Taxon sampling

We sampled 23 out of the 29 genera assigned to Plumbaginaceae in the latest classification by Hernández‐Ledesma et al. (; Table ); the genera were represented by a variable number of samples (see below). Three monospecific genera and three oligospecific genera (with two or three species) were not sampled, because herbarium specimens are rare, and hence difficult to acquire and sample. For Limonium, the most species‐rich genus of Plumbaginaceae and the focus of this study, sampling was designed to cover its taxonomic and geographic diversity. Two hundred and three taxa (representing 201 species, one subspecies and three varieties) were sampled, including representatives from all sections and subsections described by Boissier () and later authors (see Table ), and spanning the full geographic breadth of this cosmopolitan genus (Table S1). The exact percentage of sampled Limonium species per section cannot be provided due to the plethora of unclassified species (e.g., see Table S2). Additionally, 64 species of Plumbaginaceae genera other than Limonium, representing the subfamilies Plumbaginoideae and Limonioideae, were included in the study (Table ). Finally, 20 species from the sister family Polygonaceae (APG IV, ) were used as outgroups to reach a total sampling of 287 taxa.

Plant material was obtained from many different sources (Data S1). First, fieldwork was conducted in Greece, Turkey, Spain, Portugal, and Macaronesia, where many Limonium species were collected, as well as one species of Myriolimon Lledó, Erben & M.B.Crespo. Fresh leaves were stored in silica gel and/or press‐dried as part of herbarium specimens. Second, a large number of dried leaf samples were requested and acquired from collections of several herbaria (ATH, AZB, E, L, LISC, ORT, P, U, UPA, WAG, Z, ZT). Third, fresh material for several Plumbaginaceae species was obtained from living collections of Botanical Gardens, especially from the Botanical Garden of the University of Zurich. In the latter, some Plumbaginaceae species were grown from seeds obtained through the exchange program of seed collections among botanical gardens. Fourth, DNA samples were provided by the Plant DNA Bank of Kew Gardens. Finally, 60 taxa with published DNA sequences were added to complement our sampling.

Molecular sampling

The chloroplast trnL‐F region (i.e., the trnL intron, the 3’ trnL exon, and the trnL‐trnF spacer), rbcL and matK genes, and the nuclear ITS region (i.e., the internal transcribed spacer 1, 5.8S rRNA gene, and the internal transcribed spacer 2) compose the genetic dataset in this study. The choice of genetic loci was informed by the availability of pre‐existing sequences for genetic markers generated in previous Plumbaginaceae and Limonium studies (e.g., Lledó et al., ; Lledó et al., ; Lledó et al., ; Lledó, Crespo, et al., ; Palacios et al., ; Ding, Zhang, Yu, Zhao, & Zhang, ; Akhani et al., ; Moharrek, Osaloo, & Assadi, ) and by a pilot study that we conducted on 12 Plumbaginaceae taxa (ten Limonium taxa: three of L. subg. Pteroclados and seven of L. subg. Limonium, following the subgeneric division by Lledó, Crespo, et al., ), and two taxa from other Plumbaginaceae genera: one for each of the two subfamilies). In the pilot study, in addition to rbcL, trnL‐F, and ITS regions used frequently in existing Plumbaginaceae phylogenies, we also explored the adequacy of some DNA barcoding regions for plants (accD, matK, ndhJ, rpoB, rpoC1) proposed by Ford et al. (). We found that the short coding regions of accD, ndhJ, rpoB, and rpoC1 had very few variable sites and provided little phylogenetic resolution. Phylogenies were better resolved when using rbcL, matK, trnL‐F and ITS regions, especially in combination. Thus, the selected sampling scheme of this study complements, significantly expands both taxon and gene sampling for Plumbaginaceae and Limonium in particular, with regard to previous global Plumbaginaceae/Limonium datasets (Lledó, Crespo, et al., ; Malekmohammadi et al., ; Table ), and provides sufficient resolution at the taxonomic level of interest (primarily among genera of Plumbaginaceae and sections of Limonium).

DNA extraction, amplification, and sequencing

Prior to DNA isolation, dried leaves were ground into a fine powder using metal beads and a Mixer Mill MM301 (Retsch GmbH, Haan, Germany). DNA was extracted using a modified cetyltrimethylammonium bromide (CTAB) method (Doyle & Doyle ; Data S2) and visualized in a 1% agarose gel. As expected, DNA samples from old herbarium specimens were generally more degraded than those from recently collected leaf material, which gave higher molecular weight DNA. In order to overcome problems with PCR amplification of entire loci when DNA samples of relatively low quality were used as template (e.g., degraded DNA from old herbarium specimens), we attempted to amplify some loci in two partially overlapping fragments. For this, we used two primer pairs, each pair composed of a primer hybridizing at the 5’ or 3’ end of the locus and one hybridizing within the locus (“internal” primer). For the trnL‐F region, we used primers c and f and the internal primers d and e (Taberlet, Gielly, Pautou, & Bouvet, ), and for the rbcL gene, we used primers 1F and 1368R and the internal primers 636F and 724R (Lledó et al., ). The matK gene was amplified with either matK X and matK 5 primer pair (Ford et al., ) or 390F and CAR_R primers (Cuénoud et al., ; Dunning & Savolainen, ). For the ITS region, we primarily used ITS5 and ITS4 primers (White, Bruns, Lee, & Taylor, ), but due to problems of fungal contaminations for some samples, we additionally used the recently developed primers ITS‐p5 and ITS‐u4 and the internal primers ITS‐p3 and ITS‐u2 (Cheng et al., ). Each PCR was performed in a final volume of 20 μl, containing 12 μl of ddH₂O, 4 μl of Taq‐Buffer (5×, 7.5 mM MgCl₂), 0.2 μl of Taq‐Polymerase (5 U/μl), 0.8 μl of dNTPs (10 mM), 1 μl of each primer (10 μM), and 1 μl of DNA template. For the trnL‐F region, we additionally used 1 μl DMSO (5%), and for rbcL and matK, 1.2 μl MgCl₂ (~0.025 M). The volume of any additional reagent was subtracted from ddH₂O. The PCR amplification program for trnL‐F and rbcL had a first denaturation step of 5 min at 95°C and 35 cycles of: 1 min at 94°C, 1 min at 53°C, and 2 min at 72°C. For matK, there was an initial denaturation of 4 min at 95°C followed by 35 cycles of: 1 min at 94°C, 1 min at 52°C, and 1.5 min at 72°C. For the ITS amplification using the primers ITS5 and ITS4, we used a program of 1 min at 94°C and 40 cycles of: 30 s at 94°C, 40 s at 53°C, and 40 s at 72°C, whereas for primers ITS‐p5 and ITS‐u4, we used a program of 4 min at 94°C followed by 34 cycles of: 30 s at 94°C, 40 s at 55°C, and 1 min at 72°C. All PCR protocols included a final extension step of 10 min at 72°C. The purification of successfully amplified PCR products was performed using Exonuclease I (ExoI) and FastAP Thermosensitive Alkaline Phosphatase (FastAP) (Thermo Scientific, Waltham, USA). For cycle sequencing, BigDye Terminator Mix (Applied Biosystems, Inc., Foster City, California, USA) and the same primers listed above were used, and the PCR program consisted of 25 cycles of 10 s at 96°C, 5 s at 50°C, and 4 min at 60°C. Finally, ABI 3100 Genetic Analyzer (Applied Biosystems, Foster City, California, USA) was used to obtain both forward and reverse sequences for each PCR product of the four loci under study.

