and Töpfer R (2007) The use of molecular markers for pyramiding resistance genes in grapevine breeding. Vitis 46: 120-124. , Töpfer et al. 2011bTöpfer R, Hausmann L and Eibach R (2011b) Molecular breeding. In Adam-Blondon AF, Martinez-Zapater JM and Kole C (eds) Genetics, genomics and breeding of grapes. Science Publishers, Enfield, p. 160-185.). In addition to the pyramiding of resistance genes the development of inbred lines has a crucial role in gene introgression, because it ensures that all progeny will inherit the alleles of interest. Moreover, vines homozygous for downy mildew resistance allele Rpv12 (Venuti et al. 2013Venuti S, Copetti D, Foria S, Falginella L, Hoffmann S, Bellin D, Cindric P, Kozma P, Scalabrin S, Morgante M, Testolin R and Di Gaspero G (2013) Historical introgression of the downy mildew resistance gene Rpv12 from the asian species Vitis amurensis into grapevine varieties. PLoS ONE 8: e61228. doi:10.1371/journal.pone.0061228.
https://doi.org/10.1371/journal.pone.006... ) and for seedlessness (Sdl) [according to VIVC table of loci] locus responsible for apyrenic grape fruits have been reported (Doligez et al. 2002Doligez A, Bouquet A, Danglot Y, Lahogue F, Riaz S, Meredith CP, Edwards KJ and This P (2002) Genetic mapping of grapevine (Vitis vinifera L.) applied to the detection of QTLs for seedlessness and berry weight. Theoretical and Applied Genetics 105: 780-795., Akkurt et al. 2012Akkurt M, Çakir A, Shidfar M, Çelikkol BP and Söylemezoğlu G (2012) Using SCC8, SCF27 and VMC7f2 markers in grapevine breeding for seedlessness via marker assisted selection. Genetics and Molecular Research 11: 2288-2294.).

The locus Rpv1 is located on chromosome 12 of M. rotundifolia, and it is associated to locus Run1, which confers resistance to downy mildew (Barker et al. 2005Barker CL, Donald T, Pauquet J, Ratnaparkhe A, Bouquet A, Adam-Blondon AF, Thomas MR and Dry I (2005) Genetic and physical mapping of the grapevine powdery mildew resistance gene, Run1, using a bacterial artificial chromosome library. Theoretical and Applied Genetics 111: 370-377. , Merdinoglu et al. 2003Merdinoglu D, Wiedemann-Merdinoglu S, Coste P, Dumas V, Haetty S, Butterlin G, Greif C, Adam-Blondon AF, Bouquet A and Pauquet J (2003) Genetic analysis of downy mildew resistance derived from Muscadinia rotundifolia. Acta Horticulturae 603: 451-456.). Rpv1/Run1 alleles were introduced in V. vinifera by backcrossing (Pauquet et al. 2001Pauquet J, Bouquet A, This P and Adam-Blondon AF (2001) Establishment of a local map of AFLP markers around the powdery mildew resistance gene Run1in grapevine and assessment of their usefulness for marker assisted selection. Theoretical and Applied Genetics 103: 1201-1210. ). The locus Rpv3 was identified on chromosome 18 in the grape variety 'Regent' (Fischer et al. 2004Fischer BM, Salakhutdinov I, Akkurt M, Eibach R, Edwards KJ, Töpfer R and Zyprian EM (2004) Quantitative trait locus analysis of fungal disease resistance factors on a molecular map of grapevine. Theoretical and Applied Genetics 108: 501-515., Welter et al. 2007Welter LJ, Göktürk-Baydar N, Akkurt M, Maul E, Eibach R, Töpfer R and Zyprian EM (2007) Genetic mapping and localization of quantitative trait loci affecting fungal disease resistance and leaf morphology in grapevine (Vitis vinifera L). Molecular Breeding 20: 359-374. ) and conferred significant resistance to downy mildew on both leaves and berries in all evaluated years (Welter et al. 2007Welter LJ, Göktürk-Baydar N, Akkurt M, Maul E, Eibach R, Töpfer R and Zyprian EM (2007) Genetic mapping and localization of quantitative trait loci affecting fungal disease resistance and leaf morphology in grapevine (Vitis vinifera L). Molecular Breeding 20: 359-374. ). In grapevine, this Rpv3 locus was responsible for causing the hypersensitive response (HR) at infection sites within two days after the inoculation (dpi) (Bellin et al. 2009Bellin D, Peressotti E, Merdinoglu D, Wiedemann-Merdinoglu S, Adam-Blondon AF, Cipriani G, Morgante M, Testolin R and Di Gaspero G (2009) Resistance to Plasmopara viticola in grapevine ‘Bianca’ is controlled by a major dominant gene causing localized necrosis at the infection site. Theoretical and Applied Genetics 120: 163-176. , Casagrande et al. 2011Casagrande K, Falginella L, Castellarin SD, Testolin R and Di Gaspero G (2011) Defence responses in Rpv3-dependent resistance to grapevine downy mildew. Planta 234: 1097-1109. ).

