Linkage disequilibrium and population structure in <i>Fragaria chiloensis</i> revealed by SSR markers transferred from commercial strawberry

Oñate, Felipe Alberto; Hasbún, Rodrigo; Mora, Freddy; Figueroa, Carlos Rodrigo

doi:10.4025/actasciagron.v40i1.34966

ABSTRACT.

The Chilean strawberry [Fragaria chiloensis (L.) Mill.] is the maternal progenitor of the commercial strawberry (Fragaria ( ananassa Duch.), which is characterized by fruits with high organoleptic quality and is well-suited to areas where drought and salinity represent a constraint on crop growth and productivity. We examined the patterns of linkage disequilibrium, genetic diversity and population structure among 54 accessions of F. chiloensis to understand the genetic basis of this species. We used a core microsatellite marker set (n = 95) from a consensus linkage map of strawberry. A transferability rate of 82.1% (78/95) was found, and 38 markers were selected for this study. The SSR primers produced a total of 259 alleles, which varied between 112 and 342 bp. Lower genetic diversity at the species level (H_E = 0.17, Shannon’s index = 0.28) was found compared to previous studies of this species. No climatic region pattern for SSR diversity was observed. Structure analysis suggests that the accessions are grouped into three significantly differentiated clusters. Pairwise estimates of φ_ST indicated a low degree of differentiation between the three genetic groups (φ_ST = 0.023 to 0.06). These groups are in concordance with potential glacial refugia in the region, with many accessions being an admixture of them.

Keywords:
genetic diversity; microsatellites; Chilean strawberry; marker transferability

RESUMO.

O morango chileno [Fragaria chiloensis (L.) Mill.] é o progenitor materno do morangueiro comercial (Fragaria ( ananassa Duch.), caracterizado por frutos com alta qualidade organoléptica, sendo uma cultura bem adequada para áreas caracterizadas pela seca e a salinidade. Neste trabalho, foram examinados os padrões de desequilíbrio de ligação, diversidade genética e estrutura da populacional em 54 acessos de F. chiloensis, com o intuito de avaliar a base genética da espécie. Utilizou-se um conjunto de marcadores de microssatélites (n = 95) obtidos do mapa de ligação consenso do morango comercial. A taxa de transferibilidade foi de 82,1% (78/95). Dos marcadores transferidos, 38 foram selecionados e usados neste estudo, os quais produziram um total de 259 alelos, que variaram entre 112 e 342 pb. Encontrou-se uma menor diversidade genética ao nível da espécie (H_E = 0,17, índice de Shannon = 0,28), em comparação com estudos prévios com a espécie. Não foi observado padrão de região climática para a diversidade genética. A análise da estrutura sugere que os acessos são agrupados em três grupos significativamente diferenciados. As estimativas de pares de φST indicaram baixo grau de diferenciação entre os três grupos genéticos (φST = 0,023 a 0,06). Esses grupos estão em concordância com os potenciais refúgios glaciários na região, sendo muitas adições uma mistura deles.

Palavras-chave:
diversidade genética; microssatélites; morango chileno; transferibilidade de marcadores

Introduction

Fragaria chiloensis is a native Chilean polyploid species (2n = 8X = 56) of the Rosaceae family. This family includes many economically important edible fruit crops such as apples, peaches, and cherries (Folta & Davis, 2006Folta, K. M., & Davis, T. M. (2006). Strawberry genes and Genomics. Critical Reviews in Plant Sciences, 25(5), 399-415.). F. chiloensis (aka beach, Chilean or coastal strawberry) is best known as the parental mother of F. ( ananassa, the commercial strawberry (Hancock, Lavín, & Retamales, 1999Hancock, J., Lavín, A., & Retamales, J. B. (1999). Our southern strawberry heritage: Fragaria chiloensis of Chile. HortScience, 34(5), 814-816.). This species has a wide geographical distribution across the Chilean territory, from 34°55’S to 47°33’S and from sea level to 1850 m above (Lavín, Del Pozo, & Maureira, 2000Lavín, A., Del Pozo, A., & Maureira, M. (2000). Distribución actual de Fragaria chiloensis (L.) en Chile. Plant Genetic Resources Newsletter, 122, 24-28.). Although F. chiloensis is a small-scale cultivar with poor agronomical management over the last several years, it has gained attention due to the interesting organoleptic properties of its fruits turning into a fruit ripening study model (Cherian, Figueroa, & Nair, 2014Cherian, S., Figueroa, C. R., & Nair, H. (2014). ‘Movers and shakers’ in the regulation of fruit ripening: a cross-dissection of climacteric versus non-climacteric fruit. Journal of Experimental Botany, 65(17), 4705-4722.). Moreover, the plant is resistant to many pathogens and has adapted to different abiotic stresses, including drought and soil salinity (Retamales, Caligari, Carrasco, & Saud, 2005Retamales, J. B., Caligari, P. D. S., Carrasco, B., & Saud, G. (2005). Current status of the Chilean native strawberry (Fragaria chiloensis L. (Duch.) and the research needs to convert the species into a commercial crop. HortScience, 40(6), 1633-1634.). Thus, F. chiloensis has become a valuable source for the genetic improvement of the commercial strawberry, in particular for breeding programs with a limited genetic base (Stegmeir, Finn, Warner, & Hancock, 2010Stegmeir, T.L., Finn, C. E., Warner, R. M., & Hancock, J. F. (2010). Performance of an Elite Strawberry Population Derived from Wild Germplasm of Fragaria chiloensis and F. virginiana. HortScience, 45(8), 1140-1145.; Carrasco et al., 2007Carrasco, B., Garcés, M., Rojas, P., Saud, G., Herrera, R., Retamales, J. B., & Caligari, P. D. S. (2007). The Chilean strawberry [Fragaria chiloensis (L.) Duch.]: genetic diversity and structure. Journal of the American Society for Horticultural Science, 132(4), 501-506.). Recently, the characterization of a F. chiloensis germplasm collection has confirmed the potential for selective breeding of this Fragaria species (Mora, Concha, & Figueroa, 2016Mora, F., Concha, C. M., & Figueroa, C. R. (2016). Bayesian inference of genetic parameters for survival, flowering, fruit set, and ripening in a germplasm collection of Chilean Strawberry using threshold models. Journal of the American Society for Horticultural Science, 141(3), 285-291.).

