Reciprocal controlled crosses between Pinus sylvestris and P. mugo verified by a species-specific cpDNA marker

A species-specific marker of cpDNA (paternally inherited in pines) was used to verify the hybrid origin of seedlings from controlled reciprocal crosses between Pinus sylvestris and P. mugo. A very low degree of compatibility between those two species has been revealed. In the three consecutive years of experiments, no filled seeds were obtained in the combination with P. mugo as the seed parent. From P. sylvestris as the seed parent and P. mugo as the pollen donor, we succeeded to obtain four filled seeds (about 1 %), but only in one year. The seedling obtained from the seeds had cpDNA haplotypes specific to P. mugo, which proves their hybrid origin. This method enables verification of the result of controlled crosses. The importance of the results has been discussed in the aspect of postulated natural hybridisation in sympatric populations of the two species.     

DNA marker based identification of spontaneous hybrids between Pinus mugo and P. sylvestris at the Lithuanian sea‐side

The objective was to identify spontaneous hybrids between P. mugo and P. sylvestris using organelle DNA markers in sympatric zones at the sea‐side spit of Kursiu Nerija in western Lithuania. A field inventory was carried out over the entire Lithuanian part of the spit and 203 individuals morphologically intermediate between P. sylvestris and P. mugo were tested for their male parent with chloroplast DNA PCR‐RFLP markers and for their female parent with mitochondrial DNA PCR markers. Unfortunately, the mitochondrial DNA Nad7 marker failed to identify the female parent species in our study. However, the chloroplast DNA PCR‐RFLP marker revealed that out of 203 tested individuals only 23 had a paternity different than that indicated by morphology. Of these, 13 individuals were morphologically identified as P. sylvestris but possessed cpDNA of P. mugo (putative hybrids with P. sylvestris (female) ×P. mugo (male parent), and 10 individuals morphologically identified as P. mugo possessed cpDNA of P. sylvestris and may be hybrids with P. mugo (female) ×P. sylvestris (male parent). The remainder of the 177 individuals identified in the field inventory were were considered as pure species. In conclusion, our study indicates ongoing spontaneous hybridization between P. mugo and P. syvestris in Kursiu Nerija. Human impact via seed transfer on altered hybridization rates as well as evolutionary consequences are discussed.     

Seed quality in hybrid swarm populations of Pinus mugo Turra and P. sylvestris L.

Crop characteristics involving cone size, average number of seeds per cone, and seed germinability have been studied for three hybrid swarm populations of Pinus mugo and P. sylvestris, two pure P. mugo populations and one pure P. sylvestris population, in northern Slovakia. Generally, reproduction capability characteristics were significantly reduced in hybrid swarms in relation to the control populations. Although there were no consistent differences between hybrid swarms and control populations in the average number of seeds per cone or cone size, seed germination rates and full seed production in hybrid swarms were lower than for the control population of P. sylvestris and one of the pure populations of P. mugo. Based on these data a conclusion has been drawn postulating partial rather than full fertility of the hybrid swarm populations of P. mugo and P. sylvestris.     

Hybridisation processes in sympatric populations of pines Pinus sylvestris L., P. mugo Turra and P. uliginosa Neumann

Natural hybridisation was postulated between the closely related pine species Pinus sylvestris and the P. mugo complex, however no clear evidence on propagation of mature hybrids in nature has been documented so far. To test the hybridisation hypothesis we applied chloroplast DNA (cpDNA) markers and isozymes in the analyses of 300 individuals representing the variety of morphological forms in the sympatric populations of P. sylvestris, P. mugo and P. uliginosa at the peat bog complex in the Sudety Mts., Poland. Additionally, the haplotypes of paternally inherited cpDNA of 149 open pollinated progeny derived from seeds were compared to the haplotypes of parental trees to access the intensity and direction of contemporary hybridisation. The morphologically highly variable polycormic (multi-stemmed) hybrids between P. mugo and P. uliginosa were identified. The second group of hybrids was found among the monocormic (single-stemmed) P. sylvestris-like individuals carrying the cpDNA from P. mugo complex. Hybrids of P. sylvestris as a pollen donor and P. mugo or P. uliginosa as a mother were not found, either in the group of examined trees, or among the open pollinated progeny. The results indicate that numerous hybrids can exist in the sympatric population of the species studied and that gene flow can successfully proceed from P. mugo complex to P. sylvestris. Hybridisation and ecological selection seems to play a significant role in diversification and evolution of the investigated species.     

