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Obtaining interspecific hybrids, and molecular analysis by microsatellite markers in grapevine

Obtenção de híbridos interespecíficos e análise molecular por marcadores microssatélites em videira

Abstracts

The objective of this work was to assess the potential of interspecific hybridization of Vitis labruscana and Muscadinia rotundifolia by using artificial cross-pollinations. Microsatellite markers were used to confirm interspecific hybridizations and the identity of the parental genotypes. In crosses in which M. rotundifolia was used as the female parent, no true hybrids were obtained. In the reciprocal crosses, 114 seedlings were identified as true V. labruscana x M. rotundifolia hybrids. Self pollination occurred in direct and in reciprocal crosses. The crossings between 'Bordo' x 'Carlos', 'Magnolia', 'Regale' and' Roanoke', and between' Isabel' x 'Bountiful', 'Carlos', 'Magnolia', 'Regale' and 'Roanoke' were confirmed. The 15 markers evaluated showed that two M. rotundifolia parental genotypes had the same fingerprint profile, indicating a like lyplanting error. The success of hybridization depends mainly on the species and on the cultivar used as the female parent. Microsatellite markers are efficient to confirm the paternity of interspecific F1 hybrids and to determine the correct identity of M. rotundifolia cultivars.

Muscadinia rotundifolia; Vitis labruscana; hybrid identification; interspecific crosses; SSRs


O objetivo deste trabalho foi avaliar o potencial da hibridação interespecífica entre Vitis labruscana e Muscadinia rotundifolia por meio de polinizações cruzadas artificiais. Marcadores microssatélites foram utilizados para confirmar as hibridizações interespecíficas e a identidade dos parentais. Nos cruzamentos em que M. rotundifolia foi utilizada como parental feminino, nenhum híbrido verdadeiro foi obtido. Nos cruzamentos recíprocos, 114 plântulas foram identificadas como verdadeiros híbridos de V. labruscana x M. rotundifolia. Ocorreu autopolinização nos cruzamentos diretos e nos recíprocos. Foram confirmados os cruzamentos 'Bordo' x 'Carlos', 'Magnolia', 'Regale' e 'Roanoke', e 'Isabel' x 'Bountiful', 'Carlos', 'Magnolia', 'Regale' e 'Roanoke'. Os 15 marcadores avaliados revelaram que dois parentais de M. rotundifolia apresentaram o mesmo perfil genético, o que indica provável erro de plantio. O sucesso da hibridização depende principalmente da espécie e da cultivar utilizada como parental feminino. Os marcadores microssatélites são eficientes para confirmar a paternidade de híbridos interespecíficos F1 e para determinar a correta identidade de cultivares de M. rotundifolia.

Muscadinia rotundifolia; Vitis labruscana; identificação híbrida; cruzamentos interespecíficos; SSRs


POMOLOGY

Obtaining interspecific hybrids, and molecular analysis by microsatellite markers in grapevine

Obtenção de híbridos interespecíficos e análise molecular por marcadores microssatélites em videira

Mariane Ruzza SchuckI; Luiz Antonio BiasiI; Ada Michele MarianoI; Bernardo LipskiI; Summaira RiazII; Michael Andrew WalkerII

IUniversidade Federal do Paraná, Departamento de Fitotecnia e Fitossanitarismo, CEP 80035-050 Curitiba, PR, Brazil. E-mail: schuck337@gmail.com, biasiufpr@gmail.com, adamichele@ibest.com.br, bernardolipski@hotmail.com

IIUniversity of California, Department of Viticulture and Enology, Davis, CA 95616, USA. E-mail: snriaz@ucdavis.edu, awalker@ucdavis.edu

ABSTRACT

The objective of this work was to assess the potential of interspecific hybridization of Vitis labruscana and Muscadinia rotundifolia by using artificial cross-pollinations. Microsatellite markers were used to confirm interspecific hybridizations and the identity of the parental genotypes. In crosses in which M. rotundifolia was used as the female parent, no true hybrids were obtained. In the reciprocal crosses, 114 seedlings were identified as true V. labruscana x M. rotundifolia hybrids. Self pollination occurred in direct and in reciprocal crosses. The crossings between 'Bordo' x 'Carlos', 'Magnolia', 'Regale' and' Roanoke', and between' Isabel' x 'Bountiful', 'Carlos', 'Magnolia', 'Regale' and 'Roanoke' were confirmed. The 15 markers evaluated showed that two M. rotundifolia parental genotypes had the same fingerprint profile, indicating a like lyplanting error. The success of hybridization depends mainly on the species and on the cultivar used as the female parent. Microsatellite markers are efficient to confirm the paternity of interspecific F1 hybrids and to determine the correct identity of M. rotundifolia cultivars.