Previous genetic studies of F. chiloensis have shown that it has high genetic diversity (Becerra, Paredes, & Lavín 2005Becerra, V., Paredes, M., & Lavín, A. (2005). Biochemical and molecular diversity in the Chilean strawberry and its implications for plant breeding. HortScience, 40(6), 1642-1643.; Carrasco et al., 2007Carrasco, B., Garcés, M., Rojas, P., Saud, G., Herrera, R., Retamales, J. B., & Caligari, P. D. S. (2007). The Chilean strawberry [Fragaria chiloensis (L.) Duch.]: genetic diversity and structure. Journal of the American Society for Horticultural Science, 132(4), 501-506.), as determined by using analysis of amplified fragment length polymorphism (AFLP) and inter simple sequence repeat (ISSR) markers. We proposed that the findings of these studies should be maintained by using genome-wide co-dominant markers such as simple sequence repeats (SSR), or at least validated, as has been proven in other species such as olive (Belaj et al., 2003Belaj, A., Satovic, Z., Cipriani, G., Baldoni, L., Testolin, R., Rallo, L., & Trujillo, I. (2003). Comparative study of the discriminating capacity of RAPD, AFLP, and SSR markers and of their respective effectiveness in establishing genetic relationships in olive. Theoretical and Applied Genetics, 107(4), 736-744.), maize (García et al., 2004García, A. A. F., Bemchimol, L. L., Barbosa, A. M. M., Geraldi, I. O., Souza Jr., C. L., & De Souza, A. P. (2004). Comparison of RAPD, RFLP, AFLP and SSR markers for diversity studies in tropical maize inbred lines. Genetics and Molecular Biology, 27(4), 579-588.) and Brassica napus (Li et al., 2011Li, L., Wanapu, C., Huang, X., Huang, T., Li, Q., Peng, Y., & Huang, G. (2011). Comparison of AFLP and SSR for genetic diversity analysis of Brassica napus hybrids. Journal of Agricultural Science, 3(3), 101-110.). In fact, SSR markers have been predominantly used in the Fragaria genus for genetic diversity studies, genetic mapping and identification of quantitative trait loci (QTL) (Sargent et al., 2012Sargent, D. J., Passey, T., Surbanovski, N., Lopez-Girona, E., Kuchta, P., Davik, J., … Simpson, D. W. (2012). A microsatellite linkage map for the cultivated strawberry (Fragaria ( ananassa) suggest extensive regions of homozygosity in the genome that may have resulted from breeding and selection. Theoretical and Applied Genetics, 124(7), 1229-1240.; Yoon et al., 2012Yoon, M., Moe, K. T., Kim, D., Rho, I., Kim, S., Kim, K., … Park, Y. (2012) Genetic diversity and population structure analysis of strawberry (Fragaria ( ananassa Duch.) using SSR markers. Electronic Journal of Biotechnology, 15(2), 1-16. doi: 10.2225/vol15-issue2-fulltext-5
https://doi.org/10.2225/vol15-issue2-ful... ; Zorrilla-Fontanesi et al., 2011Zorrilla-Fontanesi, Y., Cabeza, A., Domínguez, P., Medina, J. J., Valpuesta, V., Denoyes-Rothan, B., … Amaya, I. (2011). Quantitative trait loci and underlying candidate genes controlling agronomical and fruit quality traits in octoploid strawberry (Fragaria ( ananassa). Theoretical and Applied Genetics, 123(5), 755-778.). One reason that SSR markers are currently used in many species of the Fragaria genus, such as F. moschata, F. ( ananassa and F. virginiana (Gil-Ariza et al., 2006Gil-Ariza, D. J., Amaya, I., Botella, M. A., Muñoz-Blanco, J., Caballero, J. L., López-Aranda, J.M., … Sánchez-Sevilla, J. F. (2006). EST-derived polymorphic microsatellites from cultivated strawberry (Fragaria ×ananassa) are useful for diversity studies and varietal identification among Fragaria species. Molecular Ecology Notes, 6(4), 1195-1197.) is because they represent a valuable option for the genetic evaluation of polyploid species even if they are analyzed as dominant markers. In fact, according to Pffeifer, Roschanski, Pannell, Korkbecka, and Schnittler (2011Pffeifer, T., Roschanski, A. M., Pannell, J. R., Korkbecka, G., & Schnittler, M. (2011). Characterization of microsatellite loci and reliable genotyping in a polyploidy plant, Mercurialis perennis (Euphorbiaceae). Journal of Heredity, 102(4), 479-488.) SSR markers are more precise and reliable than other dominant markers such as AFLP and ISSR.

SSR markers can be found in both coding and non-coding regions of DNA, are widely used in genetic studies due to their abundance and co-dominance and are easy to read and interpret because they are present in just one locus per microsatellite (Rentaría-Alcántara, 2007Rentaría-Alcántara, M. (2007) Breve revisión de los marcadores moleculares. In: L. E. Eguiarte, V. Souza, & X. Aguirre (Eds.), Ecología Molecular (p. 541-566). México: Instituto Nacional de Ecología.). Cross-species amplification of SSR loci is considered a cost-effective method that facilitates genetic studies in species where sequence information is not available such as F. chiloensis. A cross-species SSR transferability rate between 70% and 100% has previously been reported in the Fragaria genus (Folta & Davis, 2006Folta, K. M., & Davis, T. M. (2006). Strawberry genes and Genomics. Critical Reviews in Plant Sciences, 25(5), 399-415.; Dirlewanger, Denoyes-Rothan, Yamamoto, & Chagné, 2009Dirlewanger, E., Denoyes-Rothan, B., Yamamoto, T., & Chagné, D. (2009). Genomics tools across Rosaceae species. In K. M. Folta, & S. E. Gardiner (Eds.), Genetics and Genomics of Rosaceae (p. 539-561). New York, USA: Springer.). The aim of this study was to examine the genetic diversity, linkage disequilibrium, and population structure in natural populations of F. chiloensis in order to improve the knowledge about the genetic basis of this species.

Material and methods

Plant material and DNA extraction

For genetic and population analysis, 54 accessions were studied covering most of the natural geographic range of this species in Chile: 51 accessions previously reported by Mora et al. (2016Mora, F., Concha, C. M., & Figueroa, C. R. (2016). Bayesian inference of genetic parameters for survival, flowering, fruit set, and ripening in a germplasm collection of Chilean Strawberry using threshold models. Journal of the American Society for Horticultural Science, 141(3), 285-291.) plus 3 other recently collected (Table 1). Samples were grouped as putative populations of 6 to 13 individuals per population according to their climatic distributions as reported by Lavín et al. (2000Lavín, A., Del Pozo, A., & Maureira, M. (2000). Distribución actual de Fragaria chiloensis (L.) en Chile. Plant Genetic Resources Newsletter, 122, 24-28.), which were noted as MTM (Marine and Temperate Mediterranean), FCM (Fresh and Cold Marine), HPM (Humid Patagonian Marine), CM (Cold Mediterranean) and PAT (Polar Alpine Tundra) (Table 1). DNA extraction from fresh leaves was performed using the DNeasy plant mini kit (Qiagen, USA) following manufacturer's instructions with slight modifications. We used 60 mg of fresh weight per sample instead of 100 mg. To remove phenolics from the samples, 4% (w/v) polyvinylpyrrolidone (Bioworld, USA) was added to AP1 buffer (Qiagen, USA). To obtain a higher yield of DNA, only one elution was performed with nanopure water at 70°C instead of two elutions at room temperature (15-25ºC) as recommend by the manufacturer.