Cryptic hybrids between Pinus uncinata and P. sylvestris

We tested the performance of molecular markers and biometric traits in the identification of hybrids between closely related mountain pine (Pinus uncinata) and Scots pine (Pinus sylvestris). A plastid DNA marker and a set of morphological and anatomical needle traits were applied in analyses of individuals from several sympatric stands of the species and a single‐species' population from southern Europe, used as a reference. A polymerase chain reaction‐restriction fragment length polymorphism (PCR‐RFLP) marker from the plastid trnL–trnF region and morphological and anatomical traits clearly discriminated between the pure species. Significant differences were found between P. uncinata and P. sylvestris, mostly in the shape of epidermal cells and the number of stomata. Four putative hybrids with P. sylvestris morphology, but with P. uncinata plastid DNA haplotypes, were found in a population from Sierra de Gúdar near Valdelinares, the southernmost locality of the latter species in eastern Spain. Discrimination analyses between and within populations placed these individuals on the edge of an agglomeration of P. sylvestris individuals. The results suggest that hybridization between the species is rare, but can result in cryptic hybrids morphologically similar to the maternal species. © 2010 The Linnean Society of London, Botanical Journal of the Linnean Society, 2010, 163 , 473–485.     

A morphometric analysis of spontaneous and artificial hybrids of Pinus mugo ×sylvestris (Pinaceae)

Hybridization among Pinus mugo and P.sylvestris is visualized in Wells' distance diagrams using either equally or differently weighted characters. Parents and hybrids are better resolved in diagrams using differently weighted characters. Putative hybrids from mixed, planted or naturalized stands of P. mugo and P. sylvestris in SW and NW Jutland, Denmark, are compared with artificial F₁ and spontaneous material of P. mugo × sylvestris (P. × rhaetica ) from the Alps and the Pyrenees. The natural hybrids are primary hybrids, rather than introgressants.     

Population history of European mountain pines Pinus mugo and Pinus uncinata revealed by mitochondrial DNA markers

The dwarf mountain pine (Pinus mugo) and the Pyrenean pine (P. uncinata) constitute a pair of closely related coniferous taxa of poorly resolved evolutionary history and affinity, which inhabit numerous stands scattered over subalpine environments of European mountain ranges. The aim of the study was to investigate their phylogeography and mutual relationships, shedding new light on their taxonomy and the past of the alpine flora. Previous evolutionary reconstructions of the mountain pines relied mainly on bi‐parentally or paternally inherited markers that quickly homogenize between populations, showing rather shallow and recent differentiation of gene pools. Therefore, to contrast these pictures, we analyzed diversity and differentiation within a large set of new mitochondrial loci, inherited in maternal line and distributed by seeds at short geographical distances. Samples of the taxa were taken from 27 natural populations representing their range‐wide distributions—17 populations of P. mugo and 10 of P. uncinata. All markers appeared polymorphic, providing a total of 31 multilocus haplotypes. Two of the loci proved to be species‐diagnostic and nearly fixed between analyzed samples. Distribution of mitotypes indicate that allopatric populations of the taxa constitute separate mitochondrial haplogroups, and the two mountain pines have independent evolutionary history. However, introgression of P. mugo mitotypes by P. uncinata specimens revealed in the species contact zone in Western Alps shows that their speciation is not fully completed.     

Microsatellite loci polymorphism of chloroplast DNA of scots pine (Pinus sylvestris L.) in Asia and eastern Europe

The variability of four microsatellite loci of chloroplast DNA was studied in 38 populations of Pinus sylvestris in the European part of Russia, in Siberia, Kazakhstan, Transbaikalia and Mongolia. High variability was observed in all regions. In total, 152 haplotypes were identified. The level of population differentiation R _ST was 2.1%. The differentiation of three geographical groups of populations (European, Siberian-Kazakhstan and Transbaikalian-Mongolian) was insignificant (R _CT = 0.004). At the same time, some rare haplotypes were found to be specific for a certain geographical region. Distribution of the rare haplotypes, which differentiated European populations from Asian populations and Mongolian and Transbaikalian populations from the Siberian, showed the independence of the history of these regions. This corresponds more to the hypothesis that the modern area of Pinus sylvestris originated via settlement from many origins than to the hypothesized single center of the post-glacial recolonization. The distribution of the pairwise differences between the individual specimens corresponded to the model of sudden population growth. The assessments of the age of this event for Pinus sylvestris (4.5–4.7 million years), which were obtained on the basis of this model, significantly exceeded the age of the Quaternary. Therefore, the revealed population growth is hardly due to the changes in flora related with the glaciation, but rather mirrors the moment of the species formation.     

