Abstract
Background
Microsatellite markers were developed for distylous Linum suffruticosum and tested in the monomorphic sister species Linum tenuifolium. These species are perennial herbs endemic to the western and northwestern Mediterranean, respectively, with a partially overlapping distribution area.
Methods and results
We developed 12 microsatellite markers for L. suffruticosum using next generation sequencing, and assessed their polymorphism and genetic diversity in 152 individuals from seven natural populations. The markers displayed high polymorphism, with two to 16 alleles per locus and population, and average observed and expected heterozygosities of 0.833 and 0.692, respectively. All loci amplified successfully in the sister species L. tenuifolium, and 150 individuals from seven populations were also screened. The polymorphism exhibited was high, with two to ten alleles per locus and population, and average observed and expected heterozygosities of 0.77 and 0.62, respectively.
Conclusions
The microsatellite markers identified in L. suffruticosum and tested in L. tenuifolium are a powerful tool to facilitate future investigations of the population genetics, mating patterns and hybridization between both Linum species in their contact zone.
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Introduction
Linum L. (Linaceae) is a cosmopolitan and diverse genus with a great economic and ecological importance. In addition, it stands as a model system for studying the evolution of heterostyly from the early observations of Darwin [1] to the last advances on genomics of the S-locus [2]. Heterostyly consists in the co-occurrence of two to three floral morphs within a population, with floral morphs (1) being hermaphroditic, and (2) presenting stigmas and anthers at different reciprocal positions within the flower [3]. Linum exhibits high variation in morphology, mating system and presence of heterostyly and related floral polymorphisms, which have evolved multiple independent times [4,5,6].
The sister species Linum suffruticosum and L. tenuifolium (Fig. 1) appear as an ideal study system to assess the microevolutionary mechanisms that support the maintenance and loss of heterostyly in Linum [7, 8]. Distributed in the western Mediterranean Basin, Linum suffruticosum is a heteromorphic and self-incompatible species showing a unique case of three-dimensional heterostyly [8]. The self-compatible and monomorphic L. tenuifolium is the sister species of L. suffruticosum and is distributed in southern Europe [6, 9, 10]. Both species have a contact zone area in the NW of the Mediterranean Basin, from NE Spain to NW Italy, where populations co-occur in nearby sites or even intermingled and are able to hybridize [10]. This contact zone makes the L. suffruticosum-L. tenuifolium complex an excellent system to address questions about the evolution of mating systems, and to understand the processes underlying reproductive isolation and species divergence [11].
In the last twenty years, Simple Sequence Repeat markers (SSR) have been the most common tool for a variety of applications in molecular biology, from genome mapping to population and ecological genetics, due to their codominant mode of heredity and their highly polymorphic nature [12, 13]. SSR markers are commonly developed to investigate genetic variation within particular species [e.g. 14, 15]. However, SSR markers can be also transferable between closely related species when genomic resources are not available for de novo development [e.g. 16, 17].
To date, the development of molecular tools for population studies in Linum has been mostly restricted to the cultivated flax L. usitatissimum [18,19,20], meaning a lack of suitable molecular resources for studying the evolutionary ecology of several wild Linum species. Here, we characterize 12 new polymorphic microsatellite loci for L. suffruticosum and their transferability to L. tenuifolium in seven wild populations of each species. These markers will be useful for future research on the genetics, mating patterns as well as potential natural hybridization within and between sister species in their contact zone.
Materials and methods
Identification of candidate SSR loci and primer design
Genomic DNA was extracted from two individuals of L. suffruticosum sampled in a natural population (Prat d’Aguiló, Lleida, Spain; 42.34301, 1.71806) with Invisorb® Spin Plant Mini Kit. DNA was conveyed to Ecogenics GmbH (Schlieren-Zürich, Switzerland, https://www.ecogenics.ch) for the development of a library of suitable SSR candidates and primer design. The Illumina TruSeq Nano library was analyzed on an Illumina MiSeq sequencing platform with a nano v2 500 cycles sequencing chip. The chastity-filtered paired-end reads were subject to de-multiplexing and trimming of Illumina adapter sequences. Subsequently, the quality of the reads was checked with FastQC v0.117 software [21]. Afterwards, the paired-end reads were merged with the software USEARCH v10.0.240 [22]. The 99,943 merged reads were screened with the software Tandem Repeats Finder, v4.09 [23]. After this process, 5704 merged reads contained a microsatellite insert with a tetra- or a trinucleotide of at least six repeat units or a dinucleotide of at least ten repeat units. Primer design was performed with default parameters in Primer3 [24], resulting in 4243 microsatellite candidates.
Primer testing and polymorphism assessment
A total of 302 individuals, from seven populations of each L. suffruticosum and L. tenuifolium distributed in their contact zone, were used for primer testing and polymorphism assessment (Online Appendix 1). Leaf tissue was collected from individuals separated at least 1 m from each other and preserved in silica gel. Vegetative reproduction is negligible or very limited in L. tenuifolium and L. suffruticosum, respectively. Some of the population sites were pure and other were mixed, containing both species that are clearly distinguishable (Fig. 1 and Online Appendix 1). Linum tenuifolium has been described as a diploid species throughout its range and, although L. suffruticosum is a polyploid complex, all populations screened were diploid [25].