The resistance alleles Rpv1 and Rpv3 revealed complete dominance at both of their loci. Through pyramiding Rpv1 and Rpv2, Eibach et al. (2007Eibach R, Zyprian E, Welter L and Töpfer R (2007) The use of molecular markers for pyramiding resistance genes in grapevine breeding. Vitis 46: 120-124. ) obtained heterozigous plants that exhibited resistance to downy mildew. The effect of either Rpv1 or Rpv3 in single locus plants showed significantly higher resistance to downy mildew; however, genotypes with both resistance alleles showed no infection (Eibach et al. 2007Eibach R, Zyprian E, Welter L and Töpfer R (2007) The use of molecular markers for pyramiding resistance genes in grapevine breeding. Vitis 46: 120-124. ). In other studies, the combination of multiple resistance alleles, such as Rpv1 and Rpv3 (Calonnec et al. 2013Calonnec A, Wiedemann‐Merdinoglu S, Deliere L, Cartolaro P, Schneider C and Delmotte F (2013) The reliability of leaf bioassays for predicting disease resistance on fruit: a case study on grapevine resistance to downy and powdery mildew. Plant Pathology 62: 533-544.); Rpv3 is equal to QTLRgD as already described in Bellin et al. (2009Bellin D, Peressotti E, Merdinoglu D, Wiedemann-Merdinoglu S, Adam-Blondon AF, Cipriani G, Morgante M, Testolin R and Di Gaspero G (2009) Resistance to Plasmopara viticola in grapevine ‘Bianca’ is controlled by a major dominant gene causing localized necrosis at the infection site. Theoretical and Applied Genetics 120: 163-176. ), Di Gaspero et al. (2012Di Gaspero G, Copetti D, Coleman C, Castellarin SD, Eibach R, Kozma P, Lacombe T, Gambetta G, Zvyagin A, Cindric P, Kovács L, Morgante M and Testolin R (2012) Selective sweep at the Rpv3 locus during grapevine breeding for downy mildew resistance. Theoretical and Applied Genetics 124: 277-286.), Zyprian et al. (2016Zyprian E, Ochßner I, Schwander F, Šimon S, Hausmann L, Bonow‑Rex M, Moreno‑Sanz P, Grando MS, Wiedemann‑Merdinoglu S, Merdinoglu D, Eibach R and Töpfer R (2016) Quantitative trait loci affecting pathogen resistance and ripening of grapevine. Molecular Genetics and Genomics 291: 1573-1594.), Rpv3 and Rpv10 (Schwander et al. 2012Schwander F, Eibach R, Fechter I, Hausmann L, Zyprian E and Töpfer R (2012) Rpv10: a new locus from the Asian Vitis gene pool for pyramiding downy mildew resistance loci in grapevine. Theoretical and Applied Genetics 124: 163-176. ), Rpv3 and Rpv12 (Venuti et al. 2013Venuti S, Copetti D, Foria S, Falginella L, Hoffmann S, Bellin D, Cindric P, Kozma P, Scalabrin S, Morgante M, Testolin R and Di Gaspero G (2013) Historical introgression of the downy mildew resistance gene Rpv12 from the asian species Vitis amurensis into grapevine varieties. PLoS ONE 8: e61228. doi:10.1371/journal.pone.0061228.
https://doi.org/10.1371/journal.pone.006... ), likewise conferred significantly enhanced resistance to pathogen infection in comparison to single resistance alleles. Thus, the objective of this study was to develop, characterize, and select breeding lines homozygotic for the pyramided resistance alleles Rpv1 and Rpv3 for future breeding purposes.