Genetic variation of F1 hybrids from controlled crosses between Pinus montana var. rostrata and Pinus sylvestris in morphological needle traits

One hundred and seventeen hybrids, representing ten families from controlled crosses between Pinus montana var. rostrata and Pinus sylvestris, were examined in respect to six morphological traits of two-year-old needles. The biometric data obtained from the measurements provided a basis for multivariate statistical analyses, including discriminant analysis and Mahalanobis distances as principal methods. The analysed families formed two complexes, which were significantly different. The main traits responsible for the distinction were numbers of stomatal rows on both sides of the needles.     

Cuticular Analysis – a method to distinguish the leaves of Pinus sylvestris L. (Scots Pine) from those of Pinus mugo s. str. (Dwarf Mountain-pine)

Fragments of leaf needles from the early Holocene were found in peat sediments of the Adršpašskoteplické skály nature reserve in northeast Bohemia. These remains were identified from macroscopic characters as belonging to Pinus sp. (pine), and they were identified to species level by cuticular analysis. This identification method uses the number and shape of subsidiary stomatal cells and has been verified by comparision of both fossil and modern material. Taxonomic characters have been discovered which distinguish the leaves of Pinus sylvestris (Scots Pine) from those of P. mugo s. str. (Dwarf Mountain-pine) on the basis of stomatal density, crypt morphology and length of the crypt. This method is helpful in palaeobotany and archaeobotany for identifying most such leaf remains. Received June 28, 2001 / Accepted June 18, 2002     

Dry-matter Production by Pinus sylvestris L.

This paper contains the data for the gross weight and relativeproportions of canopy, bole, and roots in a series of twelveeven-aged forest stands. From these it is possible to describe the growth curves of treesof Pinus sylvestris in Britain under the observed conditionsand the production of dry matter per unit area of such standsof trees. The following general results are given: regressionsrelating weight to bole, height, and diameter; the relativegrowth of leaves, roots, and bole; annual increments of drymatter; relative growth-rates per unit leaf area or per unitdry weight per annum. Some comparative data are given for Pinus nigra (one plantation)which is more productive than Pinus sylvestris.     

Gene-pool variation in caledonian and European Scots pine (Pinus sylvestris L.) revealed by chloroplast simple-sequence repeats.

We have used polymorphic chloroplast simple-sequence repeats to analyse levels of genetic variation within and between seven native Scottish and eight mainland European populations of Scots pine (Pinus sylvestris L.). Diversity levels for the Scottish populations based on haplotype frequency were far in excess of those previously obtained using monoterpenes and isozymes and confirmed lower levels of genetic variation within the derelict population at Glen Falloch. The diversity levels were higher than those reported in similar studies in other Pinus species. An analysis of molecular variance (AMOVA) showed that small (3.24-8.81%) but significant (p < or = 0.001) portions of the variation existed between the populations and that there was no significant difference between the Scottish and the mainland European populations. Evidence of population substructure was found in the Rannoch population, which exhibited two subgroups. Finally, one of the loci studied exhibited an allele distribution uncharacteristic of the stepwise mutation model of evolution of simple-sequence repeats, and sequencing of the PCR products revealed that this was due to a duplication rather than slippage in the repeat region. An examination of the distribution of this mutation suggests that it may have occurred fairly recently in the Wester Ross region or that it may be evidence of a refugial population.     