Cross-species amplification of SSR markers

A total of ninety-five SSR markers distributed across the whole genome (i.e., 8 sets of chromosomes) of F. ( ananassa were screened for PCR amplification feasibility in F. chiloensis. The SSR primer pairs were selected from the first high-density SSR-based linkage map of F. ( ananassa (Sargent et al., 2012Sargent, D. J., Passey, T., Surbanovski, N., Lopez-Girona, E., Kuchta, P., Davik, J., … Simpson, D. W. (2012). A microsatellite linkage map for the cultivated strawberry (Fragaria ( ananassa) suggest extensive regions of homozygosity in the genome that may have resulted from breeding and selection. Theoretical and Applied Genetics, 124(7), 1229-1240.). Particular interest was given to markers associated with QTL in F. ( ananassa following the work of Zorrilla-Fontanesi et al. (2011Zorrilla-Fontanesi, Y., Cabeza, A., Domínguez, P., Medina, J. J., Valpuesta, V., Denoyes-Rothan, B., … Amaya, I. (2011). Quantitative trait loci and underlying candidate genes controlling agronomical and fruit quality traits in octoploid strawberry (Fragaria ( ananassa). Theoretical and Applied Genetics, 123(5), 755-778.). Cross-species amplification of SSR markers was carried out using ten F. chiloensis accessions selected from a germplasm collection (Mora et al., 2016Mora, F., Concha, C. M., & Figueroa, C. R. (2016). Bayesian inference of genetic parameters for survival, flowering, fruit set, and ripening in a germplasm collection of Chilean Strawberry using threshold models. Journal of the American Society for Horticultural Science, 141(3), 285-291.) according to their geographic distance (Table 1). The PCR amplifications were carried out in a total volume of 0.015 cm³, containing 20 ng of DNA template, 1X reaction buffer (5X MangoTaq Colored Reaction Buffer, Bioline, USA), 0.2 µM primers, 200 µM dNTPs, 2 mM MgCl₂ (Bioline, USA), and 0.5 U MangoTaq DNA polymerase (Bioline, USA). A T100^TM thermal cycler (Bio-Rad, USA) was used with the following amplification program: initial denaturation at 94°C for 3 min., 30 cycles of denaturation at 94°C for 30 s, annealing at 60°C for 30 s, and extension at 72°C for 45 s, and a final extension at 72°C for 10 min. SSR markers were considered successfully transferred if they had clear and intense amplification in at least 6 out of 10 samples, and in a 100 bp range of the size described for the marker, following the parameters described by Kuleung, Baezinger, and Dweikat (2004Kuleung, C., Baezinger, P. S., & Dweikat, I. (2004). Transferability of SSR markers among wheat, rye, and triticale. Theoretical and Applied Genetics, 108(6), 1147-1150.).

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Table 1
List of the fifty-four Fragaria chiloensis accessions used in this study. Putative Populations were established as MTM (Marine and Temperate Mediterranean), FCM (Fresh and Cold Marine), HPM (Humid Patagonian Marine), CM (Cold Mediterranean) or PAT (Polar Alpine Tundra) according to the climate regions described by Lavín et al. (2000Lavín, A., Del Pozo, A., & Maureira, M. (2000). Distribución actual de Fragaria chiloensis (L.) en Chile. Plant Genetic Resources Newsletter, 122, 24-28.).

Molecular data

Thirty-nine SSR markers were selected among the successfully transferred markers distributed across the F. ( ananassa linkage map carried out by Sargent et al. (2012Sargent, D. J., Passey, T., Surbanovski, N., Lopez-Girona, E., Kuchta, P., Davik, J., … Simpson, D. W. (2012). A microsatellite linkage map for the cultivated strawberry (Fragaria ( ananassa) suggest extensive regions of homozygosity in the genome that may have resulted from breeding and selection. Theoretical and Applied Genetics, 124(7), 1229-1240.). These SSR markers were amplified using the Multiplex-Ready PCR protocol (Hayden, Nguyen, Waterman, & Chalmers, 2008Hayden, M. J., Nguyen, T. M., Waterman, A., & Chalmers, K. J. (2008). Multiplex-Ready PCR: A new method for multiplexed SSR and SNP genotyping. BMC Genomics, 9, 80. doi: 10.1186/1471-2164-9-80
https://doi.org/10.1186/1471-2164-9-80... ). The reactions occurred in a total volume of 0.01 cm³, containing 20 ng of DNA template, 1X reaction buffer (10X PCR Buffer, Invitrogen, USA), 25 nM tag primers with either 6-FAM, VIC or PET fluorophores (Invitrogen, USA), 20 to 40 nM locus specific primers, 8 µg BSA (Bovine serum albumin), 200 µM dNTPs, 1.5 mM MgCl₂ (Invitrogen, USA), and 0.5 U Platinum Taq DNA polymerase (Invitrogen). A T100^TM thermal cycler (Bio-Rad, USA) was used with the following amplification program: initial denaturation at 94°C for 2 min., 20 cycles of denaturation at 92°C for 30 s, annealing at 63°C for 90 s, and extension at 72°C for 60 s, then 40 cycles of denaturation at 92°C for 15 s, annealing at 54°C for 30 s and extension 72°C for 60 s and a final extension at 72°C for 10 min. Samples were evaluated through capillary electrophoresis in an ABI3130 Genetic Analyzer (Applied Biosystems, USA) with an injection time of 10 s and 15,000 V, and it was run at 13,000 V in a 36 cm capillary. The resulting data were analyzed using Genemapper^® (v 4.0, Applied Biosystems, USA), and the detected alleles of each marker were converted to a binary matrix.

Genetic diversity and linkage disequilibrium

The GenAlEx 6.5 software package (Peakall & Smouse, 2006Peakall, R., & Smouse, P. E. (2006). GENALEX 6: genetic analysis in Excel. Population genetic software f or teaching and research. Molecular Ecology Notes, 6(1), 288-295.; Peakall & Smouse, 2012Peakall, R., & Smouse, P. E. (2012). GenAlEx 6.5: genetic analysis in Excel. Population genetic software for teaching and research-an update. Bioinformatics, 28(19), 2537-2539.) was used to calculate total number of alleles (N_A), effective alleles (N_E), Shannon’s index (S), percentage of polymorphic loci (P) and expected heterozygosity (H_E). Linkage disequilibrium (LD) was estimated using TASSEL 5 (Bradbury et al., 2007Bradbury, P. J., Zhang, Z., Kroon, D. E., Casstevens, T. M., Ramdoss, Y., & Buckler, E. S. (2007). TASSEL: software for association mapping of complex traits in diverse samples. Bioinformatics, 23(19), 2633-2635.) by means of pairwise linkage tests with 100,000 steps in Markov chain and 1,000 steps of dememorization. Pairwise LD was estimated for the entire set of F. chiloensis samples as well as for each genetic group derived from structure analysis. The program LOSITAN (Antao, Lopes, Lopes, Beja-Pereira, & Luikart, 2008Antao, T., Lopes, A., Lopes, R. J., Beja-Pereira, A., & Luikart, G. (2008). Lositan: A workbench to detect molecular adaptation based on a Fst-outlier method. BMC Bioinformatics, 9, 323. doi: 10.1186/1471-2105-9-323
https://doi.org/10.1186/1471-2105-9-323... ) was used to discriminate the SSR loci that did not fulfill the criteria of neutrality (outliers) following the work of Excoffier, Hofer, and Foll (2009Excoffier, L., Hofer, T., & Foll, M. (2009). Detecting loci under selection in a hierarchically structured population. Heredity, 103(4), 285-298.).

