Microsatellite fingerprinting of homonymous grapevine (Vitis vinifera L.) varieties in neighboring regions of South-East Turkey

Scientia Horticulturae 114 (2007) 164–169 www.elsevier.com/locate/scihorti

Microsatellite fingerprinting of homonymous grapevine (Vitis vinifera L.) varieties in neighboring regions of South-East Turkey Hu¨seyin Karatas¸ a, Dilek Deg˘irmenci b, Riccardo Velasco c, Silvia Vezzulli c, C¸ag˘rı Bodur d, Y. Sabit Ag˘aog˘lu b,* a

Dicle University, Faculty of Agriculture, Department of Horticulture, Diyarbaky´r, Turkey Ankara University, Faculty of Agriculture, Department of Horticulture, Ankara, Turkey c Istituto Agrario di San Michele all’Adige, San Michele a/Adige (TN), Italy d Middle East Technical University, Department of Biology, Ankara, Turkey

b

Received 24 January 2007; received in revised form 26 June 2007; accepted 6 July 2007

Abstract Genotyping of Turkish grapevine (Vitis vinifera L.) germplasm was characterized by use of six highly polymorphic microsatellite loci (VVS2, VVMD5, VVMD7, VVMD27, VrZAG62, VrZAG79). In this study we aimed to clarify the relationships between homonymous varieties coming from different regions. Our results showed a large degree of genetic variability among most of the homonymous cultivars. The number of alleles per locus ranged from 10 to 21, and gene diversity (expected heterozygosity) values ranged from 0.85 to 0.93. Cultivars presenting the same names of Sergi karası (sampled from S¸anlıurfa and Gaziantep), Yediveren (sampled from S¸anlıurfa, Gaziantep, and National Germplasm Repository Vineyard in Tekirdag˘) and Serpenekıran (sampled from S¸anlıurfa and Gaziantep) were clustered together, or very close to each other, in a phenogram. Moreover, the alleles at the six microsatellite loci analyzed were found to be similar in terms of base pairs within each of these three closely positioned varieties. However, all the other cultivars failed to show a suitable clustering pattern when comparing their DNA profiles and names. Similarly named cultivars were not generally grouped together in the phenogram. On the other hand, we detected a tendency for differently named homonymous grape cultivars to cluster together. # 2007 Elsevier B.V. All rights reserved. Keywords: Vitis vinifera L.; Microsatellite; Turkish grapevine germplasm

1. Introduction Grapevine (Vitis vinifera L.) is one of the oldest and most important perennial crops in the world. Alleweld et al. (1990) estimated the existence of about 14,000 cultivars, with numerous synonyms and occasional use of the same or similar names for genetically different cultivars. Anatolia has long been linked with the origin of viticulture and wine making, especially in its eastern and southeastern regions to which the earlier authors commonly ascribe its origin. In Turkey, a large grape germplasm, consisting of about 1200 accessions, is conserved and has so far been transferred from the different ecological zones of the country to the National Germplasm

* Corresponding author. Tel.: +90 317 05 50; fax: +90 312 91 19. E-mail address: [email protected] (Y.S. Ag˘aog˘lu). 0304-4238/$ – see front matter # 2007 Elsevier B.V. All rights reserved. doi:10.1016/j.scienta.2007.07.001

Repository Vineyard in Tekirdag˘ (C ¸ elik et al., 2000; Ergu¨l et al., 2002). Truness-to-type is necessary when planting vineyards, making wine, managing germplasm collections, choosing parents for controlled crosses and legally protecting new cultivars. The large number of grapevine cultivars and clones makes the corrected identification and characterization a challege. Traditional ampelography (from the Greek ampelos-grapevine and graphos-description), analysing and comparing morphological characters to identify cultivars, is not sufficiently reliable and consistent due to environmental factors, individual plant biology, and plant growth stage (Lamboy and Alpha, 1998; Sefc et al., 1998, 1999; Fatahi et al., 2003). Up-to-now in Turkey, varietal identifications have been carried out with ampelographic studies through a few isoenzymatic approaches. On the other hand, a DNA-based identification has been performed for a limited number of

