Karyotype and genome size comparative analyses among six species of the oilseed-bearing genus <i>Jatropha</i> (Euphorbiaceae)

Marinho, Anne C.T.A.; Vasconcelos, Santelmo; Vasconcelos, Emanuelle V.; Marques, Daniela A.; Benko-Iseppon, Ana Maria; Brasileiro-Vidal, Ana Christina

doi:10.1590/1678-4685-GMB-2017-0120

Abstract

Jatropha is an important genus of Euphorbiaceae, with species largely used for various purposes, including the manufacturing of soaps and pharmaceutical products and applications in the bioenergetic industry. Although there have been several studies focusing J. curcas in various aspects, the karyotype features of Jatropha species are poorly known. Therefore, we analyzed six Jatropha species through fluorochrome staining (CMA/DAPI), fluorescent in situ hybridization (FISH) with 5S and 45S rDNA probes and genome size estimation by flow cytometry. Our results revealed several chromosome markers by both CMA/DAPI and FISH for the analyzed species. Five Jatropha species (J. curcas, J. gossypiifolia, J. integerrima, J. multifida and J. podagrica) showed four CMA-positive (CMA⁺) bands associated with the 5S and 45S rDNA sites (one and two pairs, respectively). However, J. mollissima displayed six CMA⁺/DAPI^- bands co-localized with both 5S and 45S rDNA, which showed a FISH superposition. A gradual variation in the genome sizes was observed (2C = 0.64 to 0.86 pg), although an association between evidenced heterochromatin and genome sizes was not found among species. Except for the unique banding pattern of J. mollissima and the pericentromeric heterochromatin of J. curcas and J. podagrica, our data evidenced relatively conserved karyotypes.

Keywords:
Cytotaxonomy; DNA C-value; heterochromatin; physic nut; rDNA

Euphorbiaceae is one of the most complex and diverse angiosperm families, presenting a worldwide distribution, mainly in the Americas and in Africa. The group has approximately 8,000 species, including several genera with remarkable economic importance, such as Hevea (the rubber tree genus), Manihot (cassavas), Ricinus (castor) and Jatropha (Webster, 1987Webster GL (1987) The saga of the spurges: A review of classification and relationships in the Euphorbiales. Bot J Linn Soc 94:3-46.; Souza and Lorenzi, 2008Souza VC and Lorenzi H (2008) Botânica Sistemática: Guia ilustrado para identificação das famílias de fanerógamas nativas e exóticas no Brasil, baseado em APG II. 2nd edition. Instituto Plantarum, São Paulo, 704 p.). The genus Jatropha is composed of approximately 200 species (Webster, 1994Webster GL (1994) Synopsis of the genera and suprageneric taxa of Euphorbiaceae. Ann Mo Bot Gard 81:33-144.; The Plant List, 2013The Plant List (2013). Version 1.1, http://www.theplantlist.org/ (October 19, 2016).
http://www.theplantlist.org/... ), which present a vast biotechnological potential due to outstanding characteristics, such as drought tolerance, secondary metabolites with medicinal properties and high seed oil content and quality. The species J. gossypiifolia and J. podagrica, for instance, have an extensive use as ornamental plants, while J. ribifolia have been used as raw material for soaps and detergents. Both the oil and latex have been drawing attention by the pharmaceutical industry, due to their active principles that can be used in the production of antiseptics, antifungals, healing drugs, laxatives, among other products (e.g., Anani et al., 2016Anani K, Adjrah Y, Améyapoh Y, Karou SD, Agbonon A, de Souza C and Gbeassor M (2016) Antimicrobial, anti-inflammatory and antioxidant activities of Jatropha multifida L. (Euphorbiaceae). Pharmacognosy Res 8:142-146.; Shahinuzzaman et al., 2016Shahinuzzaman M, Yaakob Z and Moniruzzaman M (2016) Medicinal and cosmetics soap production from Jatropha oil. J Cosmet Dermatol 15:185-193.; Sharma et al., 2016Sharma AK, Gangwar M, Kumar D, Nath G, Kumar Sinha AS and Tripathi YB (2016) Phytochemical characterization, antimicrobial activity and reducing potential of seed oil, latex, machine oil and presscake of Jatropha curcas. Avicenna J Phytomed 6:366-375.). On the other hand, fruits and seeds, mainly from J. curcas, present high oil content, also serving as a strategic crop to be used as an alternative raw material for the production of biofuels (Openshaw, 2000Openshaw K (2000) A review of Jatropha curcas: an oil plant of unfulfilled promise. Biomass Bioenerg 19:1-15.; Montes and Melchinger, 2016Montes JM and Melchinger AE (2016) Domestication and breeding of Jatropha curcas L. Trends Plant Sci 21:1045-1057.).

The domestication process and the enhancement of traits of interest of J. curcas is still in the beginning (Yue et al., 2013Yue GH, Sun F and Liu P (2013) Status of molecular breeding for improving Jatropha curcas and biodiesel. Renew Sust Energ Rev 26:332-343.; Montes and Melchinger, 2016Montes JM and Melchinger AE (2016) Domestication and breeding of Jatropha curcas L. Trends Plant Sci 21:1045-1057.), although there has been a constant increase in the knowledge on the genetic variability of the species in the last decade (see, for instance, Guo et al., 2016Guo GY, Chen F, Shi XD, Tian YS, Yu MQ, Han XQ, Yuan LC and Zhang Y (2016) Genetic variation and phylogenetic relationship analysis of Jatropha curcas L. inferred from nrDNA ITS sequences. C R Biol 339:337-346.), being improved considerably since the publication of the genome by Sato et al. (2011)Sato S, Hirakawa H, Isobe S, Fukai E, Watanabe A, Kato M, Kawashima K, Minami C, Muraki A, Nakazaki N, et al. (2011) Sequence analysis of the genome of an oil-bearing tree, Jatropha curcas L. DNA Res 18:65-76.. Nevertheless, the vast majority of the species of Jatropha is poorly known, lacking even characterization studies aiming interspecific genetic similarities and karyotype information (Marques and Ferrari, 2008Marques DA and Ferrari RA (2008) O papel das novas biotecnologias no melhoramento genético do pinhão-manso. Biológico 70:65-67.; Ovando-Medina et al., 2011Ovando-Medina I, Espinosa-García FJ, Núñez-Farfán JS and Salvador-Figueroa M (2011) State of the art of genetic diversity research in Jatropha curcas. Sci Res Essays 6:1709-1719., Marques et al., 2013Marques DA, Siqueira WJ, Colombo CA and Ferrari RA (2013) Breeding and biotechnology of Jatropha curcas. In: Bahadur B, Sujatha M and Carels N (eds) Jatropha, challenges for a new energy crop (V2): Genetic improvement and biotechnology. Springer, New York, pp 457-478.).