Population structure

The population structure determination and identification of admixed individuals were performed using the program STRUCTURE 2.3.4 (Pritchard, Stephens, & Donnelly, 2000Pritchard, J. K.; Stephens, M., & Donnelly, P. (2000). Inference of population structure using multilocus genotype data. Genetics, 155(2), 945-959.). Based on an admixture and independent allele frequency population model, we proposed that the number of genetic groups (K) could vary between 1 and 10, as previous studies suggested that a bigger number of groups would not be viable (Carrasco et al., 2007Carrasco, B., Garcés, M., Rojas, P., Saud, G., Herrera, R., Retamales, J. B., & Caligari, P. D. S. (2007). The Chilean strawberry [Fragaria chiloensis (L.) Duch.]: genetic diversity and structure. Journal of the American Society for Horticultural Science, 132(4), 501-506.). The K value was calculated from 3 independent repetitions for each possible K, with a burn-in value of 100,000 samples and the number of Gibbs chains estimated at 1,000,000. The optimal K value was calculated using a method described by Evanno, Regnaut, and Goudet (2005Evanno, G., Regnaut, S., & Goudet, J. (2005). Detecting the number of clusters of individuals using the software STRUCTURE: a simulation study. Molecular Ecology, 14(8), 2611-2620.) using STRUCTURE HARVESTER (Earl & vonHoldt, 2012Earl, D. A., & vonHoldt, B. M. (2012). Structure Harvester: a website and program for visualizing Structure output and implementing the Evanno method. Conservation Genetics Resources, 4(2), 359-361.). An analysis of molecular variance (AMOVA, p < 0.05; Excoffier, Smouse, & Quattro, 1992Excoffier, L., Smouse, P. E., & Quattro, J. M. (1992). Analysis of molecular variance inferred from metric distances among DNA haplotypes: application to human mitochondrial DNA restriction data. Genetics, 131(2), 479-491.) for the optimal K clusters, and the putative populations, was performed using GENALEX 6.5 (Peakall & Smouse, 2006Peakall, R., & Smouse, P. E. (2006). GENALEX 6: genetic analysis in Excel. Population genetic software f or teaching and research. Molecular Ecology Notes, 6(1), 288-295.). Pairwise estimates of the correlation of alleles within subpopulations (φ_ST) for the model-based groupings were calculated using an analysis of molecular variance (AMOVA) approach. Pairwise φ_ST estimates were calculated for all genetic groups determined by structure using the AMOVA approach in GENALEX 6.5 (Peakall & Smouse, 2006). φ_ST is a measure analogous to the better known F_ST derived from AMOVA (Meirmans & Hedrick, 2011Meirmans, P. G., & Hedrick, P. W. (2011). Assessing population structure: FST and related measures. Molecular Ecology Resources, 11(1), 5-18.).

Results and discussion

The SSR primers yielded a total of 259 alleles whose size varied between 112 and 342 bp. The population's genetic diversity parameters were estimated at P = 80%, H_E = 0.17, and S = 0.28, as shown in Table 2. These results are average results for mixed breeding plants assessed with dominant markers (Nybom, 2004Nybom, H. (2004). Comparison of different nuclear DNA markers for estimating intraspecific genetic diversity in plants. Molecular Ecology, 13(5), 1143-1155.), and they relate to our data because the SSR markers were evaluated as binary data. Compared to previous studies (Becerra et al., 2005Becerra, V., Paredes, M., & Lavín, A. (2005). Biochemical and molecular diversity in the Chilean strawberry and its implications for plant breeding. HortScience, 40(6), 1642-1643.; Carrasco et al., 2007Carrasco, B., Garcés, M., Rojas, P., Saud, G., Herrera, R., Retamales, J. B., & Caligari, P. D. S. (2007). The Chilean strawberry [Fragaria chiloensis (L.) Duch.]: genetic diversity and structure. Journal of the American Society for Horticultural Science, 132(4), 501-506.), we found lower heterozygosity, but that can be caused by differences in the samples utilized or the marker chosen for these studies.

Significant pairwise LD (p < 0.1) was observed in 3,752 pairs of loci. The r² values ranged from 0.001 and 0.652. The threshold beyond which the LD is probably caused by real physical linkage was estimated to be r² = 0.24. The intersection of the fitted curve of r² values with this threshold was considered to be an estimate of the range of LD (Figure 1; horizontal dotted line). Sixteen pairs of loci (0.4%) were higher than the threshold. The ﬁtted regression intersected the thresholds at approximately 4 cM. Reports of LD range in the Rosaceae family are scarce (Khan & Korban, 2012Khan, M. A., & Korban, S. S. (2012). Association mapping in forest trees and fruit crops. Journal of Experimental Botany, 63(11), 4045-4060.), however our result is slightly lower than that of wild Chinese landraces of peach at 6 cM (Cao et al., 2012Cao, K., Wang, L., Zhu, G., Fang, W., Chen, C., & Luo, J. (2012). Genetic diversity, linkage disequilibrium, and association mapping analyses of peach (Prunus persica) landraces in China. Tree Genetics & Genomes, 8(5), 975-990.). Meanwhile, improved peach cultivars had an LD range of 13.3-15.2 cM (Aranza, Abbassi, Howad, & Arus, 2010Aranza, M. J., Abbassi, E. K., Howad, W., & Arus, P. (2010). Genetic variation, population structure and linkage disequilibrium in peach commercial varieties. BMC Genetics, 11, 69. doi: 10.1186/1471-2156-11-69, 2010
https://doi.org/10.1186/1471-2156-11-69,... ).

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Table 2
Summary of statistics for the genetic variation of 54 Fragaria chiloensis accessions using 259 bands produced by 38 simple sequence repeat markers: (A) accessions grouped by climate region and (B) accessions grouped by genetic groups suggested by STRUCTURE software, which share at least >70% membership with any of the clusters. The abbreviations MTM, FCM, HPM, CM and PAT represent Marine and Temperate Mediterranean, Fresh and Cold Marine, Humid Patagonian Marine, Cold Mediterranean, and Polar Alpine Tundra, respectively, according to the climate regions described by Lavín et al. (2000Lavín, A., Del Pozo, A., & Maureira, M. (2000). Distribución actual de Fragaria chiloensis (L.) en Chile. Plant Genetic Resources Newsletter, 122, 24-28.).

In the population structure analysis, F. chiloensis accessions were previously and putatively grouped by climate region (Table 1). In this scenario, the genetic diversity parameters ranged between P = 54% and 76%, H_E = 0.15 and 0.16, and S = 0.24 and 0.27. The Bayesian clustering analysis always tended to group the accessions into three genetic groups, which was confirmed by the ad hoc quantity (ΔK) having its highest value (ΔK = 277.78) for K = 3. Thirty-nine samples shared > 70% membership with any of the genetic groups (Figure 2), whereas 15 samples were admixture forms with varying levels of membership shared among each group. Genetic group 1 consisted of 11 accessions, genetic group 2 of 11 accessions, and genetic group 3 of 17 accessions, with the remaining being an admixture. These groups had genetic diversity parameters similar to those of the putative populations by climate region (Table 1). An analysis among botanical forms was not performed, as only six accessions belonged to F. chiloensis ssp. chiloensis f. chiloensis.

Figure 1
Linkage disequilibrium (r²) plot of whole genome in 54 accessions of Fragaria chiloensis. The horizontal dotted lines indicate the 95^th percentile of the distribution of unlinked r², which gives the critical value of r².

Figure 2
Bar plot showing the probability of membership for 54 accessions (ordered from north to south) assessed using SSR markers. Each accession is represented by a vertical column. Black, light gray and dark gray bars correspond to genetic groups 1, 2, and 3, respectively.

According to the AMOVA, 96% of the genetic variation was present within the genetic groups. Meanwhile, 4% of the variation was present among the groups (Table 3). The average φ_ST of the overall loci was 0.043, and pairwise estimates of φ_ST indicated a low degree of differentiation between the three genetic groups with values ranging from 0.023 to 0.06. In comparison, Carrasco et al. (2007Carrasco, B., Garcés, M., Rojas, P., Saud, G., Herrera, R., Retamales, J. B., & Caligari, P. D. S. (2007). The Chilean strawberry [Fragaria chiloensis (L.) Duch.]: genetic diversity and structure. Journal of the American Society for Horticultural Science, 132(4), 501-506.) described that among F. chiloensis individuals grouped by latitude, genetic distance φ_ST = 0.03, which is remarkably similar to our results. It is worth noting that the genetic groups described by STRUCTURE analysis strongly resemble the distribution of potential glacial refuges in Chile (Figure 3), and samples that are not present in these refugia coincide with colonization routes described for other plant and vertebrate species (Sérsic et al., 2011Sérsic, A .N., Cosacov, A., Cocucci, A. A., Johnson, L. A., Pozner, R., Avila, L. J., … Morando, M. (2011). Emerging phylogeographical patterns of plants and terrestrial vertebrates from Patagonia. Biological Journal of the Linnean Society, 103(2), 475-494.). In particular, samples located in Chiloé Island and its surroundings are separated from the rest in the structure analysis and should be the focus of future in depth studies.

