The African tree Guibourtia tessmannii (Harms) J. Léonard (Fabaceae, Caesalpinioideae) is a hermaphrodite rainforest species distributed from Cameroon to Gabon (Fougère-Danezan et al., 2007; Tosso et al., 2015). Known as “bubinga” or “kevazingo,” it has high commercial and social value but is under significant threat due to illegal logging. The genus Guibourtia Benn. includes 13 African species distributed from Senegal to Mozambique in forest or savannah habitats. The genus was divided by Léonard (1949) into three main subgenera: (i) Pseudocopaiva: G. tessmannii, G. pellegriniana J. Léonard, G. coleosperma (Benth.) J. Léonard, G. leonensis J. Léonard; (ii) Guibourtia: G. carrissoana (M. A. Exell) J. Léonard, G. copallifera Benn., G. demeusei (Harms) J. Léonard, G. sousae J. Léonard; and (iii) Gorskia: G. arnoldiana (De Wild. & T. Durand) J. Léonard, G. conjugata (Bolle) J. Léonard, G. dinklagei (Harms) J. Léonard, G. ehie (A. Chev.) J. Léonard, G. schliebenii (Harms) J. Léonard. We developed polymorphic microsatellite markers for G. tessmannii and tested them on nine African congeneric species to verify species delimitation and document population genetic structure and gene flow patterns. Because microsatellite typing suggested that some species were polyploid, we used flow cytometry to compare the ploidy levels of two related species for which appropriate fresh material was available.
METHODS AND RESULTS
Microsatellite development—We extracted total DNA from 30 mg of dry leaf of G. tessmannii (FT0001; Appendix 1) using a cetyltrimethylammonium bromide (CTAB) method (Fu et al., 2005). We prepared a nonenriched DNA genomic library, following Mariac et al. (2014), and generated 150-bp-long paired-end reads on an Illumina MiSeq platform (San Diego, California, USA). We assembled the resulting 78,279 reads by pair with PANDAseq (Masella et al., 2012). Using the software QDD (Meglécz et al., 2014), we detected 2483 microsatellite loci. Of these, 149 had at least eight repeats and flanking regions appropriate to define pairs of PCR primers. We developed primers for 48 loci with at least eight di-, tri-, or tetranucleotide repeats and primer regions at least 20 bp distant from the microsatellite region. We added one of four possible linkers (Q1–Q4; Micheneau et al., 2011) to the 5′ end of the forward primer of each locus to label PCR products with fluorochromes FAM, NED, VIC, and PET (Table 1).
We tested 48 primer pairs using two samples of G. tessmannii (FT0002 and FT0003 ; Appendix 1). PCR reactions (total volume of 15 µL) used 1.5 µL of buffer (10×), 0.6 µL MgCl2 (25 mM), 0.45 µL dNTPs (10 mM each), 0.3 µL of each primer (0.2 µM), 0.08 µL TopTaq DNA Polymerase (5 U/µL; QIAGEN, Venlo, The Netherlands), 1.5 µL of Coral Load, 1 µL of template DNA (of ca. 10– 50 ng/µL), and 9.27 µL of water. PCR conditions were: 94°C (4 min); 30 cycles of 94°C (30 s), 55°C (45 s), and 72°C (1 min); and a final extension at 72°C (10 min). We visualized PCR products stained with SYBR Safe (Invitrogen, Merelbeke, Belgium) on a 1% agarose gel. Forty-two loci amplified consistently.
We assessed polymorphism on seven G. tessmannii individuals from Cameroon and Gabon (Appendix 1). We used fluorescent labeling by PCR amplification in a total volume of 15 µL, combining 0.15 µL of the reverse and 0.1 µL of the forward (0.2 µM for both) microsatellite primers, 0.15 µL of Q1–Q4 labeled primers (0.2 µM each), 3 µL of Type-it Microsatellite PCR Kit (QIAGEN), H2O, and 1 µL of DNA. PCR conditions were: 5-min initial denaturation at 95°C; followed by 30 cycles of (95°C for 30 s, 60°C for 90 s, 72°C for 1 min) and 10 cycles of (95°C for 30s, 55°C for 45 s, 72°C for 60 s, 72°C for 1 min); and a final elongation step at 60°C for 30 min. We mixed 1.1 µL of each PCR product with 12 µL of Hi-Di Formamide (Life Technologies, Carlsbad, California, USA) and 0.3 µL of MapMarker 500 labeled with DY-632 (Eurogentec, Seraing, Belgium). The preparation was genotyped on an ABI3730 sequencer (Applied Biosystems, Lennik, The Netherlands).
Table 1.
Characterization of 16 polymorphic and one monomorphic nuclear microsatellite loci isolated from Guibourtia tessmannii.
