Analysis of genetic diversity by SSR markers of date palm in the Al-Jufra

Ministero Affari Esteri ISTITUTO AGRONOMICO PER L’OLTREMARE

LIBIA “ IMPROVEMENT AND DEVELOPMENT OF DATE PALM IN THE OASIS OF AL JUFRA”

GENETIC UNIT ___________

Analysis of genetic diversity by SSR markers of date palm in the Al-Jufra oasis Andrea Bove and Milvia Luisa Racchi

Analysis of genetic diversity by SSR markers of date palm in the Al-Jufra oasis12 Date palm (Phoenix dactylifera L., 2N = 36), a perennial monocotyledonous fruit plant, is the most important arbocultural crop oasis for that reason it has been recently object of many studies both at phylogenetic and at molecular level and the first draft sequence is started in 2009 (Weill Cornell Medical College in Quatar) where a predicted genome size of 550 Mb is available on the web.

Identification of date palm cultivars is principally based on fruit morphology. However, morphological traits are often variable or imprecise indicators of plant genotype, being influenced by environmental conditions or varying with the developmental stage of plant. Consequently, discrimination among closely related cultivars and clones based on morphometric descriptors is often difficult. Nowadays, molecular markers, based on polymorphisms at DNA level, are increasingly used to address species delimitation problems where morphological methods are unreliable or inconclusive often providing greater resolution between closely related taxa and hybrids.

Among molecular markers microsatellites, or simple-sequence repeats (SSRs) because of their particular features represent a convenient tool for genotyping. They are tandem repeat of short (1-6 nucleotides) DNA segments that are highly variable in number due to slippage of polymerase during DNA replication. SSRs are intersperse in the genome (both organelle and nuclear genome), show no environmental or developmental influence and present simple codominant inheritance, this mean that in a diploid organism as date palm, both alleles at a SSR locus should be visible in the heterozygote condition.

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Andrea Bove and Milvia Luisa Racchi Dipartimento Biotecnologie agrarie, sezione di Genetica UniversitĂ degli studi di Firenze via Maragliano 77, 50144 Firenze 2

The present study has been conducted in the framework of the Italy - Lybia bilateral cooperation project "Improvement and Valorisation of Date Palm in Al Jufrah Oasis", carried out by Istituto Agronomico per l'Oltremare (Italy) and the Board of Improving and Developing Olive and Palm Trees (Tripoli, Libya).With the general objective of supporting and strengthening the date palm production through the improvement and valorisation of production, transformation and commercialisation of local varieties, the project aims to contribute to the social and economic development of the Al Jufra Region. In this framework, the characterisation and description of local varieties, performed through the sampling and description of genetic, morphometric and chemical characteristics, is accompanied by an integrated study of the palm dates cropping system in the Al Jufrah Region. Such study has been carried out for the five oasis of Waddan, Hun, Sokna, Zellah and Al Fugha.

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Because of their high mutation rates and the ease of the analysis we used SSR as molecular markers to perform the genetic fingerprinting of the Libyan date palm’s resources. in fact this methodology was proved useful and effective for genetic fingerprinting, cultivar identification and phylogenetic studies among different accessions. Materials and Methods Plant materials Samples were collected in palm date groves, both of recent and ancient constitution in the locality of Sawkanah, Hun, Waddan, Zillah and Al Faqqah. The names of 18 varieties commercially relevant sampled in farms of the different localities are listed in Table1. Plant materials consists of young leaves of adult trees randomly samples from the mentioned localities of Al-Jufra oasis.

