Genetic variability revealed by microsatellite markers in a germplasm collection of <i>Jatropha curcas</i> L. in Brazil: an important plant for biofuels

Souza, Romero de Lima; Dias, Luiz Antônio dos Santos; Corrêa, Thais Roseli; Caixeta, Eveline Teixeira; Fernandes, Erika da Costa; Muniz, Dandara Rêgo; Rosmaninho, Lucas Barbosa de Castro; Cardoso, Poliane Marcele Ribeiro

doi:10.1590/1984-70332019v19n3a46

Abstract

We evaluated the genetic variability of a collection of Jatropha curcas germplasm, represented by 93 accessions, using microsatellite markers. Among the 60 markers tested, five of them detected polymorphisms, with a total of 11 alleles and mean of 2.2 alleles per loci. These five markers enabled the quantification of genetic variability through estimates of expected (He=0.42) and observed (Ho=0.64) heterozygosity, Shannon-Weaver index (H'=0.62), coefficient of inbreeding (ƒ=-0.44) and the formation of 11 clusters. Simultaneously, 14 accessions randomly sampled among the 93 and represented by seven plants each, were analyzed with these same five markers to quantify the within and between variability. Most of the genetic variation (92.58%) was contained within the accessions. These analyses revealed, for the first time, expressive genetic variability to be explored in this collection. The accessions UFVJC 05, 07, 12, 18, and 53 presented expressive variability among them with potential for the constitution of a base population for the breeding program.

Keywords:
Variability; molecular markers; germplasm bank; breeding

INTRODUCTION

Oil price volatility, combined with the need to reduce greenhouse gas emissions, has boosted global demand for biofuels. Among the potential species for the production of biofuels, Jatropha curcas L. deserves to be highlighted, as its seeds contain high oil content (36.2%) with the best quality (Freitas et al. 2016Freitas RG, Dias LAS, Cardoso PMR, Evaristo AB, Silva MF and Araújo NM (2016) Diversity and genetic parameter estimates for yield and its components in Jatropha curcas L. Genetics and Molecular Research 15: 1-10. ). These aspects have led to rapid expansion of cultivated areas and demand for improved cultivars (Sorrel et al. 2010Sorrell S, Miller R, Bentley R and Speirs J (2010) Oil futures: a comparison of global supply forecasts. Energy Policy 38: 4990-5003. ).

Despite its great potential, J. curcas is still a species undergoin domestication, but with considerable variability to be explored. However, information regarding genetic variability and population structure is still limited (Bressan et al. 2012Bressan EA, Scotton DC, Ferreira RR, Jorge EC, Sebbenn AM, Gerald LTS and Figueira A (2012) Development of microsatellite primers for Jatropha curcas (Euphorbiaceae) and transferability to congeners. American Journal of Botany 99: 237-239.) and breeding programs are rare compared to other oilseed species (Dias et al. 2012Dias LAS, Missio RF and Dias DCFS (2012) Antiquity, botany, origin and domestication of Jatropha curcas (Euphorbiaceae), a plant species with potential for biodiesel production. Genetics and Molecular Research 11: 2719-2728. , Pecina-Quintero et al. 2014Pecina-Quintero V, Anaya-López JL, Zamarripa-Colmenero A, Núñez-Colín CA, Montes-García N, Solís-Bonilla JL and Jiménez-Becerril MF (2014) Genetic structure of Jatropha curcas L. in Mexico and probable centre of origin. Biomass & Bioenergy 60: 147-155.).

The initial phase of a breeding program involving any kind of plant species requires a germplasm collection, functioning as a repository of genes for the future development of varieties. Therefore, the success of an improvement program depends on knowledge of the available genetic variability, which will allow the efficient selection of different genotypes to produce hybrids and similar genotypes to produce lines (Pecina-Quintero et al. 2014Pecina-Quintero V, Anaya-López JL, Zamarripa-Colmenero A, Núñez-Colín CA, Montes-García N, Solís-Bonilla JL and Jiménez-Becerril MF (2014) Genetic structure of Jatropha curcas L. in Mexico and probable centre of origin. Biomass & Bioenergy 60: 147-155.).

Molecular markers are suitable tools for the characterization of genetic variability in germplasm collections. Microsatellites, also known as Simple Repeated Sequence (SSR) markers, have high reproducibility, codominant inheritance and high polymorphism. Studies involving these markers have been successfully used to characterize the genetic variability of J. curcas (Pamidimarri et al. 2008Pamidimarri DVNS, Singh S, Mastan SG, Patel J and Reddy MP (2008) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Plant Molecular Biology Report 36: 1357-1364., Sun et al. 2008Sun QB, Li LF, Li Y, Wu GJ and Ge XJ (2008) SSR and AFLP markers reveal low genetic diversity in the biofuel plant Jatropha curcas in China. Crop Science 48: 1865-1871., Sudheer et al. 2009Sudheer PDVN, Singh S, Mastan SG, Patel J and Reddy MP (2009) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Molecular Biology Reports 36: 1357-1364., Rosado et al. 2010Rosado TB, Laviola BG, Faria DA, Pappas MR, Bhering LL, Quirino B and Grattapaglia D (2010) Molecular markers reveal limited genetic diversity in a large germplasm collection of the biofuel crop Jatropha curcas L. in Brazil. Crop Science 50: 2372-2382., Wen et al. 2010Wen M, Wang H, Xia Z, Zou M, Lu C and Wang W (2010) Development of EST-SSR and genomic-SSR markers to assess genetic diversity in Jatropha curcas L. BMC Research Notes 3: 42-50., Bressan et al. 2012Bressan EA, Scotton DC, Ferreira RR, Jorge EC, Sebbenn AM, Gerald LTS and Figueira A (2012) Development of microsatellite primers for Jatropha curcas (Euphorbiaceae) and transferability to congeners. American Journal of Botany 99: 237-239., Na-ek et al. 2011Na-ek Y, Wongkaew A, Phumichai T, Kongsiri N, Kaveeta R, Reewongchai T and Phumichai C (2011) Genetic diversity of physic nut (Jatropha curcas L.) revealed by SSR markers. Journal of Crop Science and Biotechnology 14: 10-110., Pecina-Quintero et al. 2014Pecina-Quintero V, Anaya-López JL, Zamarripa-Colmenero A, Núñez-Colín CA, Montes-García N, Solís-Bonilla JL and Jiménez-Becerril MF (2014) Genetic structure of Jatropha curcas L. in Mexico and probable centre of origin. Biomass & Bioenergy 60: 147-155., Sinha et al. 2015Sinha P, Islam MA, Negi MS and Tripathi SB (2015) First identification of core accessions of Jatropha curcas from India based on molecular genetic diversity. Journal of Plant Genetic Resources 14: 77-80., Santos et al. 2016Santos DN, Ferreira JL, Setoaw TA, Cançado GMA, Pasqual M, Londe LCN, Saturnino HM and Vendrame WA (2016) Genetic structure from the oldest Jatropha germplasm bank of Brazil and contribution for the genetic improvement. Anais da Academia Brasileira de Ciências 88: 2363-2374., Vásquez-Mayorga et al. 2017Vásquez-Mayorga M, Fuchs EJ, Hernández EJ, Herrera F, Hernández J, Moreira I, Arnáez E and Barboza NM (2017) Molecular characterization and genetic diversity of Jatropha curcas L. in Costa Rica. Peer J 5: 29-31., Gangapur et al. 2018Gangapur DR, Agarwal P and Agarwal PK (2018) Molecular markers for genetic diversity studies in Jatropha (Jatropha curcas L.). AIMS Environmental Science 5: 340-352. ). In all of these studies, the genetic variability revealed for this species has been considered low.