Apatite as a P source in mycorrhizal and non-mycorrhizal Pinus sylvestris seedlings

The objectives of the study are firstly to test the ability of ectomycorrhizal pine seedlings to use apatite as a P source in comparison with non-mycorrhizal pine seedlings and secondly, to determine if there is a relation between exudation of organic acids and the ability to use apatite as a P source. Non-mycorrhizal Pinus sylvestris (L.) seedlings and seedlings ectomycorrhizal with 4 different isolates of ectomycorrhizal fungi were grown for 220 days in sand/peat filled pots with apatite (Ca₅(F,OH)(PO₄)₃) as the sole P source. In an additional experiment, non-mycorrhizal Pinus sylvestris (L.) seedlings and seedlings ectomycorrhizal with 2 different isolates of ectomycorrhizal fungi were grown without any P source for 250 days. All other nutrients were supplied in a balanced nutrient solution.Ectomycorrhizal seedlings grew less than non-mycorrhizal seedlings but ectomycorrhizal seedlings produced a large external mycelium not included in the biomass estimates. All seedlings in the present study had low shoot:root ratios compared to seedlings growing under optimal conditions. All seedlings grown with apatite as P source had higher foliar P concentrations (0.71–2.11 mg/g) than seedlings growing without any P source (0.57–0.75 mg/g) indicating a significant ability to use apatite as a P source. Seedlings colonized by Suillus variegatus and Paxillus involutus had higher concentrations and total contents of P in shoots compared with non-mycorrhizal seedlings, indicating significant improvement of P uptake by these fungi in comparison with non-mycorrhizal seedlings or seedlings colonized Piloderma croceum.No clear relationship between exudation of organic acids and uptake of P was found. Seedlings colonized by S. variegatus reduced the pH of the soil more than seedlings colonized by P. involutus or non-mycorrhizal seedlings. It is suggested that S. variegatus colonization improves the P uptake by reducing the pH of the soil while P. involutus improves P uptake by having a greater ability to absorb dissolved phosphate than non-mycorrhizal roots or roots colonized by the other fungi used in the study.     

Genetic diversity and differentiation of two Mediterranean pines (Pinus halepensis Mill. and Pinus pinaster Ait.) along a latitudinal cline using chloroplast microsatellite markers

Several studies have reported glacial refugia and migration pathways for different pine species in the Iberian Peninsula, all of them based on a single‐species approach. In this paper, chloroplast microsatellites (cpSSRs) are used to compare population genetic structure and diversity estimates for interspecific pairs of populations located along a cline from southwestern (latitude 36°32′ N, longitude 5°17′ W) to northeastern Spain (latitude 42°14′ N, longitude 2°47′ E) in two widely distributed Mediterranean pines, Pinus halepensis Mill. and Pinus pinaster Ait. Some cpSSRs were shared between species, facilitating comparison of levels of gene diversity at the species level and inferences about within and among species differentiation. P. pinaster showed a much higher number of variants (29) and haplotypes (69) than P. halepensis (20 and 21, respectively). Moreover, genetic diversity estimates for interspecific pairs of populations along the cline were negatively correlated. Three main causes may explain the differences between species in the present‐day distribution of genetic diversity: (1) the distribution of genetic variability before the Quaternary glaciations, with an earlier presence of P. pinaster in the Iberian Peninsula and a late spread of P. halepensis from eastern and central Europe, (2) the location of the Holocene glacial refugia and the migration pathways from these refugia to the present‐day range (from northeast to southwest in P. halepensis and from southwest to northeast and northwest in P. pinaster) and (3) the interactions between species during the postglacial spread.     

Genetic structure of montane isolates of Pinus sylvestris L. in a Mediterranean refugial area