DNA extraction The dry leaf material was ground into a fine powder using bead-mill homogenizer TissueLyser (Qiagen, Italy ). The leaf powder was then subjected to DNA extraction using both DNeasy Plant Maxi/Mini Kits (Qiagen, Milano Italia) or E-Z 96 Plant kit (Omega), according to manufacturer’s instructions and the resulting DNA solutions were stored at –20°C. After purification, DNA concentration and quality were determined on 1% of agarose gel electrophoresis. Microsatellites amplification and Genotyping We have tested a total of 16 date-palms specific primer pairs selected for their polymorphic information content among SSR loci developed by Billote et al. (2004) and Akkak et al.(2009). PCR reactions were performed in a total reaction mixture of 14 µL containing: 20 ng of total genomic DNA, 1X/PCR buffer (Promega Corp. Madison, USA), 0.2 mM of dNTP (Promega), 0.05 U of Taq DNA polymerase (Promega), 0,07 µM of the forward primer with M13 tail, 0,2 µM of the reverse primer and 0,2 µM of M13 primer-fluorescent dye (Invitrogen). For a given locus, the forward SSR primer was 5’-end labeled with M13 extension (5’TGTAAAACGACGGCCAGT-3’) for incorporate, via PCR step, a fluorochrome (6-FAM, VIC or NED) necessary for detect the PCR products on the sequencer.

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Amplifications were performed in Applied Biosystem Thermocycler (AB System, Germany) with the following conditions: for Billote’s primer, a initial denaturation at 95°C for 1 min, then 35 cycles of 94°C for 30 sec, 52°C for 1 min and 72°C for 2 min and a final elongation step at 72°C for 8 min; for Akkak’s primer a initial denaturation at 95°C for 9 min, then 28-35 cycles of 94°C for 30 sec, 55°C for 45 sec and 72°C for 1 min and a final elongation step at 72°C for 45 min. A negative control, with the reaction mixture excluding DNA, was also included in each experiment. Amplification products were checked on 1,5 % agarose gel to verify the presence of a band of the expected size. PCR products were resolved on an MegaBace 1000 (GE Healthcare, USA) sequencer. Data were analyzed using the software Fragment profiler ver. 2.1 (Amersham Biosciences) Genetic Data Analysis The total number of alleles, number of genotype, alleles frequencies and the measured of genetic diversity and differentiation were calculated for all individuals at all loci, using the opensourse software GenAlEx 6 (Peakall, R. and Smouse P.E.; 2006).

Barcode set Barcode has been developed using the software opensource “Barcode Label Generator Plus” (www.scansecretary.com) Using that software DNA data obtained by SSR genotyping at 12 loci were transformed in a numeric code consisting of 24 characters giving to each allele a progressive number from 0 to 9.

Results and discussion In a preliminary analysis 18 SSR marker were tested and afterward the 12 more polymorphic were used to perform the analysis. All the markers selected gave successful amplification in the condition used in all the samples evaluated. The SSR marker gave rise to a electropherogram profile that revealed the nature homozygote or heterozygote of the locus analyzed. In figure 1 the profiles of some representative markers were reported. Genetic diversity evaluated as number of alleles and genotypes for each SSR locus was presented in Table 2.

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The total number of alleles found at 12 SSR loci, considering the three localities more represented in the collection was 75, with a weighted average on 6,25 alleles per each marker. It is interesting to note as this number was enough to allow the unambiguous identification the cultivars. The distribution of alleles frequencies for the SSR loci in the five locality of Al-Jufra was presented in Figure 2. The multilocus genotypes of the cultivars analyzed were presented in Table 3. The 12 SSR profiles obtained allow to indentify clearly each cultivar with the exception of three varieties indicated by an asterisk. In that cases variability was observed both among localities as for Bamour and Noyat Meka or as in the case of Sokeri within farm. This result can be related to the small number of trees sampled for the former and to the practice of seed reproduction instead of the clonal propagation for the latter (Al Sanusse personal communication). In the whole the results evidenced that the clonal propagation of the cultivar was a practice common to the majority of the farmers and that in general they had a good skill, based on a long habit, in the classification of the cultivars even if some mistakes were noted. The cases of misclassification could due both to errors in the sampling or during propagation because of the difficulty, in some cases, to identify some cultivars on the base of the morphology. Since each variety was identified by a unique profile, it has been possible to generate an individual barcode using the multilocus genotype. In figure 3 the barcodes for the date palms of Al Jufra oasis are presented. The barcode represents an important tool for the genetic identity and the traceability of the products consequently its availability can represent an additional value for Libyan dates.