MATERIAL AND METHODS

Plant materials

A total of 637 plants from two segregating population were used in this study. The first, UFSC-2013-1 (n=420), was obtained by self-pollination of the F₁ plant 2000-305-97 (red grapes). The second, UFSC-2013-2 (n=217), was obtained by the self-pollination of the F 1 plant 2000-305-134 (white grapes). The two self-pollinated F 1 plants are full sib obtained by the cross between VRH 3082-1-42 x 'Regent' and are heterozygous for both Rpv1 and Rpv3 pyramided loci (Eibach 2007Eibach R, Zyprian E, Welter L and Töpfer R (2007) The use of molecular markers for pyramiding resistance genes in grapevine breeding. Vitis 46: 120-124. ).

Genotyping

DNA extraction

DNA was extracted from approximately 100 mg of leaf samples dissected on silica gel. The samples were macerated using four 2.8 mm ceramic beads placed in 2 ml self-standing micro-tubes (Precellys^® 24 homogenizer, Bertin Technologies) during two 30 s agitation cycles at 5000 rpm. Subsequently, the DNA was isolated using a NucleoSpin^® Plant Kit as described by the supplier (Macherey-Nagel). The DNA samples were quantified with a NanoDrop 1000 Spectrophotometer (Thermo Scientific). The DNA was diluted to a concentration of 1 ng μL^-1 for further use in PCR reactions.

Amplification of microsatellite markers by PCR

Microsatellite markers Sc34_8 and Sc35_2 (NCBI STS database accession: GF111545 and GF111546), flanking the Rpv1 locus located on chromosome 12, and the markers GF18-06 (Schwander et al. 2012Schwander F, Eibach R, Fechter I, Hausmann L, Zyprian E and Töpfer R (2012) Rpv10: a new locus from the Asian Vitis gene pool for pyramiding downy mildew resistance loci in grapevine. Theoretical and Applied Genetics 124: 163-176. ) and GF18-08 (Zyprian et al. 2016Zyprian E, Ochßner I, Schwander F, Šimon S, Hausmann L, Bonow‑Rex M, Moreno‑Sanz P, Grando MS, Wiedemann‑Merdinoglu S, Merdinoglu D, Eibach R and Töpfer R (2016) Quantitative trait loci affecting pathogen resistance and ripening of grapevine. Molecular Genetics and Genomics 291: 1573-1594.), located on chromosome 18, which flank the Rpv3 locus, were used to all genotype the plants. The four pairs of primers were added in the same polymerase chain reaction (PCR) to obtain both amplicons at once.

The PCR reactions were performed in a total volume of 5 µL, using the KAPA 2G Kit (Kapa Biosystems, Inc. Boston, USA). The mix contains 1x of KAPA Fast Multiplex Mix and four pairs of primers (0.01 µM). The forward primer (5’) was labeled with 6-FAM, VIC or PET fluorophore. The PCR reactions were carried out in a C-1000TM Thermal Cycler (Biorad), with the following thermal profile: 94 °C for 3 min, followed by 30 touchdown cycles at 94 °C for 30 s, 60 °C for 30 s, 72 °C for 1 min, and a final elongation of 40 min at 72 °C. To confirm amplification, 5 uL of PCR product was used for electrophoresis in 1.5% agarose gel and visualized under UV transilluminator.

Capilar electrophoresis

Sequencing reaction was prepared to a final volume of 10 uL of diluted PCR product (1.0 µl PCR reaction in 27 µl autoclaved ultrapure water), 0.5 µl of size ladder Gene Scan 600 LIZ (Life Technologies) and 8.5 µL of Formamide (Life Technologies). The alleles were separated by capillary electrophoresis done in a 3500 XL Applied Biosystems with the polymer POP-7. Allele sizes were determined using a Gene Mapper Version 4.1 software (Applied Biosystems).

Resistance phenotyping on artificially inoculated leaf discs

To validate the genotyping data, 142 randomly-selected plants in variable proportions from the nine obtained allelic combinations were evaluated for resistance to P. viticola (Table 1). Inoculations were performed on leaf discs according to Schwander et al. (2012Schwander F, Eibach R, Fechter I, Hausmann L, Zyprian E and Töpfer R (2012) Rpv10: a new locus from the Asian Vitis gene pool for pyramiding downy mildew resistance loci in grapevine. Theoretical and Applied Genetics 124: 163-176. ). All materials used during the inoculations, except the inoculum, were autoclaved at 120 °C and 1.1 atm for 19 min.