We randomly selected 60 microsatellites to test their amplification in 2–4 individuals from each species and population (96 individuals in total). Genomic DNA was extracted with ISOLATE II Plant DNA Kit (Bioline). PCR amplifications were conducted using 20 µL of master mix that included: 1x MyTaq Red Reaction Buffer (Bioline), 0.4 μm of each forward and reverse primers, 0.01% bovine serum albumin (BSA, Promega), 0.5 u MyTaqTM Red DNA Polymerase (Bioline), 50–70 ng gDNA and deionized water up to 20 µL. A touchdown procedure was performed for all loci with initial denaturation for 2 min at 94 °C; followed by 10 cycles of 92 °C for 30 s, 30 s at 63 °C with an increment of − 1 °C per cycle, and 30 s at 72 °C; followed by 20 cycles of 94 °C for 30 s, 30 s at 56 °C, and 30 s at 72 °C; and an extra extension of 5 min at 72 °C. The amplification of PCR products was assessed in 2% agarose gels. Twelve markers that amplified well in both species (Table 1) were selected for polymorphism assessment.
Forward primers were labelled with either 6-FAM, VIC, NED or PET fluorescent labels for fragment analyses on 18–24 individuals from each species and population (302 individuals in total; Online Appendix 1). DNA extractions and PCR reactions were performed with the same protocol as for primer testing. PCR products were analysed on an automatic ABI 3730 capillary DNA sequencer (Sequencing Service, University of Dundee, UK), using a GeneScan 500 LIZ internal size standard. Allele binning and calling were performed in Geneious (Biomatters).
For each locus and population, the number of alleles per locus (A), observed heterozygosity (HO) and expected heterozygosity (HE) were calculated with the popgenreport function of R package PopGenReport [26]. The deviation from Hardy-Weinberg equilibrium for each locus was tested using the function mk.hw. The presence of null alleles was tested with the function null, following the methods of Brookfield [27] and Chakraborty et al. [28].
Results and discussion
In this study, we characterized 12 SSR markers for Linum suffruticosum based on a genomic library developed with new generation sequencing, and tested their transferability to the sister species L. tenuifolium. The 12 SSR markers amplified and showed high levels of polymorphism in the seven populations tested for each evaluated species. All microsatellite regions were deposited in NCBI Genbank (Table 1).
In L. suffruticosum, the number of alleles per locus per population (A) ranged from 2 to 16, with a mean of 6.7; the observed heterozygosity (HO) ranged from 0.09 to 1, with a mean of 0.83; and the expected heterozygosity (HE) ranged from 0.45 to 0.9, with a mean of 0.69 (Table 2). In each population, four to nine loci deviated significantly from Hardy–Weinberg equilibrium after Bonferroni correction, and two to four loci showed presence of null alleles (Table 2). In L. tenuifolium, the number of alleles per locus per population (A) ranged from 2 to 10, with a mean of 5.1; the observed heterozygosity (HO) ranged from 0 to 1, with a mean of 0.77; and the expected heterozygosity (HE) ranged from 0.05 to 0.88, with a mean of 0.62 (Table 3). In each population, five to twelve loci deviated significantly from Hardy–Weinberg equilibrium after Bonferroni correction, and two to four loci showed presence of null alleles (Table 3). We found high levels of genetic diversity and significant deviations from Hardy–Weinberg equilibrium. These are congruent with the inherent outcrossing of the three-dimensional heterostylous L. suffruticosum, as well as with the potential hybridization between the two taxa in the analysed populations.
These SSR markers will be a useful tool to investigate the mating patterns within and between L. suffruticosum and L. tenuifolium in their contact zone, and patterns of gene flow and spatial genetic structuring among and within pure and mixed populations. The genus Linum has been the object of renewed attention for the study of heterostyly, from macroevolutionary patterns [5, 6] to finer scale processes within or across Linum species and populations [2, 29], and polyploidy [25, Valdés et al., under review]. Given the full transferability success shown, these SSR markers could potentially be applied to other Linum species for studies of ecological genetics.
Data availability
The selected SSR sequences are publicly available on GeneBank under the corresponding accession codes in Table 1.
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Acknowledgements
The authors thank Benjamin Laenen and Jörg Bachmann for support with experimental work at DEEP and SciLifeLab during EOV stay at Stockholm University.
Funding
Open access funding provided by Stockholm University. This project has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement No 757451, ERC starting grant to TS). The research was funded by the Spanish Ministry of Science of Innovation (CGL2013-45037-P, PGC2018 099608 B 100 and PID2021-122715NB-I00 to JA). This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 897890 FLAXMaTE to VISP. EOV was supported by a full graduate fellowship (Consejo de Ciencia y Tecnología CONACYT-México CVU-363401) and short-stay fellowships (ERASMUS PLUS and University of Seville “Plan Propio de Investigación”).
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Olmedo-Vicente, E., Désamoré, A., Simón-Porcar, V.I. et al. Development of microsatellite markers for sister species Linum suffruticosum and Linum tenuifolium in their overlapping ranges. Mol Biol Rep 50, 7927–7933 (2023). https://doi.org/10.1007/s11033-023-08471-9
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DOI: https://doi.org/10.1007/s11033-023-08471-9