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Table 1 Names of 18 varieties commercially relevant sampled in farms of the different localities Name of cultivar

Abel

Bamour Berni

Bestian

Deglet

Halima

Hamria

Kathari

Noyat Meka Omglaib

Saiedi

Saila

Locality

N째 of samples analysed

Sokna Hon Waddan Sokna Waddan Sokna Hon Waddan Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Sokna Hon Waddan Sokna Hon Waddan Zillah Al Fuqqah

7 8 10 1 7 5 7 9 8 10 9 3 4 10 7 7 1 7 3 6 8 9 7 5 5

Sokna Hon Waddan Zillah Hon Waddan Sokna Hon Waddan Sokna Hon Waddan Zillah Sokna Hon

12 10 6 6 1 8 1 4 6 4 7 6 4 3 8

6

Sokeri

Tagiat

Talis

Tameg

Tasferit

Zebur

Sokna Hon Waddan Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Sokna Hon Waddan Sokna Hon Waddan Sokna Hon Waddan

8 2 9 7 10 11 6 5 8 6 6 5 6 9 7 4 4 4 6 6 2

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Table 2 Genetic diversity measured by the number of alleles/genotypes for each marker in the different localities of Al-jufra oasis.

Markers name DM 1

DM 2

DM 3

DM 4

DM 5

DM 6

DM 7

DM 8

Locality Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah

Number of alleles detected 5 5 5 5 3 5 5 5 5 3 7 7 7 6 3 7 7 7 6 4 7 5 6 5 3 8 7 8 5 4 9 7 9 5 4 7 6 7 5 3

Number of genotypes 11 11 10 5 3 7 6 6 5 3 12 11 13 8 2 11 11 13 5 3 10 9 11 6 3 13 12 14 7 3 15 13 17 5 2 11 9 10 5 2

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DM 9

DM 10

DM 11

DM 12

Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah Sokna Hon Waddan Zillah Al Fuqqah

6 6 6 5 3 6 7 6 6 4 5 5 9 4 3 4 4 5 3 3

8 8 9 6 3 14 13 12 9 3 7 7 10 5 3 7 6 7 5 5

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Figure 1 Allelic profiles at the microsatellite loci of the principal date palm varieties in the five localities of Al-Jufra oasis. Numbers on X axis refer to allele size (bp) and on Y axis to fluorochrome intensity.

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Figure 2 Distribution microsatellites alleles frequencies in five localities of Al-Jufra oasis date palms Allele Frequency for locus DM 2

0,600

0,600 sokna

0,400

hon

0,200

w addan

0,000

zillah

142

144

146

151

158

Frequency

Frequency

Allele Frequency for locus DM 1

sokna

0,400

hon

0,200

w addan zillah

0,000

faqqah

faqqah

309

Alleles

310

sokna hon w addan zillah

188

191

192

193

198

sokna hon w addan zillah

186

faqqah

192

196

sokna hon w addan zillah

158

166

168

172

w addan zillah

133

139

141

143

145

Alleles

Allele Frequency for locus DM 7

Allele Frequency for locus DM 8

147

149

faqqah

0,600 sokna

0,200

hon

0,100

w addan

0,000

zillah

212

213

215

217

219

223

225

227

Frequency

Frequency

faqqah

hon

Alle les

0,300

205

sokna

0,400

hon

0,200

w addan zillah

0,000

faqqah

222

225

246

Alleles

252

254

256

258

faqqah

Alleles

Allele Frequency for locus DM 9

Allele Frequency for locus DM 10

0,800

0,600

0,600

sokna

0,400

hon

0,200

waddan

0,000

zillah

131

141

143

147

151

157

Frequency

Frequency

209

sokna

123

faqqah

0,400

sokna

0,400

hon

0,200

waddan

0,000

zillah

154

faqqah

158

159

Alleles

163

167

175

177

faqqah

Alleles

Allele Frequency for locus DM 12

Allele Frequency for locus DM 11

0,600

0,600

sokna

0,400

hon

0,200

waddan

0,000

zillah

141

143

145

147

149 Alleles

151

155

157

163

faqqah

Frequency

0,800 Frequency

206

0,500 0,400 0,300 0,200 0,100 0,000

Frequency

Frequency

0,500 0,400 0,300 0,200 0,100 0,000 156

199

Allele Frequency for locus DM 6

Allele Frequency for locus DM 5

150

198 Alleles

Alleles

143

321

0,500 0,400 0,300 0,200 0,100 0,000

Frequency

Frequency

0,500 0,400 0,300 0,200 0,100 0,000 186

318

Allele Frequency for locus DM 4

Allele Frequency for locus DM 3

181

316

sokna

0,400

hon

0,200

waddan zillah

0,000 106

108

120

123

127

faqqah

Alleles

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Figure 3 Barcodes of the 18 date palm varieties belonging to Al-Jufra oasis ABEL

