search
for
 About Bioline  All Journals  Testimonials  Membership  News


Electronic Journal of Biotechnology
Universidad Católica de Valparaíso
ISSN: 0717-3458
Vol. 9, Num. 3s1, 2006, pp. 248-252

Electronic Journal of Biotechnology, Vol. 9, No. 3, June, 2006, Supp. 1, 2006, pg. 248-252

RESEARCH ARTICLE

Construction of a molecular identification profile of new varieties of Nierembergia linariaefolia by anchored microsatellites

Mariana C. Pérez de la Torre1 , Alejandro S. Escandón*2

1Instituto de Floricultura, INTA Castelar, Nicolás Reppetto y De los Reseros s/n. (1712), Buenos Aires, Argentina Tel/Fax: 54 11 4681 3736 E-mail: mpdelatorre@cnia.inta.gov.ar
|
2Instituto de Floricultura, INTA Castelar, Nicolás Reppetto y De los Reseros s/n. (1712), Buenos Aires, Argentina Tel/Fax: 54 11 4681 3736 E-mail: aescandon@cnia.inta.gov.ar  
Web site: http://www.inta.gov.ar
*Corresponding author

Financial support: Granted by INTA Project number 1837.

Code Number: ej06095

Abstract

The objective of the present work was to establish the molecular identification profile for six new varieties of Nierembergia linariaefolia to incorporate the fingerprint, as complementary information to the standard registration data. Total DNA was extracted from young leaves following the protocol of the cetyltrimethylammonium bromide. Anchored microsatellites were used as molecular markers. The amplification reactions were carried out with seven primers. A total of 251 loci were detected, 98% of them were polymorphic. The average of polymorphic loci was 35 loci per primer and, 41 loci per genotype. Six out of the seven primers used discriminated all the individuals involved in the present study; consequently, it was possible to generate the molecular identification profile for the six new varieties. This result, supported together with our previous reports, indicates that the anchored microsatellites are a very useful technique for the fingerprints generation in N. linariaefolia.

Keywords: ISSR, ornamentals, varietal identification.

Abbreviations:

CTAB: Cetyltrimethylammonium bromide
ISSR: Inter simple sequence repeat
MIP: Molecular identification profile
PCR: Polymerase chain reaction
Rp: Resolving power

The genus Nierembergia, a member of the Solanaceae family, comprises about 21 species, 15 of them are natives from Argentina (Cocucci, 1995). The distribution centre of this specie is located in the central region of the country (Zuloaga and Morrone, 1999). 

Four species of the genus Nierembergia were incorporated to the native ornamental plants breeding program: N. rivularis, N. tandilensis, N. calycina and N. linariaefolia, which is the most advance in the breeding process.

Based on the abundant and length of the flowering period, the variability in the colour of the flowers and the easiness of propagation six new varieties of N. linariaefolia were selected. Four of these varieties ("Nube", "Luna", "Estrella" and "Cielo") are already registered, whereas the remainders ("Bruma" and "Nieve") are under registration process. Into this context, the molecular markers for varietal identification can be used as a tool to avoid the fraudulent multiplications as well as to preserve property rights, and they have become a complement of the traditional methods based on observable characters of the plants (Cenis, 2000).

The ISSR markers (Zietkiewicz et al. 1994) are generated from single-primer PCR reactions where the primer is designed from di- or trinucleotide repeat motifs with a 5' or 3' anchoring sequence of one to three nucleotides (Wolfe et al. 1998), without the requirement for prior sequence information (McGregor et al. 2000). Its application as PCR primer revealed high polymorphism degree (Zietkiewicz et al. 1994), generating reliable information for DNA analysis and with the necessary sensibility to distinguish among individuals genetically related (Pérez de la Torre et al. 2003).

This technique was successfully applied to the study of Astragalus oniciformi populations (Alexander et al. 2004), Penstemon sp (Wolfe et al. 1998) and in taxonomic studies of Vigna (Ajibade et al. 2000). In ornamental species ISSRs have been used in Jacaranda sp (Pérez de la Torre et al. 2003; Escandón et al. 2005a), Nierembergia (Escandón et al. 2005b), Pandorea sp (Jain et al. 1999) and Chrysantemum (Wolff et al. 1995). The ISSR strategy was applied to generate fingerprints in selected clones of N. linariaefolia, supported by the reproducibility of the banding patterns compared to the RAPD's ones, being the longer primers and the higher annealing temperature the probable causes of this difference (Nybon, 2004).