H. Karatas¸ et al. / Scientia Horticulturae 114 (2007) 164–169

grapevine cultivars (Ag˘aog˘lu and Ergu¨l, 1999a,b; Ag˘aog˘lu et al., 2000; Ergu¨l, 2000; Ergu¨l and Ag˘aog˘lu, 2001; Ergu¨l et al., 2002; Atak, 2003; Karatas¸ and Ag˘aog˘lu, 2006). For a profitable exploitation of the germplasm in future, breeding and MAS (marker assisted selection) programs, the genetic identification and characterization of grapevine cultivars represent a basic requirement. Compared to different molecular markers, SSRs (simple sequence repeats) provide a unique genetic profile for every cultivar, permitting unambiguous identification that is not affected by enviroment, disease or farming methods (Meredith, 2001). Owing to their high degree of polymorphism, reproducibility and codominant nature, microsatellite markers have been favoured and widely employed as powerful and versatile molecular tools. Nowadays, more than 500 grape SSRs are publicly available (Thomas and Scott, 1993; Bowers et al., 1996, 1999; Sefc et al., 1999; Scott et al., 2000; Di Gaspero et al., 2000; Di Gaspero et al., 2005; Merdinog˘lu et al., 2005). Traditionally assigned to non-coding genomic regions, additional 405 ‘‘functional’’ SSRs have recently been identified in a grape EST collection (Moser et al., 2005). Microsatellite markers have extensively been used for varietal characterization (Botta et al., 1995; Zulini et al., 2005; Fatahi et al., 2003; Hvarleva et al., 2004; Costantini et al., 2005) and for rootstock identification (Lin and Walker, 1998). Pedigree (Meredith et al., 1996; Sefc et al., 1998) and parantage analysis (Sefc et al., 1997; Vouillamoz et al., 2004) has also been reported. Since SSRs have been revealed fully informative and solid markers, they have definitely been involved in mapping studies (Grando et al., 2003; Riaz et al., 2004; AdamBlondon et al., 2004; Doligez et al., 2006). Moreover, these markers have been used for identification of chimaeras of grapes (Franks et al., 2002; Riaz et al., 2002; Hocquigny et al., 2004; Zulini et al., 2005). A novel SSR application has finally concerned the authentication of varietal wines (Siret et al., 2000). The aim of the present research was to achieve the genetic discrimination of ancient homonymous grapevine varieties in neighboring regions of South-East Turkey. Genotypes, grown under the same name in three different cities, were collected to evaluate their genetic diversity by using a minimal standard SSR marker set.

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Table 1 Grapevine genotypes studied with SSR markers N

Sample name

Collection

Berry colour

Use (table/ raisin/wine)

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39

C ¸ ilores¸ (U) C ¸ ilores¸ (G) C ¸ ilores¸ (T–U) C ¸ ilorut (U) C ¸ ilorut (G) C ¸ ilorut (T–U) Ho¨nu¨su¨ (U) Ho¨nu¨su¨ (G) Ho¨nu¨su¨ (T–G) Dımıs¸kı (U) Dımıs¸kı (G) Dımıs¸kı (T–G) Kabarcık (U) Kabarcık (G) Kabarcık (T–G) Ku¨lahi (U) Ku¨lahi (G) Hatunparmag˘ı (U) Hatunparmag˘ı (G) Hatunparmag˘ı (T–G) Sergi karası (U) Sergi karası (G) Kızlartahtası (G) Kızlartahtası (U) Azezi (G) Azezi (U) Yediveren (U) Yediveren (G) Yediveren (T–G) Serpenekıran (U) Sepenekıran (G) Gu¨lgu¨lu¨ (U) Gu¨lgu¨lu¨ (G) Kızılbanki (G) Kızılbanki (U) Horoz karası (U) Horoz karası (G) Muhammediye (U) Muhammediye (G)

U G T–U U G T–U U G T–G U G T–G U G T–G U G U G T–G U G G U G U U G T–G U G U G G U U G U G

White White White White White White Red Red Red White White White White White White White White White White White Red Red White White White White Red Red Red White White Pink Pink Pink Pink Red Red White White

Table Table Table Table Table Table Table Table Table Table Table Table Table Table Table Table Table Table, raisin Table, raisin Table, raisin Raisin Raisin Table Table Table Table Table Table Table Table Table Table Table Table Table Table, raisin, wine Table, raisin, wine Table Table

U: S¸anlıurfa; G: Gaziantep; T: Tekirdag˘ (National Germplasm Repository Vineyard); T–G: National Germplasm Repository Vineyard samples that were previously brought from Gaziantep; T–U: National Germplasm Repository Vineyard samples that were previously brought from S¸anlıurfa city.