The present study aimed to quantify the genetic variability present in a germplasm collection of J. curcas, composed of 93 accessions, using microsatellite markers. This study is part of the strategy to identify superior genotypes for cultivar development.

MATERIAL AND METHODS

Plant material

The germplasm collection of J. curcas of the Federal University of Viçosa (UFV), located in the Araponga Experimental Farm (lat 20º 39' S, long 42º 32' W and alt 823 m asl), in the municipality of Araponga, MG, Brazil is composed of accessions originating from different Brazilian geographic regions and from abroad (Table 1), all propagated by seeds. Currently, this collection is composed of 93 accessions (1504 plants) and is installed in modules of five trials in randomized block design, with four replications and 4-plant plots in 2 x 2 m spacing, with two common controls (Freitas et al. 2011Freitas RG, Missio RF, Matos FS, Resende MDV and Dias LAS (2011) Genetic evaluation of Jatropha curcas: an important oilseed for biodiesel production. Genetics and Molecular Research 10: 1490-1498., Freitas et al. 2016Freitas RG, Dias LAS, Cardoso PMR, Evaristo AB, Silva MF and Araújo NM (2016) Diversity and genetic parameter estimates for yield and its components in Jatropha curcas L. Genetics and Molecular Research 15: 1-10. ).

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Table 1
Provenance of 93 accessions of Jatropha curcas L. evaluated

DNA extraction

The DNA extraction process was conducted at the Laboratory of Forest Pathology of the UFV, based on the protocol for eucalyptus, modified from Doyle and Doyle (1990). This modification was due to the maceration of the samples in the following the steps: after removing of the central and secondary veins, the leaves were placed in 2 mL microcentrifuge tubes with metal beads and 700 μL extraction buffer (100 mM Tris-HCl pH 8.0, 20 mM EDTA, 1.4 M NaCl, 2% (w/v) CTAB, 2% (w/v) PVP and 0.4% (v/v) β-mercaptoetanol, the latter separated from the other components). The samples were macerated with Tissuelyser II (Qiagen) and incubated in a water bath at 65 °C for 30 minutes. After incubation, 500 μL of chloroform-isoamyl alcohol (24:1) was added to the tubes, which were manually inverted several times. The tubes were then centrifuged at 12,000 rpm for 5 min. The supernatants were transferred to new tubes and the extraction with chloroform was repeated. The supernatants (~ 500 μL) were transferred to fresh tubes and 0.9 volumes (450 μL) of cold isopropanol were added. The precipitated DNA was washed twice with 500 μL of cold 70% and 95% ethanol. The DNA was dried at room temperature for 1 hour and dissolved in 50 μL of TE (10 mM Tris and 1 mM EDTA, pH 8.0) plus RNAse (10 μg mL^-1) for 2 hours at 37 °C and then stored at -20 °C. DNA quantification was performed using a Thermo Scientific's NanoDrop spectrophotometer and standardized with final concentrations adjusted to 10 ng mL^-1.

Microsatellite molecular markers

Sixty pairs of microsatellite primers were tested (see Table 2). All primers used were previously reported in the literature surrounding J. curcas, some of them drawn based on microsatellite loci derived from genomic sequences and specific ESTs of the species by Bressan et al. (2012Bressan EA, Scotton DC, Ferreira RR, Jorge EC, Sebbenn AM, Gerald LTS and Figueira A (2012) Development of microsatellite primers for Jatropha curcas (Euphorbiaceae) and transferability to congeners. American Journal of Botany 99: 237-239.), partial genomic sequences developed initially for cassava by Wen et al. (2010Wen M, Wang H, Xia Z, Zou M, Lu C and Wang W (2010) Development of EST-SSR and genomic-SSR markers to assess genetic diversity in Jatropha curcas L. BMC Research Notes 3: 42-50.), and a number developed by Sudheer Pamidimarri et al. (2009Sudheer PDVN, Singh S, Mastan SG, Patel J and Reddy MP (2009) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Molecular Biology Reports 36: 1357-1364.) for differentiation of J. curcas toxic and non-toxic genotypes. PCRs (Polymerase Chain Reaction) were performed in a volume of 20 μL containing 50 ng DNA sample, 1x Taq DNA polymerase buffer, 100 μM of each dNTP, 1.5 mM MgCl₂, 0.2 μM of each primer and 1.0 U Taq DNA polymerase (Life Science). Amplifications were performed in an MJ Research PTC 100 thermocycler with denaturation at 94 °C for 3 minutes, followed by 40 cycles of denaturation at 94 °C for 1 min, annealing for 1 min at the specific temperature of each primer and extension at 72 °C for 1 min. Final extension was performed at 72 °C for 8 min. PCR products were separated on a 6% denaturing polyacrylamide gel and visualized by silver staining solution, according to Creste et al. (2001Creste S, Tulmann Neto A and Figueira A (2001) Detection of single sequence repeat polymorphisms in denaturing polyacrylamide sequencing gels by silver staining. Plant Molecular Biology Reporter 19: 299-306. ).

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Table 2
SSR primers tested in the evaluation of the genetic variability of Jatropha curcas L. accessions

Variability between and within accessions

To quantify the genetic variability among the 93 accessions, one individual was selected from the seven collected, based on the highest concentration and the best DNA quality. After that, the most polymorphic primers were selected to analyze the variability between and within the accessions. To quantify the genetic variability between and within accessions, DNA from seven plants was extracted from 14 accessions randomly selected from the 93 accessions (Table 2).

Statistical analyses

The markers were coded as codominant, assigning numbers to the alleles. Thus, when a locus presented three alleles, the codes 11, 22, 33 were attributed to the homozygotes and 12, 13, and 23 for the heterozygotes. Popgene software version 1.31 (Yeh et al. 1999Yeh FC, Boyle T, Rongca Y, Ye Z and Xiyan JM (1999) POPGENE. Microsoft window-based freeware for population genetic analysis. Version 1.31, Manual) was used to estimate the genetic variability statistics such as allele frequencies, number of alleles (na), number of effective alleles (ne), observed (H_O) and expected (H_E) heterozygosity, Shannon-Weaver index (H´), Nei’s (1972Nei M (1972) Genetic distance between populations. American Naturalist 106: 283-292.) genetic distance of and the coefficient of inbreeding (ƒ). Analysis of molecular variance (AMOVA, Excoffier et al. 1992Excoffier L, Smouse PE and Quattro JM (1992) Analysis of molecular variance inferred from metric distances among DNA haplotypes: application to human mitochondrial DNA restriction data. Genetics 131: 479-491.) and polymorphism information content (PIC, Botstein et al. 1980Botstein D, White RL, Skolnick M and Davis RW (1980) Construction of genetic linkage map in man using restriction fragment length polymorphisms. American Journal of Human Genetics 32: 314-331.) were performed using Genes software (Cruz 2013Cruz CD (2013) Genes - a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum 35: 271-276.). For the construction of a circular dendrogram, the Mega7 (Kumar et al. 2016Kumar S, Stecher G and Tamura K (2016) MEGA7: Molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution 33: 1870-1874. ) software was used to perform the UPGMA clustering algorithm from Nei’s (1972) genetic distance. Interpretation of the dendrogram was conducted taking into consideration high-change points of cluster fusion.