Data analysis and phylogenetic inference

Forward and reverse complement strands of sequences were assembled and edited with Sequencher v.5.0.1 (Gene Codes Corp., Ann Arbor, Michigan, USA), resulting in reliable consensus sequences. These sequences were compared with the public sequence database using the BLASTn‐NCBI in order to verify their identity and check for any contamination. Sequences were aligned with MAFFT v.7 (Katoh & Standley, ) and default parameters (“Auto”) for rbcL, matK, and ITS, and with the progressive method “G‐INS‐1” for trnL‐F dataset. All alignments were checked and edited manually in BioEdit v.5.0.6 (Hall, ). In addition, we used the Recombination Detection Program (RDPv.4; Martin, Murrell, Golden, Khoosal, & Muhire, ) to check for recombination in the aligned ITS sequences of Limonium, which could affect phylogenetic reconstruction and account for potential incongruences between chloroplast and nuclear markers; recombination was not detected in our dataset.

Datasets for the three chloroplast loci and one nuclear locus including newly generated and pre‐existing sequences were initially analyzed separately. Phylogenies were inferred for each of the four datasets using the maximum likelihood (ML) criterion as implemented in RAxML v.8.2.9 (Stamatakis, ). We carried out 40 ML searches using a different maximum parsimony starting tree each time, used a generalized time‐reversible model of nucleotide substitution with gamma‐distributed rates across sites (GTR +Γ, Tavaré, ; Yang, ), and performed a rapid bootstrap analysis with 1,000 replicates. The bootstrap replicate trees were then used to draw bipartition information (i.e., confidence values) on the best ML tree found among the 40 independent ML searches. Gene trees from the three chloroplast markers were inspected for conflicting relationships; in the absence of any well‐supported incongruence (i.e., bootstrap values (bs) ≥ 80%), the three datasets were combined for further analyses (hereafter, cpDNA dataset). ML analysis of the cpDNA dataset was done by partitioning the dataset per locus (trnL‐F, rbcL, and matK) and assigning a GTR +Γ model to each of the three partitions. We additionally conducted 40 ML searches and an analysis of 1,000 rapid bootstrap replicates to infer the cpDNA tree.

Furthermore, cpDNA and ITS datasets were analyzed using Bayesian MCMC inference (BI; Yang & Rannala, ) in MrBayes v.3.2.6 (Ronquist et al., ). For each dataset, we performed two independent runs with four chains (one cold and three incrementally heated). Chains were run for 10,000,000 generations each, while parameters and trees were sampled every 5,000th generation. In order to account for uncertainty of DNA substitution model, we employed a model‐averaging approach using a reversible‐jump MCMC algorithm (rjMCMC; Huelsenbeck, Larget, & Alfaro, ) that allows the chain to explore all the possible models of the GTR family (203 models). The number of times that a chain visits a model is relative to its marginal probability. It has been shown that this method results in less biased estimates for the parameters sampled during the MCMC, including tree topology and clade posterior probabilities (Alfaro & Huelsenbeck, ). This rjMCMC algorithm +Γ distributed rates (MrBayes command: “lset nst=mixed rates=gamma”) was assigned to ITS and to every partition (i.e., locus) in the cpDNA dataset. MCMC diagnostics for the independent and combined runs (e.g., convergence of parameter estimates and effective sample sizes >200) were assessed using Tracer v.1.5 (Rambaut & Drummond, ). The two runs of each analysis were then combined discarding the initial 25% of the sampled parameters and trees as burn‐in. The resulting BI and ML trees of the cpDNA and ITS datasets were compared to detect potential incongruences between well‐supported clades, which are here defined as: (a) clades with both high posterior probability (pp) and bootstrap values (i.e., pp ≥ 0.95 and bs ≥ 80%) and (b) clades with either one of those values high and the other moderate (i.e., pp ≥ 0.95 and bs = 70%–79%; or bs ≥ 80% and pp = 0.85–0.94).