Index terms:Muscadinia rotundifolia, Vitis labruscana, hybrid identification, interspecific crosses, SSRs.

RESUMO

O objetivo deste trabalho foi avaliar o potencial da hibridação interespecífica entre Vitis labruscana e Muscadinia rotundifolia por meio de polinizações cruzadas artificiais. Marcadores microssatélites foram utilizados para confirmar as hibridizações interespecíficas e a identidade dos parentais. Nos cruzamentos em que M. rotundifolia foi utilizada como parental feminino, nenhum híbrido verdadeiro foi obtido. Nos cruzamentos recíprocos, 114 plântulas foram identificadas como verdadeiros híbridos de V. labruscana x M. rotundifolia. Ocorreu autopolinização nos cruzamentos diretos e nos recíprocos. Foram confirmados os cruzamentos 'Bordo' x 'Carlos', 'Magnolia', 'Regale' e 'Roanoke', e 'Isabel' x 'Bountiful', 'Carlos', 'Magnolia', 'Regale' e 'Roanoke'. Os 15 marcadores avaliados revelaram que dois parentais de M. rotundifolia apresentaram o mesmo perfil genético, o que indica provável erro de plantio. O sucesso da hibridização depende principalmente da espécie e da cultivar utilizada como parental feminino. Os marcadores microssatélites são eficientes para confirmar a paternidade de híbridos interespecíficos F1 e para determinar a correta identidade de cultivares de M. rotundifolia.

Termos para indexação:Muscadinia rotundifolia, Vitis labruscana, identificação híbrida, cruzamentos interespecíficos, SSRs.

Introduction

The use of rootstocks in viticulture is a widespread practice. Since the invasion by phylloxera [Daktulosphaira vitifoliae (Fitch, 1856)], grape growers began grafting susceptible Vitis vinifera L. fruiting cultivars onto rootstocks bred from resistant NorthAmerican Vitis species, particularly V. rupestris Scheele, V. riparia Michx., V. berlandieri Planch. and V. labruscana L.H. Bailey. However, in addition to phylloxera resistance, a good rootstock must show adaptability to the local climate and soil conditions, besides easy rooting, affinity with the scion, good vegetative growth, longevity and resistance or tolerance to pests and pathogens (Reynolds &Wardle, 2001).

Rootstock usage in the wine regions of Southern Brazil is dominated by different North American hybrid cultivars. Some of these cultivars are considered traditional, such as Solferino, SO4, Kober 5BB and 101-14 Mgt (V. berlandieri x V. riparia), whereas others were more recently introduced, such as Paulsen 1103 and R99 (V. berlandieri x V. rupestris). Although these rootstocks have been recommended due to their resistance to Fusarium oxysporum Schlecht., they are the most susceptible to the main soil pest of this region, the Brazilian ground pearl [Eurhizococcus brasiliensis Hempel (Hemiptera: Margarodidae)] (Botton & Colleta, 2010; Botton et al., 2010).

The muscadine genotypes [V. rotundifolia Michx. Syn. M. rotundifolia (Michx.) Small] are resistant to the Brazilian ground pearl (Botton & Colleta, 2010). This species has been classified as having the highest level of resistance to grape pests and disease (Kellow et al., 2002) and has consequently been used in many breeding programs worldwide to create resistant rootstocks. Although M. rotundifolia (2n = 40) is not used as a rootstock, due to its graft incompatibility with commercial cultivars of Vitis species (2n = 38) and to its inability to form roots from dormant cuttings (Goldy & Onokpise, 2001), interspecific hybrids showing compatibility were created with Vitis species (Olmo, 1986). Some hybrids from these crosses, including VR039-16 and VR043-43 (V. vinifera x M. rotundifolia), released by the grape breeding program at the University of California, Davis, CA, USA (Walker et al., 1991), are currently the main rootstocks used for management of the Brazilian ground pearl (Dalbó et al., 2007). However, 'VR043-43' is no longerrecommended for use inphylloxera-infestedsites, since the resistance of its rootstock to Brazilian ground pearlw as recently placed in doubt (De Césaro, 2008). Its full sibling 'VRO39-16 'is only recommended for use in grapevine fanleaf virus-infected sites, as its long-term resistance to phylloxera is also questionable (Smith, 2010). Therefore, given that phylloxera resistance should be in the background of all new rootstocks and that the use of V. vinifera in rootstock development has almost invariably been disappointing, it is important to develop rootstocks with broader Brazilian ground pearl resistance and durable resistance to phylloxera, which can be obtainedthrough breeding.