The objective of the present work was to establish a MIP to add to the classical variety descriptors as complementary information for cultivar registration.

Materials and Methods

Plant material and DNA isolation

Total DNA was extracted following the CTAB procedure according to CIMMYT, Laboratory Protocols. (2005). Young leaves of N. linariaefolia var. Nube INTA-JICA, Luna INTA-JICA, Estrella INTA-JICA, Cielo INTA-JICA, Nieve INTA-JICA and Bruma INTA-JICA were frozen with liquid nitrogen and ground using mortar and pestle. DNA quality was assessed by running 0.8% agarosa gels stained with Ethidium Bromide (1/100 v/v), using λ Hind III as molecular weight pattern.

Polymerase chain reaction 

Seven ISSR primers were used in the present study: 5'CT: CCGGATCC(CT)9 (Pérez de la Torre et al. 2003), 5'GT: CCCGGATCC(GT)9, 5'GA: CCCGGATCC(GA)9, 5'CA: CCCGGATCC(CA)9, 3'GA: (GA)9T (Blair et al. 1999), 3'AC: (AC)8G, 3'GGG: GGG(TGGGG)2TG (University of British Columbia, UBC).

PCR reactions were carried out in a final volume of 25 μl containing 30 ng of total DNA; 0.5 U Taq polymerase (InBio-Unicem, Tandil, Argentina); 2.5 µl of 10X reaction buffer (InBio-Unicem, Tandil, Argentina); 0.2 mM of dNTP's; 0.8 μM primers and 3.0 mM MgCl2. DNA amplifications were performed in an Eppendorf thermocycler (Mastercycler personal) with a preliminary step of 10 min at 94ºC, for the primers 3'AC and 3'GGG a touch down from 47ºC to 42ºC was done, 45 sec at 47ºC, 90 sec at 72ºC and 40 sec at 94ºC, followed by 40 cycles with the following conditions: 40 sec at 94ºC, 45 sec at 42ºC, 90 sec at 72ºC and a final 10 min extension at 72ºC. For the other primers (5'GA; 5'CT; 5'GT, 5'CA and 3'GA) the PCR conditions were: initial step of 10 min at 94ºC, and 40 cycles with 40 sec at 94ºC, 45 sec at 57ºC, 90 sec at 72ºC and a final 10 min extension at 72ºC.

10 µl of PCR products were analyzed on 2.5% agarose gels in TAE buffer running at 60 V for 240 min. Gels were stained with Ethidium Bromide (5/100 v/v). The bands obtained were sized (in base pairs) by comparison with standard marker (100 bp and 50 bp ladder, PB-L, UNQ, Quilmes, Argentina).

For the analysis only the well defined and reproducible bands were considered. Bands with the same migration distance were considered homologous fragments, independently of their intensity. The analysis was performed in a visual way, with the support of the program for calculation of molecular weight designed by Dr. Jorge Dubcovsky (Professor of Agronomy and Extension Department of California University, Davis, USA). Accordingly the presence of a band was scored as "1" while the absence of the band was scored as "0", representing null-alleles. Data sets derived from the respective banding patterns were used to generate a basic data matrix for each accession.

The power of each ISSR primer to distinguish among the studied genotypes was evaluated by the Resolving Power (Rp) (Prevost and Wilkinson, 1999). It is defined per primer as: Rp= Σ Ib where Ib is the band informativeness, that takes the values of: 1-(2x[0.5-p]), being p the proportion of the six Nierembergia varieties containing the band.

Results and Discussion

Ornamental crops involve a wide range of species, most of them are almost unknown at a genetic level. Into this frame, molecular markers procedures play a relevant role in the study of the genetic diversity, in determining cultivar purity and hence leading to improve property rights protection (De Riek, 2001).

In the present work seven ISSR primers were used to generate fingerprints in selected clones of N. linariaefolia. The ISSR primers were described as highly conserved in most of the studied plant genomes (Blair et al. 1999). These authors evaluated the genetic diversity among 59 rice cultivars. Fernández et al. (2002) reported that sixteen barley cultivars were distinguished applying this technique. Jain et al. (1999) evaluated the genetic diversity and generated genome fingerprinting of genus Pandorea. In the same way, Pérez de la Torre et al. (2003) and Escandón et al. 2005a discriminated among 6 and 21 accessions of J. mimosifolia respectively.

