Andru Suman scite author profile

Target region amplification polymorphism (TRAP) is a fairly new PCR-based molecular marker technique which uses gene-based information for primer design. The objective of this study was to evaluate the utility of TRAP markers for assessing genetic diversity and interrelationships in sugarcane germplasm collections. Thirty genotypes from the genera Saccharum, Miscanthus, and Erianthus were used in the study. Among the genus Saccharum were the species, S. officinarum L., S. barberi Jesw., S. sinense Roxb., S. spontaneum L., S. robustum Brandes and Jeswiet ex Grassl, cultivars, cultivar-derived mutants and interspecific hybrids between S. officinarum and S. spontaneum. Six fixed primers, designed from sucrose-and cold tolerance-related EST (expressed sequence tags) sequences, paired with three arbitrary primers, were used to characterize the germplasm. Both the cluster and principal coordinate (PCoA) analyses placed the Erianthus spp. and Miscanthus spp. genotypes distinctly from each other and from the Saccharum species, thus, supporting their taxonomic classification as separate genera. Genotypes of the low sucrose and cold tolerant species, S. spontaneum, formed one distinct group, while the rest of the Saccharum species formed one interrelated cluster with no distinct subgroups. Sequence analysis of TRAP bands derived from a S. spontaneum genotype revealed homology with known gene sequences from other grass species including Sorghum. A BLASTn search using the homologous sequences from Sorghum matched with the S. officinarum GenBank accession from which the fixed TRAP primer was designed. These results ratify TRAP as a potentially useful marker technique for genetic diversity studies in sugarcane.

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Genetic analysis of the sugarcane (Saccharum spp.) cultivar ‘LCP 85-384’. I. Linkage mapping using AFLP, SSR, and TRAP markers

Suman

Pan

Thongthawee

et al. 2011

Theor Appl Genet

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Sugarcane hybrids are complex aneu-polyploids (2n = 100-130) derived from inter-specific hybridization between ancestral polyploid species, namely S. officinarum L. and S. spontaneum L. Efforts to understand the sugarcane genome have recently been enhanced through the use of new molecular marker technologies. A framework genetic linkage map of Louisiana's popular cultivar LCP 85-384 was constructed using the selfed progeny and based on polymorphism derived from 64 AFLP, 19 SSR and 12 TRAP primer pairs. Of 1,111 polymorphic markers detected, 773 simplex (segregated in 3:1 ratio) and 182 duplex (segregate in 77:4 ratio) markers were used to construct the map using a LOD value of ≥ 4.0 and recombination threshold of 0.44. The genetic distances between pairs of markers linked in the coupling phase was computed using the Kosambi mapping function. Of the 955 markers, 718 simplex and 66 duplex markers were assigned to 108 co-segregation groups (CGs) with a cumulative map length of 5,617 cM and a density of 7.16 cM per marker. Fifty-five simplex and 116 duplex markers remained unlinked. With an estimated genome size of 12,313 cM for LCP 85-384, the map covered approximately 45.6% of the genome. Forty-four of the 108 CGs were assigned into 9 homo(eo)logous groups (HGs) based on information from locus-specific SSR and duplex markers, and repulsion phase linkages detected between CGs. Meiotic behavior of chromosomes in cytogenetic studies and repulsion phase linkage analysis between CGs in this study inferred the existence of strong preferential chromosome pairing behavior in LCP 85-384. This framework map marks an important beginning for future mapping of QTLs associated with important agronomic traits in the Louisiana sugarcane breeding programs.

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Molecular Diversity Among Members of the Saccharum Complex Assessed Using TRAP Markers Based on Lignin-Related Genes

et al. 2011

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In addition to the cultivation of sugarcane for sugar, the crop is considered seriously as an important bioenergy grass crop for its high biomass production ability. But, lignin is a serious bottleneck in the bioconversion of lignocellulosic biomass to ethanol. Hence, genetic relationships among 64 genotypes within the Saccharum complex were studied with respect to lignin-related genes using target region amplified polymorphic (TRAP) primers derived from caffeic acid O-methyltransferase (COMT), cinnamoyl alcohol dehydrogenase (CAD), cinnamoyl coA reductase (CCR), and ferrulate 5-hydroxylase (F5H) genes. While the average polymorphism detected by the TRAP markers was 43%, the markers derived from F5H gene (34%) were less polymorphic in comparison to those derived from COMT (46%), CCR (44%), and CAD (46%) genes. The lignin gene-based TRAP markers differentiated members of the Saccharum complex broadly according to previously established genetic relationships in the order of Miscanthus>Erianthus>Saccharum spontaneum>Saccha-rum robustum/Saccharum barberi/Saccharum sinense> Saccharum officinarum/cultivars. Principal coordinate analysis showed that 29% of the total variation was explained by the genotypes with respect to the lignin-related genes. The association of genetic variation revealed in this study with the biomass composition-related genes of the genotypes within a species will be helpful to design breeding strategies to develop superior energy cane cultivars with improved biomass quality of the sugarcane.

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Sequence-related amplified polymorphism (SRAP) markers for assessing genetic relationships and diversity in sugarcane germplasm collections

et al. 2008

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Characterization of wild germplasm provides essential information on genetic diversity that breeders utilize for crop improvement. The potential of the sequence-related amplified polymorphism (SRAP) technique, which preferentially amplifies gene-rich regions, was evaluated to assess the genetic relationships among members of the Saccharum species. A panel of 31 SRAP primer combinations were used to score 30 genotypes of Saccharum officinarum, Saccharum spontaneum, Saccharum robustum, Saccharum sinense, Saccharum barberi and sugarcane hybrids, with Miscanthus and Erianthus included as outgroups. The amplifications produced 1364 DNA fragments for an average of 44 per primer combination, with 83% (1135) being polymorphic and 8.7% (119) being species specific. Based on the Dice index, all 30 genotypes were differentiated from each other with genetic similarity (GS) estimates ranging from 0.60 to 0.96 (mean ¼ 0.79). Both the dendrogram [obtained by the unweighted pairgroup method with arithmetic mean or (UPGMA)] and the non-metric multidimensional scaling method grouped the genotypes according to their phylogenetic relationships. Erianthus and Miscanthus were separated as two outgroups (at GS levels of 0.56 and 0.72, respectively) into two major clusters: cluster I separated the S. robustum, S. sinense, S. barberi and hybrids as different subgroups with each one including some S. officinarum clones, while cluster II included the S. spontaneum clones, exclusively. A S. officinarum -S. spontaneum sequence comparison of some of the monomorphic and polymorphic bands revealed 65 -90% homology with rice, corn or sugarcane sequences deposited in databases. The high discriminatory power coupled with the possibility that most of the amplicons may be amplifying gene-rich regions of the genome makes SRAP a potentially robust tool for genetic mapping aimed at markerassisted introgression in sugarcane.

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Andru Suman

Target Region Amplification Polymorphism (TRAP) for Assessing Genetic Diversity in Sugarcane Germplasm Collections

Genetic analysis of the sugarcane (Saccharum spp.) cultivar ‘LCP 85-384’. I. Linkage mapping using AFLP, SSR, and TRAP markers

Molecular Diversity Among Members of the Saccharum Complex Assessed Using TRAP Markers Based on Lignin-Related Genes

Sequence-related amplified polymorphism (SRAP) markers for assessing genetic relationships and diversity in sugarcane germplasm collections

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