The hybridization of North American species with M. rotundifolia is an alternative to hybridization with V. vinifera. Among the many North American species, V. labruscana hybrids are well adapted to the wine regions of Southern Brazil. These hybrids are commonly planted with their own roots and show some resistance to soil pathogens, such as F. oxysporum (Garrido et al., 2004), besides adequate phylloxera resistance. However, these hybrids do not exhibit the high level of resistance to E. brasiliensis that M. rotundifolia cultivars do.

In breeding, molecular markers have been used as a tool to reduce the time required to develop a new cultivar. Among the various uses of molecular markers, the identification of true hybrids is an extremely useful tool in breeding programs. Therefore, the use of molecular markers to identify plants from crosses is highly important, so that plants from self or undesirable crosses can be identified and discarded in the F1 generation (Cordeiro et al., 2006).

The objective of this work was to assess the potential of interspecific hybridization of V. labruscana and M. rotundifolia by using artificial cross-pollinations.

Materials and Methods

All crosses were done at the Estação Experimental do Canguiri, of Universidade Federal do Paraná, Pinhais, PR, Brazil (25º25'S, 49º08"W, at 930-m altitude), and at the Estação Experimental de Videira, Videira, SC, Brazil (27º0'5"S, 51º7'60"W, at 750-m altitude) and at the Estação Experimental de Campos Novos, Campos Novos, Santa Catarina, Brazil (27º23'60"S, 51º12'0"W,at 947-maltitude), of Empresa de Pesquisa Agropecuária e Extensão Rural de Santa Catarina (Epagri). The controlled crosses were made in both directions between M. rotundifolia cultivars: Bountiful, Carlos, Magnolia, Magoon, Regale and Roanoke, and V. labruscana cultivars: Bordo, Goethe, Isabel, Marta and Niagara Rosada, in 2008 and 2009. Sixty crosses were made. The number of controlled artificial pollinations varied among the crosses depending on the availability of flowers (Tables 1 and 2). Simple sequence repeat (SSR) markers were used to confirm the paternity of the putative hybrids and to authenticate the identity of the parental genotypes.

The controlled crosses were performed according to Leão & Borges (2009). The female parents were emasculated before anthesis and bagged with paper bags to avoid contamination from unwanted pollen. The pollen was collected from flower clusters before anthesis in the morning, eliminating open flowers. The anthers were separated from the calyptra with a sieve, placed in petri dishes and dried at room temperature (20 to 25ºC) for three days. The pollen was placed in small bottles, labeled and stored in a desiccator with silica gel at 4ºC. Pollination was done with a brush for three consecutive days when the stigmas of the female parents were receptive, and the inflorescences were covered with paper bags.

Due to uneven maturation, the berries were harvested individually from January to April in both years. The seeds were extracted by forcing the fruits through a sieve, washed with water to remove the pulp, treated with a fungicide solution of Cercobin 2 g L-1 and then placed in moist media of sterilized vermiculite in petri dishes and stratified at 4ºC for a period of 75 days to break dormancy. Seeds were planted in seedling trays containing a steam-sterilized commercial substrate of Plantmax. When the first true leaves of seedlings appeared, they were transferred to individual pots (125 cm3), containing a mixture of 2 Plantmax:1soil:1 humus:1 vermiculite, and kept in the greenhouse.

