Abstract
Narrow-leafed lupin (Lupinus angustifolius L.) has recently been supplied with advanced genomic resources and, as such, has become a well-known model for molecular evolutionary studies within the legume family—a group of plants able to fix nitrogen from the atmosphere. The phylogenetic position of lupins in Papilionoideae and their evolutionary distance to other higher plants facilitates the use of this model species to improve our knowledge on genes involved in nitrogen assimilation and primary metabolism, providing novel contributions to our understanding of the evolutionary history of legumes. In this study, we present a complex characterization of two narrow-leafed lupin gene families—glutamine synthetase (GS) and phosphoenolpyruvate carboxylase (PEPC). We combine a comparative analysis of gene structures and a synteny-based approach with phylogenetic reconstruction and reconciliation of the gene family and species history in order to examine events underlying the extant diversity of both families. Employing the available evidence, we show the impact of duplications on the initial complement of the analyzed gene families within the genistoid clade and posit that the function of duplicates has been largely retained. In terms of a broader perspective, our results concerning GS and PEPC gene families corroborate earlier findings pointing to key whole genome duplication/triplication event(s) affecting the genistoid lineage.
Highlights
The last decade has seen gradual progress in evolutionary studies on plants, mainly due to simultaneous, rapid advancement in theory, computing, and molecular technology
The presence of analyzed genes within selected bacterial artificial chromosome (BAC) was positively verified by PCR amplification and Sanger sequencing with gene-specific primers
Two such contigs and two singletons were constructed for the glutamine synthetase (GS) sub-library and two contigs with one singleton were constructed for phosphoenolpyruvate carboxylase (PEPC)
Summary
The last decade has seen gradual progress in evolutionary studies on plants, mainly due to simultaneous, rapid advancement in theory, computing, and molecular technology. Due to their outstanding agronomic potential and complex evolutionary history, involving whole-genome duplication [15] and subsequent chromosome rearrangements, L. angustifolius has become an object of extensive molecular studies in terms of genomics, proteomics, and metabolomics. Sequence-defined markers have been associated with major agronomic traits for this species, including soft seededness, anthracnose and Phomopsis stem blight resistance, pod shattering, vernalization requirement, and alkaloid content [16,18,23,24,25,26,27]. Selected BAC clones have been used as anchors for the integration of linkage groups in particular chromosomes by the molecular cytogenetic approach [30,31] and have served as material in evolutionary studies of the Lupinus genus [32,33]. Other duplication mechanisms, such as segmental duplications or chromosome additions, from related species cannot be ruled out [36]
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