The fourth leaf from the apex to the base of all plants were collected. The leaves were sterilized with sodium hypochlorite (1% of active chlorine) for 30 s, and, subsequently, triple-rinsed in ultrapure water (Milli-Q®) for 30 s, 30 s and 60 s, respectively. In a laminar flow hood, six leaf disks 12 mm in diameter were excised from each plant and placed abaxial-side-up on moist filter paper in glass petri dishes to produce a moist chamber for pathogen proliferation. Then, a droplet of 30 µL of the sporangia suspension, at a concentration of 50,000 spores mL^-1, was applied to each leaf disk. Three replicates were performed for each plant.

The Petri dishes were sealed and incubated in a growth chamber. In the first 10 h the disks were kept in the dark at 22 °C. Subsequently, conditions were changed to a photoperiod of 14 h light and a constant temperature of 25 °C. After 15 h, the droplet was removed from each disc, and left incubated for seven days to evaluate the sporulation of downy mildew. The degree of infection was rated in each genotypic class on the basis of sporangia intensity formed by leaf disc.

Statistical analysis

Frequency distribution and chi-square tests were used to analyze the obtained segregations in genotypic data from the expected ones. When distorted segregation was statistically significant, the Lorieux et al. (1995Lorieux M, Perrier X, Goffinet B, Lanaud C and González de León D (1995) Maximum-likelihood models for mapping genetic markers showing segregation distortion. 2. F2 populations. Theoretical and Applied Genetics 90: 81-89. ) methodology was used to determine the type of selection acting in the analyzed populations. Confidence intervals (CIs) of 95% were used for comparison of means of phenotypic evaluations of the downy mildew. The degree of resistance of other genotypes to P. viticola was calculated based on the susceptible genotypes rpv1/rpv1 and rpv3/rpv3 that showed 100% of mildew infection.

RESULTS AND DISCUSSION

Genotyping

Genotyping with four microsatellite markers linked to resistance alleles Rpv1 and Rpv3 (with two pairs of primers flanking each of the loci) classified plants according to the number of resistance alleles present in each plant. Plants were considered to have the resistance loci when the two microsatellite markers for each locus presented alleles originally linked to the resistance alleles. Out of 637 genotyped plants, 15 showed genetic recombination (2.3%) between the pairs of microsatellite markers and were excluded from the analysis. This recombination rate of 2.3% rate is quite acceptable to breeders in terms of indirect selection efficiency.

Of the remaining 622 plants, 36 (5.8%) did not show any of the resistance alleles, 92 (14.8%) had only the Rpv1 allele, 194 (31.2%) carried only the Rpv3 allele, and 300 (48.2%) exhibited both resistance alleles Rpv1 and Rpv3 (Figure 1). Out of these 300 plants, 10 of them (1.6% of total plants) showed resistance alleles in homozygous state at both loci (Rpv1/Rpv1, Rpv3/Rpv3). A similar frequency of genotypic classes was observed in both segregating populations (Figure 1).

The analysis of the genotypic classes of individually loci clearly showed a distorted segregation from the expected Mendelian proportion, especially for the Sc34_8 and Sc35_2 markers linked to Rpv1 (Table 2). In the UFSC-2013-1 population, both markers segregated in the proportion of 23 Rpv1/Rpv1, 229 Rpv1/rpv1 and 161 rpv1/rpv1 [ x 2 = 97.12 (P=2.2^e-16)], equivalent to 1: 10.5: 6.7. A similar result was showed by the UFSC-2013-2 population, being 11 Rpv1/Rpv1, 129 Rpv1/rpv1 and 69 rpv1/rpv1 [ x 2 = 43.68 (P=3.274^e-10)] or 1: 11.6: 2.2 (Table 2). In both F₂ populations, a deficit of homozygous resistant plants to downy mildew was verified with the markers Sc34_8 and Sc35_2. The significant deviation revealed by the x 2 test could be due to the occurrence of zygotic selection in this locus, resulting changes in allele and genotypic frequencies in both populations.