Aim This work investigates the population genetic effects of periodic altitudinal migrations and interstadial fragmentation episodes in long‐term Scots pine (Pinus sylvestris L.) populations at a regional scale. Location The study focuses on Scots pine populations in the northern Meseta and peripheral mountain chains, central and north‐western Iberian Peninsula. The ample macrofossil record in the area shows that this 60,000‐km² region represent a glacial refugium for Scots pine. The species occupied large areas on the Meseta plains during glacial cold stages, but it has periodically sheltered at high elevation in the surrounding mountain chains during warm episodes, conforming to a fragmented pattern similar to its present‐day distribution. Methods We perform a fine‐scale chloroplast microsatellite (cpSSR) survey to assess the genetic structure of 13 montane Scots pine isolates in the northern Meseta (total N = 322 individuals). Using a hierarchical analysis of molecular variance (amova ), we test the hypothesis of genetic isolation among disjunct mountain areas. We use a standard coalescence model to estimate genealogical relationship among populations, investigating the potential role of the regional relief as a factor influencing historic gene exchange among Scots pine populations. Results Population haplotypic diversity was high among Scots pine populations (H_e = 0.978), greater than values reported for other more thermophilic pine species in the Iberian Peninsula. The amova revealed low (but significant) differentiation among populations (Φ_ST = 0.031, P = 0.010), showed that the disjoint montane distribution could not account for the genetic divergence among areas (Φ_CT = 0.012, P = 0.253), and that there was non‐trivial subdivision among populations within the same mountain region (Φ_SC = 0.021, P = 0.012). The genealogical relationships among populations showed that Scots pine isolates growing on disjoint mountain blocks, but on slopes flowing to the same basin, were genetically closer than populations growing on different slopes of the same mountain chain, flowing to different basins. Main conclusions The observed genetic structure for Scots pine is consistent with its population history, inferred from the palaeobotanical record, with vertical migrations throughout climatic pulses and with the drainage basins and large long‐term population sizes connecting different mountain blocks during the cooler glacial periods. Overall, the results suggest that, despite periodic interstadial fragmentation episodes, Scots pine biology provides for the long‐term maintenance of high within‐population and low among‐population genetic diversity at neutral genetic markers.     

Differentiation and Genetic Structure of Sclerophoma pythiophila Strains on Pinus sylvestris in Poland

Between 1996 and 2006, 97 strains of Sclerophoma pythiophila were isolated from 3 to 10-year-old trees of Pinus sylvestris from three regions of Poland differing by climatic conditions and geographic location. On the basis of 56 random amplified microsatellites (RAMS) markers obtained with the use of five primers, very high level of genetic variability of strains (mean Jaccard's coefficient 0.56) was ascertained. Among the analysed markers only one was completely monomorphic, whereas six were monomorphic in 90%. Greater genetic similarity was ascertained for strains in southern Poland (0.58) in comparison with strains deriving from northern Poland (0.52). Correlation between the percentage share of polymorphic loci and the average annual temperature of places of strain isolation ( r  = 0.62) were shown, as well as the number of days with snow cover ( r  = 0.79). On the basis of the amova analysis, it was ascertained that 11.6% of genetic variability was located between regions of the strains origin and 88.4% within the regions.     

Genetic maps for Pinus elliottii var. elliottii and P. caribaea var. hondurensis using AFLP and microsatellite markers

Genetic maps for individual Pinus elliottii var. elliottii and P. caribaea var. hondurensis trees were generated using a pseudo-testcross mapping strategy. A total of 329 amplified fragment length polymorphic (AFLP) and 12 microsatellite markers were found to segregate in a sample of 93 interspecfic F(1) progeny. The male P. caribaea var. hondurensis parent was more heterozygous than the female P. elliottii var. elliottii parent with 19% more markers segregating on the male side. Framework maps were constructed using a LOD 5 threshold for grouping and interval support threshold of LOD 2. The framework map length for the P. elliottii var. elliottii megagametophyte parent (1,170 cM Kosambi; 23 linkage groups) was notably smaller than the P. caribaea var. hondurensis pollen parent (1,658 cM Kosambi; 27 linkage groups). The difference in map lengths was assumed to be due to sex-related recombination variation, which has been previously reported for pines, as the difference in map lengths not be accounted for by the larger number of markers mapping to the P. caribaea var. hondurensis parent - 109 compared with 78 in P. elliottii var. elliottii parent. Based on estimated genome sizes for these species, the framework maps for P. elliottii var. elliottii and P. caribaea var. hondurensis covered 82% and 88% of their respective genomes. The pseudo-testcross strategy was extended to include AFLP and microsatellite markers in an intercross configuration. These comprehensive maps provided further genome coverage, 1,548 and 1,828 cM Kosambi for P. elliottii var. elliottii and P. caribaea var. hondurensis, respectively, and enabled homologous linkage groups to be identified in the two parental maps. Homologous linkage groups were identified for 11 out of 24 P. elliottii var. elliottii and 10 out of 25 P. caribaea var. hondurensis groups. A higher than expected level of segregation distortion was found for both AFLP and microsatellite markers. An explanation for this segregation distortion was not clear, but it may be at least in part due to genetic mechanisms for species isolation in this wide cross.