Lyophilized leaf tissue of the parental genotypes and putative F1 hybrids was homogenized with DNA extraction buffer in plastic bags using a Homes 6 mechanical homogenizer (Bioreba, Longmont, CO, USA). DNA was extracted with a modified CTAB (hexadecyltrimethylammonium bromide) procedure (Riaz et al., 2004). In the final step, DNA pellets were suspended in 100 µL 1X Tris-EDTA buffer and stored at -20ºC. The integrity of the DNA was visualized on 1.2% agarose gel.

To analyze the extent of polymorphism of SSR markers in the parental genotypes, a set of 20 SSRs were tested on the M. rotundifolia and V. labruscana cultivars. A quality score, A, B, C or D, was given to each marker: Score A was given to four primer pairs (UDV41, UDV43, VrZAG62 and VVIN75) of good quality, displaying clear single band patterns easily scorable in both parents; score B to four medium quality markers (VVIM11, VVIC72, VVMD5 and VVMD31), displaying smears and fainter bands occasionally difficult to read; score C to three markers (UDV76, UDV111 and VVIP16), displaying multiband profiles; andscoreDtotenmarkers(UDV35,UDV111,VVIV05, VVIV21,UDV32,UDV35,UDV67,UDV124,VVIB68 and NVMCNG), producing smears, non-reproducible bands or no products. The four markers with score A were run on the entire populations to confirm the hybrid origin of the progenies. To verify the identity of the parental genotypes used in the crosses, the molecular profile of five M. rotundifolia cultivars was compared to the Grape DNA Identification Reference Database (Foundation Plant Services, University of California, Davis, CA, USA) with 15 SSR markers. However, 'Roanoke' was not analyzed due to its absence in the reference database. DNA fingerprinting of the V. labruscana cultivars was done in a previous study by Schuck et al. (2009). The SSR markers used in the present study were VVS2, VVMD5, VVMD7, VVMD27, VVMD31, VVMD32, VrZag62, VrZag79, VMC4f3.1, VMC8g9, VMC7f2, VMC3df, VMC5a1, VMC5h2 and UDV108. PCR conditions used were described by Riaz et al. (2004). PCR reactions were carried out in 10 µL reaction mixtures containing 5 pmol of each primer, 2.5 mmol L-1 of each dNTP, 1 µL 10X gold PCR buffer (Perkin Elmer Inc., Wellesley, MA, USA), 0.5 unit AmpliTaq Gold DNA polymerase (Perkin ElmerInc.,Wellesley, MA, USA), 2 mmol L-1 of MgCl2 solution and 10 ng of genomic DNA. Temperature cycling for PCR was carried out on either a Peltier Thermal Cycler-200 (MJ Research, Inc., Waltham, MA, USA) or on a Bio-Rad iCycler (Bio-Rad Laboratories, Hercules, CA, USA). The following cycling program was used: denaturation of DNA and activation of Taq DNA polymerase at 95ºC for 10 min; 35 cycles of amplification distributed in 45 s at 94ºC, 45 s at 56ºC and 1 min at 72ºC; final extension of 10 min at 72ºC; and cooling at 4ºC. To separate amplification products, PCR reactions were mixed with denaturing dye (98% formamide, 10 mmol L-1 EDTA, 0.05% bromophenol blue and xylene cyanol) and heated at 94ºC for 2 min before loading on a 5% polyacrylamide sequencing gel. Gels were run at constant 70Wfor 2-3 hours depending on allele sizes. Samples were visualized by silver staining with a commercial kit (Promega, Madison,WI, USA). Assuming Mendelian inheritance of the SSR loci, each of the analyzed progeny genotypes was considered to be ahybrid when oneof the two SSR alleles amplified with each locus was common to the alleles in the maternal genotype and the other was the same as one of the SSR alleles found in the paternal genotype. All gels were scanned and storedin a digital archive.

Results and Discussion

In 2008, 30 cross combinations were made between six M. rotundifolia cultivars; Bountiful, Carlos, Magnolia, Magoon, Regale and Roanoke, and five V. labruscana cultivars: Bordo, Goethe, Isabel, Marta and Niagara Rosada. A total of 14,775 flowers were pollinated with V. labruscana pollen and 217 berries (1.5% fruit set) were obtained. From these berries, 427 seeds were extracted and 236 germinated (Table 1). The number of berries obtained compared to the total flowers pollinated was extremely low, indicating that the crosses were very inefficient. Therefore, crosses using M. rotundifolia as the seed parent were not repeated in 2009. In 2008 and 2009, the reciprocals V. labruscana x M. rotundifolia were also made, and 9,398 V. labruscana flowers were pollinated producing 416 berries (4.4% fruit set), 1,040 seeds and 342 seedlings (Table 2).