In the general sense, Jatropha is supposed to present a high karyotypic stability, with the diploid number 2n = 22 being reported for almost all the 31 analyzed species so far (see Rice et al., 2015Rice A, Glick L, Abadi S, Einhorn M, Kopelman NM, Salman-Minkov A, Mayzel J, Chay O and Mayrose I (2015) The chromosome counts database (CCDB) - a community resource of plant chromosome numbers. New Phytol 206:19-26.), including J. curcas, J. gossypiifolia, J. integerrima, J. mollissima, J. multifida and J. podagrica, although J. cuneata Wiggins & Rollins and J. dioica Sessé were reported as tetraploids (2n = 44) (Miller and Webster, 1966Miller KI and Webster GL (1966) Chromosome numbers in the Euphorbiaceae. Brittonia 18:372-379.; Dehgan and Webster, 1979Dehgan B and Webster GL (1979) Morphology and infrageneric relationships of the genus Jatropha (Euphorbiaceae). U Calif Publ Bot 74:1-73.; Sasikala and Paramathma, 2010Sasikala R and Paramathma M (2010) Chromosome studies in the genus Jatropha L. Electron J Plant Breeding 4:637-642.). Also, both the chromosome morphologies and sizes have been reported as highly stable within the genus, with a predominance of small metacentric and submetacentric chromosomes (Deghan and Webster, 1979Dehgan B and Webster GL (1979) Morphology and infrageneric relationships of the genus Jatropha (Euphorbiaceae). U Calif Publ Bot 74:1-73.; Carvalho et al., 2008Carvalho CR, Clarindo WR, Praça MM, Araújo FS and Carels N (2008) Genome size, base composition and karyotype of Jatropha curcas L., an important biofuel plant. Plant Sci 174:613-617.).

Basically, J. curcas is the only species with more refined analyses published, other than just chromosome counts, although there is an available genome size estimation for J. podagrica (2C = 0.60 ± 0.05 pg; Vesely et al., 2012Vesely P, Bures P, Smarda P and Pavlicek T (2012) Genome size and DNA base composition of geophytes: The mirror of phenology and ecology? Ann Bot 109:65-75.). Carvalho et al. (2008)Carvalho CR, Clarindo WR, Praça MM, Araújo FS and Carels N (2008) Genome size, base composition and karyotype of Jatropha curcas L., an important biofuel plant. Plant Sci 174:613-617., for instance, presented a detailed karyotype analysis for J. curcas through standard staining and flow cytometry procedures, observing both small DNA content (2C = 0.85 ± 0.01 pg) and small chromosomes (ranging between 1.24-1.71 μm). Some authors have been assessing the physical distribution of large repetitive DNA clusters, such as rDNAs 5S and 45S, as well as different copia-type retrotransposons and subtelomeric repetitions in the J. curcas karyotype, observing several chromosome markers for the species (Witkowska et al., 2009Witkowska M, Ohmido N, Cartagena J, Shibagaki N, Kajiyama S and Fukui K (2009) Physical mapping of ribosomal DNA genes on Jatropha curcas chromosomes by multicolor FISH. Cytologia 74:133-139.; Kikuchi et al., 2010Kikuchi S, Tsujimoto H, Sassa H and Koba T (2010). JcSat1, a novel subtelomeric repeat of Jatropha curcas L. and its use in karyotyping. Chromosome Sci 13:11-16.; Alipour et al., 2013Alipour A, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2013) Structural characterization of copia-type retrotransposons leads to insights into the marker development in a biofuel crop, Jatropha curcas L. Biotechnol Biofuels 6:129.; Gong et al., 2013Gong Z, Xue C, Zhang M, Guo R, Zhou Y, and Shi G (2013). Physical localization and DNA methylation of 45S rRNA gene loci in Jatropha curcas L. PLoS One 8:e84284.).

The economic importance of Jatropha species is noteworthy, and there is an evident need for more information regarding the genetic differentiation within the genus. Therefore, this work aimed to describe cytogenetic markers by means of CMA/DAPI banding and FISH with 5S and 45S rDNA probes, besides providing genome size estimates, analyzing six species (Supplementary Table S1) largely used by several industry sectors, in order to contribute to a better understanding of the karyotype evolution of the genus.

Six Jatropha species were analyzed: J. curcas L., J. gossypiifolia L., J. integerrima Jacq., J. multifida L., J. mollissima (Pohl) Baill. and J. podagrica Hook (Figure 1). Root tips were collected either from germinated seeds or seedlings, pre-treated with 2 mM 8-hydroxyquinolein (8-HQ) for 4.5 h at 18 °C. The material was fixed in methanol:acetic acid (3:1, v/v) for at least 4 h and then stored at -20 °C. The preparation of slides followed the protocol described by Carvalho and Saraiva (1993)Carvalho CR and Saraiva LS (1993) An air drying technique for maize chromosomes without enzymatic maceration. Biotech Histochem 68:142-145., with modifications introduced by Vasconcelos et al. (2010)Vasconcelos S, Souza AA, Gusmão CLS, Milani M, Benko-Iseppon AM and Brasileiro-Vidal AC (2010) Heterochromatin and rDNA 5S and 45S sites as reliable cytogenetic markers for castor bean (Ricinus communis, Euphorbiaceae). Micron 41:746-753..

Figure 1
Representatives of the six analyzed Jatropha species: (A) Jatropha curcas; (B) J. gossypiifolia; (C) J. integerrima; (D) J. mollissima; (E) J. multifida; and (F) J. podagrica.

After preparation, the slides were stored for three days at room temperature (~25 °C) and then stained with 0.5 mg/mL CMA for 1 h and 2 μg/mL DAPI for 30 min, mounted in McIlvaine’s buffer (pH 7.0):glycerol (1:1, v/v) and stored for another three days (Schweizer and Ambros, 1994Schweizer D and Ambros PF (1994) Chromosome banding. In: Gosden JR (ed) Methods in Molecular Biology. Humana Press, Totowa, pp 97-112.). After image capture, slides were destained in ethanol:acetic acid (3:1, v/v) for 30 min at room temperature, followed by immersion in ethanol for 1 h and storage at -20 °C.