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Table 3
Analysis of molecular variance of 203 alleles from 38 simple sequence repeat bands in Fragaria chiloensis accessions: (A) 54 accessions of F. chiloensis grouped by climate region and (B) 54 accessions grouped according to the genetic groups suggested by structure analysis.

Figure 3
Map with the locations of the 54 accessions of Fragaria chiloensis used in this study. Each accession is represented by a circle with the probability of membership in each cluster determined by STRUCTURE analysis. Black, light gray and dark gray bars correspond to genetic group 1, genetic group 2 and genetic group 3, respectively.

Conclusion

In this study, we analyzed the patterns of linkage disequilibrium, genetic diversity and population structure present in natural populations of the Chilean strawberry. The genetic diversity showed lower values than in previous studies, with low genetic differentiation among genetic groups.

These results validate previous studies of the population structure of the species with different type of genetic markers, as expected. The genetic groups proposed through the structure analysis resemble historical ecological processes of other species that share the same habitat. Our results also provide preliminary insight into the degree of linkage disequilibrium among loci, which is moderate among inbred species.

Acknowledgements

This research was funded by the National Commission for Scientific and Technological Research (CONICYT, Chile), grant CONICYT, PIA/ACT-1110. F.A.O. acknowledges CONICYT for a master scholarship. In addition, the authors are grateful for the help of Mr. Andrés Esparza (Laboratorio de Ecología de Paisaje, Universidad de Concepción) in assistance for preparation of the map shown in Figure 3.

References

Antao, T., Lopes, A., Lopes, R. J., Beja-Pereira, A., & Luikart, G. (2008). Lositan: A workbench to detect molecular adaptation based on a Fst-outlier method. BMC Bioinformatics, 9, 323. doi: 10.1186/1471-2105-9-323
» https://doi.org/10.1186/1471-2105-9-323
Aranza, M. J., Abbassi, E. K., Howad, W., & Arus, P. (2010). Genetic variation, population structure and linkage disequilibrium in peach commercial varieties. BMC Genetics, 11, 69. doi: 10.1186/1471-2156-11-69, 2010
» https://doi.org/10.1186/1471-2156-11-69, 2010
Becerra, V., Paredes, M., & Lavín, A. (2005). Biochemical and molecular diversity in the Chilean strawberry and its implications for plant breeding. HortScience, 40(6), 1642-1643.
Belaj, A., Satovic, Z., Cipriani, G., Baldoni, L., Testolin, R., Rallo, L., & Trujillo, I. (2003). Comparative study of the discriminating capacity of RAPD, AFLP, and SSR markers and of their respective effectiveness in establishing genetic relationships in olive. Theoretical and Applied Genetics, 107(4), 736-744.
Bradbury, P. J., Zhang, Z., Kroon, D. E., Casstevens, T. M., Ramdoss, Y., & Buckler, E. S. (2007). TASSEL: software for association mapping of complex traits in diverse samples. Bioinformatics, 23(19), 2633-2635.
Cao, K., Wang, L., Zhu, G., Fang, W., Chen, C., & Luo, J. (2012). Genetic diversity, linkage disequilibrium, and association mapping analyses of peach (Prunus persica) landraces in China. Tree Genetics & Genomes, 8(5), 975-990.
Carrasco, B., Garcés, M., Rojas, P., Saud, G., Herrera, R., Retamales, J. B., & Caligari, P. D. S. (2007). The Chilean strawberry [Fragaria chiloensis (L.) Duch.]: genetic diversity and structure. Journal of the American Society for Horticultural Science, 132(4), 501-506.
Cherian, S., Figueroa, C. R., & Nair, H. (2014). ‘Movers and shakers’ in the regulation of fruit ripening: a cross-dissection of climacteric versus non-climacteric fruit. Journal of Experimental Botany, 65(17), 4705-4722.
Dirlewanger, E., Denoyes-Rothan, B., Yamamoto, T., & Chagné, D. (2009). Genomics tools across Rosaceae species. In K. M. Folta, & S. E. Gardiner (Eds.), Genetics and Genomics of Rosaceae (p. 539-561). New York, USA: Springer.
Earl, D. A., & vonHoldt, B. M. (2012). Structure Harvester: a website and program for visualizing Structure output and implementing the Evanno method. Conservation Genetics Resources, 4(2), 359-361.
Evanno, G., Regnaut, S., & Goudet, J. (2005). Detecting the number of clusters of individuals using the software STRUCTURE: a simulation study. Molecular Ecology, 14(8), 2611-2620.
Excoffier, L., Hofer, T., & Foll, M. (2009). Detecting loci under selection in a hierarchically structured population. Heredity, 103(4), 285-298.
Excoffier, L., Smouse, P. E., & Quattro, J. M. (1992). Analysis of molecular variance inferred from metric distances among DNA haplotypes: application to human mitochondrial DNA restriction data. Genetics, 131(2), 479-491.
Folta, K. M., & Davis, T. M. (2006). Strawberry genes and Genomics. Critical Reviews in Plant Sciences, 25(5), 399-415.
García, A. A. F., Bemchimol, L. L., Barbosa, A. M. M., Geraldi, I. O., Souza Jr., C. L., & De Souza, A. P. (2004). Comparison of RAPD, RFLP, AFLP and SSR markers for diversity studies in tropical maize inbred lines. Genetics and Molecular Biology, 27(4), 579-588.
Gil-Ariza, D. J., Amaya, I., Botella, M. A., Muñoz-Blanco, J., Caballero, J. L., López-Aranda, J.M., … Sánchez-Sevilla, J. F. (2006). EST-derived polymorphic microsatellites from cultivated strawberry (Fragaria ×ananassa) are useful for diversity studies and varietal identification among Fragaria species. Molecular Ecology Notes, 6(4), 1195-1197.
Hancock, J., Lavín, A., & Retamales, J. B. (1999). Our southern strawberry heritage: Fragaria chiloensis of Chile. HortScience, 34(5), 814-816.
Hayden, M. J., Nguyen, T. M., Waterman, A., & Chalmers, K. J. (2008). Multiplex-Ready PCR: A new method for multiplexed SSR and SNP genotyping. BMC Genomics, 9, 80. doi: 10.1186/1471-2164-9-80
» https://doi.org/10.1186/1471-2164-9-80
Khan, M. A., & Korban, S. S. (2012). Association mapping in forest trees and fruit crops. Journal of Experimental Botany, 63(11), 4045-4060.
Kuleung, C., Baezinger, P. S., & Dweikat, I. (2004). Transferability of SSR markers among wheat, rye, and triticale. Theoretical and Applied Genetics, 108(6), 1147-1150.
Lavín, A., Del Pozo, A., & Maureira, M. (2000). Distribución actual de Fragaria chiloensis (L.) en Chile. Plant Genetic Resources Newsletter, 122, 24-28.
Li, L., Wanapu, C., Huang, X., Huang, T., Li, Q., Peng, Y., & Huang, G. (2011). Comparison of AFLP and SSR for genetic diversity analysis of Brassica napus hybrids. Journal of Agricultural Science, 3(3), 101-110.
Meirmans, P. G., & Hedrick, P. W. (2011). Assessing population structure: F_ST and related measures. Molecular Ecology Resources, 11(1), 5-18.
Mora, F., Concha, C. M., & Figueroa, C. R. (2016). Bayesian inference of genetic parameters for survival, flowering, fruit set, and ripening in a germplasm collection of Chilean Strawberry using threshold models. Journal of the American Society for Horticultural Science, 141(3), 285-291.
Nybom, H. (2004). Comparison of different nuclear DNA markers for estimating intraspecific genetic diversity in plants. Molecular Ecology, 13(5), 1143-1155.
Peakall, R., & Smouse, P. E. (2006). GENALEX 6: genetic analysis in Excel. Population genetic software f or teaching and research. Molecular Ecology Notes, 6(1), 288-295.
Peakall, R., & Smouse, P. E. (2012). GenAlEx 6.5: genetic analysis in Excel. Population genetic software for teaching and research-an update. Bioinformatics, 28(19), 2537-2539.
Pffeifer, T., Roschanski, A. M., Pannell, J. R., Korkbecka, G., & Schnittler, M. (2011). Characterization of microsatellite loci and reliable genotyping in a polyploidy plant, Mercurialis perennis (Euphorbiaceae). Journal of Heredity, 102(4), 479-488.
Pritchard, J. K.; Stephens, M., & Donnelly, P. (2000). Inference of population structure using multilocus genotype data. Genetics, 155(2), 945-959.
Rentaría-Alcántara, M. (2007) Breve revisión de los marcadores moleculares. In: L. E. Eguiarte, V. Souza, & X. Aguirre (Eds.), Ecología Molecular (p. 541-566). México: Instituto Nacional de Ecología.
Retamales, J. B., Caligari, P. D. S., Carrasco, B., & Saud, G. (2005). Current status of the Chilean native strawberry (Fragaria chiloensis L. (Duch.) and the research needs to convert the species into a commercial crop. HortScience, 40(6), 1633-1634.
Sargent, D. J., Passey, T., Surbanovski, N., Lopez-Girona, E., Kuchta, P., Davik, J., … Simpson, D. W. (2012). A microsatellite linkage map for the cultivated strawberry (Fragaria ( ananassa) suggest extensive regions of homozygosity in the genome that may have resulted from breeding and selection. Theoretical and Applied Genetics, 124(7), 1229-1240.
Sérsic, A .N., Cosacov, A., Cocucci, A. A., Johnson, L. A., Pozner, R., Avila, L. J., … Morando, M. (2011). Emerging phylogeographical patterns of plants and terrestrial vertebrates from Patagonia. Biological Journal of the Linnean Society, 103(2), 475-494.
Stegmeir, T.L., Finn, C. E., Warner, R. M., & Hancock, J. F. (2010). Performance of an Elite Strawberry Population Derived from Wild Germplasm of Fragaria chiloensis and F. virginiana HortScience, 45(8), 1140-1145.
Yoon, M., Moe, K. T., Kim, D., Rho, I., Kim, S., Kim, K., … Park, Y. (2012) Genetic diversity and population structure analysis of strawberry (Fragaria ( ananassa Duch.) using SSR markers. Electronic Journal of Biotechnology, 15(2), 1-16. doi: 10.2225/vol15-issue2-fulltext-5
» https://doi.org/10.2225/vol15-issue2-fulltext-5
Zorrilla-Fontanesi, Y., Cabeza, A., Domínguez, P., Medina, J. J., Valpuesta, V., Denoyes-Rothan, B., … Amaya, I. (2011). Quantitative trait loci and underlying candidate genes controlling agronomical and fruit quality traits in octoploid strawberry (Fragaria ( ananassa). Theoretical and Applied Genetics, 123(5), 755-778.