RESULTS

Among the 60 microsatellite markers tested in the 93 accessions, five were able to detect polymorphisms (Table 2, underlined); therefore, these were used in the analysis of genetic variability.

Genetic variability among the 93 accessions

The locus CESR 0756 was the only one among the five analyzed which allowed the detection of three alleles in the 93 accessions. The locus JCENA 87 enabled the detection of less polymorphism according to allele frequency, although two alleles were detected, similar to the JCDS 10, SSRY 107 and SSRY 127 loci. In JCENA 87, the allele A₁ frequency was almost 100%. The five microsatellite loci used to evaluate the accessions generated a total of 11 alleles (na), with an average of 2.2 alleles per locus. The number of effective alleles (ne) ranged from 1.01 to 2.71, with a mean of 1.91 (Table 3). Because the A₂ allele of locus JCENA87 presented a frequency lower than 0.05 (P < 0.05) it can be considered to be rare, with occurrence in only one individual of the accession UFVJC18.

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Table 3
Diversity statistics and frequency of the alleles A₁, A₂ and A₃ for five polymorphic SSR loci used in the evaluation of genetic variability among 93 accessions of Jatropha curcas L.. The same five loci were also used on 14 accessions, randomly selected among 93 accessions, for evaluating the variability within and between them

To quantify the genetic variability between 93 accessions, estimates of expected (He) and observed (Ho) heterozygosity are important. Ho values were found to be ranging from 0.02 to 0.92, with an average of 0.64. He values spanned 0.02 to 0.64, with a mean of 0.42 (Table 3), which indicated a possible heterozygous origin of the collection accessions. For all loci (except JCENA 87), Ho was higher than He, revealing an excess of heterozygotes relative to that expected when in Hardy-Weinberg equilibrium. For genetic improvement purposes, this result demonstrated the presence of heterozygotes able to be explored in this collection.

A parameter of great importance in assessing genetic variability in populations, by measuring the level of homozygosity, is the coefficient of inbreeding (f). It is essential to verify the existence of crossing among related individuals. Here, f values ranged from -0.005 to -0.85 (Table 3). Notably, negative f values are interpreted as null inbreeding, suggesting that there were no crosses between related individuals in the collection.

The Shannon-Weaver index (H´) presented values ranging from 0.03 to 1.05, and the mean value found was 0.62 (Table 3). This mean value of 0.62 reveals the existence of high genetic variability in the collected accessions of J. curcas, more than sufficient for the continuity of the breeding program.

All 93 accessions were clustered by the UPGMA method (Figure 1) and the formation of the following 11 clusters was observed: cluster I (orange, 23 accessions), cluster II (purple, 15 accessions), cluster III (pink, 10 accessions), cluster VI (blue, 14 accessions), cluster V (yellow, 4 accessions), cluster VI (dark green, 5 accessions), cluster VII (red, 4 accessions), cluster VIII (light green, 6 accessions), cluster IX (dark blue, 10 accessions) and two single clusters (X and XI) formed by accessions UFVJC 53 and UFVJC 7, respectively, which stood out from the others and were collected in Barbacena (MG) and João Pinheiro (MG), respectively. The accessions UFVJC 61 and 70 collected in Rio Grande do Sul (RS) and Ariquemes (RO) were grouped in the same cluster II.

Figure 1
Dendrogram based on the UPGMA cluster analysis among 93 accessions of Jatropha curcas L. using five microsatellite loci.

Genetic variability within and between 14 accessions

The same five polymorphic SSR loci were used on 14 accessions, randomly selected on 93, for evaluating the variability within and between them. A mean of 1.86 alleles per locus was found. The analysis of polymorphism information content (PIC) allowed quantification of the genetic polymorphism of each locus in the accessions evaluated. The highest PIC value observed was 0.35 for the locus SSRY 107, while the lowest value occurred for the locus JCENA 87 which did not distinguish within and between accessions (Table 3). The mean value of PIC (0.20) indicated a moderate level of polymorphism of the analyzed loci, with the exception of the locus JCENA 87.

Values of He ranged from 0 for the locus JCENA 87 to 0.46 in the locus SSRY 107, with mean of 0.25. Ho ranged from 0 for the locus JCENA 87 to 0.79 at the locus SSRY 107, with an average of 0.42 (Table 3).

The proportion of variability within and between the 14 accessions was evaluated by AMOVA. Most of the genetic variation (92.58%) was within the populations (Table 4). Thus, it can be concluded that there is considerable genetic variability within populations.

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Table 4
Analysis of molecular variance within and between 14 accessions of Jatropha curcas L.

DISCUSSION

The characterization of germplasm collections using molecular markers is an important strategy for the success of breeding programs. Molecular markers have been used in several studies to characterize accessions of J. curcas. Sun et al. (2008Sun QB, Li LF, Li Y, Wu GJ and Ge XJ (2008) SSR and AFLP markers reveal low genetic diversity in the biofuel plant Jatropha curcas in China. Crop Science 48: 1865-1871.) used SSR and AFLP markers to characterize 58 accessions from China, and found a low level of polymorphism. Tatikonda et al. (2009Tatikonda L, Wani SP, Kannan S, Beerelli N, Sreedevi TK, Hoisington DA, Devi P and Varshney RK (2009) AFLP-based molecular characterization of an elite germplasm collection of Jatropha curcas L., a biofuel plant. Plant Science 176: 505-513. ) evaluated the genetic variability of 48 accessions from six different regions of China using AFLP markers. Sudheer et al. (2009Sudheer PDVN, Singh S, Mastan SG, Patel J and Reddy MP (2009) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Molecular Biology Reports 36: 1357-1364.) used SSR markers to characterize germplasm from India. Santos et al. (2016Santos DN, Ferreira JL, Setoaw TA, Cançado GMA, Pasqual M, Londe LCN, Saturnino HM and Vendrame WA (2016) Genetic structure from the oldest Jatropha germplasm bank of Brazil and contribution for the genetic improvement. Anais da Academia Brasileira de Ciências 88: 2363-2374.) evaluated genetic variability using SSR and ISSR markers in 48 accessions from northern Minas Gerais state, Brazil.

The evaluation of genetic variability, by means of microsatellite markers, in 93 accessions from the UFV´s J. curcas collection was performed for the first time. This rich collection presents accessions from several Brazilian regions and abroad and its genetic evaluation is important for both genetic conservation and development of improved cultivars.

