Applied Genetics and Genomics in Alfalfa Breeding

Li, Xuehui; Brummer, E. Charles

doi:10.3390/agronomy2010040

Cited by 128 publications

(114 citation statements)

References 116 publications

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“…Alfalfa, a perennial and outcrossing species, is one of the most valuable forage crops with high-protein content and biomass production and has been widely cultivated as an economic crop worldwide. However, it is moderately tolerant to salinity and can only be cultivated in moderate salt-alkaline soils, which limit the growth range of alfalfa (Suárez et al, 2009;Li and Brummer, 2012;Zhang et al, 2012). The expression of foreign genes, such as GmDREB1, SsNHX1, AhBADH, and TaNHX2, increases salt tolerance in transgenic alfalfa plants compared with that of wild-type plants (Jin et al, 2010;Liu et al, 2011;Zhang et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Salicornia europaea L. Na+/H+ antiporter gene improves salt tolerance in transgenic alfalfa (Medicago sativa L.)

Zhang¹,

Niu²,

Huridu³

et al. 2014

Genet. Mol. Res.

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ABSTRACT. In order to obtain a salt-tolerant perennial alfalfa (Medicago sativa L.), we transferred the halophyte Salicornia europaea L. Na + /H + antiporter gene, SeNHX1, to alfalfa by using the Agrobacterium-mediated transformation method. The transformants were confirmed by both PCR and RT-PCR analyses. Of 197 plants that were obtained after transformation, 36 were positive by PCR analysis using 2 primer pairs for the CaMV35S-SeNHX1 and SeNHX1-Nos fragments; 6 plants survived in a greenhouse. RT-PCR analysis revealed that SeNHX1 was expressed in 5 plants. The resultant transgenic alfalfa had better salt tolerance. After stress treatment for 21 days with 0.6% NaCl, the chlorophyll and MDA contents in transgenic plants were lower, but proline content and SOD, POD, and CAT activities were higher than those in wild-type plants. These results suggest that the salt tolerance of transgenic alfalfa was improved by the overexpression of the SeNHX1 gene.

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Section: Introductionmentioning

confidence: 99%

Salicornia europaea L. Na+/H+ antiporter gene improves salt tolerance in transgenic alfalfa (Medicago sativa L.)

Zhang¹,

Niu²,

Huridu³

et al. 2014

Genet. Mol. Res.

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“…The breeding strategy is based on the partial exploitation of heterosis in alfalfa proposed for the development of semihybrids by crossing genetically divergent germplasm and identifying heterotic groups (Brummer, 1999;Milic et al, 2013;Annicchiarico et al, 2017). One potential source of a heterotic combination within an alfalfa combination would be crossing between genetically distant populations (Li and Brummer, 2012). Therefore, we assumed that local Tunisian germplasm, which has a long history of growing in the relatively isolated environment of the oasis, can be valuable heterotic populations in semi-hybrids with selected, geographically distant populations.…”

Section: Discussionmentioning

confidence: 99%

Assessment of the genetic variation in alfalfa genotypes using SRAP markers for breeding purposes

Rhouma

Taški-Ajduković

Zitouna

et al. 2017

Chil. j. agric. res.

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The molecular diversity studies of alfalfa (Medicago sativa L.) germplasm could contribute to a more precise selection of parental populations in many breeding programs. Sequence-related amplified polymorphism (SRAP) markers were used to assess the genetic diversity of 110 individual plants from 13 selected alfalfa cultivars, landraces, and natural populations from Tunisia, Australia, Serbia, and Kazakhstan. Ten polymorphic SRAP primer combinations generated 137 alleles with 0.90 polymorphism information content. The percentage of polymorphic bands per genotype ranged from 57.66% to 70.07% with a mean of 64.29% and overall value of 100%. The genotype Sardi 10 had the highest value for the effective number of alleles; Nei's gene diversity and Shannon information index, exhibited the highest variability level (Ne = 1.453, He = 0.259, I = 0.381, respectively), whereas the genotype Nera exhibited the lowest variability level (Ne = 1.359, He = 0.211, I = 0.317, respectively). The AMOVA analysis showed that 68% of the variance was within the genotypes; this was in line with the coefficient of genetic differentiation (Gst = 0.370). The genetic relatedness of alfalfa individuals analyzed by the neighbor-joining dendrogram was consistent with the Bayesian model-based clustering approach. The exceptions were individuals from genotypes Slavija and Nera, which were grouped separately by STRUCTURE analyses. These results provide useful information for the management of alfalfa genetic resources and the rational use of local and foreign alfalfa populations in breeding programs focused on the development of new, high-yielding cultivars more adapted to drought conditions in North Africa.

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“…Main goals in alfalfa breeding are biomass yield (for hay or biofuel), forage quality: protein, neutral detergent fibre (NDF), acid detergent fibre (ADF), acid detergent lignin (ADL) content, leaf to stem ratio (Milić et al 2011a), but also persistence, adaptability and stability of newly created populations/cultivars (Katić et al 2008, Veronesi et al 2010, Milić et al 2011c. Breeding alfalfa for yield has not been very successful compared to other species (Lamb et al 2006, Brummer 2008, Veronesi et al 2010, Li & Brummer 2012. The progress of alfalfa breeding has been slow, most notably due to its complex genetic structure (autotetraploidy), allogamy and tetrasomic inheritance present in alfalfa, and besides this plant architecture, hermaphroditic flowers and meadow conditions (Scotti & Brummer 2010).…”

Section: Introductionmentioning

confidence: 99%

“…Alfalfa breeding programs are based on recurrent phenotypic selection with or without progeny testing, to accumulate desirable alleles at high frequency into a population (Li & Brummer 2012). The tetraploid species usually express severe inbreeding depression.…”

Section: Introductionmentioning

confidence: 99%

10.5937/ratpov50-5059 = Heterosis in alfalfa breeding

Milić¹,

Taški-Ajduković²,

Nagl³

et al. 2013

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Summary: The progress of alfalfa breeding has been slow, most notably due to its complex genetic structure (autotetraploidy) and tetrasomic inheritance. Alfalfa breeding programs are based on recurrent phenotypic selection with or without progeny testing. The genetic control of major agronomic traits is determined by both additive gene action (accumulation of frequency of desirable alleles represented by significant general combining ability (GCA) effects, and nonadditive gene action, complementary gene interactions represented by significant specific combining ability (SCA) effects. This type of gene action expression in alfalfa also determines the way in which breeding is carried out and brings about changes in the methods used. It has also given rise to the idea of the semi-hybrid breeding of this crop which involves breeding alfalfas within the population, identification of heterotic germplasm, and the seed production of semi or free hybrid seed. The studies of the relationship between the molecular variability of alfalfa populations and heterosis in their hybrids could contribute to a more precise selection of parental populations to be used for crossing in semi-hybrid alfalfa breeding procedure, aiming to reduce number of necessary crossings and therefore make future alfalfa breeding programs more efficient. Future tasks of alfalfa breeders should be to discover how to translate heterosis from single plants in hybrids planted in dense stand to generate "yield for free" (capture heterosis) in alfalfa semi hybrids.

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Applied Genetics and Genomics in Alfalfa Breeding

Cited by 128 publications

References 116 publications

Salicornia europaea L. Na+/H+ antiporter gene improves salt tolerance in transgenic alfalfa (Medicago sativa L.)

Salicornia europaea L. Na+/H+ antiporter gene improves salt tolerance in transgenic alfalfa (Medicago sativa L.)

Assessment of the genetic variation in alfalfa genotypes using SRAP markers for breeding purposes

10.5937/ratpov50-5059 = Heterosis in alfalfa breeding

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