Sexual reproduction and crossing barriers in white pines: the case between <Emphasis Type="Italic">Pinus lambertiana</Emphasis> (sugar pine) and <Emphasis Type="Italic">P. monticola</Emphasis> (western white pine)

The sexual reproductive process in Pinus lambertiana has not been completely described, and previous attempts to generate hybrids with Pinus monticola and other North American pines have not been successful. The nature of incompatibility barriers between P. lambertiana and P. monticola is unknown. This needs to be understood if strategies are to be developed to overcome the said barriers. In this paper, development on interspecific crosses is compared with that on intraspecific crosses on the same parent trees. Pollen grains of both species germinated on the nucellus of both species within a week after pollination. Seed cone receptivity in P. lambertiana came approximately 2 weeks after receptivity in P. monticola, and this delay was perpetuated throughout ovule development in the first year of the reproductive process. Development of the second-year seed cones proceeded more gradually in P. lambertiana. However, seed cones reached maturity only for P. monticola x P. lambertiana. In both crosses, the barriers to hybridization occurred during the second year of the reproductive process. With the P. lambertiana as the seed parent, it was manifested through the failure of the megaspores at the free-nuclear stage to resume development. When P. monticola was used as the seed parent, the male and female gametes failed to fuse. Our results clearly show that the barriers to hybridization in these species occur before or at fertilization. However, the exact mechanisms behind these are still unknown. Based on the results of this study, we present several strategies to bypass the developmental barriers and possibly produce hybrid progenies.     

Niche Divergence versus Neutral Processes: Combined Environmental and Genetic Analyses Identify Contrasting Patterns of Differentiation in Recently Diverged Pine Species

Background and Aims

Solving relationships of recently diverged taxa, poses a challenge due to shared polymorphism and weak reproductive barriers. Multiple lines of evidence are needed to identify independently evolving lineages. This is especially true of long-lived species with large effective population sizes, and slow rates of lineage sorting. North American pines are an interesting group to test this multiple approach. Our aim is to combine cytoplasmic genetic markers with environmental information to clarify species boundaries and relationships of the species complex of Pinus flexilis, Pinus ayacahuite, and Pinus strobiformis.

Methods

Mitochondrial and chloroplast sequences were combined with previously obtained microsatellite data and contrasted with environmental information to reconstruct phylogenetic relationships of the species complex. Ecological niche models were compared to test if ecological divergence is significant among species.

Key Results and Conclusion

Separately, both genetic and ecological evidence support a clear differentiation of all three species but with different topology, but also reveal an ancestral contact zone between P. strobiformis and P. ayacahuite. The marked ecological differentiation of P. flexilis suggests that ecological speciation has occurred in this lineage, but this is not reflected in neutral markers. The inclusion of environmental traits in phylogenetic reconstruction improved the resolution of internal branches. We suggest that combining environmental and genetic information would be useful for species delimitation and phylogenetic studies in other recently diverged species complexes.     

Comparing EST-based genetic maps between <Emphasis Type="BoldItalic">Pinus sylvestris</Emphasis> and <Emphasis Type="BoldItalic">Pinus taeda</Emphasis>

A genetic map of Pinus sylvestris was constructed using ESTP (expressed sequence tag polymorphism) markers and other gene-based markers, AFLP markers and microsatellites. Part of the ESTP markers (40) were developed and mapped earlier in Pinus taeda, and additional markers were generated based on P. sylvestris sequences or sequences from other pine species. The mapping in P. sylvestris was based on 94 F₁ progeny from a cross between plus-tree parents E635C and E1101. AFLP framework maps for the parent trees were first constructed. The ESTP and other gene sequence-based markers were added to the framework maps, as well as five published microsatellite loci. The separate maps were then integrated with the aid of AFLPs segregating in both trees (dominant segregation ratios 3:1) as well as gene markers and microsatellites segregating in both parent trees (segregation ratios 1:1:1:1 or 1:2:1). The integrated map consisted of 12 groups corresponding to the P. taeda linkage groups, and additionally three and six smaller groups for E1101 and E635C, respectively. The number of framework AFLP markers in the integrated map is altogether 194 and the number of gene markers 61. The total length of the integrated map was 1,314 cM. The set of markers developed for P. sylvestris was also added to existing maps of two P. taeda pedigrees. Starting with a mapped marker from one pedigree in the source species resulted in a mapped marker in a pedigree of the other species in more than 40% of the cases, with about equal success in both directions. The maps of the two species are largely colinear, even if the species have diverged more than 70 MYA. Most cases of different locations were probably due to problems in identifying the orthologous members of gene families. These data provide a first ESTP-containing map of P. sylvestris, which can also be used for comparing this species to additional species mapped with the same markers.Communicated by C. Möllers     