The following probes were used in the FISH procedures: (1) R2, a 6.5 kb fragment containing the 18S-5.8S-25S rDNA repeat unit from Arabidopsis thaliana (L.) Heynh. (Wanzenböck et al., 1997Wanzenböck EM, Schöfer C, Schweizer D and Bachmair A (1997) Ribosomal transcription units integrated via T-DNA transformation associate with the nucleolus and do not require upstream repeat sequences for activity in Arabidopsis thaliana. Plant J 11:1007-1016.), and (2) D2, a 400 bp containing two 5S rDNA repeat units from Lotus corniculatus L. [as L. japonicus (Regel) K.Larsen] (Pedrosa et al., 2002Pedrosa A, Sandal N, Stougaard J, Schweizer D and Bachmair A (2002) Chromosomal map of the model legume Lotus japonicus. Genetics 161:1661-1672.), which were labeled by nick translation with digoxigenin-11-dUTP (Roche Diagnostics) and biotin-11-dUTP (Sigma), respectively. The FISH pre-treatment and post-hybridization washes followed Pedrosa et al. (2002)Pedrosa A, Sandal N, Stougaard J, Schweizer D and Bachmair A (2002) Chromosomal map of the model legume Lotus japonicus. Genetics 161:1661-1672., in which the stringency wash (77%) was performed with 0.1X SSC at 42 °C. Chromosome and probe denaturation and detection were performed according to Heslop-Harrison et al. (1991)Heslop-Harrison JS, Schwazarcher T, Anamthawat-Jónsson K, Leitch AR and Shi M (1991) In situ hybridization with automated chromosome denaturation. Technique 3:109-115.. Ten microliters of the hybridization mixture, which contained 50% formamide (v/v), 2X SSC, 10% dextran sulfate (w/v) and 2.5-5 ng/μL of the probe, were added to each slide, being hybridized at 37 °C for at least 18 h. Detection of the digoxigenin-labelled probes was carried out using sheep anti-digoxigenin-FITC (Roche Diagnostics), and the signal was amplified with donkey anti-sheep-FITC (Sigma), in 1% (w/v) BSA. Biotin-labelled probes were detected with mouse anti-biotin (Dako), and the signal was visualized with rabbit anti-mouse TRITC conjugate (Dako), in 1% (w/v) BSA. Preparations were counterstained and mounted with 2 μg/mL DAPI in Vectashield (Vector) (1:1; v/v).

Images of the cells were captured on a Leica DMLB microscope with a Leica DFC 340FX camera, using the software Leica CW4000, with optimization for contrast and brightness using Adobe Photoshop CC (Adobe Systems Incorporated) software.

The DNA 2C-values were measured by using approximately 20-30 mg of fresh leaves of the six species, each with an internal reference standard (Solanum lycopersicum cv. Stupicke polni tyckove, 2C = 1.96 pg), being chopped in 1 mL of WPB buffer (Loureiro et al., 2007Loureiro J, Rodriguez E, Dolezel J and Santos C (2007) Two new nuclear isolation buffers for plant DNA flow cytometry: a test with 37 species. Ann Bot 100:875-888.), following the procedures described by Dolezel et al. (1989)Dolezel J, Binarova P and Lucretti S (1989) Analysis of nuclear DNA content in plant cells by flow cytometry. Biol Plantarum 31:113-120.. The nuclei suspension was filtered through a 30 μm nylon mesh and then stained with 30 μL of 1% propidium iodide (w/v). Three individuals per species were analyzed and three replicates per individual, with at least 10,000 nuclei per sample, using the Partec CyFlow Space flow cytometer. Each histogram obtained from the relative fluorescence of the nuclei of the samples and the internal reference was analyzed in the software Partec FloMax 2.4. Afterward, the mean DNA 2C-values were calculated after discarding both the smallest and the largest readings obtained for each species.

All analyzed karyotypes presented the diploid number 2n = 22, with chromosomes predominantly metacentric and submetacentric (Table 1; Figures 2 and 3), as well as semi-reticulated interphase nucleus, confirming previous counts for all six species (Perry, 1943Perry BA (1943) Chromosome number and phylogenetic relationships in the Euphorbiaceae. Am J Bot 30:527-543.; Miller and Webster, 1962Miller KI and Webster GL (1962) Systematic position of Cnidoscolus and Jatropha. Brittonia 14:174-180.; Miller and Webster, 1966)Miller KI and Webster GL (1966) Chromosome numbers in the Euphorbiaceae. Brittonia 18:372-379.. Additionally, at least two satellited chromosomes were visualized for all six species.

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Table 1
Karyotype characterization of the six analyzed Jatropha species, showing diploid chromosome numbers (2n); distribution pattern of CMA+/DAPI bands and 5S and 45S rDNA sites; genome size estimation (pg) and mean CV (%) per species.

Figure 2
Mitotic metaphases of six Jatropha species stained with chromomycin A₃ (CMA) and 4’,6-diamidino-2-phenylindole (DAPI), evidencing CMA+/DAPI^- bands in yellow: (A) Jatropha curcas; (B) J. gossypiifolia; (C) J. integerrima; (D) J. mollissima; (E) J. multifida; and (F) J. podagrica.

Figure 3
Localization of 5S (red) and 45S (green) rDNA sites in mitotic metaphases of six Jatropha species: (A) Jatropha curcas; (B) J. gossypiifolia; (C) J. integerrima; (D) J. mollissima; (E) J. multifida; and (F) J. podagrica. Arrows and arrowheads indicate the 5S and 45S rDNA sites, respectively. Numbers in D evidence the 5S rDNA sites in J. mollissima.

The CMA/DAPI staining revealed four chromosomes with terminal CMA⁺/DAPI^- bands for J. curcas, J. gossypiifolia, J. integerrima, J. multifida and J. podagrica (Figures 2A-C,E,F and 4A-C,E,F). However, J. mollissima diverged from the other five species by showing six terminal CMA⁺/DAPI^- bands (Figures 2D and 4D). In addition, J. curcas and J. podagrica presented pericentromeric CMA⁺/DAPI^- bands in all chromosomes, although they were not always clear, depending on the condensation level of the chromosomes (Table 1; Figures 2A,B,F and 4A,B-F). Also, depending on the chromatin condensation level, terminal CMA⁺/DAPI^- dots were visible in almost all chromosome arms of J. curcas (Figures 2A and 4A). The high amount of CMA⁺ heterochromatin (GC-rich) is in accordance to Guo et al. (2016)Guo GY, Chen F, Shi XD, Tian YS, Yu MQ, Han XQ, Yuan LC and Zhang Y (2016) Genetic variation and phylogenetic relationship analysis of Jatropha curcas L. inferred from nrDNA ITS sequences. C R Biol 339:337-346., who reported an average G+C content of 65.04% for J. curcas. The pericentromeric heterochromatin in J. curcas is at least partially related to gypsy-type retrotransposons (Alipour et al., 2014Alipour A, Cartagena JA, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2014) Identification and characterization of novel gypsy-type retrotransposons in a biodiesel crop, Jatropha curcas L. Plant Mol Biol Rep 32:923-930.), while terminal heterochromatic dots are related to copia-type retrotransposons (Alipour et al., 2013Alipour A, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2013) Structural characterization of copia-type retrotransposons leads to insights into the marker development in a biofuel crop, Jatropha curcas L. Biotechnol Biofuels 6:129.). These patterns of heterochromatin rich karyotypes have also been described for other Euphorbiaceae species, such as castor (Ricinus communis L.), Euphorbia characias L., E. hirta L., E. hyssopifolia L., Manihot dichotoma Ule and M. esculenta Crantz (Carvalho and Guerra, 2002Carvalho R and Guerra M (2002) Cytogenetics of Manihot esculenta Crantz (cassava) and eight related species. Hereditas 136:159-168.; D’Emerico et al., 2003D’Emerico S, Pignone D, Vita F and Scrugli A (2003) Karyomorphological analyses and chromatin characterization by banding techniques in Euphorbia characias L. and E. wulfenii Hoppe (= E. veneta Willd.) (Euphorbiaceae). Caryologia 56:501-508.; Vasconcelos et al., 2010Vasconcelos S, Souza AA, Gusmão CLS, Milani M, Benko-Iseppon AM and Brasileiro-Vidal AC (2010) Heterochromatin and rDNA 5S and 45S sites as reliable cytogenetic markers for castor bean (Ricinus communis, Euphorbiaceae). Micron 41:746-753.; Santana et al., 2016Santana KCB, Pinangé DSB, Vasconcelos S, Oliveira AR, Brasileiro-Vidal AC, Alves MV and Benko-Iseppon AB (2016) Unraveling the karyotype structure of the spurges Euphorbia hirta L. and E. hyssopifolia L. (Euphorbiaceae) using genome size estimation and heterochromatin differentiation. Comp Cytogenet 10:657-696.).