BERNI

BESTIAN

HALIMA

HAMRIA

KATHARI

OMGLAIB

SAIEDI

SAILA

TAGIAT

TALIS

TAMEG

BAMOUR

DEGLET

NOYAT MEKA

SOKERI

TASFERIT

ZEBUR

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Table 3 Multilocus genotypes of 18 commercial date palm clones at twelve nuclear microsatellite loci ‥

clone

locality

DM 1

DM 2

DM 3

DM 4

DM 5

DM 6

DM 7

DM 8

DM 9

DM 10

DM 11

DM 12

S ,H, W

142 146

309 316

191 198

196 209

150 158

123 145

217 219

222 252

147 147

163 175

141 141

123 123

W

146 158

316 321

198 198

186 196

158 158

123 145

217 225

252 252

147 147

159 175

149 151

123 127

S, H, W

146 151

309 316

191 191

196 198

150 158

145 147

212 217

246 252

147 147

159 175

141 141

123 123

Bestian

S, H, W, Z, F

144 146

309 316

191 191

206 206

156 156

149 149

217 225

222 246

141 147

159 163

141 155

108 108

Deglet

S, H, W, Z

144 158

310 318

191 193

196 209

156 168

141 149

213 213

246 256

147 147

167 167

155 155

123 123

Halima

S, H, W

142 151

316 321

191 193

186 209

150 156

147 149

213 225

246 254

141 147

159 175

155 155

123 123

Hamria

S, H, W, Z, F

144 158

316 316

181 198

199 206

150 158

145 149

217 225

246 252

147 157

163 175

143 155

108 123

Kathari

S, H, W, Z

142 146

309 316

191 198

186 209

156 158

123 149

213 215

222 246

147 147

163 163

141 143

123 123

W

146 146

309 309

181 191

186 206

150 156

149 149

212 217

246 246

147 147

159 159

141 155

108 108

S, H, W

142 144

309 316

198 198

206 209

158 158

123 145

205 219

246 252

147 147

163 175

155 155

123 123

Saiedi

S, H, W, Z

144 146

316 316

192 198

192 196

156 172

139 149

213 215

252 258

143 151

154 175

143 163

123 123

Saila

S, H

142 142

309 316

191 193

196 209

150 156

133 149

213 217

246 246

141 141

159 159

141 155

108 108

S

151 158

316 318

186 198

196 206

150 158

133 145

219 219

246 252

147 147

154 177

155 155

106 106

S, H, W, Z, F

146 158

309 321

181 198

186 209

150 156

123 141

205 215

246 252

141 157

154 163

155 155

123 127

S, H, W, Z

146 158

309 309

188 198

186 209

150 156

123 145

213 215

252 252

157 157

163 177

155 155

127 127

Tameg

S, H, W

142 151

316 321

181 193

186 196

156 158

133 149

213 225

246 246

141 141

159 167

155 155

106 106

Tasferit

S, H, W

158 158

309 321

188 188

199 209

158 172

145 149

219 225

254 254

141 147

163 177

157 157

123 123

Zebur

S, H, W

158 158

316 316

186 198

186 186

150 150

145 149

215 217

246 252

131 147

154 154

141 143

106 106

Abel Bamour* Berni

Noyat Meka* Omglaib

Sokeri*** Tagiat Talis

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localities S, Sokna; H, Hon; W, Waddan; Z, Zillah; F, Al Faqqah; * : the profil refers to Waddan only **: the profil refers to Sokna only. In Waddan the Sokeri variety is seed propagated and then selected on the base of morphometric important traits therefore cannot be considered as a clone..

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