Regarding the genetic variability statistics obtained here, the number of alleles per loci (na), ranged from 2 to 3 (mean=2.2), was similar to that found by several other authors. Santos et al. (2016Santos DN, Ferreira JL, Setoaw TA, Cançado GMA, Pasqual M, Londe LCN, Saturnino HM and Vendrame WA (2016) Genetic structure from the oldest Jatropha germplasm bank of Brazil and contribution for the genetic improvement. Anais da Academia Brasileira de Ciências 88: 2363-2374.), using 11 SSR markers, found 2 to 5 alleles per locus, whereas Bressan et al. (2012Bressan EA, Scotton DC, Ferreira RR, Jorge EC, Sebbenn AM, Gerald LTS and Figueira A (2012) Development of microsatellite primers for Jatropha curcas (Euphorbiaceae) and transferability to congeners. American Journal of Botany 99: 237-239.) found 2 to 8 alleles per locus. However, Na-ek et al. (2011Na-ek Y, Wongkaew A, Phumichai T, Kongsiri N, Kaveeta R, Reewongchai T and Phumichai C (2011) Genetic diversity of physic nut (Jatropha curcas L.) revealed by SSR markers. Journal of Crop Science and Biotechnology 14: 10-110.) identified only 1.4 alleles per locus, after evaluating 32 accessions. Rosado et al. (2010Rosado TB, Laviola BG, Faria DA, Pappas MR, Bhering LL, Quirino B and Grattapaglia D (2010) Molecular markers reveal limited genetic diversity in a large germplasm collection of the biofuel crop Jatropha curcas L. in Brazil. Crop Science 50: 2372-2382.) found 1 to 2 alleles per locus in accessions in other Brazilian collection, and of the six microsatellite markers selected by them, four were monomorphic. According to Cruz et al. (2011Cruz CD, Ferreira FM and Pessoni LA (2011) Biometria aplicada ao estudo da diversidade genética. Universidade Federal de Viçosa, Viçosa, 620p.) it is important to have polymorphic loci that have sufficient numbers of alleles to infer the genetic variability of a population in relation to another or its own over time, especially when subjected to evolutionary forces that promote differentiation.

The number of effective alleles (ne) is a measure that quantifies the alleles with significant frequency in a population. In the present study, ne ranged from 1.01 to 2.71. This result was superior to those found by Pecina-Quintero et al. (2014Pecina-Quintero V, Anaya-López JL, Zamarripa-Colmenero A, Núñez-Colín CA, Montes-García N, Solís-Bonilla JL and Jiménez-Becerril MF (2014) Genetic structure of Jatropha curcas L. in Mexico and probable centre of origin. Biomass & Bioenergy 60: 147-155.) (ne from 1.06 to 1.25) evaluating genetic variability in nine J. curcas populations from Mexico. Wen et al. (2010Wen M, Wang H, Xia Z, Zou M, Lu C and Wang W (2010) Development of EST-SSR and genomic-SSR markers to assess genetic diversity in Jatropha curcas L. BMC Research Notes 3: 42-50.), in a study of genetic variability of five J. curcas populations, found values for ne ranging from 1.45 to 1.68.

In addition to estimating the number of polymorphic loci, other quantitative measures can be adopted, such as Ho and He, which allow to infer about the genetic structure of the population. The means of Ho and He in the present study (Ho=0.64 and He=0.40) were similar to those found by Santos et al. (2016Santos DN, Ferreira JL, Setoaw TA, Cançado GMA, Pasqual M, Londe LCN, Saturnino HM and Vendrame WA (2016) Genetic structure from the oldest Jatropha germplasm bank of Brazil and contribution for the genetic improvement. Anais da Academia Brasileira de Ciências 88: 2363-2374.). Bressan et al. (2012Bressan EA, Scotton DC, Ferreira RR, Jorge EC, Sebbenn AM, Gerald LTS and Figueira A (2012) Development of microsatellite primers for Jatropha curcas (Euphorbiaceae) and transferability to congeners. American Journal of Botany 99: 237-239.) also reported similar values (Ho=0.53 and He=0.66) for these measures, although with He higher than Ho, in a direction contrary to that verified in the present study and by Santos et al. (2016Santos DN, Ferreira JL, Setoaw TA, Cançado GMA, Pasqual M, Londe LCN, Saturnino HM and Vendrame WA (2016) Genetic structure from the oldest Jatropha germplasm bank of Brazil and contribution for the genetic improvement. Anais da Academia Brasileira de Ciências 88: 2363-2374.).

The coefficient of inbreeding or fixation index (f) is a parameter of importance in breeding programs that aim at the development of superior cultivars, as it allows measurement of the level of homozygosity in the population. In our study, the values of f varied from -0.01 to -0.85, being close to expected measures, given the genetic nature of the accessions. Vásquez-Mayorga et al. (2017Vásquez-Mayorga M, Fuchs EJ, Hernández EJ, Herrera F, Hernández J, Moreira I, Arnáez E and Barboza NM (2017) Molecular characterization and genetic diversity of Jatropha curcas L. in Costa Rica. Peer J 5: 29-31.), in evaluating accessions from Costa Rica, found negative values (-0.10) for f, evidencing that there was no crossing between relatives among accessions. Cruz et al. (2011Cruz CD, Ferreira FM and Pessoni LA (2011) Biometria aplicada ao estudo da diversidade genética. Universidade Federal de Viçosa, Viçosa, 620p.) stated that negative values of the inbreeding coefficient are common when the Ho values are greater than the expected heterozygosity, suggesting an excess of heterozygous loci. The negative f values should be interpreted as estimates of null inbreeding, that is, there was no crossing among related individuals. J. curcas is a monoic species, so it is expected that the loci are in the heterozygous state due to the mating system by allogamy, as evidenced by Sun et al. (2008Sun QB, Li LF, Li Y, Wu GJ and Ge XJ (2008) SSR and AFLP markers reveal low genetic diversity in the biofuel plant Jatropha curcas in China. Crop Science 48: 1865-1871.), Rosado et al. (2010Rosado TB, Laviola BG, Faria DA, Pappas MR, Bhering LL, Quirino B and Grattapaglia D (2010) Molecular markers reveal limited genetic diversity in a large germplasm collection of the biofuel crop Jatropha curcas L. in Brazil. Crop Science 50: 2372-2382.) and Wen et Al. (2010Wen M, Wang H, Xia Z, Zou M, Lu C and Wang W (2010) Development of EST-SSR and genomic-SSR markers to assess genetic diversity in Jatropha curcas L. BMC Research Notes 3: 42-50.).

The Shannon-Weaver index (H') has been used in genetic studies as a measure of genetic variability within populations and resembles a genotype richness index. Here, H' values varied from 0.03 to 1.05 (mean of 0.62), which revealed the existence of high genetic variability among our 93 accessions of J. curcas collection. Wen et al. (2010Wen M, Wang H, Xia Z, Zou M, Lu C and Wang W (2010) Development of EST-SSR and genomic-SSR markers to assess genetic diversity in Jatropha curcas L. BMC Research Notes 3: 42-50.) also used this index to verify genotypic richness in 45 accessions. These authors found an average value of 0.55 using SSR markers and suggested a high level of genetic variability to be explored in five J. curcas populations.

Among the accessions that showed the greatest genetic diversity, as revealed by the UPGMA algorithm (Figure 1), we highlight: UFVJC 05, 07, 12, 18, and 53, collected in João Pinheiro, Montalvânia and Barbacena (MG). The greater variability present in the accessions collected in Minas Gerais ratifies the study presented by Dias et al. (2012Dias LAS, Missio RF and Dias DCFS (2012) Antiquity, botany, origin and domestication of Jatropha curcas (Euphorbiaceae), a plant species with potential for biodiesel production. Genetics and Molecular Research 11: 2719-2728. ) that considered the State of Minas Gerais as a secondary center of genetic variability in J. curcas.