The segregation of the markers GF18-06 and GF18-08, linked to the Rpv3 resistance locus, was Mendelian in one population and distorted in the other (Table 2). The Mendelian segregation occurred in the UFSC-2013-2 population: 53 Rpv3/Rpv3, 104 Rpv3/rpv3 and 52 rpv3/rpv3 [ x 2 = 0.014 (P = 0.99)]. In the UFSC-2013-1 population, both markers segregated to proportion of 132 Rpv3/Rpv3, 205 Rpv3/rpv3 and 76 rpv3/rpv3 [ x 2 = 15.20 (P= 0.0005)], therefore, distorted. Significant deviations in the value of χ² in that population were partly influenced by the death of 51 sensitive plants.

The deviation from the expected Mendelian segregation ratio has often been observed in the offspring of intra- and inter-species hybrids (Harushima et al. 1996Harushima Y, Kurata N, Yano M, Nagamura Y, Sasaki T, Minobe Y and Nakagahra M (1996) Detection of segregation distortions in an indica-japonica rice cross using a high-resolution molecular map. Theoretical and Applied Genetics 92: 145-150. ). Thus, segregation distortion comprises a group of systems of genic drive found in a wide range of organisms, usually involving a small number of interacting primary loci (Lyttle 1991Lyttle TW (1991) Segregation distorters. Annual Review of Genetics 25: 511-557. ).

Because the parental donor VRH 3082-1-42 had been obtained from interspecific cross between Muscadinia rotundifolia G52 x Malaga seedling No.1 (V. vinifera), followed by four backcrosses to V. vinifera varieties (Pauquet et al. 2001Pauquet J, Bouquet A, This P and Adam-Blondon AF (2001) Establishment of a local map of AFLP markers around the powdery mildew resistance gene Run1in grapevine and assessment of their usefulness for marker assisted selection. Theoretical and Applied Genetics 103: 1201-1210. ), it is possible that the plants inherited, in addition to resistance alleles of locus Run1 (that is linked to Rpv1), some factor that cause the deviations of segregation on the region where the allele of resistance Rpv1 is located. In this same cross, Bouquet (1986Bouquet A (1986) Introduction dans l’espèce Vitis vinífera L. d’un caractère de résistance à l’o (Uncinula necator Schw. Burr.) issu de l’espèce Muscadinia rotundifolia (Michx.) Small. Vignevini 12 (suppl): 141-146.) observed a high distorted segregation ratio due to chromosome disequilibrium and plant mortality. Likewise, Pauquet et al. (2001Pauquet J, Bouquet A, This P and Adam-Blondon AF (2001) Establishment of a local map of AFLP markers around the powdery mildew resistance gene Run1in grapevine and assessment of their usefulness for marker assisted selection. Theoretical and Applied Genetics 103: 1201-1210. ), studying populations of the fourth and fifth backcross to V. vinifera from this same cross (M. rotundifolia x M. seedling), also found two populations with an excess of susceptible genotypes that caused a distorted segregation ratio. The authors hypothesized that this was the result of the influence of genetic background from which the gene was taken. A comparison of physical and genetic mapping data indicates that recombination is severely repressed in the vicinity of Run1 (chromosome 12), possibly due to divergent sequence contained within the introgressed fragment from M. rotundifolia that carries the locus Run1 (Backer et al. 2005Barker CL, Donald T, Pauquet J, Ratnaparkhe A, Bouquet A, Adam-Blondon AF, Thomas MR and Dry I (2005) Genetic and physical mapping of the grapevine powdery mildew resistance gene, Run1, using a bacterial artificial chromosome library. Theoretical and Applied Genetics 111: 370-377. ), which is linked to Rpv1.

Segregation distortions were also found in other interspecific crosses when one of the homozygotes was favored, which may suggest the involvement of gametophytic and zygotic factors. In grapes, segregation distortions were found in the crosses V. rupestres x V. arizonica/girdiana (Riaz et al. 2006Riaz S, Krivanek AF, Xu K and Walker MA (2006) Refined mapping of the Pierce’s disease resistance locus, PdR1, and Sex on an extended genetic map of Vitis rupestris x V. arizonica. Theoretical and Applied Genetics 113: 1317-1329.), and V. vinifera x V. arizonica/candicans (Riaz et al. 2008Riaz S, Tenscher AC, Rubin J, Graziani R, Pao SS and Walker MA (2008) Fine-scale genetic mapping of two Pierce’s disease resistance loci and a major segregation distortion region on chromosome 14 of grape. Theoretical and Applied Genetics 117: 671-681. ). In the chromosomal region where the allele Run1/Rpv1 is located, the zygotic selection acted in favor of susceptible homozygous or heterozygous genotypes in the two studied populations, which can prevent the development of a larger number of plants homozygous with resistance alleles. Thus, the deficit of homozygote genotypes found in the present work for the resistance alleles suggests the occurrence of zygotic selection.