A genetic linkage map for Pinus radiata based on RFLP, RAPD, and microsatellite markers

A genetic linkage map for radiata pine (Pinus radiata D. Don) has been constructed using segregation data from a three-generation outbred pedigree. A total of 208 loci were analyzed including 165 restriction fragment length polymorphism (RFLP), 41 random amplified polymorphic DNA (RAPD) and 2 microsatellite markers. The markers were assembled into 22 linkage groups of 2 or more loci and covered a total distance of 1382 cM. Thirteen loci were unlinked to any other marker. Of the RFLP loci that were mapped, 93 were detected by loblolly pine (P. taeda L.) cDNA probes that had been previously mapped or evaluated in that species. The remaining 72 RFLP loci were detected by radiata pine probes from a PstI genomic DNA library. Two hundred and eighty RAPD primers were evaluated, and 41 loci which were segregating in a 11 ratio were mapped. Two microsatellite markers were also placed on the map. This map and the markers derived from it will have wide applicability to genetic studies in P. radiata and other pine species.     

Intra- and inter-specific variations in Lens revealed by RAPD markers

Randomly amplified polymorphic DNA (RAPD) markers were used to estimate intra- and interspecific variations in the genus Lens (lentil). Twenty cultivars of L. culinaris ssp. culinaris, including 11 microsperma (small-seeded) and nine macrosperma (large-seeded) types, and 16 wild relatives (four accessions each of L. culinaris ssp. orientalis, L. odemensis, L. nigricans and L. ervoides), were evaluated for genetic variability using a set of 40 random 10-mer primers. Fifty reproducibly scorable DNA bands were observed from ten of the primers, 90% of which were polymorphic. Genetic distances between each of the accessions were calculated from simple matching coefficients. A dendrogram showing genetic relationships between them was constructed by an unweighted pair-group method with arithmetical averages (UPGMA). This study revealed that (1) expect for L. ervoides, the level of intraspecific variation in cultivated lentil is lower than that in wild species, (2) L. culinaris ssp. orientalis is the most likely candidate for a progenitor of the cultivated species, and (3) microsperma and macrosperma cultivars were indistinguishable by the RAPD markers identified here.     

A chalcone synthase/stilbene synthase DNA probe for conifers

A probe for chalcone synthase (CHS) was generated by PCR using chalcone synthase conserved sequences. The cloned PCR product has high similarity to both chalcone synthase and stilbene synthase sequences. The probe was used to examine the organization of chalcone synthase and stilbene synthase genes in Abies procera, Pinus lambertiana, P. monticola, Picea glauca, P. sitchensis, Pseudostuga menziesii, Taxus brevifolia, and Thuja plicata. A large number of hybridizing bands were found in all species except T. plicata which did not cross hybridize. The hybridization patterns are highly polymorphic between the species and are also polymorphic within several of them.     