We also employed a total evidence approach by combining sequences of all four loci into a single supermatrix. Well‐supported topological conflicts between the chloroplast and nuclear datasets were relatively few and usually at a phylogenetic scale shallower (i.e., toward the tips of the tree) than the desired level of phylogenetic inference (i.e., corresponding to the level of intergeneric relationships for Plumbaginaceae and intersectional relationships for Limonium). Therefore, a total evidence approach was appropriate to resolve phylogenetic relationships at the level of investigation. However, where necessary, the inferred phylogenetic relationships are presented and discussed separately in cases of well‐supported phylogenetic conflicts between cpDNA and nuclear ITS signals (see below “Mediterranean lineage”). Both ML and BI analyses were conducted on a reduced supermatrix that excluded six “rogue taxa” (i.e., taxa in different well‐supported clades of the cpDNA and ITS phylogenies; see Results). This was done in order to facilitate analyses and recover the monophyly of clades previously containing the “rogue taxa.” In ML analysis of the reduced supermatrix, we used a GTR +Γ model for every locus (four partitions) and conducted 40 ML inferences and 1,000 rapid bootstrap searches. For the BI on the same dataset and partitioning for every locus, rjMCMC algorithm was used for model averaging +Γ and two independent runs of 10,000,000 iterations were employed. All trees were visualized and rooted using FigTree v.1.4.2 (Rambaut, ), Dendroscope v.3.5.9 (Huson & Scornavacca, ), and Archaeopteryx 0.9921 (Han & Zmasek, ) in order to verify the correct assignment of support values on the nodes after rooting, as suggested by Czech, Huerta‐Cepas, and Stamatakis ().

Genetic datasets and phylogenetic analyses

Six hundred and ninety‐four sequences were generated for this study of Plumbaginaceae, comprising 189 new trnL‐F sequences (GenBank: MH560967–MH561155), 172 new rbcL sequences (GenBank: MH582667–MH582838), 179 new matK sequences (GenBank: MH582839–MH583017), and 154 new ITS sequences (GenBank: MH582513–MH582666; see also Data S3). Additionally, 270 pre‐existing sequences were retrieved from GenBank or provided to us by the authors of Lledó, Crespo, et al. (; Data S3). For some taxa, problems in amplification and sequencing resulted in either the complete absence of some sequences or the generation of only a part of the full sequences (for trnL‐F, rbcL, and ITS, where internal primers were available). Information about data matrices of individual and combined loci can be found in Table . The ITS region exhibits the highest amount of potentially informative characters (56%), followed by matK (34%), trnL‐F (28%), and rbcL (18%). The cpDNA dataset and the reduced supermatrix contained 26% and 32% potentially informative characters, respectively.

For each dataset, phylogenies produced with ML and BI methods showed very similar topologies, with moderate (pp = 0.85–0.94 for BI and bs = 70%–79% for ML) and strongly supported nodes (pp ≥ 0.95 for BI and bs ≥ 80% for ML) being largely identical. We present the Bayesian 50% majority‐rule trees in all figures with posterior probabilities and bootstrap support values noted at the nodes. The chloroplast (cpDNA) and nuclear (ITS) phylogenetic trees were generally similar, while some topological differences were mostly found between non‐supported nodes and only a few exceptions of well‐supported incongruences were observed (see below). The ITS Bayesian tree showed better resolution (146 out of 237 nodes resolved in the 50% majority‐rule tree; Figure S1) compared to the cpDNA tree (132 out of 280 nodes resolved; Figure S2), in accordance with the higher number of informative characters in the nuclear dataset (Table ). The tree based on the reduced supermatrix exhibited highest resolution with 166 out of 280 nodes resolved in the 50% majority‐rule Bayesian tree. Thus, phylogenetic relationships are presented and discussed based on the tree from the reduced supermatrix dataset, except for the “Mediterranean lineage” of Limonium, where both cpDNA and ITS phylogenies are presented to account for well‐supported topological discrepancies between the two datasets.

Phylogeny of Plumbaginaceae

The Plumbaginaceae are divided into the two monophyletic subfamilies Plumbaginoideae (pp = 1, bs = 100%) and Limonioideae (pp = 1, bs = 100%; Figure ). In Plumbaginoideae, both Ceratostigma Bunge and Dyerophytum Kuntze are monophyletic (pp = 1, bs = 100%), whereas Plumbago is not. Specifically, Plumbago europaea L. is sister to Plumbagella (pp = 1, bs = 100%), while other Plumbago species form a sister clade to Dyerophytum (pp = 1, bs = 100%). Plumbago, Plumbagella, and Dyerophytum form a clade (pp = 1, bs = 99%) sister to Ceratostigma (Figure ).

In Limonioideae, Aegialitis (tribe Aegialitideae) is sister to a well‐supported clade (pp = 1, bs = 100%) consisting of genera of the tribe Limonieae (Figure ). In this clade, Armeria, Limoniastrum Fabr., Ceratolimon M.B.Crespo & M.D.Lledó, Psylliostachys (Jaub. & Spach) Nevski and Limonium are monophyletic, whereas Acantholimon and Goniolimon Boiss. are not. Limonieae consist of four mostly well‐supported major clades (see clades I–IV; Figure ), forming a tetratomy (sister relationship of clades II and III is not well‐supported, bs < 50% and pp = 0.83; Figure ). In clade IV, Armeria (pp = 1, bs = 100%) is sister to Psylliostachys (pp = 1, bs = 100%) and together they are sister to a clade (pp = 1, bs = 100%) comprised of Saharanthus, Myriolimon, Bakerolimon, and Muellerolimon. In clade III, Ceratolimon and Limoniastrum are reciprocally monophyletic sister lineages (pp = 1, bs = 100%). In clade II, Goniolimon as currently circumscribed is paraphyletic, with Ikonnikovia nested in it. Goniolimon and Ikonnikovia (pp = 1, bs = 100%) are sister to a clade formed by Acantholimon, Vassilczenkoa, Cephalorhizum, Popoviolimon, Dictyolimon, and Buckiniczia (pp = 1, bs = 100%). There are two monophyletic groups of Acantholimon species (pp = 1, bs = 92% and pp = 1, bs = 97%, respectively): One is part of a well‐supported clade (pp = 1, bs = 98%) sister to a clade comprised of Dictyolimon and Bukiniczia (pp = 1, bs = 100%), and the other forms part of a moderately to poorly supported clade (pp = 0.92 and bs = 57%, respectively) that also contains the sister genera Cephalorhizum and Popoviolimon (pp = 0.98, bs = 93%; Figure ).