Publication Dates

Publication in this collection
2018

History

Received
25 Jan 2017
Accepted
05 Apr 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Antao, T., Lopes, A., Lopes, R. J., Beja-Pereira, A., & Luikart, G. (2008). Lositan: A workbench to detect molecular adaptation based on a Fst-outlier method. BMC Bioinformatics, 9, 323. doi: 10.1186/1471-2105-9-323
» https://doi.org/10.1186/1471-2105-9-323

[2] Aranza, M. J., Abbassi, E. K., Howad, W., & Arus, P. (2010). Genetic variation, population structure and linkage disequilibrium in peach commercial varieties. BMC Genetics, 11, 69. doi: 10.1186/1471-2156-11-69, 2010
» https://doi.org/10.1186/1471-2156-11-69, 2010

[3] Becerra, V., Paredes, M., & Lavín, A. (2005). Biochemical and molecular diversity in the Chilean strawberry and its implications for plant breeding. HortScience, 40(6), 1642-1643.

[4] Belaj, A., Satovic, Z., Cipriani, G., Baldoni, L., Testolin, R., Rallo, L., & Trujillo, I. (2003). Comparative study of the discriminating capacity of RAPD, AFLP, and SSR markers and of their respective effectiveness in establishing genetic relationships in olive. Theoretical and Applied Genetics, 107(4), 736-744.

[5] Bradbury, P. J., Zhang, Z., Kroon, D. E., Casstevens, T. M., Ramdoss, Y., & Buckler, E. S. (2007). TASSEL: software for association mapping of complex traits in diverse samples. Bioinformatics, 23(19), 2633-2635.

[6] Cao, K., Wang, L., Zhu, G., Fang, W., Chen, C., & Luo, J. (2012). Genetic diversity, linkage disequilibrium, and association mapping analyses of peach (Prunus persica) landraces in China. Tree Genetics & Genomes, 8(5), 975-990.

[7] Carrasco, B., Garcés, M., Rojas, P., Saud, G., Herrera, R., Retamales, J. B., & Caligari, P. D. S. (2007). The Chilean strawberry [Fragaria chiloensis (L.) Duch.]: genetic diversity and structure. Journal of the American Society for Horticultural Science, 132(4), 501-506.

[8] Cherian, S., Figueroa, C. R., & Nair, H. (2014). ‘Movers and shakers’ in the regulation of fruit ripening: a cross-dissection of climacteric versus non-climacteric fruit. Journal of Experimental Botany, 65(17), 4705-4722.

[9] Dirlewanger, E., Denoyes-Rothan, B., Yamamoto, T., & Chagné, D. (2009). Genomics tools across Rosaceae species. In K. M. Folta, & S. E. Gardiner (Eds.), Genetics and Genomics of Rosaceae (p. 539-561). New York, USA: Springer.

[10] Earl, D. A., & vonHoldt, B. M. (2012). Structure Harvester: a website and program for visualizing Structure output and implementing the Evanno method. Conservation Genetics Resources, 4(2), 359-361.

[11] Evanno, G., Regnaut, S., & Goudet, J. (2005). Detecting the number of clusters of individuals using the software STRUCTURE: a simulation study. Molecular Ecology, 14(8), 2611-2620.

[12] Excoffier, L., Hofer, T., & Foll, M. (2009). Detecting loci under selection in a hierarchically structured population. Heredity, 103(4), 285-298.

[13] Excoffier, L., Smouse, P. E., & Quattro, J. M. (1992). Analysis of molecular variance inferred from metric distances among DNA haplotypes: application to human mitochondrial DNA restriction data. Genetics, 131(2), 479-491.

[14] Folta, K. M., & Davis, T. M. (2006). Strawberry genes and Genomics. Critical Reviews in Plant Sciences, 25(5), 399-415.