2.2. Microsatellite analysis 2. Materials and methods 2.1. Grapevine genotypes and DNA extraction Microsatellite analysis was carried out on 39 grapevine genotypes; 16 samples, showing the same name, were collected from both Gaziantep (G) and S¸anlıurfa (U) provinces, and one small group (7 samples), containing individuals coming from the ‘‘National Germplasm Repository Vineyard’’, was collected in Tekirdag˘ (T) province. The cultivars used in this study are listed in Table 1. The Pinot noir genotype was added as a well known and reference cultivar (This et al., 2004). DNA was isolated from young leaves as described by Lodhi et al. (1994).

In order to allow a comparison among internationally grown homonymous varieties, a minimal standard SSR marker set was considered (This et al., 2004). This set consists of six highly polimorphic loci as follows: VVS2 (Thomas and Scott, 1993), VVMD5 (Bowers et al., 1996), VVMD7 and VVMD27 (Bowers et al., 1999), VrZAG62 and VrZAG79 (Sefc et al., 1999). For each SSR locus, annealing temperatures and allele size ranges are shown in Table 2. Genomic DNA was amplified by the polymerase chain reaction (PCR) according to the following conditions: 20 ng of DNA template, 1 PCR reaction buffer (Qiagen), 1.5 mM MgCl2, 0.2 mM for each dNTP, 0.5 mM forward and reverse primer, 0.25 Unit HotStartTaq DNA polymerase (Qiagen) and

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Table 2 The minimal standard SSR marker set used for grapevine genotyping Locus

Annealing temperature (8C)

Allele size range (bp)

N

He

Ho

VVS2 VVMD5 VVMD7 VVMD27 VrZAG62 VrZAG79

51 52 51 52 52 52

119–137 222–250 230–256 161–191 138–204 220–256

15 10 10 14 21 18

0.85 0.89 0.92 0.86 0.91 0.93

0.48 0.42 0.47 0.85 0.73 0.62

14.66

0.89

0.60

Mean

N: number of alleles; He: expected heterozygosity; Ho: observed heterozygosity.

milliQ water to 12.5 ml PCR final volume. PCR thermocycling reactions were performed with a 15-min initial denaturation/ activation step, followed by 35 cycles at 94 8C for 45 s, annealing temperature (Ta) for 45 s, and 72 8C for 1 min 30 s, with a final extension step of 7 min at 72 8C. PCR products were assessed by gel electrophoresis in 1.5% agarose, visualized by means of Syber Gold probe. The Mass ruler DNA ladder mix (Fermentas, Life Sciences) was used for their quantification. Capillary electrophoresis of PCR products was performed on ABI PRISM1 3100 Genetic Analyzer (Applied Biosystems Inc.). First, 0.5 ml of suitably diluted PCR products were added to a mixture containing 9.4 ml of Hi-Di Formamide and 0.1 ml of Genescan1-500 ROX Size Standard (Applied Biosystems Inc.) and then injected prior to denaturation at 95 8C for 2 min. Allele identification was performed by using GeneScan v3.7 software (Applied Biosystems Inc.); automatic size calling of peak positions was double-checked by Genotyper v3.7 software (Applied Biosystems Inc.). 2.3. Statistical analysis Heterozygosities, allele numbers and frequencies were estimated for each microsatellite locus using Hardy–Weinberg equilibrium option of Arlequin v2.000 software (Schneider et al., 2000). Phenogram was obtained by the drawgram program in PHYLIP v3.6 software (Felsenstein, 1988) using the DLR distance matrix. Genotype likelihood ratio distance (DLR) is based on the assignment test that was described by Paetkau et al. (1997). DLR distances were calculated by using Doh assignment test calculator which is freely available at http:// www.biology.ualberta.ca/jbrzusto/Doh.php. 3. Results and discussion In this study, homonymous grapevine cultivars in neighbouring regions were genotyped with a minimal standard SSR marker set for their discrimination. Microsatellite profiles of homonymous cultivars are presented in Table 3. Each homonymous variety had got the same name in three different cities. However, cultivars presenting the same designation were found to have shown different morphological characters. We investigated the genetic similarity between them by microsatellite analysis.