Phenotyping

One-fourth of the genotyped plants were tested phenotypically for resistance to downy mildew, whereby all nine obtained allelic combinations for the two populations are represented (Table 1). The analysis of the average number of sporangia per leaf disc resulted in the formation of three general groups: the first group showed the highest incidences of mildew infection and were associated with absence of resistance alleles; the second group showed moderate infection and was associated with resistance alleles in one locus, regardless if the alleles were homozygous or heterozygous (Rpv1/rpv1, rpv3/rpv3; Rpv1/Rpv1, rpv3/rpv3; rpv1/rpv1, Rpv3/rpv3 and rpv1/rpv1, Rpv3/Rpv3); and the third group showed the least incidences of infection and exhibited pyramiding of resistance alleles (Rpv1/rpv1, Rpv3/rpv3; Rpv1/Rpv1, Rpv3/rpv3; Rpv1/rpv1, Rpv3/Rpv3 and Rpv1/Rpv1, Rpv3/Rpv3). Genotypes with at least one resistance allele in each loci demonstrated better performance in the disease control compared to plants with one or neither resistance allele in both loci (Figure 2). The lowest average value of sporangiophores/disc (4.9) was observed in plants homozygous for both loci carrying the resistance alleles.

Table 1 includes also the phenotypic mean for downy mildew resistance, in which the number of sporangiophores was converted to 9 to 1 Scale, according to OIV 452. Again, it was possible to verify that the resistance alleles of the locus Rpv3 have higher contribution to resistance to downy mildew.

Resistance to P viticola in grape is greatly increased through pyramiding resistance alleles (Figure 3). Plants with absence of resistance alleles showed the highest level of infection = 2.1; s=1.7). Intermediate resistance was shown by genotypes with resistance alleles in one of the loci (Rpv1, =4.0; s=2.1 and Rpv3, =4.9; s=2.2), and the highest level of resistance was obtained with the presence of resistance alleles in both loci  =7.2; s= 2.0). However, the presence of a specific resistance allele was not enough to consistently be associated with a specific phenoype (Figure 3). The frequency distribution indicated that, in addition to the resistance alleles, the genetic background of the plant could be responsible for the variation of phenotypes associated with plants with the same alleles. In this study, plants with the same genotypic class showed varying response to the pathogen in each inoculation (Figure 2). In addition, the effect of single locus or combination of resistance genes was associated with degrees of resistance. Thus, when the plants carried resistance alleles from only one locus, regardless whether it homozygous or heterozygous, the disease control was less than or equal to 45.1%. However, when the plants carried a combination of resistance alleles of two loci the infections control by P. viticola was between 76.8 to 88.9%.

The inoculation technique on leaf discs is widely used in genetic resistance studies against P. viticola. In grape, this strategy is effective for distinguishing phenotypic differentiation between resistant and susceptible plants. With the use of first bioassays in grape leaves, it was possible to select genotypes with reasonable accuracy. This approach could possibly be used as a diagnostic marker for selecting which individual plants with disease resistance are most suitable to be planted in the field (Calonnec et al. 2013Calonnec A, Wiedemann‐Merdinoglu S, Deliere L, Cartolaro P, Schneider C and Delmotte F (2013) The reliability of leaf bioassays for predicting disease resistance on fruit: a case study on grapevine resistance to downy and powdery mildew. Plant Pathology 62: 533-544.). The combination of alleles at loci Rpv1 and Rpv3 showed better disease control when compared to the intermediate resistance of individual loci. These results suggest that each locus has a partial and additive effect on grape resistance to downy mildew and the dominance of the resistance allele within a locus.

Phenotype variations in plants carrying the same resistance alleles might be partially due to the methodology and the different genetic backgrounds of each resistance alleles. It is also possible that some minor QTLs or other coding sequences, which also participate in plant pathogen response, segregated in the studied populations. Therefore, different genotypes with the same major resistance alleles can show different degrees of disease resistance, as based on observed average confidence levels for disease resistance in each genotype in this study.