Figure 1 show, as an example, the amplification profile obtained with the 5'CA, 3'AC and 3'GGG primers. The analysis of bands per primer in the present gel, shows, for the primer 5'CA polymorphic loci in: 1243, 1082, 1011, 878, 857, 816, 791, 744, 709, 683, 658, 615, 584, 577, 549, 531, 495, 457, 416, 385, 371 and 361 bp. For the primer 3'AC, the bands that revealed polymorphic loci were: 1169, 1049, 1005, 980, 951, 933, 862, 846, 801, 787, 754, 735, 687, 630, 545, 528, 501, 491, 445 and 374 bp. Finally, the primer 3'GGG shows polymorphic loci at: 999, 911, 889, 796, 782, 642 and 498 bp.

The generated MIP for each variety of N. linariaefolia is shown in Table 1.

Table 2 summarized the data obtained: the number of total loci (TL), the number of polymorphic loci (PL), the percentage of polymorphic loci (%P), the number of different genotypes identified (IG) and the Rp of each primer. The seven primers used detected a total of 251 loci, 98% of them were polymorphic, and an average of 41 loci per genotype and 35 loci per primer. The percentage of polymorphic loci ranged from 93.1% for 3'GGG to 100% for 5'CT, 5'GT y 5'GA. Rp ranged from 4.33 for 5'GA to 13.67 for 5'CA (Table 2).

Prevost and Wilkinson (1999) reported the Rp as the capacity of a given primer to discriminate among different genotypes. As can be seen in Table 2, with primers that show a Rp value equal or higher than 4.83 it was possible to discriminate among the six Nierembergia varieties.   

Primers 5'CA, 5'GT, 5'CT and 3'GA were tested in a previous study with other very related genotypes (Escandón et al. 2005b). The Rp values obtained in the mentioned report were different of the corresponding values obtained here, being the most dramatic case for primer 5'CA, that gave a Rp value of 13.67 in the present study in contrast with a value of 5.5 obtained of the previous report (Escandón et al. 2005b). This fact confirms that the power of a primer to discriminate among different genotypes must be circumscribed to the set of individuals involved in each study.

Together with the stability and the uniformity, to be different is a necessary requisite for a variety registration; the ISSR have shown to be an adequate tool for the differentiation of varieties being a true fingerprint of each genotype. In this report 246 new traits are presented. These traits, together with the morphological ones are excellent tools for the differentiation of Nierembergia varieties

Concluding Remarks

A MIP was obtained for each of the six new varieties of N. linariaefolia presented in this paper.

All primers, with exception of 5'GA that discriminated among 4 varieties only, were able to distinguish among the genotypes analyzed in this study. 

The anchored microsatellites showed to be an economic, fast, and simple technique, besides reproducible and reliable for the generation of fingerprints and the establishment of genetic relations in N. linariaefolia