The formation of 11 clusters with the UPGMA algorithm evidences the expressive genetic variability and structuring of the collection. Sun et al. (2008Sun QB, Li LF, Li Y, Wu GJ and Ge XJ (2008) SSR and AFLP markers reveal low genetic diversity in the biofuel plant Jatropha curcas in China. Crop Science 48: 1865-1871.), evaluating 58 accessions using microsatellite markers, found low genetic variability. Rosado et al. (2010Rosado TB, Laviola BG, Faria DA, Pappas MR, Bhering LL, Quirino B and Grattapaglia D (2010) Molecular markers reveal limited genetic diversity in a large germplasm collection of the biofuel crop Jatropha curcas L. in Brazil. Crop Science 50: 2372-2382.) analyzed the genetic variability of 192 accessions by means of RAPD and SSR markers, finding limited variability among the accessions. Na-ek et al. (2011Na-ek Y, Wongkaew A, Phumichai T, Kongsiri N, Kaveeta R, Reewongchai T and Phumichai C (2011) Genetic diversity of physic nut (Jatropha curcas L.) revealed by SSR markers. Journal of Crop Science and Biotechnology 14: 10-110.) evaluated 32 plants from different regions of the world with five SSR markers and also recorded low genetic variability. Naresh et al. (2015Naresh B, Medipally SR, Dhanasri G and Devi P (2015) Genetic diversity of Jatropha curcas L. accessions and screening for high biodiesel production. International Journal of Pure & Applied Bioscience 3: 124-135.) assessed genetic variability among 14 accessions from India using RAPD markers and observed considerable variability among accessions.

The collection of seeds led to the formation of our genebank, prioritizing higher number of seeds per accessions, may be the differential of it in terms of expressive varibility. Dias and Kageyama (1991Dias LAS and Kageyama PY (1991) Variação genética em espécies arbóreas e consequências para o melhoramento florestal. Agrotrópica 3: 119-127. ) reported that knowledge of the level of genetic variation and its distribution within and between populations is critical. It is possible to better target the breeding strategies to be adopted, in order to maximize genetic gains through the selection cycles. In J. curcas, some studies have also detected a greater amount of genetic variability within populations (Bhering et al. 2015Bhering LL, Peixoto LA, Leite NLSF and Laviola BG (2015) Molecular analysis reveals new strategy for data collection in order to explore variability in Jatropha. Industrial Crops and Products 74: 898-902., Pioto et al. 2015Pioto F, Costa RS, França SC, Gavioli EA, Bertoni BW and Zingaretti SM (2015) Genetic diversity by AFLP analysis within Jatropha curcas L. populations in the State of São Paulo, Brazil. Biomass & Bioenergy 80: 316-320., Sinha et al. 2015Sinha P, Islam MA, Negi MS and Tripathi SB (2015) First identification of core accessions of Jatropha curcas from India based on molecular genetic diversity. Journal of Plant Genetic Resources 14: 77-80.). This high concentration of genetic variation within populations implies sampling more plants per population, as recommended by Dias and Kageyama (1991Dias LAS and Kageyama PY (1991) Variação genética em espécies arbóreas e consequências para o melhoramento florestal. Agrotrópica 3: 119-127. ) and Bhering et al. (2015Bhering LL, Peixoto LA, Leite NLSF and Laviola BG (2015) Molecular analysis reveals new strategy for data collection in order to explore variability in Jatropha. Industrial Crops and Products 74: 898-902.). This strategy was effectively practiced in our collection, when priority was given to collecting more seeds per accession. The present study confirmed the accuracy of our accession collection process, in which each accession was represented by 16 plants. Previous studies employing molecular markers evaluated collections with a reduced number of plants per accession. This is possibly the main reason why they have systematically revealed low genetic variability in the species.

CONCLUSION

The five microsatellite markers selected (JCENA 87, JCDS 10, SSRY 107, SSRY 127 and CESR 0756) were able to detect genetic variability among J. curcas accessions, and to enable genetic evaluation through diversity statistics.

The accessions UFVJC 05, 07, 12, 18 and 53 exhibited expressive diversity, being able to comprise a base population for breeding.

Our results demonstrated the existence of molecular genetic variability within and between and accessions, indicating that our germplasm collection can be used as a base for breeding program.

ACKNOLEGMENTS

Thanks are due to CNPq, FAPEMIG and CAPES for financial support.

REFERENCES

Bhering LL, Peixoto LA, Leite NLSF and Laviola BG (2015) Molecular analysis reveals new strategy for data collection in order to explore variability in Jatropha Industrial Crops and Products 74: 898-902.
Botstein D, White RL, Skolnick M and Davis RW (1980) Construction of genetic linkage map in man using restriction fragment length polymorphisms. American Journal of Human Genetics 32: 314-331.
Bressan EA, Scotton DC, Ferreira RR, Jorge EC, Sebbenn AM, Gerald LTS and Figueira A (2012) Development of microsatellite primers for Jatropha curcas (Euphorbiaceae) and transferability to congeners. American Journal of Botany 99: 237-239.
Creste S, Tulmann Neto A and Figueira A (2001) Detection of single sequence repeat polymorphisms in denaturing polyacrylamide sequencing gels by silver staining. Plant Molecular Biology Reporter 19: 299-306.
Cruz CD, Ferreira FM and Pessoni LA (2011) Biometria aplicada ao estudo da diversidade genética. Universidade Federal de Viçosa, Viçosa, 620p.
Cruz CD (2013) Genes - a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum 35: 271-276.
Dias LAS and Kageyama PY (1991) Variação genética em espécies arbóreas e consequências para o melhoramento florestal. Agrotrópica 3: 119-127.
Dias LAS, Missio RF and Dias DCFS (2012) Antiquity, botany, origin and domestication of Jatropha curcas (Euphorbiaceae), a plant species with potential for biodiesel production. Genetics and Molecular Research 11: 2719-2728.
Excoffier L, Smouse PE and Quattro JM (1992) Analysis of molecular variance inferred from metric distances among DNA haplotypes: application to human mitochondrial DNA restriction data. Genetics 131: 479-491.
Freitas RG, Missio RF, Matos FS, Resende MDV and Dias LAS (2011) Genetic evaluation of Jatropha curcas: an important oilseed for biodiesel production. Genetics and Molecular Research 10: 1490-1498.
Freitas RG, Dias LAS, Cardoso PMR, Evaristo AB, Silva MF and Araújo NM (2016) Diversity and genetic parameter estimates for yield and its components in Jatropha curcas L. Genetics and Molecular Research 15: 1-10.
Gangapur DR, Agarwal P and Agarwal PK (2018) Molecular markers for genetic diversity studies in Jatropha (Jatropha curcas L.). AIMS Environmental Science 5: 340-352.
Kumar S, Stecher G and Tamura K (2016) MEGA7: Molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution 33: 1870-1874.
Na-ek Y, Wongkaew A, Phumichai T, Kongsiri N, Kaveeta R, Reewongchai T and Phumichai C (2011) Genetic diversity of physic nut (Jatropha curcas L.) revealed by SSR markers. Journal of Crop Science and Biotechnology 14: 10-110.
Naresh B, Medipally SR, Dhanasri G and Devi P (2015) Genetic diversity of Jatropha curcas L. accessions and screening for high biodiesel production. International Journal of Pure & Applied Bioscience 3: 124-135.
Nei M (1972) Genetic distance between populations. American Naturalist 106: 283-292.
Pamidimarri DVNS, Singh S, Mastan SG, Patel J and Reddy MP (2008) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Plant Molecular Biology Report 36: 1357-1364.
Pecina-Quintero V, Anaya-López JL, Zamarripa-Colmenero A, Núñez-Colín CA, Montes-García N, Solís-Bonilla JL and Jiménez-Becerril MF (2014) Genetic structure of Jatropha curcas L. in Mexico and probable centre of origin. Biomass & Bioenergy 60: 147-155.
Pioto F, Costa RS, França SC, Gavioli EA, Bertoni BW and Zingaretti SM (2015) Genetic diversity by AFLP analysis within Jatropha curcas L. populations in the State of São Paulo, Brazil. Biomass & Bioenergy 80: 316-320.
Rosado TB, Laviola BG, Faria DA, Pappas MR, Bhering LL, Quirino B and Grattapaglia D (2010) Molecular markers reveal limited genetic diversity in a large germplasm collection of the biofuel crop Jatropha curcas L. in Brazil. Crop Science 50: 2372-2382.
Santos DN, Ferreira JL, Setoaw TA, Cançado GMA, Pasqual M, Londe LCN, Saturnino HM and Vendrame WA (2016) Genetic structure from the oldest Jatropha germplasm bank of Brazil and contribution for the genetic improvement. Anais da Academia Brasileira de Ciências 88: 2363-2374.
Sinha P, Islam MA, Negi MS and Tripathi SB (2015) First identification of core accessions of Jatropha curcas from India based on molecular genetic diversity. Journal of Plant Genetic Resources 14: 77-80.
Sorrell S, Miller R, Bentley R and Speirs J (2010) Oil futures: a comparison of global supply forecasts. Energy Policy 38: 4990-5003.
Sudheer PDVN, Singh S, Mastan SG, Patel J and Reddy MP (2009) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Molecular Biology Reports 36: 1357-1364.
Sun QB, Li LF, Li Y, Wu GJ and Ge XJ (2008) SSR and AFLP markers reveal low genetic diversity in the biofuel plant Jatropha curcas in China. Crop Science 48: 1865-1871.
Tatikonda L, Wani SP, Kannan S, Beerelli N, Sreedevi TK, Hoisington DA, Devi P and Varshney RK (2009) AFLP-based molecular characterization of an elite germplasm collection of Jatropha curcas L., a biofuel plant. Plant Science 176: 505-513.
Vásquez-Mayorga M, Fuchs EJ, Hernández EJ, Herrera F, Hernández J, Moreira I, Arnáez E and Barboza NM (2017) Molecular characterization and genetic diversity of Jatropha curcas L. in Costa Rica. Peer J 5: 29-31.
Wen M, Wang H, Xia Z, Zou M, Lu C and Wang W (2010) Development of EST-SSR and genomic-SSR markers to assess genetic diversity in Jatropha curcas L. BMC Research Notes 3: 42-50.
Yeh FC, Boyle T, Rongca Y, Ye Z and Xiyan JM (1999) POPGENE. Microsoft window-based freeware for population genetic analysis. Version 1.31, Manual