[15] García, A. A. F., Bemchimol, L. L., Barbosa, A. M. M., Geraldi, I. O., Souza Jr., C. L., & De Souza, A. P. (2004). Comparison of RAPD, RFLP, AFLP and SSR markers for diversity studies in tropical maize inbred lines. Genetics and Molecular Biology, 27(4), 579-588.

[16] Gil-Ariza, D. J., Amaya, I., Botella, M. A., Muñoz-Blanco, J., Caballero, J. L., López-Aranda, J.M., … Sánchez-Sevilla, J. F. (2006). EST-derived polymorphic microsatellites from cultivated strawberry (Fragaria ×ananassa) are useful for diversity studies and varietal identification among Fragaria species. Molecular Ecology Notes, 6(4), 1195-1197.

[17] Hancock, J., Lavín, A., & Retamales, J. B. (1999). Our southern strawberry heritage: Fragaria chiloensis of Chile. HortScience, 34(5), 814-816.

[18] Hayden, M. J., Nguyen, T. M., Waterman, A., & Chalmers, K. J. (2008). Multiplex-Ready PCR: A new method for multiplexed SSR and SNP genotyping. BMC Genomics, 9, 80. doi: 10.1186/1471-2164-9-80
» https://doi.org/10.1186/1471-2164-9-80

[19] Khan, M. A., & Korban, S. S. (2012). Association mapping in forest trees and fruit crops. Journal of Experimental Botany, 63(11), 4045-4060.

[20] Kuleung, C., Baezinger, P. S., & Dweikat, I. (2004). Transferability of SSR markers among wheat, rye, and triticale. Theoretical and Applied Genetics, 108(6), 1147-1150.

[21] Lavín, A., Del Pozo, A., & Maureira, M. (2000). Distribución actual de Fragaria chiloensis (L.) en Chile. Plant Genetic Resources Newsletter, 122, 24-28.

[22] Li, L., Wanapu, C., Huang, X., Huang, T., Li, Q., Peng, Y., & Huang, G. (2011). Comparison of AFLP and SSR for genetic diversity analysis of Brassica napus hybrids. Journal of Agricultural Science, 3(3), 101-110.

[23] Meirmans, P. G., & Hedrick, P. W. (2011). Assessing population structure: F_ST and related measures. Molecular Ecology Resources, 11(1), 5-18.

[24] Mora, F., Concha, C. M., & Figueroa, C. R. (2016). Bayesian inference of genetic parameters for survival, flowering, fruit set, and ripening in a germplasm collection of Chilean Strawberry using threshold models. Journal of the American Society for Horticultural Science, 141(3), 285-291.

[25] Nybom, H. (2004). Comparison of different nuclear DNA markers for estimating intraspecific genetic diversity in plants. Molecular Ecology, 13(5), 1143-1155.

[26] Peakall, R., & Smouse, P. E. (2006). GENALEX 6: genetic analysis in Excel. Population genetic software f or teaching and research. Molecular Ecology Notes, 6(1), 288-295.

[27] Peakall, R., & Smouse, P. E. (2012). GenAlEx 6.5: genetic analysis in Excel. Population genetic software for teaching and research-an update. Bioinformatics, 28(19), 2537-2539.

[28] Pffeifer, T., Roschanski, A. M., Pannell, J. R., Korkbecka, G., & Schnittler, M. (2011). Characterization of microsatellite loci and reliable genotyping in a polyploidy plant, Mercurialis perennis (Euphorbiaceae). Journal of Heredity, 102(4), 479-488.

[29] Pritchard, J. K.; Stephens, M., & Donnelly, P. (2000). Inference of population structure using multilocus genotype data. Genetics, 155(2), 945-959.

[30] Rentaría-Alcántara, M. (2007) Breve revisión de los marcadores moleculares. In: L. E. Eguiarte, V. Souza, & X. Aguirre (Eds.), Ecología Molecular (p. 541-566). México: Instituto Nacional de Ecología.

[31] Retamales, J. B., Caligari, P. D. S., Carrasco, B., & Saud, G. (2005). Current status of the Chilean native strawberry (Fragaria chiloensis L. (Duch.) and the research needs to convert the species into a commercial crop. HortScience, 40(6), 1633-1634.

[32] Sargent, D. J., Passey, T., Surbanovski, N., Lopez-Girona, E., Kuchta, P., Davik, J., … Simpson, D. W. (2012). A microsatellite linkage map for the cultivated strawberry (Fragaria ( ananassa) suggest extensive regions of homozygosity in the genome that may have resulted from breeding and selection. Theoretical and Applied Genetics, 124(7), 1229-1240.

[33] Sérsic, A .N., Cosacov, A., Cocucci, A. A., Johnson, L. A., Pozner, R., Avila, L. J., … Morando, M. (2011). Emerging phylogeographical patterns of plants and terrestrial vertebrates from Patagonia. Biological Journal of the Linnean Society, 103(2), 475-494.

[34] Stegmeir, T.L., Finn, C. E., Warner, R. M., & Hancock, J. F. (2010). Performance of an Elite Strawberry Population Derived from Wild Germplasm of Fragaria chiloensis and F. virginiana HortScience, 45(8), 1140-1145.

[35] Yoon, M., Moe, K. T., Kim, D., Rho, I., Kim, S., Kim, K., … Park, Y. (2012) Genetic diversity and population structure analysis of strawberry (Fragaria ( ananassa Duch.) using SSR markers. Electronic Journal of Biotechnology, 15(2), 1-16. doi: 10.2225/vol15-issue2-fulltext-5
» https://doi.org/10.2225/vol15-issue2-fulltext-5

[36] Zorrilla-Fontanesi, Y., Cabeza, A., Domínguez, P., Medina, J. J., Valpuesta, V., Denoyes-Rothan, B., … Amaya, I. (2011). Quantitative trait loci and underlying candidate genes controlling agronomical and fruit quality traits in octoploid strawberry (Fragaria ( ananassa). Theoretical and Applied Genetics, 123(5), 755-778.