Within the 39 grapevine cultivars obtained from S¸anlıurfa, Gaziantep and ‘‘National Germplasm Repository Vineyard’’ of Tekirdag˘, we detected a total of 88 alleles at the 6 studied SSR loci. In case of 1-bp shift between the reported (This et al., 2004) reference cultivar SSR profile and our actual results at a given locus, the corresponding Turkish genotype profiles were also adjusted. In this way, possible misscoring due to technical differences led to a correct allele size assessment. Allele numbers, expected and observed heterozygosities are shown in Table 2. We found the mean allele number per locus as 14.66. The most polymorphic microsatellite was VrZAG62 (21 alleles) and the least polymorphic ones were VVMD5 and VVMD7 (10 alleles). Expected heterozygosity (gene diversity) levels of the studied loci ranged from 0.85 (locus VVS2) to 0.93 (locus VrZAG79). The lowest observed heterozygosity was detected at VVMD5 locus with 0.42 and the highest one at VVMD27 with 0.85. We found that the observed proportions of heterozygous individuals (observed heterozygosities) were significantly ( p < 0.05) lower than the expected ones at 5 out of 6 microsatellite loci, when considering all the 39 samples as one population. Only VVMD27 locus did not give a significant deviation from Hardy–Weinberg equilibrium. However, when we tested the deviation from Hardy–Weinberg equilibrium for 16 single populations, containing cultivars with the same variety names, we did not detect any significant deviation at p = 0.05 level. The excess genic diversity that we observed in heterozygosity values for the whole population of 39 grapevine cultivars clearly results from the presence of population structure. These 39 cultivars correspond to 16 different homonymous grapevine variety names, collected from 3 different cities in Turkey. Expected heterozygosities are significantly higher than the observed ones because these grapevine cultivars are not expected to behave as one population. In order to further characterize the structure of Turkish grapevine gene pool, a phenogram based on the genetic similarity of investigated homonymous varieties was constructed using the homonymous cultivars as operational taxonomic units (Fig. 1). However, it is important to underline that the results of this phenetic analysis cannot be used to draw conclusions with regard to the degree of kinship between the cultivars since clusters illustrate similarity rather than kinship (Sefc et al., 1999; Pellorone et al., 2001). Only 4 out of 16 grapevine varieties showed phenogram positioning consistent with their names (i.e. the samples having the same variety names clustered together or very close to each other in the phenogram) when considering the samples collected from S¸anlıurfa and Gaziantep. When we considered seven cases that contain sampling from all the three locations (S¸anlıurfa, Gaziantep, and National Germplasm Repository Vineyard in Tekirdag˘), we noticed that four out of seven cases showed congruent positioning with their names. The homonymous grapevine cultivars C¸ilorut, Ho¨nu¨su¨, Gu¨lgu¨lu¨, Horoz karası, Kızılbanki, Kızlartahtası, and Ku¨lahi, which that were collected from different locations did not show a clustering pattern consistent with their variety names. The first two varieties in this group, C ¸ ilorut and Ho¨nu¨su¨, came from S¸anlıurfa, Gaziantep and National Germplasm Repository

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Table 3 Genetic profile of 16 Turkish homonymous Vitis vinifera L. cultivars analyzed at 6 highly polymorphic microsatellite loci (allele sizes are given as base pairs) Population

Homonymous cultivar name

VVS2

VVMD5

VVMD7

1

C¸ilores¸ (U) C¸ilores¸ (G) C¸ilores¸ (T–U)

129 129 123

129 129 123

222 224 248

222 224 248

230 230 248

250 250 248

181 181 181

191 191 181

198 198 204

202 202 204

224 224 242

248 248 256

2

Cilorut (U) C¸ilorut (G) C¸ilorut (T–U)

131 139 131

139 149 141

232 228 228

232 228 228

244 248 248

250 256 248

191 177 175

191 191 191

146 156 160

146 156 160

248 220 238

248 220 254

3

Ho¨nu¨su¨ (U) Ho¨nu¨su¨ (G) Ho¨nu¨su¨ (T–G)

