Abstract
Fast and accurate detection of plant species and their hybrids using molecular tools will facilitate the assessment and monitoring of local biodiversity in an era of climate and environmental change. Herein, we evaluate the utility of the plastid trnL marker for species identification applied to Mediterranean pines (Pinus spp.). Our results indicate that trnL is a very sensitive marker for delimiting species biodiversity. Furthermore, High Resolution Melting (HRM) analysis was exploited as a molecular fingerprint for fast and accurate discrimination of Pinus spp. DNA sequence variants. The trnL approach and the HRM analyses were extended to wood samples of two species (Pinus nigra and Pinus sylvestris) with excellent results, congruent to those obtained using leaf tissue. Both analyses demonstrate that hybrids from the P. brutia (maternal parent) × P. halepensis (paternal parent) cross, exhibit the P. halepensis profile, confirming paternal plastid inheritance in Group Halepensis pines. Our study indicates that a single one-step reaction method and DNA marker are sufficient for the identification of Mediterranean pines, their hybrids and the origin of pine wood. Furthermore, our results underline the potential for certain DNA regions to be used as novel biological information markers combined with existing morphological characters and suggest a relatively reliable and open taxonomic system that can link DNA variation to phenotype-based species or hybrid assignment status and direct taxa identification from recalcitrant tissues such as wood samples.
Highlights
Forest trees constitute about 82% of continental biomass and harbour more than 50% of terrestrial biodiversity
We have demonstrated that sequence variation within the analyzed region of the trnL gene enabled the use of High Resolution Melting (HRM) analysis for the differentiation of even closely related Pinus species
Diagnostic character states at eight selected nucleotide positions for trnL, different in at least one position per species combination, are shown. doi:10.1371/journal.pone.0060945.t005. This is the first comprehensive study describing the application of HRM curve analysis for differentiation of Pinus species and hybrids in leaf and wood samples
Summary
Forest trees constitute about 82% of continental biomass and harbour more than 50% of terrestrial biodiversity. The first seed plants to have evolved were Gymnosperms, which today occupy about 25% of the planet’s forests. Pinus is the most important genus within the Gymnosperms and within the Pinaceae family, taking into account the number of species (109), [1]and their contribution to forest ecosystems [2]. Pine trees (Pinus L.) are important elements of the Mediterranean landscape. They have played a major role in the evolution of Mediterranean flora and vegetation [3] and have been widely used by its inhabitants since prehistoric times [4]. Various classifications have been proposed in this genus [5], [6] with the most recent efforts focusing on DNA phylogenetics to identify related species [7], [8]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