Previously, Eibach et al. (2007Eibach R, Zyprian E, Welter L and Töpfer R (2007) The use of molecular markers for pyramiding resistance genes in grapevine breeding. Vitis 46: 120-124. ) demonstrated that the combination of alleles from both genes Rpv1 and Rpv3 in the F 1 progeny of the cross VRH3082-1-42 x Regent, resulted in an additive effect in disease resistance. Likewise, Schwander et al. (2012Schwander F, Eibach R, Fechter I, Hausmann L, Zyprian E and Töpfer R (2012) Rpv10: a new locus from the Asian Vitis gene pool for pyramiding downy mildew resistance loci in grapevine. Theoretical and Applied Genetics 124: 163-176. ) observed an additive effect on resistance to downy mildew by combining the Rpv3 and Rpv10 resistance loci, indicating that they are applicable for pyramiding of resistance pathway MAS. Introgression of resistance alleles Rpv3 and Rpv12 from V. amurensis to V. vinifera also showed the positive effects of pyramiding resistance genes; plants heterozygous for both alleles restricted pathogen growth much more effectively than plants with only one or neither of the resistance alleles (Venuti et al. 2013Venuti S, Copetti D, Foria S, Falginella L, Hoffmann S, Bellin D, Cindric P, Kozma P, Scalabrin S, Morgante M, Testolin R and Di Gaspero G (2013) Historical introgression of the downy mildew resistance gene Rpv12 from the asian species Vitis amurensis into grapevine varieties. PLoS ONE 8: e61228. doi:10.1371/journal.pone.0061228.
https://doi.org/10.1371/journal.pone.006... ).

The positive effect of resistance gene pyramiding in controlling pathogens extends to other plant species: Exserohilum turcicum and Sphacelotheca reiliana in maize (Min et al. 2012Min J, Chunyu Z, Khalid H, Nan L, Quan S, Qing M, Suwen W and Feng L (2012) Pyramiding resistance genes to northern leaf blight and head smut in maize. International Journal of Agriculture & Biology 14: 430-434. ); Pyricularia grisea Sacc in rice (Hittalmani et al. 2000Hittalmani S, Parco A, Mew TV, Zeigler RS and Huang N (2000) Fine mapping and DNA marker-assisted pyramiding of the three major genes for blast resistance in rice. Theoretical and Applied Genetics 100: 1121-1128.); Phakopsora pachyrhizi in soybean (Maphosa et al. 2012Maphosa M, Talwana H and Tukamuhabwa P (2012) Enhancing soybean rust resistance through Rpp2, Rpp3 and Rpp4 pair wise gene pyramiding. African Journal of Agricultural Research 7: 4271-4277.).

The analyzed plants in the current study containing resistance alleles in homozygous state at the two loci showed the best results in terms of disease control. However, these genotypes did not react significantly different to P. viticola from other genotypic classes that have pyramided resistance alleles at the two loci, suggesting other type of gene action than additive effect between distinct alleles.

The results of the phenotypic evaluations showed that the loci Rpv1 and Rpv3 contribute significantly to disease control against downy mildew. The creation of plants homozygous with resistance alleles Rpv1 and Rpv3 is greatly useful to breeders and may contribute to creation of new elite cultivars. These selected plants can be crossed with other varieties of economic interest, ensuring that the F 1 plants will carry at least one resistant allele in each locus and ensuring some level of disease resistance. In addition, they can speed up the breeding programs due to the reduction of time in getting resistant varieties. Moreover, the selected resistant plants could be used to introduce resistant alleles in currently used tolerant cultivars, such as BRS Vitoria, which is tolerant to downy mildew (Maia et al. 2014Maia JDG, Ritschel P, Camargo UA, Souza RTD, Fajardo TVM, Naves RDL and Girardi CL (2014) 'BRS Vitória' - a novel seedless table grape cultivar exhibiting special flavor and tolerance to downy mildew (Plamopara viticola). Crop Breeding and Applied Biotechnology 14: 204-206.), since it is of the interest of a local viticulture industry, especially those ones focused on the fruit export.

ACKNOWLEDGEMENT

We are grateful to Fundação de Amparo à Pesquisa do Estado de Santa Catarina (FAPESC) and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for financial resources, and scholarship to RON, Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) and Secretaria Nacional de Educación Superior, Ciencia, Tecnología e Innovación - Ecuador (SENESCYT) for scholarship to FDSM.

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