Publication Dates

Publication in this collection
31 Oct 2019
Date of issue
Jul-Sep 2019

History

Received
24 Apr 2019
Accepted
07 Aug 2019

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

[1] Bhering LL, Peixoto LA, Leite NLSF and Laviola BG (2015) Molecular analysis reveals new strategy for data collection in order to explore variability in Jatropha Industrial Crops and Products 74: 898-902.

[2] Botstein D, White RL, Skolnick M and Davis RW (1980) Construction of genetic linkage map in man using restriction fragment length polymorphisms. American Journal of Human Genetics 32: 314-331.

[3] Bressan EA, Scotton DC, Ferreira RR, Jorge EC, Sebbenn AM, Gerald LTS and Figueira A (2012) Development of microsatellite primers for Jatropha curcas (Euphorbiaceae) and transferability to congeners. American Journal of Botany 99: 237-239.

[4] Creste S, Tulmann Neto A and Figueira A (2001) Detection of single sequence repeat polymorphisms in denaturing polyacrylamide sequencing gels by silver staining. Plant Molecular Biology Reporter 19: 299-306.

[5] Cruz CD, Ferreira FM and Pessoni LA (2011) Biometria aplicada ao estudo da diversidade genética. Universidade Federal de Viçosa, Viçosa, 620p.

[6] Cruz CD (2013) Genes - a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum 35: 271-276.

[7] Dias LAS and Kageyama PY (1991) Variação genética em espécies arbóreas e consequências para o melhoramento florestal. Agrotrópica 3: 119-127.

[8] Dias LAS, Missio RF and Dias DCFS (2012) Antiquity, botany, origin and domestication of Jatropha curcas (Euphorbiaceae), a plant species with potential for biodiesel production. Genetics and Molecular Research 11: 2719-2728.

[9] Excoffier L, Smouse PE and Quattro JM (1992) Analysis of molecular variance inferred from metric distances among DNA haplotypes: application to human mitochondrial DNA restriction data. Genetics 131: 479-491.

[10] Freitas RG, Missio RF, Matos FS, Resende MDV and Dias LAS (2011) Genetic evaluation of Jatropha curcas: an important oilseed for biodiesel production. Genetics and Molecular Research 10: 1490-1498.

[11] Freitas RG, Dias LAS, Cardoso PMR, Evaristo AB, Silva MF and Araújo NM (2016) Diversity and genetic parameter estimates for yield and its components in Jatropha curcas L. Genetics and Molecular Research 15: 1-10.

[12] Gangapur DR, Agarwal P and Agarwal PK (2018) Molecular markers for genetic diversity studies in Jatropha (Jatropha curcas L.). AIMS Environmental Science 5: 340-352.

[13] Kumar S, Stecher G and Tamura K (2016) MEGA7: Molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution 33: 1870-1874.

[14] Na-ek Y, Wongkaew A, Phumichai T, Kongsiri N, Kaveeta R, Reewongchai T and Phumichai C (2011) Genetic diversity of physic nut (Jatropha curcas L.) revealed by SSR markers. Journal of Crop Science and Biotechnology 14: 10-110.

[15] Naresh B, Medipally SR, Dhanasri G and Devi P (2015) Genetic diversity of Jatropha curcas L. accessions and screening for high biodiesel production. International Journal of Pure & Applied Bioscience 3: 124-135.

[16] Nei M (1972) Genetic distance between populations. American Naturalist 106: 283-292.

[17] Pamidimarri DVNS, Singh S, Mastan SG, Patel J and Reddy MP (2008) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Plant Molecular Biology Report 36: 1357-1364.

[18] Pecina-Quintero V, Anaya-López JL, Zamarripa-Colmenero A, Núñez-Colín CA, Montes-García N, Solís-Bonilla JL and Jiménez-Becerril MF (2014) Genetic structure of Jatropha curcas L. in Mexico and probable centre of origin. Biomass & Bioenergy 60: 147-155.

[19] Pioto F, Costa RS, França SC, Gavioli EA, Bertoni BW and Zingaretti SM (2015) Genetic diversity by AFLP analysis within Jatropha curcas L. populations in the State of São Paulo, Brazil. Biomass & Bioenergy 80: 316-320.

[20] Rosado TB, Laviola BG, Faria DA, Pappas MR, Bhering LL, Quirino B and Grattapaglia D (2010) Molecular markers reveal limited genetic diversity in a large germplasm collection of the biofuel crop Jatropha curcas L. in Brazil. Crop Science 50: 2372-2382.

[21] Santos DN, Ferreira JL, Setoaw TA, Cançado GMA, Pasqual M, Londe LCN, Saturnino HM and Vendrame WA (2016) Genetic structure from the oldest Jatropha germplasm bank of Brazil and contribution for the genetic improvement. Anais da Academia Brasileira de Ciências 88: 2363-2374.