Phylogeny of Limonium

Limonium forms a strongly supported clade (pp = 1, bs = 98%; clade I in Figure ) with the species previously assigned to Afrolimon, now L. sect. Circinaria (Boiss.) M.Malekm., nested in it (Figure ). Limonium is divided into two major clades (A and B; Figure ). In clade A, L. sect. Pteroclados (Boiss.) Bokhari (= L. subg. Pteroclados sensu Lledó, Crespo, et al., ) is sister to L. anthericoides (Schltr.) R.A.Dyer (pp = 1, bs = 100%), and divided into the two reciprocally monophyletic subsections, L. sect. Pteroclados subsect. Odontolepideae and subsect. Nobiles sensu Boissier (; pp = 1, bs = 100% and pp = 1, bs = 85%, respectively). In clade B, the monotypic L. sect. Limoniodendron Svent. (L. dendroides Svent.; subclade B1) is sister to two well‐supported subclades (B2: pp = 1, bs = 90% and B3: pp = 1, bs = 100%; Figure ). Clade B2 consists of taxa assigned to L. sect. Sarcophyllum, L. sect. Nephrophyllum Rech.f., L. sect. Limonium, L. sect. Plathymenium (Boiss.) Lincz., L. sect. Siphonocalyx Lincz., L. sect. Ctenostachys (Boiss.) Sauvage & Vindt, L. sect. Jovibarba sensu Boissier (), L. sect. Circinaria, L. sect. Iranolimon and L. sect. Sphaerostachys (Boiss.) Bokhari (Figure ). Clade B3 comprises taxa from L. sect. Polyarthrion (Boiss.) Sauvage & Vindt, L. sect. Siphonantha (Boiss.) Sauvage & Vindt, L. sect. Limonium and L. sect. Schizhymenium (Boiss.) Bokhari (Figure ).

At the sectional level, apart from the monotypic Limonium sect. Jovibarba, L. sect. Limoniodendron, L. sect. Schizhymenium and L. sect. Siphonantha, and the L. sect. Siphonocalyx represented here by only one species, the L. sect. Pteroclados, L. sect. Plathymenium, L. sect. Ctenostachys, L. sect. Circinaria, L. sect. Iranolimon, L. sect. Sphaerostachys, and L. sect. Polyarthrion (in the ITS tree; Figure ) are strongly supported as monophyletic (Figures and ). The remaining sections, namely L. sect. Sarcophyllum, L. sect. Nephrophyllum, and L. sect. Limonium are strongly supported as non‐monophyletic (Figures and ). It should be noted that slightly fewer than half of the Limonium taxa used in this phylogeny (72 out of 203 taxa) were not assigned to any subgenera, sections, and subsections by the authors who described them or later authors who studied the infrageneric classification of Limonium (see Table and Supporting information Table S1).

In clade B2 (Figure ), Limonium sect. Sarcophyllum sensu Linczevski () is polyphyletic with representatives in two separate and well‐supported clades (pp = 1, bs = 100%), one formed by L. cylindrifolium (Forssk.) Verdc. ex Cufod., L. axillare (Forssk.) Kuntze, L. somalorum (Vierh.) Hutch. & E.A.Bruce, L. stocksii (Boiss.) Kuntze and the unclassified L. sokotranum (Vierh.) Radcl.‐Sm., L. paulayanum (Vierh.) Ghaz. & J.R.Edm., L. sarcophyllum Ghaz. & J.R.Edm. and L. milleri Ghaz. & J.R.Edm., and the other formed by L. carnosum (Boiss.) Kuntze, L. iranicum (Bornm.) Lincz., L. suffruticosum (L.) Kuntze, L. anatolicum Hedge, and L. palmyrense (Post) Dinsm. The former clade is sister to a moderately to poorly supported clade (pp = 0.86 and bs = 62%, respectively) comprising all other Limonium taxa in clade B2, including the latter clade. This latter clade, which was recently assigned to the newly formed L. sect. Iranolimon, is part of a clade comprising L. sect. Circinaria, L. sect. Sphaerostachys, and L. sect. Limonium subsect. Genuinae sensu Boissier (; pp = 1, bs = 100%). Limonium sect. Plathymenium is monophyletic, but its subsections, L. subsect. Chrysanthae and L. subsect. Rhodanthae sensu Boissier (), are not. Limonium sect. Plathymenium is sister to a clade formed by species assigned to L. sect. Nephrophyllum and L. sect. Limonium subsect. Hyalolepideae sensu Boissier (), and these sister lineages together with L. sogdianum Ikonn.‐Gal. (L. sect. Siphonocalyx) form a well‐supported clade (pp = 0.98, bs = 79%). Limonium sect. Ctenostachys is monophyletic and sister to L. lobinii N.Kilian & Leyens, and the combined clade is sister to L. sect. Jovibarba; all together form a well‐supported clade (pp = 1, bs = 100%). In clade B3 (Figure ) of the ITS tree, L. sect. Polyarthrion is monophyletic and sister to a well‐supported clade comprising L. sect. Siphonantha and L. sect. Limonium subsect. Hyalolepideae/Pruinosae (pp = 0.98, bs = 80%), but these relationships are not corroborated by the cpDNA tree, which leaves the relationships of L. sect. Polyarthrion unresolved. In its currently accepted circumscription (Boissier, ), L. sect. Limonium is polyphyletic and, of its subsections, L. subsect. Genuinae is monophyletic (considering the latest classification for L. latifolium (Sm.) Kuntze; see Figure ), L. subsect. Pruinosae (Batt.) Sauvage & Vindt is well‐supported as monophyletic in the ITS tree, L. subsect. Hyalolepideae is clearly non‐monophyletic, with its representatives found in both clades B2 and B3, and L. subsect. Densiflorae, L. subsect. Dissitiflorae, and L. subsect. Steirocladae sensu Boissier () have their representatives in a large clade with many unsupported nodes consisting almost exclusively of Mediterranean endemic species on short branches (many of them are “microspecies”; Figure ). All three of L. subsect. Densiflorae, L. subsect. Dissitiflorae and L. subsect. Steirocladae are non‐monophyletic based on well‐supported nodes.

