Using Morphological and Microsatellite (SSR) Markers to Assess the Genetic Diversity in Alfalfa (Medicago sativa L.)
Utilization of diverse germplasm is needed to enhance
the genetic diversity of cultivars. The objective of this study was to
evaluate the genetic relationships of 98 alfalfa germplasm accessions
using morphological traits and SSR markers. From the 98 tested
populations, 81 were locals originating in Europe, 17 were introduced
from USA, Australia, New Zealand and Canada. Three primers
generated 67 polymorphic bands. The average polymorphic
information content (PIC) was very high (> 0.90) over all three used
primer combinations. Cluster analysis using Unweighted Pair Group
Method with Arithmetic Means (UPGMA) and Jaccard´s coefficient
grouped the accessions into 2 major clusters with 4 sub-clusters with
no correlation between genetic and morphological diversity. The SSR
analysis clearly indicated that even with three polymorphic primers,
reliable estimation of genetic diversity could be obtained.
[1] E. Small and M. Jomphe, "A synopsis of the genus Medicago
(Leguminosae)," Can. J. Bot., vol. 67, pp. 3260-3294, 1989.
[2] T. J. McCoy and E. T. Bingham, "Cytology and cytogenetics of alfalfa,"
in Alfalfa and alfalfa improvement. Agronomy Monograph 29 (ed. A. A.
Hanson, D. K. Bbarnes and R. R. Hill), Madison USA, 1988, pp. 737-
776.
[3] M. Keivani, S. Sanaz Ramezanpour, H. Soltanloo, R. Choukan, M.
Naghavi and M. Ranjbar, "Genetic diversity assessment of alfalfa
(Medicago sativa L.) populations using AFLP markers," Australian
Journal of Crop Science," vol. 4, no. 7, pp. 491-497, 2010.
[4] A. Mengoni, A. Gori and M. Bazzicalupo, "Use of RAPD and
microsatellite (SSR) variation to assess genetic relationships among
populations of tetraploid alfalfa, Medicago sativa," Plant Breed., 2000,
vol. 119, pp. 311-317.
[5] X. Wang, X. Yang, L. Chen, G. Feng, J. Zhang and L. Jin, "Genetic
diversity among alfalfa (Medicago sativa L.) cultivars in Northwest
China," Acta Agriculturae Scandinavica, vol. 61, no. 1, pp. 60-66,
February 2011
[6] J. R. Xavier, J. Kumar and R. B. Srivastava, "Characterization of genetic
structure of alfalfa (Medicago sp.) from trans-Himalaya using RAPD
and ISSR markers," African Journal of Biotechnology, vol. 10, no.42,
pp. 8176-8187, August 2011.
[7] N. Diwan, A. A.Bhagwat, G. R. Bauchan and P. B. Cregan, "Simple
sequence repeat DNA markers in alfalfa and perennial and annual
Medicago species," Genomes, vol. 40, pp. 887-895, 1997.
[8] N. Diwan, J. H. Bouton, G. Kochert and P. B. Cregan, "Mapping of
simple sequence repeat (SSR) DNA markers in diploid and tetraploid
alfalfa," Theor. Appl. Genet., vol. 101, pp. 165-172, 2000.
[9] Z. P. Liu, G. S. Liu and Q. C Yang, "A novel statistical method for
assessing SSR variation in autotetraploid alfalfa (Medicago sativa L.),"
Genetics and Molecular Biology, 2007, vol. 30, no. 2, pp. 385-391.
[10] V. Vacek, V. Mrázková, A. Sestrienka, J. Sehnalová, I. Bareš and D.
Hájek, "Klasifikátor, genus Medicago L., Prague, 1985, pp. 40.
[11] L. Touil, F. Guesmi, K. Fares, C. Zagrouba and A. Ferchichi, "Genetic
diversity of some mediterranean populations of the cultivated alfalfa
(Medicago sativa L.) using SSR markers," Pakistan Journal of
Biological Sciences, vol. 11, no. 15, pp. 1923-1928, 2008.
[12] B. Julier, S. Flajoulot, P. Barre, G. Cardinet, S. Santoni, T. Huguet and
Ch. Huyghe, "Construction of two genetic linkage maps in cultivated
tetraploid alfalfa (Medicago sativa L.) using microsatellite and AFLP
markers," BMC Plant Biology, vol. 3, no. 9, 2003.
[13] S. Kemp, PIC Calculator Extra free software, 2002,
(http://www.genomics.liv.ac.uk/animal/pic.html)
[14] P. Jaccard, "Étude comparative de la distribuition florale dans une
portion des Alpes et des Jura," Bull. Soc. Vandoise Sci. Nat., 1901, vol.
37, pp. 547-579.
[15] FreeTree software v. 0.9.1.50 A. Pavlíček, S. Hrdá and J. Flegr,
"FreeTree - freeware program for construction of phylogenic trees on
the basis of distance data and bootstrap/jackknife analysis of the tree
robustness. Application in the RAPD analysis of the genus Frankelia,"
Folia Biol., vol. 45, pp. 97-99, 1999.