DNA fingerprinting with the SSR loci UDV41, UDV43, VrZAG62 and VVIN75 indicated that, whenever M. rotundifolia was used as the female and V. labruscana as the male parent, the crosses were a complete failure, producing no true hybrids but only direct descendants of M. rotundifolia. From 342, in the reciprocal crosses, 114 seedlings, originated from nine different crosses, were identified at all four markers as true V. labruscana x M. rotundifolia hybrids (Table 3).

In the crosses in which 'Isabel' was the female parent, 65 true hybrids were identified (Figure 1). All the M. rotundifolia cultivars used to pollinate 'Isabel' generated true hybrids, except 'Magoon'. The largest population of V. labruscana x M. rotundifolia consists of 27 seedlings (87.1% true hybrids) and is a cross of 'Isabel' x 'Magnolia'. From the cross 'Isabel' x 'Regale', 20 seedlings were evaluated and 17 F1 hybrids were confirmed. The cross 'Isabel' x 'Carlos' yielded 16 seedlings, of which 11 were true hybrids (68.8%). The highest percentage of hybrid formation was observed in the crosses 'Isabel' x 'Roanoke' and 'Isabel' x 'Bountiful', with 100% true hybrids. From these crosses, only nine and one seedlings were analyzed, respectively (Table 3).


The crosses between the female parent 'Bordo' with M. rotundifolia cultivars produced 49 true hybrids (43.4%) (Figure 2). Of the six cultivars used as the male parent with 'Bordo', two ('Bountiful' and 'Magoon') did not produce progenies with the SSR profile expected for F1 interspecific hybrids. The percentage of hybrid formation was highest in the crosses 'Bordo' x 'Regale' and 'Bordo' x 'Roanoke', with 68.9 and 50% true hybrids, respectively. The lowest percentage (29.6%) of true hybrids originated from the cross 'Bordo' x 'Magnolia'. Out of the 54 individuals analyzed, 16 were confirmed as true hybrids. From the cross 'Bordo' x 'Carlos', seven F1 plants were evaluated and three hybrids were confirmed (42.9%) (Table 3).


Though only five V. labruscana genotypes were used as female parents in the present study, a marked difference was observed between them in their crossability with M. rotundifolia. These results clearly indicate that the success of the interspecific crosses depends not only on the species and on the direction of the cross, but also on the genotypes of the species involved in the hybridization. Other authors showed that the V. vinifera cultivars used as the female genotype influenced the crossability with M. rotundifolia (Bouquet, 1980).

The chromosome difference between Vitis spp. (2n = 38) and M. rotundifolia (2n = 40) is considered the main reason for the low success of the crosses in both directions (Goldy & Onokpise, 2001). However, in crosses involving M. rotundifolia as the maternal parent, the difficulties in obtaining hybrids are higher than in the reciprocal (Bouquet, 1980; Olmo, 1986). The failure in obtaining hybrid seedlings when M. rotundifolia serves as the female parent can be attributed to the inability of Vitis spp. pollen tubes to successfully penetrate M. rotundifolia styles and to fertilize the egg cells (Lu & Lamikanra, 1996).

In addition to the genetic incompatibility between the species, phenological factors also limit the success of reciprocal crosses. In Southern Brazil, V. labruscana blooms from September to October, and M. rotundifolia from November to January. Because of this difference, in the present study, V. labruscana cultivars were double pruned, during their regular blooming period, to force them to bloom again so that fresh pollen from M. rotundifolia could be used in the flowers of V. labruscana.

Although fresh pollen was used to make these 60 crosses, crosses in both directions produced a high proportion of non-hybrids, all of which were the result of self-fertilization. Even though paper bags were placed over the pollinated flower clusters and the adjacent clusters on the same plant were eliminated to avoid contamination from unwanted pollen, wind could have deposited pollen on the emasculated clusters during the few seconds that the protective bags were removed to perform pollination. Therefore, bagging of flowers does not guarantee the lack of undesired pollinations (Neal & Anderson, 2004). Moreover, shoot position and bunch location on the shoot in the developing canopy also influence flowering (Vasconselos et al., 2009). In the present study, the inflorescences used in the crosses were from the mid cane of the shoots.