References
  • AJIBADE, S.R.; WEDEN, N.F. and CHITE, S.M. Inter-simple sequence repeat analysis of genetic relationships in the genus Vigna. Euphytica, 2000, vol. 111, no. 1, p. 47-55. [CrossRef]
  • ALEXANDER, J.A.; LISTON, A. and POPOVICH, S. Genetic diversity of the narrow endemic Astragalus oniciformis (Fabaceae). American Journal of Botany, December 2004, vol. 91, no. 12, p. 2004-2012.
  • BLAIR, M.W; PANAUD, O. and MCCOUCH, S.R. Inter-simple sequence repeat amplification for analysis of microsatellite motif frequency and fingerprinting in rice (Oryza sativa L.). Theoretical and Applied Genetics, April 1999, vol. 98, no 5, p. 780-792. [CrossRef]
  • CENIS, J.L. Nuevas técnicas moleculares para la identificación varietal de plantas. Revista Terralia, 2000, vol. 12, p. 40-43.
  • COCUCCI, A.A. and HUNZIKER, A.T. Nierembergia, In: HUNZIKER, A.T eds. Flora Faneroámica Argentina, Córdoba, Pugliese Siena S.R.L., 1995, vol. 15, p. 3-14.
  • CIMMYT. Laboratory Protocols: CIMMYT. Applied Molecular Genetics Laboratory. Third Edition, Mexico, D.F. 2005. 102 p. ISBN 968-6923-30-6. [cited March 2006] Available from Internet: http://www.cimmyt.org/english/docs/manual/protocols/abc_amgl.pdf.
  • DE RIEK, J. Are molecular markers strengthening plant variety registration and protection? In: VAN HUYLENBROECK, J. ed. Proceedings XX EUCARPIA Symposium on New Ornamental. Acta Horticulturae (ISHS), 2001, vol. 552, p. 215-223.
  • ESCANDÓN, A.; PÉREZ DE LA TORRE, M.; ACEVEDO, A.; MARCUCCI-POLTRI, S. and MIYAJIMA, I. Anchored ISSR as molecular marker to characterize different accessions of Jacaranda mimosifolia L Don. Acta Horticulturae (ISHS), 2005a, vol. 683, p. 121-127.
  • ESCANDÓN, A.; PÉREZ DE LA TORRE, M.; SOTO, M.S. and ZELENER, N. Identificación de clones selectos de Nierembergia linariaefolia mediante microsatélites anclados. RIA , 2005b, vol. 34, no. 1, p. 5-17.
  • FERNÁNDEZ, M.E.; FIGUERAS, A.M. and BENITO, C. The use of ISSR and RAPD markers for detecting DNA polymorphism, genotype identification and genetic diversity among barley cultivars with known origin. Theoretical and Applied Genetics, April 2002, vol. 104, no. 5, p. 845-851.
  • JAIN, A.; APPARANDA, C. and BHALLA, P. Evaluation of genetic diversity and genome fingerprinting of Pandorea (Bignoniacea) by RAPD and inter-SSR PCR. Genome, 1999, vol. 42, no. 4, p. 714-719.
  • MCGREGOR, C.E.; LAMBERT, C.A.; GREYLING, M.M.; LOUW, J.H. and WARNICH, L. A comparative assesement of DNA fingerprinting techniques (RAPD, ISSR, AFLP and SSR) in tetraploide potato (Solanum tuberosum L.) germplasm. Euphytica, 2000, vol. 113, no. 2, p. 135-144. [CrossRef]
  • NYBON, H. Comparison of different nuclear DNA markers for estimating intraspecific genetic diversity in plants. Molecular Ecology, May 2004, vol. 13, p. 1143-1155. [CrossRef]
  • PÉREZ DE LA TORRE, M.; ACEVEDO, A.; SERPA, J.C.; MIYAJIMA, I. and ESCANDÓN, A.S. Puesta a punto de la técnica de microsatélites anclados para la caracterización de individuos selectos de jacarandá. In: MASCARINI, L.; VILELLA, F. and WRIGHT, E. eds. Floricultura en la Argentina. Investigación y Tecnología de Producción, 2003, p. 3-12.
  • PREVOST, A. and WILKINSON, M.J. A new system of comparing PCR primers applied to ISSR fingerprinting of potato cultivars. Theoretical and Applied Genetics, January 1999, vol. 98, no. 1, p. 107-112. [CrossRef]
  • UBC, University of British Columbia [online]. [cited June 2005] Available from Internet: http://www.michaelsmith.ubc.ca/services/NAPS/Primer_Sets/Primers.pdf
  • WOLFE, A.; XIANG Q-Y. and KEPHART, S.R. Assessing hybridization in natural populations of Penstemon (Scrophulariaceae) using hypervariable inter-simple sequence repeat markers. Molecular Ecology, September 1998, vol. 7, no. 9, p. 1107-1125. [CrossRef]
  • WOLFF, K.; ZIETEKEWICZ, E. and HOFSTRA, H. Identification of chrysantemun cultivars and stability of DNA fingerprinting patterns. Theoretical and Applied Genetics, August 1995, vol. 91, no. 3, p. 439-447. [CrossRef]
  • ZIETKIEWICZ, E.; RAFALSKI, A. and LABUDA, D. Genome fingerprinting by simple sequence repeat (SSR)-anchored polymorphism chain reaction amplification. Genomics, March 1994, vol. 20, no. 2, p. 176-183. [CrossRef]
  • ZULOAGA, F. and MORRONE, O. Dicotyledoneae (Fabaceae-Zigophhyllaceae). In: Catálogo de las Plantas Vasculares de la República Argentina II; Missouri Botanical Garden Press, 1999, vol. F-Z, p. 1080-1084.

Note: Electronic Journal of Biotechnology is not responsible if on-line references cited on manuscripts are not available any more after the date of publication.
Supported by UNESCO / MIRCEN network

© 2006 by Pontificia Universidad Católica de Valparaíso -- Chile


The following images related to this document are available:

Photo images

[ej06095f1.jpg] [ej06095t1.jpg] [ej06095t2.jpg]
Home Faq Resources Email Bioline
© Bioline International, 1989 - 2024, Site last up-dated on 01-Sep-2022.
Site created and maintained by the Reference Center on Environmental Information, CRIA, Brazil
System hosted by the Google Cloud Platform, GCP, Brazil