[22] Sinha P, Islam MA, Negi MS and Tripathi SB (2015) First identification of core accessions of Jatropha curcas from India based on molecular genetic diversity. Journal of Plant Genetic Resources 14: 77-80.

[23] Sorrell S, Miller R, Bentley R and Speirs J (2010) Oil futures: a comparison of global supply forecasts. Energy Policy 38: 4990-5003.

[24] Sudheer PDVN, Singh S, Mastan SG, Patel J and Reddy MP (2009) Molecular characterization and identification of markers for toxic and non-toxic varieties of Jatropha curcas L. using RAPD, AFLP and SSR markers. Molecular Biology Reports 36: 1357-1364.

[25] Sun QB, Li LF, Li Y, Wu GJ and Ge XJ (2008) SSR and AFLP markers reveal low genetic diversity in the biofuel plant Jatropha curcas in China. Crop Science 48: 1865-1871.

[26] Tatikonda L, Wani SP, Kannan S, Beerelli N, Sreedevi TK, Hoisington DA, Devi P and Varshney RK (2009) AFLP-based molecular characterization of an elite germplasm collection of Jatropha curcas L., a biofuel plant. Plant Science 176: 505-513.

[27] Vásquez-Mayorga M, Fuchs EJ, Hernández EJ, Herrera F, Hernández J, Moreira I, Arnáez E and Barboza NM (2017) Molecular characterization and genetic diversity of Jatropha curcas L. in Costa Rica. Peer J 5: 29-31.

[28] Wen M, Wang H, Xia Z, Zou M, Lu C and Wang W (2010) Development of EST-SSR and genomic-SSR markers to assess genetic diversity in Jatropha curcas L. BMC Research Notes 3: 42-50.

[29] Yeh FC, Boyle T, Rongca Y, Ye Z and Xiyan JM (1999) POPGENE. Microsoft window-based freeware for population genetic analysis. Version 1.31, Manual

Accessions¹	Location of collection	Accessions	Location of collection
UFVJC 1	Santa Vitória, MG	UFVJC 52	Barbacena, MG
UFVJC 3	Santa Vitória, MG	UFVJC 53	Barbacena, MG
UFVJC 4	Santa Vitória, MG	UFVJC 54	Barbacena, MG
UFVJC 5	João Pinheiro, MG	UFVJC 55	Janaúba, MG
UFVJC 6	João Pinheiro, MG	UFVJC 56	Janaúba, MG
UFVJC 7	João Pinheiro, MG	UFVJC 57	Janaúba, MG
UFVJC 8	João Pinheiro, MG	UFVJC 58	Janaúba, MG
UFVJC 9	João Pinheiro, MG	UFVJC 59	Janaúba, MG
UFVJC 10	João Pinheiro, MG	UFVJC 60	Pompéu, MG
UFVJC 11	João Pinheiro, MG	UFVJC 61	Rio Grande do Sul
UFVJC 12	João Pinheiro, MG	UFVJC 62	Juiz de Fora, MG
UFVJC 13	Tauá, MG	UFVJC 63	Novo Repartimento, PA
UFVJC 14	Ólhos D’água, MG	UFVJC 65	Desconhecido
UFVJC 15	Veredas, MG	UFVJC 66	Desconhecido
UFVJC 16	Jaíba, MG	UFVJC 67	Desconhecido
UFVJC 17	Montalvânia, MG	UFVJC 68	São Luiz, MA
UFVJC 18	Cana Brava II-Montalvânia, MG	UFVJC 70	Ariquemes, RO
UFVJC 19	Cana Brava II-Montalvânia, MG	UFVJC 71	João Pinheiro, MG
UFVJC 20	Poções, MG	UFVJC 72	Camboja
UFVJC 22	Ipatinga, MG	UFVJC 73	Camboja
UFVJC 23	Don Lara-Caratinga, MG	UFVJC 74	Camboja
UFVJC 24	Santa Luzia-Caratinga, MG	UFVJC 75	Bomfim, MG
UFVJC 25	Imbé-Caratinga, MG	UFVJC 79	Jordânia, MG
UFVJC 28	Poté, MG	UFVJC 80	Desconhecido
UFVJC 29	Poté, MG	UFVJC 81	Jordânia, MG
UFVJC 30	Poté, MG	UFVJC 82	Jordânia, MG
UFVJC 31	Poté, MG	UFVJC 83	Araras, SP
UFVJC 32	Poté, MG	UFVJC 84	Petrolina, PE
UFVJC 33	Itaipé, MG	UFVJC 85	Jataí, GO
UFVJC 34	Itaipé, MG	UFVJC 86	Jequié, BA
UFVJC 35	Ervália, MG	UFVJC 87	Jequié, BA
UFVJC 36	Serra da Ipiapaba, MG	UFVJC 88	Jequié, BA
UFVJC 37	Janaúba, MG	UFVJC 89	Jitaúna, BA
UFVJC 38	Petrolina, PE	UFVJC 90	Ipiaú, BA
UFVJC 39	Natal, RN	UFVJC 91	Apuarema, BA
UFVJC 40	Formoso, TO	UFVJC 92	Itaitê, BA
UFVJC 41	Jales, SP	UFVJC 93	Itaitê, BA
UFVJC 42	Dourados, MS	UFVJC 94	Andaraí, BA
UFVJC 43	Matozinhos, MG	UFVJC 95	Andaraí, BA
UFVJC 44	São Carlos, SP	UFVJC 96	Mucugê, BA
UFVJC 45	Barra do Bugre, MT	UFVJC 97	Mucugê, BA
UFVJC 46	Barra do Bugre, MT	UFVJC 98	Iraquara, BA
UFVJC 47	Pirajaí, SP	UFVJC 99	Iraquara, BA
UFVJC 48	Getulina, SP	UFVJC 100	Souto Soares, BA
UFVJC 49	Bocaiúva, MG	UFVJC 101	Wagner, BA
UFVJC 50	Bocaiúva, MG	UFVJC 102	Desconhecido
UFVJC 51	Rio Pompa, MG