(http://taxonomy.zoology.gla.uc.uk/rod/rod.html).
[16] STATISTICA version 7.1.30.0, Copyright StatSoft.Inc., 2005.
[17] XLSTAT [computer program]. version 2012.3.01, Copyright AddinSoft.
Inc., 1995 - 2012.
[18] M. V. Bagavathiannan, B. Julier, P. Barre, R. H. Gulden and R. C. Van
Acker, "Genetic diversity of feral alfalfa (Medicago sativa L.)
populations occurring in Manitoba, Canada and comparison with alfalfa
cultivars: an analysis using SSR markers and phenotypic traits,"
Euphytica, vol. 173, pp. 419-432, 2010.
[19] M. Falahati - Anbaran, A. A. Habashi, M. Esfahany S. A. Mohammadi
and B. Ghareyazie, "Population genetic structure based on SSR markers
in alfalfa (Medicago sativa L.) from various regions contiguous to the
centres of origin of the species," Journal of Genetics, 1997, vol. 86, no.
1, pp. 59-63.
[20] M. L. Crochemore, C. Huyghe, C. Ecalle and B. Julier, "Structuration of
alfalfa genetic diversity using agronomic and morphological
characteristics. Relationship with RAPD markers," Agronomie, 1998,
vol. 18, pp. 79-94.
[21] S. L. Greene, M. Gritsenko and G. Vandermark, "Relating
morphological and RAPD marker variation to collection site
environment in wild populations of red clover (Trifolium pretense L.),"
Genet. Resour. Crop Evol., 2004, vol. 51, pp. 643-653.
[22] X. Zhang, Y. J. Zhang, R. Yan, J. G. Han, H. Fuzeng, J. H. Wang and K.
Cao, "Genetic variation of white clover (Trifolium repens L.) collections
from China detected by morphological traits, RAPD and SSR," Afr. J.
Biotechnol., 2010, vol. 9, no. 21, 3032-3041.
[23] L. Martinez, P. Cavagnaro, R. Masuelli and J. Rodriguez, "Evaluation of
diversity of Argentine grapevine (Vitis vinefera L.) varieties using
morphological data and AFLP markers," Electron. J. Biotechnol., 2003,
vol. 6, pp. 241-250.
[1] E. Small and M. Jomphe, "A synopsis of the genus Medicago
(Leguminosae)," Can. J. Bot., vol. 67, pp. 3260-3294, 1989.
[2] T. J. McCoy and E. T. Bingham, "Cytology and cytogenetics of alfalfa,"
in Alfalfa and alfalfa improvement. Agronomy Monograph 29 (ed. A. A.
Hanson, D. K. Bbarnes and R. R. Hill), Madison USA, 1988, pp. 737-
776.
[3] M. Keivani, S. Sanaz Ramezanpour, H. Soltanloo, R. Choukan, M.
Naghavi and M. Ranjbar, "Genetic diversity assessment of alfalfa
(Medicago sativa L.) populations using AFLP markers," Australian
Journal of Crop Science," vol. 4, no. 7, pp. 491-497, 2010.
[4] A. Mengoni, A. Gori and M. Bazzicalupo, "Use of RAPD and
microsatellite (SSR) variation to assess genetic relationships among
populations of tetraploid alfalfa, Medicago sativa," Plant Breed., 2000,
vol. 119, pp. 311-317.
[5] X. Wang, X. Yang, L. Chen, G. Feng, J. Zhang and L. Jin, "Genetic
diversity among alfalfa (Medicago sativa L.) cultivars in Northwest
China," Acta Agriculturae Scandinavica, vol. 61, no. 1, pp. 60-66,
February 2011
[6] J. R. Xavier, J. Kumar and R. B. Srivastava, "Characterization of genetic
structure of alfalfa (Medicago sp.) from trans-Himalaya using RAPD
and ISSR markers," African Journal of Biotechnology, vol. 10, no.42,
pp. 8176-8187, August 2011.
[7] N. Diwan, A. A.Bhagwat, G. R. Bauchan and P. B. Cregan, "Simple
sequence repeat DNA markers in alfalfa and perennial and annual
Medicago species," Genomes, vol. 40, pp. 887-895, 1997.
[8] N. Diwan, J. H. Bouton, G. Kochert and P. B. Cregan, "Mapping of
simple sequence repeat (SSR) DNA markers in diploid and tetraploid
alfalfa," Theor. Appl. Genet., vol. 101, pp. 165-172, 2000.
[9] Z. P. Liu, G. S. Liu and Q. C Yang, "A novel statistical method for
assessing SSR variation in autotetraploid alfalfa (Medicago sativa L.),"
Genetics and Molecular Biology, 2007, vol. 30, no. 2, pp. 385-391.
[10] V. Vacek, V. Mrázková, A. Sestrienka, J. Sehnalová, I. Bareš and D.