139 137 139

145 137 139

228 222 234

228 236 234

240 244 248

240 248 248

169 175 177

189 191 181

140 150 188

150 150 194

234 238 256

240 248 256

4

Dımıs¸kı (U) Dımıs¸kı (G) Dımıs¸kı (T–G)

129 141 129

129 141 153

224 228 232

224 234 236

230 230 248

250 250 248

181 181 175

185 185 191

200 160 192

204 160 204

248 226 254

248 244 256

5

Kabarcık (U) Kabarcık (G) Kabarcık (T–G)

129 129 129

145 139 139

222 232 232

222 232 232

240 234 234

240 250 250

191 163 163

191 167 167

188 150 150

204 160 160

238 234 234

248 246 246

6

Ku¨lahi (U) Ku¨lahi (G)

129 141

129 141

222 228

222 234

250 250

250 250

193 175

193 193

154 160

158 160

248 224

248 242

7

Hatunparmag˘ı (U) Hatunparmag˘ı (G) Hatunparmag˘ı (T–G)

131 131 131

131 139 131

222 222 234

230 224 234

248 240 248

248 248 248

183 181 181

191 189 191

150 146 188

160 150 200

248 254 238

248 256 244

8

Sergi karası (U) Sergi karası (G)

131 131

137 151

222 222

234 234

248 250

248 250

175 165

177 175

196 192

200 200

236 236

246 246

9

Kızlartahtası (G) Kızlartahtası (U)

125 121

125 121

232 224

238 224

246 250

252 250

175 181

175 185

188 184

192 200

254 248

254 248

10

Azezi (G) Azezi (U)

129 129

129 129

224 222

232 222

248 248

248 248

181 183

191 191

190 142

202 154

248 224

254 248

11

Yediveren (U) Yediveren (G) Yediveren (T–G)

147 147 125

151 151 125

250 228 250

250 228 250

238 238 238

238 250 238

175 175 175

175 191 191

188 202 146

202 202 160

222 228 224

230 234 250

12

Serpenekıran (U) Sepenekıran (G)

119 129

129 129

232 232

232 250

244 248

250 248

165 165

173 175

150 150

160 160

226 234

232 242

13

Gu¨lgu¨lu¨ (U) Gu¨lgu¨lu¨ (G)

129 129

149 131

228 232

250 232

248 238

248 248

177 169

191 179

144 150

158 154

244 238

254 242

14

Kızılbanki (G) Kızılbanki (U)

125 129

135 129

250 234

250 234

244 244

250 250

179 169

181 179

190 138

190 150

246 240

246 240

15

Horoz karası (U) Horoz karası (G)

129 131

129 139

222 234

228 248

248 248

248 248

183 181

193 191

200 160

204 160

248 236

248 236

16

Muhammediye (U) Muhammediye (G)

129 147

129 147

232 232

250 232

248 234

250 240

179 177

191 193

154 152

154 160

256 222

256 232

Vineyard in Tekirdag˘. The remaining five varieties were collected from S¸anlıurfa and Gaziantep. In this group, the grapevine cultivars with the same variety name were clustered far from each other in the phenogram. The three varieties Azezi, Dımıs¸kı, and Muhammediye also showed a non-consistent pattern with their names. Dımıs¸kı samples were collected from S¸anlıurfa, Gaziantep, and National Germplasm Repository Vineyard in Tekirdag˘, Azezi and Muhammediye from S¸anlıurfa and Gaziantep. The cultivars with the same name were not grouped together in the phenogram even if they were not as far away to each other as were the previously described seven varieties.

VVMD27

VrZAG62

VrZAG79

Genotypes with the same name of Sergi karası (from S¸anlıurfa and Gaziantep) and Yediveren (from S¸anlıurfa, Gaziantep, and National Germplasm Repository Vineyard in Tekirdag˘) clustered together. Serpenekıran varieties collected from S¸anlıurfa and Gaziantep were positioned very close to each other in the phenogram. Moreover, the alleles at the six SSR loci analyzed were found to be similar in terms of base pairs within each of these three closely positioned varieties. When analyzing the positions of three Kabarcık varieties, we observed that Kabarcık samples, collected from Gaziantep and National Germplasm Repository Vineyard in Tekirdag˘

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H. Karatas¸ et al. / Scientia Horticulturae 114 (2007) 164–169

Fig. 1. Phenogram of the 16 homonymous grapevine varieties.