Natural hybridization between <Emphasis Type="Italic">Phlomis lycia</Emphasis> D. Don × <Emphasis Type="Italic">P. bourgaei</Emphasis> Boiss., (Lamiaceae) revealed by RAPD markers

Randomly Amplified Polymorphic DNA markers (RAPD) were used to assess the hybrid identity of individuals sampled as Phlomis × termessi Davis. Out of 95 primers screened, 11 primers produced reproducible amplification patterns used for discrimination of P. × termessi and their parents. Eleven primers produced 81 bands. Forty two percent of the RAPD bands existed in parents. Of the 54 bands found in P. lycia, 19 were found only in this species and 7 of these were monomorphic. Similarly, of 57 RAPD bands observed in P. bourgaei, 18 were found only in P. bourgaei and 6 of these were monomorphic. Among hybrid individuals, 35 of the 73 markers were monomorphic. Fifteen of these existed in individual parents showing that parents were homozygous for these markers. Of the 35 monomorphic bands observed among hybrid individuals, 5 were present in the samples of one of the parents and completely absent from the samples of the other; therefore, additive inheritance is indicated. Of the 5 additive bands, 1 was inherited from P. bourgaei and 4 were inherited from P. lycia. Among 38 polymorhic markers observed in hybrid individuals, 9 were new and hybrid-specific. Pollen fertility was also investigated. Mean pollen fertility for P. lycia and P. bourgaei was 93% and 97% respectively. However, mean pollen fertility for hybrids was 65% (±10.5).     

RAPD variations among pure and hybrid populations ofPicea mariana, P. rubens, andP. glauca (Pinaceae), and cytogenetic stability ofPicea hybrids: Identification of species-specific RAPD markers

Random amplified polymorphic DNA (RAPD) analysis was used to determine genetic relationships amongP. mariana (black spruce),P. rubens (red spruce), andP. glauca (white spruce) and to assess the degree of polymorphism within populations from different provenances and among spruce hybrids. Eleven arbitrary decamer primers were used to amplify genomic DNAs extracted from embryogenic cultures and seedlings. Species-specific RAPD markers were identified.Picea mariana andP. rubens showed similar RAPD profiles confirming their close genetic relationship. Species-specific RAPD markers were identified and were useful in distinguishing white spruce from black and red spruces. RAPD differentiation between populations within each species was small. The level of polymorphism was much higher in spruce hybrid populations than in the pure species. Cytological analysis ofP. mariana ×P. rubens hybrids showed normal mitotic behaviour at prophase, metaphase, anaphase, and telophase. All the hybrids analyzed from different cross combinations were euploids.     

Assessment of genetic variation withinBrassica campestris cultivars using amplified fragment length polymorphism and random amplification of polymorphic DNA markers

Genetic relationships were evaluated among nine cultivars ofBrassica campestris by employing random amplification of polymorphic DNA (RAPD) and amplified fragment length polymorphism (AFLP) markers. RAPDs generated a total of 125 bands using 13 decamer primers (an average of 9.6 bands per assay) of which nearly 80% were polymorphic. The per cent polymorphism ranged from 60–100%. AFLP, on the other hand generated a total of 319 markers, an average of 64 bands per assay. Of these, 213 were polymorphic in nature (66.8%). AFLP methodology detected polymorphism more efficiently than RAPD approach due to a greater number of loci assayed per reaction. Cultivar-specific bands were identified, for some cultivars using RAPD, and for most cultivars with AFLP. Genetic similarity matrix, based on Jaccard’s index detected coefficients ranging from 0.42 to 0.73 for RAPD, and from 0.48 to 0.925 for AFLPs indicating a wide genetic base. Cluster analyses using data generated by both RAPD and AFLP markers, clearly separated the yellow seeded, self-compatible cultivars from the brown seeded, self-incompatible cultivars although AFLP markers were able to group the cultivars more accurately. The higher genetic variation detected by AFLP in comparison to RAPD was also reflected in the topography of the phenetic dendrograms obtained. These results have been discussed in light of other studies and the relative efficiency of the marker systems for germplasm evaluation.     