Figure 4
Representative idiograms of cytogenetic markers in all chromosome pairs of six Jatropha species. (A) Jatropha curcas; (B) J. gossypiifolia; (C) J. integerrima; (D) J. mollissima; (E) J. multifida; and (F) J. podagrica. It is important to note that only chromosome markers are evidenced in the idiograms, and actual chromosome sizes and arm ratios were not represented. Also, due to the high variation in the presence of the terminal CMA⁺ bands in the J. curcas karyotype, depending on the condensation level of the chromosomes, only signals always visualized were represented.

Five out of the six analyzed species (J. curcas, J. gossypiifolia, J. integerrima, J. multifida, and J. podagrica) presented one 5S and two 45S rDNA site pairs, both co-localized with CMA⁺/DAPI^- bands, with an apparent adjacency between the 5S rDNA and one of the 45S rDNA pairs (Figures 3A-C,E,F and 4A-C,E,F). On the other hand, J. mollissima presented six chromosomes with a co-localization between 5S and 45S rDNA sites, which also corresponded to CMA⁺/DAPI^- bands (Figures 3D and 4D). Furthermore, one of these three chromosome pairs of J. mollissima presented a heteromorphism: one of the chromosomes of the pair 1 presented a smaller 5S rDNA, not covering the satellited region (Figure 3D). Data for number and distribution of 5S and 45S rDNA sites in J. curcas corroborated previous data for the species (Witkowska et al., 2009Witkowska M, Ohmido N, Cartagena J, Shibagaki N, Kajiyama S and Fukui K (2009) Physical mapping of ribosomal DNA genes on Jatropha curcas chromosomes by multicolor FISH. Cytologia 74:133-139.). For the remaining species, rDNA data are being reported for the first time in the present work.

Both the number and the distribution patterns of 5S and 45S rDNA sites seem to be quite conserved in Jatropha, although the superposition of 5S and 45S rDNA sites and the presence of 5S rDNA in more than one chromosome pair in J. mollissima are reported for the first time in a species of Euphorbiaceae (see, for instance, Carvalho and Guerra, 2002Carvalho R and Guerra M (2002) Cytogenetics of Manihot esculenta Crantz (cassava) and eight related species. Hereditas 136:159-168.; Vasconcelos et al., 2010Vasconcelos S, Souza AA, Gusmão CLS, Milani M, Benko-Iseppon AM and Brasileiro-Vidal AC (2010) Heterochromatin and rDNA 5S and 45S sites as reliable cytogenetic markers for castor bean (Ricinus communis, Euphorbiaceae). Micron 41:746-753.; Santana et al., 2016Santana KCB, Pinangé DSB, Vasconcelos S, Oliveira AR, Brasileiro-Vidal AC, Alves MV and Benko-Iseppon AB (2016) Unraveling the karyotype structure of the spurges Euphorbia hirta L. and E. hyssopifolia L. (Euphorbiaceae) using genome size estimation and heterochromatin differentiation. Comp Cytogenet 10:657-696.). Furthermore, the presence of both 5S and 45S rDNA sites in the same chromosome arm is not common in the family, and it has been observed only in E. hyssopifolia so far (Santana et al., 2016Santana KCB, Pinangé DSB, Vasconcelos S, Oliveira AR, Brasileiro-Vidal AC, Alves MV and Benko-Iseppon AB (2016) Unraveling the karyotype structure of the spurges Euphorbia hirta L. and E. hyssopifolia L. (Euphorbiaceae) using genome size estimation and heterochromatin differentiation. Comp Cytogenet 10:657-696.). Nevertheless, besides the peculiar distribution pattern of the rRNA genes in J. mollissima, the heteromorphism observed in one chromosome pair of the species may indicate a derived karyotype within the genus. This condition may be related to active transposable elements associated with rDNA amplification, considering the abundance of such repetitive DNA in heterochromatic regions (Eickbush and Eickbush, 2007Eickbush TH and Eickbush DG (2007) Finely orchestrated movements: evolution of the ribosomal RNA genes. Genetics 175:477-485.; Schubert, 2007Schubert I (2007) Chromosome evolution. Curr Opin Plant Biol 10:109-115.; Roa and Guerra, 2015Roa F and Guerra M (2015) Non-random distribution of 5S rDNA sites and its association with 45S rDNA in plant chromosomes. Cytogenet Genome Res 146:243-249.). For instance, the terminal regions of J. curcas chromosomes are rich in copia-type elements, including the 5S rDNA bearer (Alipour et al., 2013Alipour A, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2013) Structural characterization of copia-type retrotransposons leads to insights into the marker development in a biofuel crop, Jatropha curcas L. Biotechnol Biofuels 6:129.). On the other hand, one cannot discard the possibility of additional cryptic rDNA sites that could not be evidenced by FISH in the other five analyzed karyotypes (see Cabrero and Camacho, 2008Cabrero J and Camacho JPM (2008) Location and expression of ribosomal RNA genes in grasshoppers: abundance of silent and cryptic loci. Chromosome Res 16:595-607.; Vasconcelos et al., 2010Vasconcelos S, Souza AA, Gusmão CLS, Milani M, Benko-Iseppon AM and Brasileiro-Vidal AC (2010) Heterochromatin and rDNA 5S and 45S sites as reliable cytogenetic markers for castor bean (Ricinus communis, Euphorbiaceae). Micron 41:746-753.; Roa and Guerra, 2015Roa F and Guerra M (2015) Non-random distribution of 5S rDNA sites and its association with 45S rDNA in plant chromosomes. Cytogenet Genome Res 146:243-249.). The co-localization of 5S and 45S rDNA FISH sites is very uncommon in angiosperms, being reported only for a few Asteraceae species, as a consequence of an interspersed position of both unit genes (Garcia et al., 2010Garcia S, Panero JL, Siroky J and Kovarik A (2010) Repeated reunions and splits feature the highly dynamic evolution of 5S and 35S ribosomal RNA genes (rDNA) in the Asteraceae family. BMC Plant Biol 10:176.). Such a feature hardly guarantees any evolutionary advantage due to the differences in gene functionalities between the two types of rDNAs. These are probably associated with proliferation mechanisms of transposable elements (Ciganda and Williams, 2011Ciganda M and Williams N (2011) Eukaryotic 5S rRNA biogenesis. Wiley Interdiscip Rev RNA 2:523-533.; Roa and Guerra, 2015Roa F and Guerra M (2015) Non-random distribution of 5S rDNA sites and its association with 45S rDNA in plant chromosomes. Cytogenet Genome Res 146:243-249.), and more frequently observed in gymnosperms (Garcia and Kovarik, 2013Garcia S and Kovarik A (2013) Dancing together and separate again: gymnosperms exhibit frequent changes of fundamental 5S and 35S rRNA gene (rDNA) organisation. Heredity 111:23-33.) and in early diverging land plants (Wicke et al., 2011Wicke S, Costa A, Muñoz J and Quandt D (2011) Restless 5S: The re-arrangement(s) and evolution of the nuclear ribosomal DNA in land plants. Mol Phylogenet Evol 61:321-332.).