N°	Code	Accession Name	Latitude [S]	Longitude [W]	Climate Region¹	Putative Population	Used to test cross amplification
1	MAN	Manzanar	38°02'30.24"	73°08'38.44"	Marine and Temperate Mediterranean	MTM	Yes
2	MAN-2	Manzanar 2	38°03'13.40"	73°11'46.62"	Marine and Temperate Mediterranean	MTM	No
3	NAH	Nahuelbuta	37°46'21.02"	72°56'43.14"	Marine and Temperate Mediterranean	MTM	Yes
4	NAH-2	Nahuelbuta 2	38°02'04.82"	73°08'52.09"	Marine and Temperate Mediterranean	MTM	No
5	NAH-3	Nahuelbuta 3	38°01'53.26"	73°08'37.27"	Marine and Temperate Mediterranean	MTM	No
6	QUE	Queule	39°23'53.82"	73°12'21.42"	Marine and Temperate Mediterranean	MTM	No
7	CHA	Chanco	35°44'23.04"	72°30'58.01"	Marine and Temperate Mediterranean	MTM	Yes
8	CUR	Curepto	35°05'43.84"	72°01'31.23"	Marine and Temperate Mediterranean	MTM	No
9	LIR	Lircay	35°36'17.20"	71°03'51.80"	Marine and Temperate Mediterranean	MTM	No
10	CNT	Contulmo	36°43'43.40"	72°54'07.60"	Marine and Temperate Mediterranean	MTM	No
11	HUA	Huaro	36°36'03.70"	72°43'28.33"	Marine and Temperate Mediterranean	MTM	No
12	BAR	Santa Bárbara	37°38'05.65"	71°53'46.17"	Marine and Temperate Mediterranean	MTM	No
13	PDC	Padre Las Casas	38°52'11.32"	72°28'05.83"	Marine and Temperate Mediterranean	MTM	No
14	MOL	Molinos	39°47'00.85"	73°23'20.90"	Fresh and Cold Marine	FCM	Yes
15	PUN	Punucapa	39°46'04.18"	73°16'27.84"	Fresh and Cold Marine	FCM	No
16	ALE	Alerce	39°53'07.63"	73°27'24.03"	Fresh and Cold Marine	FCM	No
17	SAV	Saval	39°48'13.48"	73°15'22.14"	Fresh and Cold Marine	FCM	No
18	VAL	Valdivia	39°48'53.90"	73°14'56.70"	Fresh and Cold Marine	FCM	Yes
19	VAL-2	Valdivia 2	39°52'28.00"	73°10'52.15"	Fresh and Cold Marine	FCM	No
20	COL	Colún	40°05'01.10"	73°38'48.80"	Fresh and Cold Marine	FCM	No
21	COL-2	Colún 2	40°04'57.50"	73°38'50.10"	Fresh and Cold Marine	FCM	Yes
22	LOB	Lobos	39°57'50.00"	73°39'36.00"	Fresh and Cold Marine	FCM	No
23	PFA	Punta Falsa	39°58'08.70"	73°40'04.30"	Fresh and Cold Marine	FCM	No
24	CUC	Cucao	42°35'50.30"	74°07'26.80"	Fresh and Cold Marine	FCM	No
25	CUC-2	Cucao 2	42°36'27.60"	74°07'03.20"	Fresh and Cold Marine	FCM	No
26	CHL	Chaiguao	43°07'58.90"	73°30'25.10"	Fresh and Cold Marine	FCM	Yes
27	LIN	Linalhue	40°17'46.80"	72°10'12.58"	Humid Patagonian Marine	HPM	No
28	3ST	3 Esteros	40°45'30.10"	73°17'19.90"	Humid Patagonian Marine	HPM	Yes
29	GUT	Cuesta Gutiérrez	41°19'58.10"	73°17'40.60"	Humid Patagonian Marine	HPM	No
30	CAU	Caulín	41°47'53.80"	73°39'36.40"	Humid Patagonian Marine	HPM	No
31	MAÑ	Mañihuales	45°09'49.00"	72°07'21.00"	Humid Patagonian Marine	HPM	No
32	MAÑ-2	Mañihuales 2	45°13'20.00"	72°12'52.00"	Humid Patagonian Marine	HPM	No
33	MAR	Mar Brava	41°08'27.80"	73°44'04.60"	Humid Patagonian Marine	HPM	No
34	PIN	Pinuno	41°31'56.20"	73°47'39.50"	Humid Patagonian Marine	HPM	No
35	PET	Petrohué	41°08'17.50"	72°24'08.30"	Humid Patagonian Marine	HPM	No
36	VIS	Vista Hermosa	45°17'36.00"	71°44'01.36"	Humid Patagonian Marine	HPM	No
37	BAL	Balmaceda	44°44'54.41"	72°39'17.11"	Humid Patagonian Marine	HPM	No
38	LLE	Lleuque	36°52'04.60"	71°30'53.20"	Cold Mediterranean	CM	No
39	TRA	Trancas	36°54'34.00"	71°30'56.40"	Cold Mediterranean	CM	Yes
40	RAN	Ranchillo	37°04'57.41"	71°39'01.86"	Cold Mediterranean	CM	No
41	RAN-2	Ranchillo 2	37°04'32.70"	71°39'41.00"	Cold Mediterranean	CM	No
42	RAN-3	Ranchillo 3	37°04'49.10"	71°39'21.90"	Cold Mediterranean	CM	No
43	PLJ	Laguna del Laja	37°23'29.13"	71°23'57.72"	Cold Mediterranean	CM	No
44	MAL	Malalcahuello	38°29'39.96"	71°35'10.52"	Polar Alpine Tundra	PAT	No
45	MAM	Mamuil-Malal	39°32'42.90"	71°33'13.50"	Polar Alpine Tundra	PAT	No
46	HUE	Huerquehue	39°10'01.30"	71°43'22.70"	Polar Alpine Tundra	PAT	No
47	HUE-2	Huerquehue 2	39°10'02.70"	71°43'05.00"	Polar Alpine Tundra	PAT	No
48	HUE-3	Huerquehue 3	39°10'19.50"	71°42'43.50"	Polar Alpine Tundra	PAT	No
49	HUE-4	Huerquehue 4	39°10'30.00"	71°42'42.80"	Polar Alpine Tundra	PAT	Yes
50	CRP	Coñaripe	39°31'56.89"	71°56'08.10"	Polar Alpine Tundra	PAT	No
51	CRC	Curacautín	38°26'05.63"	71°51'26.53"	Polar Alpine Tundra	PAT	No
52	ALT	Alto Bio Bio	37°55'24.56"	71°33'34.73"	Polar Alpine Tundra	PAT	No
53	NEL	Neltume	39°47'43.12"	71°55'38.83"	Polar Alpine Tundra	PAT	No
54	MEN	Menetue	39°19'51.30"	71°43'12.60"	Polar Alpine Tundra	PAT	No

	Sample size (no.)	Number of alleles (±SE)	Effective alleles (±SE)	Polymorphic loci (%)	Expected heterozygosity (±SE)	Shannon’s index (±SE)

A. Climate region
MTM	13	1.4±0.06	1.2±0.02	69	0.16±0.01	0.26±0.02
FCM	13	1.6±0.06	1.2±0.02	76	0.16±0.01	0.27±0.01
HPM	11	1.5±0.06	1.2±0.02	71	0.16±0.01	0.27±0.02
CM	6	1.1±0.06	1.3±0.02	54	0.15±0.01	0.24±0.02
PAT	11	1.4±0.06	1.2±0.02	68	0.16±0.01	0.26±0.02

Total/Mean	54	1.4±0.06	1.2±0.02	68	0.16±0.01	0.26±0.01

B. Genetic Groups
Group 1	11	1.3±0.06	1.2±0.02	64	0.16±0.01	0.25±0.02
Group 2	11	1.4±0.06	1.2±0.02	69	0.15±0.01	0.25±0.02
Group 3	17	1.6±0.05	1.2±0.02	80	0.17±0.01	0.28±0.01

Total/Mean	39	1.5±0.04	1.2±0.01	71	0.16±0.01	0.26±0.01

	df	Sum of squares	Variance components	Percentage of variation

A. Climate regions
Among climate regions	4	163.5	0.90	3.0*
Within climate regions	53	1523.6	31.28	97.0
B. Genetic groups
Among groups	2	100.3	50.2	4.0*
Within groups	36	1145.2	31.40	96.0

Brasil

Brasil

Linkage disequilibrium and population structure in Fragaria chiloensis revealed by SSR markers transferred from commercial strawberry

Desequilíbrio de ligação e estrutura populacional em Fragaria chiloensis usando marcadores SSR transferidos do morango comercial

ABSTRACT.

RESUMO.

Introduction

Material and methods

Plant material and DNA extraction

Cross-species amplification of SSR markers

Molecular data

Genetic diversity and linkage disequilibrium

Population structure

Results and discussion

Conclusion

Acknowledgements

References

Publication Dates

History