Name	Forward primer	Reverse primer
1JCENA 27	CATTTTTCATCAAGGCCTAC	GTATTTCTCCACACGCAACT
1JCENA 41	CTTTCTTACCCCTCATCCTT	AAAGCCAGGACATACTTGAA
1JCENA 47	GCCCGAGTTCTCTATAAGGT	CCAAGAGAAATTAGGAATGC
1JCENA 87	ATCTGGAGTGAAACCAAAGA	CACATGGTAAGCATTACAAGC
2JCDS 10	CATCAAATGCTAATGAAAGTACA	CACACCTAGCAAACTACTTGCA
2JCDS 24	GGATATGAAGTTTCATGGGACAAG	TTCATTGAATGGATGGTTGTAAGG
2JCDS 41	AACACACCATGGGCCACAGGT	TGCATGTGTGCGGGTTTGATTAC
2JCDS 58	TCCATGAAGTTTGCTGGCAAT	AGGTCATCTGGTAAAGCCATACC
2JCDS 66	CCTACGAGTGATTGGATAGTTTCTCA	TCTTCCATCAAGAGTCGTTGGGCA
2JCPS 6	CCAGAAGTAGAATTATAAATTAAA	AGCGGCTCTGACATTATGTAC
2JCPS 9	GTACTTAGATCTCTTGTAACTAACAG	TATCTCTTGTTCAGAAATGGAT
2JCPS 20	ACAGCAAGTGCACAACAATCTCA	TACTGCAGATGGATGGCATGA
2JCMS 30	GGGAAAGAGGCTCTTTGC	ATGAGTTCACATAAAATCATGCA
3CESR 0163	AACCACAGGAGTTGGTAATG	GAAAGAAGCAACAGAAATGG
3CESR 0231	GCTTTAGCAAACCAAGATTC	AATCATCGTTATCGTTGGAC
3CESR 0235	TGTCACAGTACATGCCACTT	ACCTTCGATTCATTTGTGTC
3CESR 0290	TCAATCAATTCCAACAACAA	CTAAATTCTCAACCAGGTGC
3CESR 0293	CAAAGAAGCCATTTCTGTTC	TATCATCACAAAGGTGCAAA
3CESR 0303	AAAGCCTAGTGCATTTGAAG	TCATGCTCTTTCTCCATCTT
3CESR 0312	AAGAAACAAACAATTGTGCC	TAGAAATCCTTGCTGGGTTA
3CESR 0333	ACATCTACAATGGCGATTTC	TAATGAATCTGTAGGACCCG
3CESR 0361	AGGCAGATATGCTGATTAAGTT	AGGCAGATATGCTGATTAAGTT
3CESR 0370	ATCAATGAACCTGTTGAAGG	TCCAGACTCCAAACTTAATCA
3CESR 0382	ATGACCTACAAGCAAGCACT	CCAATGACACCTCAGAATTT
3CESR 0386	ATTACTGTGAATGAAGCCCA	ACAGAGCACCCTAACGATAA
3CESR 0398	CAATCTTATTGCAGTGCTGA	CAAACAGCTAGAATCCCTTG
3CESR 0399	CAATGCATGGATCATAAGTG	CTCAAGTCAAATCTGGGAAC
3CESR 0494	GCCAAAGCTTCTCTTAACAA	TAATCACCATACCCACCTTC
3CESR 0498	GCTCGTTCATTCATCTCACT	TTAACTGTGAATGCCCTTCT
3CESR 0718	ATGATGTTAAGGACGAGGTG	ATCGGCTTCTTCTTCTTCTT
3CESR 0719	ATGATGTTAAGGACGAGGTG	GCAAGTTCTGGATTGTTCTC
3CESR 0733	CAAACAGATCAAGTACCCAGA	AAATTGATGGTGGTGATGAT
3CESR0756	CAGGTTCGTCTTCTTCAACT	ATATATGATCCCGACAACAA
3CESR 0804	CGTATTACCACCAACATCCT	CCATCAATCCACTTATCGTT
3CESR 0820	CTCGAGCACATGTTTAATGA	TGAGATCAATTCAACCACAA
3CESR 0844	GAAATAGAGACAGAAGGCGA	AAATGAACAGGGAATTGTTG
3CESR 0889	GCTCTTGATTGATTCCATTT	TGATGATGATGATGATGAGG
3CESR 0934	GTTATTATCCTCGCCACTTG	TTTGTATTTGTTCACACGGA
Name	Forward primer	Reverse primer
3CESR 1041	TTGCTGAAGCCCTTTCTAT	CAGTGTTGAGATCATAGCGA
3CESR 1042	TTGGATTCCCTATGAACAAC	TTTGTCTGTCGAATCCTCTC
3CESR 1044	TTGTCGAAGCTAAGGATTTC	CCATTCTTTCTTCCTTTGTG
3CESR 1050	TTTCCACACATCAGCGGC	ATAAACCTTCAAACGAGCAA
3CESR 1055	TTTGAGAGGTGGCAATAACT	GTCACAACCGGCAATTAG
3NS. 260	TCAGCTGTATGTTGAGTGAGCA	AGGGAAGGAACACCTCTCCTA
3NS. 308	GGAAATTGGTTATGTCCTTTCC	CGCATTGGACTTCCTACAAA
3NS. 689	AGGATGATGATGAGACAAGAAGA	CAGACTGGACTTGAACTTTCACT
3NS. 720	CCATTACTTACACATTGGACTTCCT	GGAAATTGGTTATGTCCTTTCC
3SSRY 4	ATAGAGCAGAAGTGCAGGCG	CTAACGCACACGACTACGGA
3SSRY 7	TGCCTAAGGAAAATTCATTCAT	TGCTAAGCTGGTCATGCACT
3SSRY 107	CCATTTTCTCTTGCTTCTGTCA	TGGTTTGAAGTCCTATAAAATCCTT
3SSRY 112	CGCAAGGTAAATCGGAGCTA	ACAATCAAAGGAGTCGTGTAATC
3SSRY 113	TTTGCTGACCTGCCACAATA	TCAACAATTGGACTAAGCAGC
3SSRY 127	CTTCGGCCTCTACAAAAGGA	GCTGAACTGCTTTGCCAACT
3SSRY 133	AGCATGTCATTGCACCAAAC	CGACTGCATCAGAACAATGC
3SSRY 146	TTCCCTCGCTAGAACTTGTC	CTATTTGACCGTCTTCGCCG
3SSRY 150	CAATGCAGGTGAAGTGAATACC	AGGGTGCTCTTCAGAGAAAGG
3SSRY 151	AGTGGAAATAAGCCATGTGATG	CCCATAATTGATGCCAGGTT
3SSRY 153	TTCCAGAAAGACTTCCGTTCA	CTCAACTACTGCACTGCACTC
3SSRY 159	CTTATCCTGTCCCCTCCACC	GACAATTGCATAGGAAGCACA
3SSRY 177	ACCACAAACATAGGCACGAG	CACCCAATTCACCAATTACCA

Source of variation	df	Sums of Square	Variation (%)	φ_ST
Between populations	13	3.86	7.42	0.0742
Within populations	82	15.7	92.58
Total	95	19.56	100.00

	Allelic frequencies and diversity statistics¹
	93 accessions									14 accessions
Loci	A₁	A₂	A₃	na	ne	Ho	He	ƒ	H´	Ho	He	PIC
JCENA 87	0.9946	0.0054	-	2	1.01	0.02	0.02	0.005	0.03	0.00	0.00	0.00
JCDS 10	0.5054	0.4946	-	2	1.99	0.92	0.50	-0.85	0.69	0.30	0.22	0.18
SSRY 107	0.4194	0.5806	-	2	1.94	0.84	0.49	-0.72	0.68	0.79	0.46	0.35
SSRY 127	0.3804	0.6196	-	2	1.89	0.76	0.47	-0.61	0.66	0.13	0.10	0.10
CESR 0756	0.4835	0.2363	0.2802	3	2.71	0.65	0.64	-0.02	1.05	0.41	0.27	0.22
Mean				2.2	1.91	0.64	0.42	-0.44	0.62	0.42	0.25	0.20
Total				11

Brasil

Brasil

Genetic variability revealed by microsatellite markers in a germplasm collection of Jatropha curcas L. in Brazil: an important plant for biofuels

Abstract

INTRODUCTION

MATERIAL AND METHODS

Plant material

DNA extraction

Microsatellite molecular markers

Variability between and within accessions

Statistical analyses

RESULTS

Genetic variability among the 93 accessions

Genetic variability within and between 14 accessions

DISCUSSION

CONCLUSION

ACKNOLEGMENTS

REFERENCES

Publication Dates

History