The flow cytometry analysis revealed a variation of DNA content among the analyzed species ranging between 2C = 0.64 pg for J. gossypiifolia and J. multifida and 2C = 0.86 pg for J. curcas (Table 1). For J. gossypiifolia (2C = 0.64 ± 0.02 pg), J. integerrima (0.85 ± 0.03), J. mollissima (0.79 ± 0.03) and J. multifida (2C = 0.64 ± 0.01 pg) the genome sizes were estimated for the first time (Table 1). For J. curcas, the 2C-value obtained here (2C = 0.86 ± 0.02 pg) was similar to the previously reported by Carvalho et al. (2008)Carvalho CR, Clarindo WR, Praça MM, Araújo FS and Carels N (2008) Genome size, base composition and karyotype of Jatropha curcas L., an important biofuel plant. Plant Sci 174:613-617. (2C = 0.85 ± 0.01 pg). On the other hand, our results for J. podagrica (2C = 0.74 ± 0.05 pg) were different from the obtained by Vesely et al. (2012)Vesely P, Bures P, Smarda P and Pavlicek T (2012) Genome size and DNA base composition of geophytes: The mirror of phenology and ecology? Ann Bot 109:65-75. (2C = 0.60 ± 0.05 pg). This discrepancy may be occurred either due to differences between the internal reference standards used in the two analyses (Tiryaki and Tuna, 2012Tiryaki I and Tuna M (2012) Determination of intraspecific nuclear DNA content variation in common vetch (Vicia sativa L.) lines and cultivars based on two distinct internal reference standards. Turk J Agric For 36:645-653.) or due to an intraspecific polymorphism in J. podagrica related to variations in the repetitive DNA content. Although the six species present the same chromosome number, the observed variation in the genome sizes (1.34x) reinforces the importance of DNA content estimations in order to understand the karyotype evolution of homoploid species (Loureiro et al., 2010Loureiro J, Travnicek P, Rauchova J, Urfus T, Vit P, Stech M, Castro S and Suda J (2010) The use of flow cytometry in the biosystematics, ecology and population biology of homoploid plants. Preslia 82:3-21.), helping the planning of interspecific crosses for breeding purposes.

The cytogenetic features reported here revealed different patterns of heterochromatin distribution for the first time for five Jatropha species and confirmed the previous data for J. curcas, besides allowing the identification of chromosome markers for the genus: (1) J. curcas and J. podagrica with an accumulation of pericentromeric heterochromatin; (2) five species, including J. curcas, with a conserved number and distribution of 5S and 45S rDNA; (3) 5S rDNA sites detected as CMA⁺; (4) J. mollissima as the first reported species with more than one pair of 5S rDNA sites in Euphorbiaceae and with a distinct distribution (with FISH superposition) of 5S and 45S rDNA; (5) no apparent correlation between genome size and revealed heterochromatin.

Acknowledgments

The authors would like to thank the Brazilian National Council for Scientific and Technological Development (Conselho Nacional de Desenvolvimento Científico e Tecnológico – CNPq) for financial support.