The cpDNA and ITS trees of the “Mediterranean lineage” (= clade B3; Figure ) show incongruences between some well‐supported clades (“rogue clades”). In the cpDNA phylogeny, North African/Iberian species (black bar) are included in the same clade with species from the Aegean region (orange bar) and this clade is sister to the clade comprising the rest of the Mediterranean species (blue bar). Conversely, in the ITS tree the North African/Iberian clade (black bar) is sister to a clade consisting of the Aegean species (orange bar) and the other Mediterranean species (blue bar). In addition, six species (“rogue taxa”; in bold letters in Figure ) show incongruences in their phylogenetic placement between strongly supported clades in trees from different organellar genomes, while another case of well‐supported conflict at a shallower phylogenetic level between sister species is noted with an asterisk in Figure (details in figure legend).

Subfamily Plumbaginoideae

The monophyly of Plumbaginaceae and the division of the family into two subfamilies, Plumbaginoideae and Limonioideae, are confirmed in this study and are in agreement with previous phylogenetic results based on more limited taxon and molecular sampling (Lledó et al., ). This is the first phylogenetic study to sample all four genera of Plumbaginoideae, including the monospecific Plumbagella. Here, Ceratostigma and Dyerophytum are clearly monophyletic, while Plumbago forms a non‐monophyletic assemblage (Figure ). Ceratostigma is characterized by non‐glandular, tubular, 5‐ribbed calyx, with 10‐nerved calyx base, and glabrous style (Kubitzki, ), while Dyerophytum is characterized by non‐glandular, segmented calyx, bearing sepals with strong midrib and reflexed, wide margins, and hairy style (Kubitzki, ). The polyphyly of Plumbago is confirmed in the current study, which includes six more species ascribed to Plumbaginoideae in addition to the four species of the same subfamily employed by Lledó et al. () and Lledó, Crespo, et al. (). Plumbago and Plumbagella have glandular calyces, which is a diagnostic trait, distinct for the family (Kubitzki, ). However, Plumbagella, which is the only annual herb of Plumbaginoideae, has calyces deeply divided into five lobes bearing glands and glabrous calyx tube (eFloras, ). According to our results, the circumscription of Plumbago is challenged and its generic boundaries should be either extended to accommodate Plumbagella and Dyerophytum or a new generic name should be assigned to the Plumbago clade that does not include the type for the genus (Plumbago europaea). A more comprehensive taxon sampling and a revision of diagnostic morphological characters for Plumbago are needed before a formal generic revision is proposed.

Our topology newly suggests a biogeographic disjunction between temperate and tropical/subtropical taxa. Specifically, Plumbago europaea and Plumbagella micrantha (Ledeb.) Spach, occurring predominantly in temperate regions of Eurasia, form a clade sister to the clade comprising the other Plumbago species and Dyerophytum (Figure ), which occur in tropical and subtropical regions of the Old (D. africanum (Lam.) Kuntze, D. indicum (Gibs. ex Wight) Kuntze, Plumbago indica L., Plumbago auriculata Lam. and Plumbago zeylanica L.) and New World (Plumbago caerulea Kunth and Plumbago zeylanica). All representatives of Plumbaginoideae occur in the Old World, apart from three out of ca. 20 species of Plumbago that occur in the New World. Based on our current sampling, the phylogenetic placement of the neotropical Plumbago zeylanica and Plumbago caerulea, embedded in a clade otherwise formed by paleotropical taxa, is consistent with a pattern of colonization of the New World from the Old World. More extensive sampling of Plumbago species from throughout the tropics is required to clarify the biogeographic history of the subfamily.

Subfamily Limonioideae

Limonioideae have a more complex taxonomic history than Plumbaginoideae, with many of the currently described genera originally assigned to the former genus Statice. Several new, small genera have been segregated primarily from the two most species‐rich genera (Limonium and Acantholimon). Here, we sampled 19 out of 25 genera for Limonioideae (Table ), expanding on previous molecular phylogenetic analyses (e.g., Lledó, Crespo, et al., ; Malekmohammadi et al., ; Moharrek et al., ) and further clarifying intergeneric boundaries and relationships in the subfamily. In our phylogeny (Figure ), Aegialitis (Aegialitideae) is sister to Limonieae, confirming the taxonomic subdivision of Limonioideae and previous phylogenetic results (Lledó et al., ; Lledó, Crespo, et al., ). Baker () proposed that Aegialitis represents an isolated, early divergent clade of Limonioideae, because it is characterized by morphological and chemical features typical of the subfamily (Boissier, ; Hanson et al., ; Harbone, ; Maury, ), but anatomical features intermediate between the two subfamilies (Maury, ) and breeding system similar to Plumbaginoideae (Plumbago‐type pollen and monomorphic stigma). In addition, Aegialitis is the only genus of Limonioideae with a fully tropical distribution, similar to the great majority of Plumbaginoideae. The placement of Aegialitis in our phylogeny as sister to the rest of Limonioideae supports Baker's () hypothesis described above.