Hájek, "Klasifikátor, genus Medicago L., Prague, 1985, pp. 40.
[11] L. Touil, F. Guesmi, K. Fares, C. Zagrouba and A. Ferchichi, "Genetic
diversity of some mediterranean populations of the cultivated alfalfa
(Medicago sativa L.) using SSR markers," Pakistan Journal of
Biological Sciences, vol. 11, no. 15, pp. 1923-1928, 2008.
[12] B. Julier, S. Flajoulot, P. Barre, G. Cardinet, S. Santoni, T. Huguet and
Ch. Huyghe, "Construction of two genetic linkage maps in cultivated
tetraploid alfalfa (Medicago sativa L.) using microsatellite and AFLP
markers," BMC Plant Biology, vol. 3, no. 9, 2003.
[13] S. Kemp, PIC Calculator Extra free software, 2002,
(http://www.genomics.liv.ac.uk/animal/pic.html)
[14] P. Jaccard, "Étude comparative de la distribuition florale dans une
portion des Alpes et des Jura," Bull. Soc. Vandoise Sci. Nat., 1901, vol.
37, pp. 547-579.
[15] FreeTree software v. 0.9.1.50 A. Pavlíček, S. Hrdá and J. Flegr,
"FreeTree - freeware program for construction of phylogenic trees on
the basis of distance data and bootstrap/jackknife analysis of the tree
robustness. Application in the RAPD analysis of the genus Frankelia,"
Folia Biol., vol. 45, pp. 97-99, 1999.
(http://taxonomy.zoology.gla.uc.uk/rod/rod.html).
[16] STATISTICA version 7.1.30.0, Copyright StatSoft.Inc., 2005.
[17] XLSTAT [computer program]. version 2012.3.01, Copyright AddinSoft.
Inc., 1995 - 2012.
[18] M. V. Bagavathiannan, B. Julier, P. Barre, R. H. Gulden and R. C. Van
Acker, "Genetic diversity of feral alfalfa (Medicago sativa L.)
populations occurring in Manitoba, Canada and comparison with alfalfa
cultivars: an analysis using SSR markers and phenotypic traits,"
Euphytica, vol. 173, pp. 419-432, 2010.
[19] M. Falahati - Anbaran, A. A. Habashi, M. Esfahany S. A. Mohammadi
and B. Ghareyazie, "Population genetic structure based on SSR markers
in alfalfa (Medicago sativa L.) from various regions contiguous to the
centres of origin of the species," Journal of Genetics, 1997, vol. 86, no.
1, pp. 59-63.
[20] M. L. Crochemore, C. Huyghe, C. Ecalle and B. Julier, "Structuration of
alfalfa genetic diversity using agronomic and morphological
characteristics. Relationship with RAPD markers," Agronomie, 1998,
vol. 18, pp. 79-94.
[21] S. L. Greene, M. Gritsenko and G. Vandermark, "Relating
morphological and RAPD marker variation to collection site
environment in wild populations of red clover (Trifolium pretense L.),"
Genet. Resour. Crop Evol., 2004, vol. 51, pp. 643-653.
[22] X. Zhang, Y. J. Zhang, R. Yan, J. G. Han, H. Fuzeng, J. H. Wang and K.
Cao, "Genetic variation of white clover (Trifolium repens L.) collections
from China detected by morphological traits, RAPD and SSR," Afr. J.
Biotechnol., 2010, vol. 9, no. 21, 3032-3041.
[23] L. Martinez, P. Cavagnaro, R. Masuelli and J. Rodriguez, "Evaluation of
diversity of Argentine grapevine (Vitis vinefera L.) varieties using
morphological data and AFLP markers," Electron. J. Biotechnol., 2003,
vol. 6, pp. 241-250.
@article{"International Journal of Biological, Life and Agricultural Sciences:59615", author = "T. Cholastova and D. Knotova", title = "Using Morphological and Microsatellite (SSR) Markers to Assess the Genetic Diversity in Alfalfa (Medicago sativa L.)", abstract = "Utilization of diverse germplasm is needed to enhance
the genetic diversity of cultivars. The objective of this study was to
evaluate the genetic relationships of 98 alfalfa germplasm accessions
using morphological traits and SSR markers. From the 98 tested
populations, 81 were locals originating in Europe, 17 were introduced
from USA, Australia, New Zealand and Canada. Three primers
generated 67 polymorphic bands. The average polymorphic
information content (PIC) was very high (> 0.90) over all three used
primer combinations. Cluster analysis using Unweighted Pair Group
Method with Arithmetic Means (UPGMA) and Jaccard´s coefficient
grouped the accessions into 2 major clusters with 4 sub-clusters with
no correlation between genetic and morphological diversity. The SSR
analysis clearly indicated that even with three polymorphic primers,
reliable estimation of genetic diversity could be obtained.", keywords = "genetic diversity, Medicago sativa L., morphological
traits, SSR markers", volume = "6", number = "9", pages = "734-7", }