References

Alipour A, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2013) Structural characterization of copia-type retrotransposons leads to insights into the marker development in a biofuel crop, Jatropha curcas L. Biotechnol Biofuels 6:129.
Alipour A, Cartagena JA, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2014) Identification and characterization of novel gypsy-type retrotransposons in a biodiesel crop, Jatropha curcas L. Plant Mol Biol Rep 32:923-930.
Anani K, Adjrah Y, Améyapoh Y, Karou SD, Agbonon A, de Souza C and Gbeassor M (2016) Antimicrobial, anti-inflammatory and antioxidant activities of Jatropha multifida L. (Euphorbiaceae). Pharmacognosy Res 8:142-146.
Cabrero J and Camacho JPM (2008) Location and expression of ribosomal RNA genes in grasshoppers: abundance of silent and cryptic loci. Chromosome Res 16:595-607.
Carvalho CR and Saraiva LS (1993) An air drying technique for maize chromosomes without enzymatic maceration. Biotech Histochem 68:142-145.
Carvalho CR, Clarindo WR, Praça MM, Araújo FS and Carels N (2008) Genome size, base composition and karyotype of Jatropha curcas L., an important biofuel plant. Plant Sci 174:613-617.
Carvalho R and Guerra M (2002) Cytogenetics of Manihot esculenta Crantz (cassava) and eight related species. Hereditas 136:159-168.
Ciganda M and Williams N (2011) Eukaryotic 5S rRNA biogenesis. Wiley Interdiscip Rev RNA 2:523-533.
Dehgan B and Webster GL (1979) Morphology and infrageneric relationships of the genus Jatropha (Euphorbiaceae). U Calif Publ Bot 74:1-73.
D’Emerico S, Pignone D, Vita F and Scrugli A (2003) Karyomorphological analyses and chromatin characterization by banding techniques in Euphorbia characias L. and E. wulfenii Hoppe (= E. veneta Willd.) (Euphorbiaceae). Caryologia 56:501-508.
Dolezel J, Binarova P and Lucretti S (1989) Analysis of nuclear DNA content in plant cells by flow cytometry. Biol Plantarum 31:113-120.
Eickbush TH and Eickbush DG (2007) Finely orchestrated movements: evolution of the ribosomal RNA genes. Genetics 175:477-485.
Garcia S, Panero JL, Siroky J and Kovarik A (2010) Repeated reunions and splits feature the highly dynamic evolution of 5S and 35S ribosomal RNA genes (rDNA) in the Asteraceae family. BMC Plant Biol 10:176.
Garcia S and Kovarik A (2013) Dancing together and separate again: gymnosperms exhibit frequent changes of fundamental 5S and 35S rRNA gene (rDNA) organisation. Heredity 111:23-33.
Gong Z, Xue C, Zhang M, Guo R, Zhou Y, and Shi G (2013). Physical localization and DNA methylation of 45S rRNA gene loci in Jatropha curcas L. PLoS One 8:e84284.
Guo GY, Chen F, Shi XD, Tian YS, Yu MQ, Han XQ, Yuan LC and Zhang Y (2016) Genetic variation and phylogenetic relationship analysis of Jatropha curcas L. inferred from nrDNA ITS sequences. C R Biol 339:337-346.
Heslop-Harrison JS, Schwazarcher T, Anamthawat-Jónsson K, Leitch AR and Shi M (1991) In situ hybridization with automated chromosome denaturation. Technique 3:109-115.
Kikuchi S, Tsujimoto H, Sassa H and Koba T (2010). JcSat1, a novel subtelomeric repeat of Jatropha curcas L. and its use in karyotyping. Chromosome Sci 13:11-16.
Loureiro J, Rodriguez E, Dolezel J and Santos C (2007) Two new nuclear isolation buffers for plant DNA flow cytometry: a test with 37 species. Ann Bot 100:875-888.
Loureiro J, Travnicek P, Rauchova J, Urfus T, Vit P, Stech M, Castro S and Suda J (2010) The use of flow cytometry in the biosystematics, ecology and population biology of homoploid plants. Preslia 82:3-21.
Marques DA and Ferrari RA (2008) O papel das novas biotecnologias no melhoramento genético do pinhão-manso. Biológico 70:65-67.
Marques DA, Siqueira WJ, Colombo CA and Ferrari RA (2013) Breeding and biotechnology of Jatropha curcas In: Bahadur B, Sujatha M and Carels N (eds) Jatropha, challenges for a new energy crop (V2): Genetic improvement and biotechnology. Springer, New York, pp 457-478.
Miller KI and Webster GL (1962) Systematic position of Cnidoscolus and Jatropha Brittonia 14:174-180.
Miller KI and Webster GL (1966) Chromosome numbers in the Euphorbiaceae. Brittonia 18:372-379.
Montes JM and Melchinger AE (2016) Domestication and breeding of Jatropha curcas L. Trends Plant Sci 21:1045-1057.
Openshaw K (2000) A review of Jatropha curcas: an oil plant of unfulfilled promise. Biomass Bioenerg 19:1-15.
Ovando-Medina I, Espinosa-García FJ, Núñez-Farfán JS and Salvador-Figueroa M (2011) State of the art of genetic diversity research in Jatropha curcas Sci Res Essays 6:1709-1719.
Pedrosa A, Sandal N, Stougaard J, Schweizer D and Bachmair A (2002) Chromosomal map of the model legume Lotus japonicus Genetics 161:1661-1672.
Perry BA (1943) Chromosome number and phylogenetic relationships in the Euphorbiaceae. Am J Bot 30:527-543.
Rice A, Glick L, Abadi S, Einhorn M, Kopelman NM, Salman-Minkov A, Mayzel J, Chay O and Mayrose I (2015) The chromosome counts database (CCDB) - a community resource of plant chromosome numbers. New Phytol 206:19-26.
Roa F and Guerra M (2015) Non-random distribution of 5S rDNA sites and its association with 45S rDNA in plant chromosomes. Cytogenet Genome Res 146:243-249.
Santana KCB, Pinangé DSB, Vasconcelos S, Oliveira AR, Brasileiro-Vidal AC, Alves MV and Benko-Iseppon AB (2016) Unraveling the karyotype structure of the spurges Euphorbia hirta L. and E. hyssopifolia L. (Euphorbiaceae) using genome size estimation and heterochromatin differentiation. Comp Cytogenet 10:657-696.
Sasikala R and Paramathma M (2010) Chromosome studies in the genus Jatropha L. Electron J Plant Breeding 4:637-642.
Sato S, Hirakawa H, Isobe S, Fukai E, Watanabe A, Kato M, Kawashima K, Minami C, Muraki A, Nakazaki N, et al. (2011) Sequence analysis of the genome of an oil-bearing tree, Jatropha curcas L. DNA Res 18:65-76.
Schubert I (2007) Chromosome evolution. Curr Opin Plant Biol 10:109-115.
Schweizer D and Ambros PF (1994) Chromosome banding. In: Gosden JR (ed) Methods in Molecular Biology. Humana Press, Totowa, pp 97-112.
Shahinuzzaman M, Yaakob Z and Moniruzzaman M (2016) Medicinal and cosmetics soap production from Jatropha oil. J Cosmet Dermatol 15:185-193.
Sharma AK, Gangwar M, Kumar D, Nath G, Kumar Sinha AS and Tripathi YB (2016) Phytochemical characterization, antimicrobial activity and reducing potential of seed oil, latex, machine oil and presscake of Jatropha curcas Avicenna J Phytomed 6:366-375.
Souza VC and Lorenzi H (2008) Botânica Sistemática: Guia ilustrado para identificação das famílias de fanerógamas nativas e exóticas no Brasil, baseado em APG II. 2nd edition. Instituto Plantarum, São Paulo, 704 p.
Tiryaki I and Tuna M (2012) Determination of intraspecific nuclear DNA content variation in common vetch (Vicia sativa L.) lines and cultivars based on two distinct internal reference standards. Turk J Agric For 36:645-653.
Vasconcelos S, Souza AA, Gusmão CLS, Milani M, Benko-Iseppon AM and Brasileiro-Vidal AC (2010) Heterochromatin and rDNA 5S and 45S sites as reliable cytogenetic markers for castor bean (Ricinus communis, Euphorbiaceae). Micron 41:746-753.
Vesely P, Bures P, Smarda P and Pavlicek T (2012) Genome size and DNA base composition of geophytes: The mirror of phenology and ecology? Ann Bot 109:65-75.
Wanzenböck EM, Schöfer C, Schweizer D and Bachmair A (1997) Ribosomal transcription units integrated via T-DNA transformation associate with the nucleolus and do not require upstream repeat sequences for activity in Arabidopsis thaliana Plant J 11:1007-1016.
Webster GL (1987) The saga of the spurges: A review of classification and relationships in the Euphorbiales. Bot J Linn Soc 94:3-46.
Webster GL (1994) Synopsis of the genera and suprageneric taxa of Euphorbiaceae. Ann Mo Bot Gard 81:33-144.
Wicke S, Costa A, Muñoz J and Quandt D (2011) Restless 5S: The re-arrangement(s) and evolution of the nuclear ribosomal DNA in land plants. Mol Phylogenet Evol 61:321-332.
Witkowska M, Ohmido N, Cartagena J, Shibagaki N, Kajiyama S and Fukui K (2009) Physical mapping of ribosomal DNA genes on Jatropha curcas chromosomes by multicolor FISH. Cytologia 74:133-139.
Yue GH, Sun F and Liu P (2013) Status of molecular breeding for improving Jatropha curcas and biodiesel. Renew Sust Energ Rev 26:332-343.