Mapped DNA probes from loblolly pine can be used for restriction fragment length polymorphism mapping in other conifers

A high-density genetic map based on restriction fragment length polymorphisms (RFLPs) is being constructed for loblolly pine (Pinus taeda L.). Consequently, a large number of DNA probes from loblolly pine are potentially available for use in other species. We have used some of these DNA probes to detect RFLPs in 12 conifers and an angiosperm. Thirty complementary DNA and two genomic DNA probes from loblolly pine were hybridized to Southern blots containing DNA from five species of Pinus (P. elliottii, P. lambertiana, P. radiata, P. sylvestris, and P. taeda), one species from each of four other genera of Pinaceae (Abies concolor, Larix laricina, Picea abies, and Pseudotsuga menziesii), one species from each of three other families of Coniferales [Sequoia sempervirens (Taxodiaceae), Torreya californica (Taxaceae) and Calocedrus decurrens (Cupressaceae)], and to one angiosperm species (Populus nigra). Results showed that mapped DNA probes from lobolly pine will cross-hybridize to genomic DNA of other species of Pinus and some other genera of the Pinaceae. Only a small proportion of the probes hybridized to genomic DNA from three other families of the Coniferales and the one angiosperm examined. This study demonstrates that mapped DNA probes from loblolly pine can be used to construct RFLP maps for related species, thus enabling the opportunity for comparative genome mapping in conifers.     

Analysis of genetic relationships of Central American and Mexican pines using RAPD markers that distinguish species

Phylogenetic relationships were inferred for six Central American and Mexican pine species by analysing RAPD marker differences among pooled DNA samples. This population level pooling strategy discounts low-frequency allelic variation within taxa, thus obtaining a 'cumulative genotype' to compare among taxa. We used the morphologically based taxonomy of pines as the basis for inference concerning molecular marker divergence. Only RAPD polymorphisms that were repeatable and intensely amplified were used. The resulting data set was found to have strong hierarchical structure. Phylogenetic analyses were carried out using both neighbour-joining and maximum parsimony. The phylogenetic relationships indicated by analysis of the pine RAPD data provide new insights on pine taxonomy. The phylogenetic analyses of the RAPD marker data placed Pinus tecunumanii and P. patula clearly into two different subgroups, strongly supporting the classification of P. tecunumanii as a distinct species, and raise a new set of issues concerning the distinctions between Pinus tecunumanii and P. caribaea . Phylogenetically informative RAPD markers will be useful tools to address ex-situ conservation issues that involve taxonomic identification and species admixture.     

福建省野牡丹属种质资源的ISSR分析

为探讨福建省野牡丹属(Melastoma L.)植物的亲缘关系,运用ISSR分子标记技术对源自福建省的野牡丹属野生种质及部分实生后代共34份材料进行分析。结果表明,11条多态性引物对34份种质DNA进行扩增,共获得112条完整、清晰的谱带,其中多态性条带104条,多态性比率为92.9%,表明野牡丹属种质资源具有较高的遗传多样性。34份种质材料的相似系数为0.55~0.93,平均相似系数为0.71,表明这些材料间的亲缘关系较近。聚类分析表明34份材料可划分为3个类群5个亚类,主坐标散点分析可分为4个类群,这与亲缘关系分析的结果基本一致。这从分子水平上揭示了福建省野牡丹属野生种质及部分具备优良园艺性状实生后代的亲缘关系,为该属植物的良种选育工作提供了理论依据。     

The Use of RAPD Markers to Assess Catfish Hybridization

Taiwan's endemic catfish Clarias fuscus is gradually disappearing from its native habitat, and has been proposed for genebank preservation. Environmental pressures, including exotic species interference and habitat destruction, as well as possible competitive advantages of the hybrids over this species. In order to quickly and effectively provide a reliable DNA fingerprint for the pure strain of C. fuscus we used RAPD markers to assess C. fuscus, C. mossambicus, and C.batrachus. Of the 200 primers screened to prime PCR amplification of DNA from wild-caught C. fuscus, 16 yielded reproducible DNA bands. Unique RAPD markers generated from 3 PCR primers (#211, #245 and #287) are shown to be alleles present in the genomes of C. mossambicus but absent in the genome of C. fuscus. Hybrids of C. fuscus and C. mossambicus, therefore, could possibly be distinguished by the use of these specific molecular markers. Catfish caught from the Mingder Dam were then cautiously removed from the preserved stock because of the appearance of hybrid markers in their genomes.     