In tribe Limonieae, our topology corroborates previous phylogenies (e.g., Lledó, Crespo, et al., ; Moharrek et al., ) in supporting the sister relationships of Armeria with Psylliostachys, Ceratolimon with Limoniastrum, and Goniolimon with a clade comprising Acantholimon and related genera (Figure ). Using nine species of Armeria and two species of Psylliostachys, we confirmed the reciprocal monophyly of these two sister genera (see also Lledó, Crespo, et al., ; Moharrek et al., ; Moharrek et al., ). Armeria and Psylliostachys share a unique morphological characteristic of the calyx (i.e., the rib‐like tissue of the calyx limb is not present along the calyx tube as it fuses at the limb base; Lledó et al., ), but the former comprises perennial herbs with a primarily Western Mediterranean distribution, while the latter consists of annual herbs with an Irano‐Turanian distribution. Our results also agree with Lledó, Crespo, et al. () findings in supporting the sister relationship of Armeria‐Psylliostachys clade with Myriolimon, Bakerolimon, and Saharanthus. However, while our dataset also placed the monospecific Muellerolimon in a well‐supported clade with Myriolimon, Bakerolimon, and Saharanthus, Lledó, Crespo, et al.'s () phylogeny placed it within a well‐supported clade comprising two species of Goniolimon. Our results are also corroborated by Malekmohammadi et al.’s () phylogenetic study. In the latter study, even though Goniolimon was not sampled, Muellerolimon was sister to Bakerolimon and Myriolimon in a clade sister to Psylliostachys (similar to our results) and distantly related to Acantholimon‐Popoviolimon, a clade representing the closest relative of Goniolimon. These findings suggest that the accession of Muellerolimon used by Lledó, Crespo, et al. () might have been misidentified and/or the sequences mislabeled, incorrectly placing it in the Goniolimon clade. The relatively close phylogenetic relationship of Muellerolimon and Bakerolimon (specifically Bakerolimon is sister to Muellerolimon and Saharanthus clade; Figure ) is consistent with Baker's () observations that these genera share distinctive pollen morphology and a shrubby habit with articulate, almost leafless (vestigial or absent leaves) stems; the same stem morphology is also present in Myriolimon (Lledó et al., ; Lledó, Erben, & Crespo, ). Taking into account the morphological features and distribution of Bakerolimon (in Chile and Peru) and Muellerolimon (in Western Australia), Baker () hypothesized that these genera are possibly divergent lineages (“remnants”) of an ancient stock of Limonioideae that colonized Western Australia from South America, or vice versa. Unlike Bakerolimon and Muellerolimon, Saharanthus and Myriolimon, also shrubby, occur in the Northern Hemisphere (northwestern Africa and Mediterranean, respectively).

The sister relationship of Ceratolimon and Limoniastrum and their reciprocal monophyly was originally presented by Lledó et al. () and is confirmed in the current study (clade III; Figure ). The morphological feature linking these two genera is the adnation of stamen filaments to the corolla up to its tube apex, a feature absent from all other Plumbaginaceae genera (Lledó et al., ). Ceratolimon species have rosulate leaves, spikelets with an entire to multifid outer bract, and a longer horned inner bract (middle bract absent), whereas Limoniastrum species have alternate leaves and spikelets with three smooth bracts (Crespo & Lledó, ; Lledó et al., ). Limoniastrum is distributed in coastal areas of the Mediterranean region (L. monopetalum (L.) Boiss.) and subdesert areas of northern Africa (L. guyonianum Durieu ex Boiss.), while Ceratolimon displays a disjunct distribution: C. migiurtinum (Chiov.) M.B.Crespo & M.D.Lledó in Somalia, Yemen and Saudi Arabia (Sudano‐Zambezian region) and its sister species C. weygandiorum (Maire & Wilczek) M.B.Crespo & M.D.Lledó and C. feei (Girard) M.B.Crespo & M.D.Lledó in Algeria, Morocco, Sahara and Mauritania (Saharan province, Saharo‐Arabian region; Crespo & Lledó, ).

In our study, the monospecific genus Ikonnikovia is embedded within Goniolimon in a well‐supported clade (Figure ). This result is not completely unexpected since Ikonnikovia kaufmanniana (Regel) Lincz. was previously assigned to Goniolimon (G. kaufmannianus (Regel) Voss.) and was later segregated by Linczevski () on the basis of morphological characteristics, such as style and ovary morphology (i.e., styles verrucose in the lower part and a narrowly linear cylindrical ovary very gradually transiting into the styles; Linczevski, ). However, some features link these two genera, and the combination of these features is diagnostic for Plumbaginaceae (i.e., distinguish Goniolimon and Ikonnikovia from the rest of Plumbaginaceae), namely styles not fused from the base (i.e., free) and non‐glabrous in the lower part (papillose or hairy), and capitate stigmata (Boissier, ; Siebert & Voss, ). Goniolimon, comprising 20 species, has a wide distribution from Italy to Mongolia, whereas Ikonnikovia is restricted to Central Asia (Kubitzki, ; Linczevski, ; Hassler, ). According to our phylogenetic results and the shared morphological characters between Ikonnikovia and Goniolimon, the status of Ikonnikovia as a separate genus cannot be further accepted.

The Irano‐Turanian genera Acantholimon, Vassilczenkoa, Cephalorhizum, Popoviolimon, Dictyolimon, and Bukiniczia form a well‐supported clade sister to the Goniolimon clade (clade II; Figure ), confirming previous findings (Moharrek et al., ). The lack of monophyly for Acantholimon and the presence of two separate clades comprising Acantholimon species were presented by Moharrek et al. (), who sampled 121 Acantholimon species and two molecular markers (trnY‐trnT spacer and ITS region), and are in agreement with our results. The well‐supported sister relationship between one of the two Acantholimon lineages with the Dictyolimon‐Bukiniczia clade in our study (Figure ) match closely that of Moharrek et al.’s (; see “Clade B”), which additionally included the monospecific genus Gladiolimon (not sampled here) within the Acantholimon lineage. A difference between our and Moharrek et al.’s () phylogeny is the placement of the monospecific Vassilczenkoa. Here, Vassilczenkoa is sister to all other Irano‐Turanian genera of this clade (Figure ), whereas in Moharrek et al.’s () phylogeny, Vassilczenkoa with Chaetolimon (not sampled here) are sister to Cephalorhizum–Popoviolimon–Bamiania–Acantholimon clade (see “Clade A”; Moharrek et al., ). However, in both studies the sister relationship of Vassilczenkoa (or Vassilczenkoa‐Chaetolimon; Moharrek et al., ) with related genera receives mostly moderate to low support values, so the relationships of this genus remain unclear. A wide circumscription of Acantholimon has been already proposed (Moharrek et al., ), in which Acantholimon s.s. with all the aforementioned related genera constitute Acantholimon s.l., and within it, the Dictyolimon‐Bukiniczia, Cephalorhizum–Popoviolimon–Bamiania and Vassilczenkoa–Chaetolimon clades are suggested to constitute distinct sections. The species‐rich Acantholimon, although widely distributed in Eurasia (from south‐eastern Europe to western China), has its center of diversity in the Irano‐Turanian region, where its closely related oligospecific genera are endemic (Kubitzki, ; Hassler, ).