Internet Resources

The Plant List (2013). Version 1.1, http://www.theplantlist.org/ (October 19, 2016).
» http://www.theplantlist.org/

Supplementary material

The following online material is available for this article:

Table S1 - Traits of agronomic interest of the six analyzed species of Jatropha.

Associate Editor: Everaldo Gonçalves de Barros

Publication Dates

Publication in this collection
14 May 2018
Date of issue
Apr./June 2018

History

Received
04 May 2017
Accepted
19 Sept 2017

License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License (type CC-BY), which permits unrestricted use, distribution and reproduction in any medium, provided the original article is properly cited.

[1] Alipour A, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2013) Structural characterization of copia-type retrotransposons leads to insights into the marker development in a biofuel crop, Jatropha curcas L. Biotechnol Biofuels 6:129.

[2] Alipour A, Cartagena JA, Tsuchimoto S, Sakai H, Ohmido N and Fukui K (2014) Identification and characterization of novel gypsy-type retrotransposons in a biodiesel crop, Jatropha curcas L. Plant Mol Biol Rep 32:923-930.

[3] Anani K, Adjrah Y, Améyapoh Y, Karou SD, Agbonon A, de Souza C and Gbeassor M (2016) Antimicrobial, anti-inflammatory and antioxidant activities of Jatropha multifida L. (Euphorbiaceae). Pharmacognosy Res 8:142-146.

[4] Cabrero J and Camacho JPM (2008) Location and expression of ribosomal RNA genes in grasshoppers: abundance of silent and cryptic loci. Chromosome Res 16:595-607.

[5] Carvalho CR and Saraiva LS (1993) An air drying technique for maize chromosomes without enzymatic maceration. Biotech Histochem 68:142-145.

[6] Carvalho CR, Clarindo WR, Praça MM, Araújo FS and Carels N (2008) Genome size, base composition and karyotype of Jatropha curcas L., an important biofuel plant. Plant Sci 174:613-617.

[7] Carvalho R and Guerra M (2002) Cytogenetics of Manihot esculenta Crantz (cassava) and eight related species. Hereditas 136:159-168.

[8] Ciganda M and Williams N (2011) Eukaryotic 5S rRNA biogenesis. Wiley Interdiscip Rev RNA 2:523-533.

[9] Dehgan B and Webster GL (1979) Morphology and infrageneric relationships of the genus Jatropha (Euphorbiaceae). U Calif Publ Bot 74:1-73.

[10] D’Emerico S, Pignone D, Vita F and Scrugli A (2003) Karyomorphological analyses and chromatin characterization by banding techniques in Euphorbia characias L. and E. wulfenii Hoppe (= E. veneta Willd.) (Euphorbiaceae). Caryologia 56:501-508.

[11] Dolezel J, Binarova P and Lucretti S (1989) Analysis of nuclear DNA content in plant cells by flow cytometry. Biol Plantarum 31:113-120.

[12] Eickbush TH and Eickbush DG (2007) Finely orchestrated movements: evolution of the ribosomal RNA genes. Genetics 175:477-485.

[13] Garcia S, Panero JL, Siroky J and Kovarik A (2010) Repeated reunions and splits feature the highly dynamic evolution of 5S and 35S ribosomal RNA genes (rDNA) in the Asteraceae family. BMC Plant Biol 10:176.

[14] Garcia S and Kovarik A (2013) Dancing together and separate again: gymnosperms exhibit frequent changes of fundamental 5S and 35S rRNA gene (rDNA) organisation. Heredity 111:23-33.

[15] Gong Z, Xue C, Zhang M, Guo R, Zhou Y, and Shi G (2013). Physical localization and DNA methylation of 45S rRNA gene loci in Jatropha curcas L. PLoS One 8:e84284.

[16] Guo GY, Chen F, Shi XD, Tian YS, Yu MQ, Han XQ, Yuan LC and Zhang Y (2016) Genetic variation and phylogenetic relationship analysis of Jatropha curcas L. inferred from nrDNA ITS sequences. C R Biol 339:337-346.

[17] Heslop-Harrison JS, Schwazarcher T, Anamthawat-Jónsson K, Leitch AR and Shi M (1991) In situ hybridization with automated chromosome denaturation. Technique 3:109-115.

[18] Kikuchi S, Tsujimoto H, Sassa H and Koba T (2010). JcSat1, a novel subtelomeric repeat of Jatropha curcas L. and its use in karyotyping. Chromosome Sci 13:11-16.

[19] Loureiro J, Rodriguez E, Dolezel J and Santos C (2007) Two new nuclear isolation buffers for plant DNA flow cytometry: a test with 37 species. Ann Bot 100:875-888.

[20] Loureiro J, Travnicek P, Rauchova J, Urfus T, Vit P, Stech M, Castro S and Suda J (2010) The use of flow cytometry in the biosystematics, ecology and population biology of homoploid plants. Preslia 82:3-21.

[21] Marques DA and Ferrari RA (2008) O papel das novas biotecnologias no melhoramento genético do pinhão-manso. Biológico 70:65-67.

[22] Marques DA, Siqueira WJ, Colombo CA and Ferrari RA (2013) Breeding and biotechnology of Jatropha curcas In: Bahadur B, Sujatha M and Carels N (eds) Jatropha, challenges for a new energy crop (V2): Genetic improvement and biotechnology. Springer, New York, pp 457-478.

[23] Miller KI and Webster GL (1962) Systematic position of Cnidoscolus and Jatropha Brittonia 14:174-180.

[24] Miller KI and Webster GL (1966) Chromosome numbers in the Euphorbiaceae. Brittonia 18:372-379.

[25] Montes JM and Melchinger AE (2016) Domestication and breeding of Jatropha curcas L. Trends Plant Sci 21:1045-1057.

[26] Openshaw K (2000) A review of Jatropha curcas: an oil plant of unfulfilled promise. Biomass Bioenerg 19:1-15.