The average high temperatures reported for both years (2008/2009) in the three regions where the crosses were made (Pinhais, PR - 31ºC; Campos Novos, SC - 26.5ºC; and Videira, SC - 31ºC) may have induced early pollen maturation of the flower clusters near the end of the canes of the same plant and in the neighboring inflorescences of the same vine located a few meters away. This could have accelerated pollen drying and increased the chances of pollen being carried by the wind and being deposited on unprotected flowers of M. rotundifolia and V. labruscana before they bloomed. In addition, the role of insects as pollination agents cannot be rejected.

The use of microsatellite markers for the identification of true hybrids in the early stage of the selection process has shown to be a very useful tool. A high proportion of selfed plants were identified, which were discarded in the F1 generation, allowing for significant savings in resources, particularly time and space. In species with long breeding cycles, such as Vitis spp., the conventional process of hybrid identification by morphological differences is slow. Molecular tools may overcome these difficulties and open the way to new strategies for more efficient breeding.

The identification of the V. labruscana genotypes was part of a previous study, and the SSR profiles of the cultivars Bordo, Goethe, Isabel, Niagara Rosada and Marta were the same as those available in the data banks for the same cultivars using SSR markers VVS2, VVMD5, VVMD7, VVMD27, VrZag62 and VrZag79. Therefore, these cultivars were correctly identified (Table 4) (Schuck et al, 2009).

To confirm the identity of the M. rotundifolia parental genotypes, five cultivars were genotyped at 15 SSR loci. Consistent and reliable profiles were obtained for the five cultivars at all SSR markers. The genetic profile of the M. rotundifolia cultivars Bountiful, Carlos, Magnolia and Regale were identical to those of the reference database at all 15 SSR loci. However, 'Magoon' did not match the reference profile at the same SSR loci, but matched with 'Regale', indicating that the genotype was misnamed at the time of introduction and that the same genotype was planted under different names (Table 4).

The correct identification of accessions is a basic requirement for the coherent management of germ-plasm repositories and for the use of the germplasm in ongoing breeding programs. It is essential to identify the existence of synonyms, homonyms and naming errors to avoid future propagation and breeding errors. These mistakes are difficult to detect based on morphological descriptors, since they are highly influenced by environmental and developmental factors (Sefc et al., 2001). In contrast, SSRs markers have been used to solve problematic naming and for genetic diversity assessment (Leão & Motoike, 2011), for parentage analysis (Tapia et al., 2007) and to develop genetic maps (Riaz et al., 2004).

Conclusions

1. The hybridization success between V. labruscana and M. rotundifolia depends on the species and on the cultivar used as the female parent.

2. Cultivars of V. labruscana can be successfully crossed with pollen from M. rotundifolia cultivars, but all reciprocal combinations fail to produce true hybrids.

3. Crosses between V. labruscana cultivar Isabel x M. rotundifolia cultivars Bountiful, Carlos, Magnolia, Regale and Roanoke are possible, as well as crosses between V. labruscana cultivar Bordo x M. rotundifolia cultivars Carlos, Magnolia, Regale and Roanoke, indicating that these species can be used in breeding programs.

4. SSR markers are efficient to confirm the paternity of interspecific F1 hybrids and to determine the correct identity of M. rotundifolia cultivars.

Acknowledgments

To Conselho Nacional de Desenvolvimento Científico e Tecnológico, for financial support; to Programa de Apoio a Planos de Reestruturação e Expansão das Universidades Federais and to Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, for scholarships granted; to Empresa de Pesquisa Agropecuária e Extensão Rural de Santa Catarina and to Universidade Federal do Paraná, for support; and to Rong Hu, from the University of California, for assistance with the SSR analysis.

Received on July 22, 2011 and accepted on October 10, 2011

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Publication Dates

  • Publication in this collection
    17 Jan 2012
  • Date of issue
    Nov 2011

History

  • Received
    22 July 2011
  • Accepted
    10 Oct 2011
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