Limonium forms a well‐supported monophyletic group, yet its sister group remains unresolved (clade I; Figure ). The only genera of Limonioideae not yet included in any molecular phylogenetic analyses are the Irano‐Turanian Ghaznianthus, Limoniopsis, and Neogontscharovia, which comprise one, two, and three species, respectively. New insights into the circumscription and relationships within Limonioideae were provided by the current study with complements by the recent study of Moharrek et al. (; for Acantholimon s.l.), thus improving substantially our understanding of generic integrity and relationships within the tribe.

Genus Limonium

In our phylogeny, the broad sampling for Limonium allows us to evaluate the subgeneric, sectional, and subsectional classifications previously proposed for the genus (see Table ), and suggest revisions aimed at improving, updating, and clarifying infrageneric circumscriptions. However, we acknowledge the existence of limitations, such as low support values, lack of diagnostic morphological traits, and incomplete species sampling that sometimes hinder our systematic conclusions (e.g., “Mediterranean lineage”). To address sampling concerns in Limonium, we performed an exhaustive review of the taxonomic literature and used the available morphological, biogeographic, and cytological information to assign the ca. 400 species of Limonium that were not sampled in our molecular phylogeny to the resulting clades and their corresponding taxonomic units (see Figures and ). The results of the mentioned review are compiled in Table S3, which covers the ca. 600 named species of Limonium. This effort resulted in the assignment of almost all (>99%) unsampled Limonium species to clades supported in our molecular phylogeny and the corresponding subgenera, sections, and subsections (see Table S3). Most of the Limonium species were assigned to the large “Mediterranean lineage” (Figures , and Table S3), for which further studies are needed to improve its sectional circumscriptions (see below). Below we discuss the taxonomic implications of our phylogenetic results providing additional information on geographic distributions and morphological characteristics of each group.

Taxonomic Proposals

Goniolimon Boiss. in DC., Prodr. 12: 632. 1848.—Type: Goniolimon tataricum (L.) Boiss. in DC., Prodr. 12: 632. 1848, here selected*.

= Statice sect. Tropidice Griseb. Spicil. Fl. Rumel. 2: 299. 1846.

= Ikonnikovia Lincz. in Kom., Fl. URSS 18: 378, 745. 1952.—Type: Ikonnikovia kaufmanniana (Regel) Lincz. in Kom., Fl. URSS 18: 381. t. 19. f. 3. 1952.

* Goniolimon tataricum is one of the validly named species in the genus protologue (Boissier, ), it has not been segregated from the genus or synonymized and matches the generic description. The lectotype of Goniolimon tataricum (designated by Edmonson in Jarvis, :874, leg. “Amman s.n., Herb Linn. No. 395.12 (LINN)”) is hereafter the type of the generic name.

Limonium subg. Pteroclados (Boiss.) Pignatti s.l. (emend. Koutroumpa)—Type: Limonium sinuatum (L.) Mill., Gard. Dict., ed. 8: Limonium no. 6. 1768.

= Linczevskia Tzvelev in Takhtajan, Konspekt Fl. Kavkaza 3(2): 283. 2012.—Type: Linczevskia sinuata (L.) Tzvelev in Konspekt Fl. Kavkaza 3(2): 283. 2012.

Perennial (rarely annual) herbs or shrubs with leaf rosettes; leaves entire to sinuate‐lobed; stems bearing wings, sometimes absent; inflorescence often rather lax, rarely very lax (i.e., L. anthericoides) or sometimes dense; spikelets distichous; calyx infundibuliform, conspicuous with broad limb and ribs below, reaching or slightly above the lobe tips, or rarely obconical, inconspicuous but with ribs extended well above the lobe tips (i.e., L. mouretii and L. anthericoides); corolla often white, sometimes yellow or light pink; fruit with circumscissile dehiscence.

Limonium subg. Pteroclados s.l. includes all 21 species of L. sect. Pteroclados (see Table ) and L. anthericoides of the new L. sect. Tenuiramosum (see below).

Limonium sect. Limonium (emend. Koutroumpa)—Type: Limonium vulgare Mill., Gard. Dict., ed. 8: Limonium no. 1. 1768, typ. cons.

= Statice sect. Limonium subsect. Genuinae Boiss. in DC., Prodr. 12: 643. 1848.

Perennial herbs 15–150 cm tall; leaves large, pinnately veined, forming rossete; sterile branches few or absent (rarely fairly numerous); inflorescence with more or less dense spikes; spikelets small, usually with 1–4 flowers; calyx obconical or very narrowly funnel‐form; calyx limb short, undulate, bearing 5–10 distinct lobes, usually with short lobes placed between larger lobes; corolla bluish‐violet, rarely lilac.

This is a new, more restricted circumscription of Limonium sect. Limonium that matches closely the composition of L. sect. Limonium subsect. Genuinae. Species previously assigned to L. sect. Limonium and are not part of L. subsect. Genuinae should be segregated from this section as currently circumscribed. Species of L. sect. Limonium have wide (e.g., L. gmelini (Willd.) Kuntze, L. humile Mill., L. latifolium, L. meyeri (Boiss.) Kuntze, L. vulgare) or more restricted (e.g., L. alutaceum (Stev.) Kuntze, L. asterotrichum (Salmon) Salmon, L. compactum Erben & Brullo, L. pagasaeum Erben & Brullo) distributions in the Old or New World (e.g., L. brasiliense (Boiss.) Kuntze, L. californicum (Boiss.) A. Heller, L. guaicuru (Molina) Kuntze, L. limbatum Small).

Limonium sect. Nephrophyllum Rech.f. s.l. (emend. Koutroumpa) ≡ Statice sect. Limonium subsect. Hyalolepideae Boiss. p.p. in DC., Prodr. 12: 659. 1848.—Type: Limonium reniforme (Girard) Lincz. in Kom., Fl. URSS 18: 456. 1952.