After excluding loci that did not amplify consistently or were unreadable, we combined 16 polymorphic loci (one locus [R12-Seq43] was monomorphic) in four multiplexed reactions (Table 1) using Multiplex Manager 1.0 software (Holleley and Geerts, 2009). Preliminary population genetic analyses were performed on three populations of G. tessmannii (35–58 individuals per population; Table 2 and Appendix 1). Multiplexed PCRs were as above except that 3 µL of the 5× Q-solution of the Type-it Microsatellite PCR Kit was added. The individuals of G. tessmannii studied revealed a high degree of polymorphism, with more than two alleles per individual, suggesting a polyploid genome (Table 2).
Microsatellite marker data analysis in G. tessmannii and G. coleosperma— The three populations of G. tessmannii (Table 2 and Appendix 1) had three to 14 alleles per locus (mean 8.94 alleles per locus, Table 2). Single-locus genotypes had one to eight alleles (2.35 ± 0.94 alleles per locus) and no fixed heterozygosity, suggesting an autopolyploid.
For G. coleosperma, the diploid species in which cross-amplification was the most successful (see below), we considered two populations (Table 2). For each of the 10 amplifıable loci, we calculated allele size range, number of alleles (A) per locus, observed (Ho) and expected (He) heterozygosity, inbreeding coefficient (F), and null allele frequency (r) with INEst 1.0 (Chybicki and Burczyk, 2009). Deviation from Hardy—Weinberg equilibrium (HWE) was tested for each locus with SPAGeDi (Hardy and Vekemans, 2002). Loci exhibited one to 14 alleles (mean 4.5) with Ho (mean ± SE) of 0.28 ± 0.09 and He of 0.41 ± 0.11 for the Democratic Republic of Congo (DRC) population and one to 10 alleles (mean 3.67) with Ho of 0.17 ± 0.05 and He of 0.36 ± 0.10 for the Namibia population. Significant deviation from HWE was observed in at least one population for four primer pairs. Loci R12-Seq20 and R12-Seq22 for the DRC population exhibited a significant deficit of heterozygotes due to the presence of null alleles (Table 2).
Flow cytometry—We used flow cytometry to confirm the ploidy level of G. tessmannii and compare its genome size with G. coleosperma. We used fresh material from seeds collected in central Gabon (G. tessmannii) and northern Namibia (G. coleosperma) (Appendix 1). From 1 cm2 pieces of fresh leaves, we obtained suspensions of leaf cell nuclei by chopping them in a buffer solution using the CyStain UV Precise P Kit (Partec GmbH, Münster, Germany) with DAPI (4′,6-diamidino-2-phenylindole, dilactate). We ran samples with Ploidy Analyser equipment (Partee GmbH). We used tomato as an internal standard (Solanum lycopersicum L. “Montfavet 63-5″ [2C = 1.99 pg, 40.0% GC; Marie and Brown, 1993]). Under the assumption that the GC content of our samples and the standard were similar, the genome size of G. coleosperma ranged from 3.20 to 3.70 pg (N = 3) and G. tessmannii from 11.87 to 15.78 pg (N = 3). Although these estimates should be considered with caution in the absence of information on the GC content, the genome size of G. tessmannii is nearly four times larger than that of G. coleosperma. Because the latter species displays microsatellite profiles typical of diploids, the flow cytometry results confirm that G. tessmannii is an octoploid species.
Table 2.
Results of initial primer screening of 17 nuclear microsatellite loci developed in Guibourtia tessmannii (three populations) and 10 that cross-amplified in G. coleosperma (two populations).
Cross-amplification in congeneric species and ploidy determination— Among the 17 loci selected from G. tessmannii, a majority successfully amplified in two other species from the subgenus Pseudocopaiva (Table 3). Less than six loci amplified in the other species, most of which belong to other subgenera (Table 3). In G. pellegriniana, all loci were polymorphic and the genotypes showed up to eight alleles per individual and locus, suggesting an octoploid genome. By contrast, in the other species individuals did not display more than two alleles per locus, suggesting diploid genomes.
CONCLUSIONS
We developed 16 polymorphic microsatellite markers in G. tessmannii that amplified to varying degrees in nine congeneric species. The microsatellites and flow cytometry results showed for the first time that the genus Guibourtia includes diploid and polyploid species. These markers will be useful to assess the mating system and genetic structure of Guibourtia species.
Table 3.
Results of cross-amplification (allele size ranges) of microsatellite loci isolated from Guibourtia tessmannii and tested in nine additional taxa.
ACKNOWLEDGMENTS
The authors thank the Fonds pour la Formation à la Recherche dans l'Industrie et l'Agriculture (FRIA, Belgium), the Fonds de la Recherche Scientifique (F.R.S.-FNRS, grant T.0163.13), and Belgian Science Policy (project AFRIFORD) for financial support. They also acknowledge CEB Precious Woods, Wijma Cameroun SA, and Centre national de la recherche scientifique et technologique (CENAREST) for technical and logistical support during sampling, and Bérengère Doucet, Toussaint Abessolo, and Sonja Siljak-Yakovlev for their help.