(cultivars were brought from Gaziantep to the National Germplasm Repository Vineyard), were grouped together. However, the other Kabarcık genotype coming from S¸anlıurfa clustered far from the other two. Moreover, the SSR allele sizes of these three genotypes were identical between the two cultivars that clustered together, but different for the third cultivar that was collected from S¸anlıurfa. Hatunparmag˘ı homonymous genotypes coming from Gaziantep and National Germplasm Repository Vineyard in Tekirdag˘ clustered close to each other, but the genotype from S¸anlıurfa was positioned far from the other two in the phenogram. Similar microsatellite alleles were detected for C¸ilores¸ homonymous grapevine cultivars from S¸anlıurfa and Gaziantep and they were grouped together in the phenogram. However, the National Germplasm Repository Vineyard cultivar that was brought from S¸anlıurfa was located far from these two cultivars in the phenogram. The overall positioning in the phenogram reveals that the grapevine varieties showing the same names are not genetically identical based on microsatellites. It is obvious that the varieties cultivated in different ecological conditions of Turkey have attained different genetic profiles during the time. This differentiation among cultivars with the same names was

also increased by the high mutation rates of microsatellites. What we observed when analyzing the phenogram was actually the general tendency of cultivars of the same regions to group together rather than genotypes belonging to the same variety. Naming of the homonymous grapevine genotypes is a major problem in Turkish grapevine cultivation. The current study indicates how serious the situation is. Similarly named cultivars are generally not grouped together. On the other hand, we could say that differently named homonymous grape cultivars are clustered together. Thus, we have to choose the genetic characteristics of certain cultivars as representatives of that variety and name the other ones as relatives. Nowadays, no genetic profile of our studied Turkish variety names is reported in a publicly available SSR-based grapevine database. Before any decisions, additional molecular markers and morphometric studies conducted on Turkish grapevines should be taken into account along with these microsatellite results. Another limit in interpretation of our results was the uncertainty about representing correctly the homonymous cultivars by only one genotype. We suspect that there are several somatic mutants of the same homonymous grapevine cultivar. Hence, it would be useful to analyze more than one genotype to represent a homonymous cultivar in future studies. In conclusion, we obtained a very high allelic polymorphism among genotypes expected to be different (having different variety names) or between genotypes that were supposed to have the same variety name. The sources of these differences observed among samples with the same varietal name collected from three different ecological regions could be summarized as follows. First, these homonymous grapevine varieties cultivated in different environments for many years, and those transferred to the National Germplasm Repository Vineyard could be inappropriately named. Second, changes in genetic backgrounds of these varieties may be caused by somatic mutations resulted from the effects of continuous vegetative reproduction and environmental factors. Turkey is a very rich country in terms of homonymous grape varieties which results from the ancien tradition of grape cultivation in Anatolia, which began approximately 7000–8000 years ago. We are of the opinion that it is crucial to preserve this genetic potential by describing a reasonable nomenclature and determining the relationships among these varieties through DNA-based markers. References Adam-Blondon, A.F., Roux, C., Claux, D., Butterlin, G., Merdinog˘lu, D., This, P., 2004. Mapping 245 SSR markers on the Vitis vinifera genome: a tool for grape genetics. Theor. Appl. Genet. 109, 1017–1027. Ag˘aog˘lu, Y.S., Ergu¨l, A., 1999a. Genetic identification in ecotypes of Amasya grape cultivar by RAPD markers. In: 3rd Natl. Hortic. Congr., Kızılcahamam/Ankara, Tu¨rkiye, September 14–17, 1999, pp. 372–386. Ag˘aog˘lu, Y. S., Marasalı, B., Ergu¨l, A., 2000. Molecular characterization on the grapevine (Vitis vinifera L. cvs.) by RAPD (random amplified polymorphic) technique. Ankara University Research Fond. 96-11-01-02 no.lu Report of Project Result, Ankara.

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