Perennial herbs; basal leaves forming rossete, spathulate to obovate‐spathulate, rarely oblanceolate, dying before end of flowering, rarely persistent (e.g., L. myrianthum (Schrenk) Kuntze); cauline leaves present, amplexicaule or semi‐amplexicaule, sometimes absent; sterile branches few to numerous mostly in lower part, rarely absent; inflorescence paniculate; spikelets small (c. 2–6 mm) with broadly membranous bracts; calyx usually obconical, sometimes funnel‐form, 5‐lobed; calyx ribs terminating bellow margin.

This is an expanded circumscription for L. sect. Neprophyllum that together with L. otolepis, L. perfoliatum and L. reniforme newly includes species from L. bellidifolium complex (L. bellidifolium and L. iconicum sampled in the phylogeny, and other relatives: e.g., L. caspium (Willd.) Gams, L. coralloides (Tausch) Lincz., L. macrorrhizon (Ledeb.) Kuntze, L. myrianthum, L. smithii Akaydin, L. tamaricoides Bokhari) many of them previously assigned to L. sect. Limonium subsect. Hyalolepideae sensu Boissier and are distributed in the Irano‐Turanian area, apart from L. bellidifolium that expands toward the Euro‐Siberian and Mediterranean regions.

Limonium sect. Pruinosum (Batt.) Koutroumpa, comb. nov. ≡ Statice sect. Limonium subsect. Pruinosae Battandier in Batt. et Trabut, Fl. Algérie 1: 727. 1888 ≡ Limonium sect. Limonium subsect. Pruinosa (Batt.) Sauvage & Vindt, Fl. Maroc 1: 46, 58. 1952.—Type: Limonium pruinosum (L.) Kuntze, in Revis. Gen. Pl. 2: 396. 1891.

Limonium sect. Sarcophyllum (Boiss.) Lincz. emend. Koutroumpa ≡ Statice sect. Limonium subsect. Sarcophyllae Boiss. p.p. in DC., Prodr. 12: 663. 1848.—Type: Limonium axillare (Forssk.) Kuntze in Revis. Gen. Pl. 2: 395. 1891.

Shrublets sometimes cushion‐formed; caudex woody; leaves mostly cauline on woody branches, alternate and often spirally arranged, fleshy, oblanceolate to spathulate or cylindrical, sometimes with an auricle at the apex, and with 3 large vascular bundles (i.e., nerves) in cross section; inflorescence relatively dense paniculate, rarely lax; calyx funnel‐form, sometimes obconical.

The newly circumscribed L. sect. Sarcophyllum includes Sudano‐Zambezian/Saharo‐Arabian species (e.g., L. cylindrifolium, L. maurocordatae (Schweinf. & Volk.) Cufod., L. milleri, L. paulayanum, L. sarcophyllum, L. sokotranum, L. somalorum, L. stocksii) and it does not include the Irano‐Turanian group of species currently assigned to L. sect. Iranolimon. Limonium sect. Tenuiramosum Koutroumpa sect. nov.—Type: Limonium anthericoides (Schltr.) R. A. Dyer in Bull. Misc. Inform. Kew 1935: 155. 1932.

Perennial herbs with leaf rosettes; leaves obovate or elliptic‐spathulate; stems erect, flexuous, verrucose, very laxly branched on the upper half with slender fragile branches bearing inflorescences; spikes very laxly arranged; spikelets small usually with 2–4 flowers; calyx pilose, obconical with scarious limb, and 5 main lobes with ribs and 5 short intermediate lobes; aristate calyx ribs, well above the lobes, longer than the limb; corolla white; fruit with circumscissile dehiscence.

This is a newly described monospecific section for L. anthericoides, a morphologically isolated species for Limonium, endemic to the coastal areas of the Cape in South Africa. Limonium sect. Pteroclados subsect. Nobiles (Boiss.) Koutroumpa, comb. nov. ≡ Statice sect. Pteroclados subsect. Nobiles Boiss. in DC., Prodr. 12: 636. 1848—Type: Limonium arboreum (Willd.) Erben et al. in Fl. Medit. 22: 65. 2012. Limonium sect. Pteroclados subsect. Odontolepideae (Boiss.) Koutroumpa, comb. nov. ≡ Statice sect. Pteroclados subsect. Odontolepideae Boiss. in DC., Prodr. 12: 635. 1848—Type: Limonium sinuatum (L.) Mill., Gard. Dict., ed. 8: Limonium no. 6. 1768.

= Linczevskia Tzvelev in Takhtajan, Konspekt Fl. Kavkaza 3(2): 283. 2012.—Type: Linczevskia sinuata (L.) Tzvelev in Konspekt Fl. Kavkaza 3(2): 283. 2012.

Accepted Taxonomic Units of Limonium in this study

Genus Limonium Mill.

L. subg. Pteroclados (Boiss.) Pignatti s.l. (emend. Koutroumpa)

• L. sect. Pteroclados (Boiss.) Bokhari
  • L. sect. Pteroclados subsect. Odontolepideae (Boiss.) Koutroumpa
  • L. sect. Pteroclados subsect. Nobiles (Boiss.) Koutroumpa

L. subg. Limonium

• L. sect. Circinaria (Boiss.) M. Malekm
• L. sect. Ctenostachys (Boiss.) Sauvage & Vindt
• L. sect. Iranolimon M.Malekm., Akhani & Borsch
• L. sect. Jovibarba (Boiss. sub Statice)
• L. sect. Limoniodendron Svent.
• L. sect. Limonium (emend. Koutroumpa)
• L. sect. Nephrophyllum Rech.f. s.l. (emend. Koutroumpa)
• L. sect. Plathymenium (Boiss.) Lincz.
• L. sect. Polyarthrion (Boiss.) Sauvage & Vindt
• L. sect. Pruinosum (Batt.) Koutroumpa
• L. sect. Sarcophyllum (Boiss.) Lincz. emend. Koutroumpa
• L. sect. Schizhymenium (Boiss.) Bokhari
• L. sect. Siphonantha (Boiss.) Sauvage & Vindt
• L. sect. Siphonocalyx Lincz.
• L. sect. Sphaerostachys (Boiss.) Bokhari