[27] Ovando-Medina I, Espinosa-García FJ, Núñez-Farfán JS and Salvador-Figueroa M (2011) State of the art of genetic diversity research in Jatropha curcas Sci Res Essays 6:1709-1719.

[28] Pedrosa A, Sandal N, Stougaard J, Schweizer D and Bachmair A (2002) Chromosomal map of the model legume Lotus japonicus Genetics 161:1661-1672.

[29] Perry BA (1943) Chromosome number and phylogenetic relationships in the Euphorbiaceae. Am J Bot 30:527-543.

[30] Rice A, Glick L, Abadi S, Einhorn M, Kopelman NM, Salman-Minkov A, Mayzel J, Chay O and Mayrose I (2015) The chromosome counts database (CCDB) - a community resource of plant chromosome numbers. New Phytol 206:19-26.

[31] Roa F and Guerra M (2015) Non-random distribution of 5S rDNA sites and its association with 45S rDNA in plant chromosomes. Cytogenet Genome Res 146:243-249.

[32] Santana KCB, Pinangé DSB, Vasconcelos S, Oliveira AR, Brasileiro-Vidal AC, Alves MV and Benko-Iseppon AB (2016) Unraveling the karyotype structure of the spurges Euphorbia hirta L. and E. hyssopifolia L. (Euphorbiaceae) using genome size estimation and heterochromatin differentiation. Comp Cytogenet 10:657-696.

[33] Sasikala R and Paramathma M (2010) Chromosome studies in the genus Jatropha L. Electron J Plant Breeding 4:637-642.

[34] Sato S, Hirakawa H, Isobe S, Fukai E, Watanabe A, Kato M, Kawashima K, Minami C, Muraki A, Nakazaki N, et al. (2011) Sequence analysis of the genome of an oil-bearing tree, Jatropha curcas L. DNA Res 18:65-76.

[35] Schubert I (2007) Chromosome evolution. Curr Opin Plant Biol 10:109-115.

[36] Schweizer D and Ambros PF (1994) Chromosome banding. In: Gosden JR (ed) Methods in Molecular Biology. Humana Press, Totowa, pp 97-112.

[37] Shahinuzzaman M, Yaakob Z and Moniruzzaman M (2016) Medicinal and cosmetics soap production from Jatropha oil. J Cosmet Dermatol 15:185-193.

[38] Sharma AK, Gangwar M, Kumar D, Nath G, Kumar Sinha AS and Tripathi YB (2016) Phytochemical characterization, antimicrobial activity and reducing potential of seed oil, latex, machine oil and presscake of Jatropha curcas Avicenna J Phytomed 6:366-375.

[39] Souza VC and Lorenzi H (2008) Botânica Sistemática: Guia ilustrado para identificação das famílias de fanerógamas nativas e exóticas no Brasil, baseado em APG II. 2nd edition. Instituto Plantarum, São Paulo, 704 p.

[40] Tiryaki I and Tuna M (2012) Determination of intraspecific nuclear DNA content variation in common vetch (Vicia sativa L.) lines and cultivars based on two distinct internal reference standards. Turk J Agric For 36:645-653.

[41] Vasconcelos S, Souza AA, Gusmão CLS, Milani M, Benko-Iseppon AM and Brasileiro-Vidal AC (2010) Heterochromatin and rDNA 5S and 45S sites as reliable cytogenetic markers for castor bean (Ricinus communis, Euphorbiaceae). Micron 41:746-753.

[42] Vesely P, Bures P, Smarda P and Pavlicek T (2012) Genome size and DNA base composition of geophytes: The mirror of phenology and ecology? Ann Bot 109:65-75.

[43] Wanzenböck EM, Schöfer C, Schweizer D and Bachmair A (1997) Ribosomal transcription units integrated via T-DNA transformation associate with the nucleolus and do not require upstream repeat sequences for activity in Arabidopsis thaliana Plant J 11:1007-1016.

[44] Webster GL (1987) The saga of the spurges: A review of classification and relationships in the Euphorbiales. Bot J Linn Soc 94:3-46.

[45] Webster GL (1994) Synopsis of the genera and suprageneric taxa of Euphorbiaceae. Ann Mo Bot Gard 81:33-144.

[46] Wicke S, Costa A, Muñoz J and Quandt D (2011) Restless 5S: The re-arrangement(s) and evolution of the nuclear ribosomal DNA in land plants. Mol Phylogenet Evol 61:321-332.

[47] Witkowska M, Ohmido N, Cartagena J, Shibagaki N, Kajiyama S and Fukui K (2009) Physical mapping of ribosomal DNA genes on Jatropha curcas chromosomes by multicolor FISH. Cytologia 74:133-139.

[48] Yue GH, Sun F and Liu P (2013) Status of molecular breeding for improving Jatropha curcas and biodiesel. Renew Sust Energ Rev 26:332-343.

Species	Accessions and provenances	2n	CMA⁺/DAPI^-	45S rDNA	5S rDNA	2C (pg)	CV (%)
J. curcas L.¹ 1 Cultivated in the green house of the Department of Genetics, Universidade Federal de Pernambuco, Recife, Brazil;	LGBV-S2860; Embrapa Algodão, Patos, PB, Brazil	22	4 T² 2 T – terminal signals; , P³ 3 P – pericentromeric signals in all chromosomes;	4 T	2 ST⁴ 4 ST – subterminal signals.	0.86 ± 0.02	3.95
J. gossypiifolia L.	LGBV-S3313; Engenho Ubu, BR 101 Norte, Km 24, Goiana, PE, Brazil	22	4 T, P	4 T	2 ST	0.64 ± 0.02	4.14
J. integerrima Jacq.	IAC-VI23; Instituto Agronômico (IAC), Campinas, SP, Brazil	22	4 T	4 T	2 ST	0.85 ± 0.03	4.27
J. mollissima (Pohl) Baill.¹ 1 Cultivated in the green house of the Department of Genetics, Universidade Federal de Pernambuco, Recife, Brazil;	LGBV-S3314; Parque Nacional do Catimbau, Buíque, PE, Brazil	22	5 T + 1 ST	5T + 1 ST	5T + 1 ST	0.79 ± 0.03	5.53
J. multifida L.¹ 1 Cultivated in the green house of the Department of Genetics, Universidade Federal de Pernambuco, Recife, Brazil;	IAC-V1P1; Instituto Agronômico (IAC), Campinas, SP, Brazil	22	4 T	4 T	2 ST	0.64 ± 0.01	5.17
J. podagrica Hook.¹ 1 Cultivated in the green house of the Department of Genetics, Universidade Federal de Pernambuco, Recife, Brazil;	LGBV-S2844; Gravatá, PE, Brazil	22	4 T, P	4 T	2 ST	0.74 ± 0.05	6.65

Brasil