Assessment of random amplified polymorphic DNA (RAPD) for determining the origin ofYoungia koidzumiana Kitamura (compositae)

We determined the parental species ofYoungia koidzumiana (a natural interspecific hybrid) using PCR and arbitrary 10-mer primers to generate random amplified polymorphic DNA (RAPD) markers. These markers, generated by three primers, were sufficient to distinguishYoungia sonchifolia, Youngia denticulata, Youngia chelidoniifolia, andY. koidzumiana. The electrophoresis profiles of the amplified products from each of the four species were then compared. Three primers produced a total of 42 scorable markers; nine were specific markers forY. denticulata andY. chelidoni-ifolia. The length of the amplified DNA fragments ranged from 370 to 2500 b p. The three primers revealed polymorphic bands, which were indicators of the parental species ofY. koidzumiana. These bands showed a combination of specific profiles forY. denticulata andY. chelidoniifolia. Our results also were comparable to the data obtained for flowering times, floret numbers, and chromosome numbers of the four species. Therefore, we suggest thatY. koidzumiana is a hybrid betweenY. denticulata andY. chelidoniifolia}, and that RAPD markers are well suited for assessing the origins of plant species.     

Noncoding chloroplast DNA variation in Mexican pines

Universal primers were used for PCR amplification of three noncoding regions of chloroplast DNA in order to study restriction site variation in 12 Mexican pine species. Two length mutations were identified that are of diagnostic value for two subgenera or sections of the genus. Phylogenetic analysis of the restriction site and length variation showed patterns of variation largely consistent with previous arrangements of these pines, except for the position of Pinus nelsonii, indicating that Pinus section Parraya Mayr, as circumscribed by Little and Critchfield (1969) and later authors, is not a monophyletic group.     

Optimized conditions for rapd analysis inPinus radiata

Summary Pinus radiata is the most important softwood plantation species in Australia and New Zealand. The improtance of this species in forestry has led to an increasing demand to improve the efficiency of selection time of the production population, which currently takes 13 yr by traditional methods. With the application of molecular biology techniques such as random amplified polymorphic DNA (RAPD) the selection period can be reduced to 6 yr. In this study, the conditions for RAPD were optimized and the feasibility of this marker system was investigated with different families ofPinus radiata from Tasmania and South Australia. Best concentrations of Taq-polymerase (1 U), magnesium chloride (2 mM), and template DNA (20 ng) were selected to test different polymerase chain reaction (PCR) thermocycler profiles. Devey's et al. (1996) program was the most effective for production of clear RAPD bands. Best conditions were investigated to screen 10–12 bp arbitrary Breasatec and Operon primers. Both types were found useful at detecting genetic variation between families. Seventy percent and thirty percent of the selected Bresatec and Operon primers, respectively, produced polymorphic bands.     

Evaluation of genetic relationships in Dalbergia species using RAPD markers

Conservation of identified germplasm is an important component forefficient and effective management of plant genetic resources. Traditionally,species identification has relied on morphological characters like growth habit,floral morphology like flower colour, and agronomic characteristics of the plant.Dalbergia species are important wind-dispersed tropicaltimber trees which exhibit high intrafruit seed abortion because of intensesibling competition for maternal resources. Studies were undertaken foridentification and genetic relationships in five species ofDalbergia and to evaluate genetic diversity withinpopulations of Dalbergia sisso, D.latifolia, D. paniculata, D.assamica and D. spinosa by using randomamplified polymorphic DNAs (RAPD) markers. Analysis was started by using 30decamer primers that allowed to distinguish five species and to select a reducedset of primers. The selected primers were used for identification and forestablishing a profiling system to estimate genetic relationships and toevaluate the genetic variability among the individuals in a population ofDalbergia species. A total of 120 distinct DNA fragments(bands), ranging from 0.3 to 4.0 kb, were amplified byusing nine selected random decamer primers. The genetic similarity was evaluated onthe basis of presence or absence of bands, which revealed a wide range ofvariability within the species. The cluster analysis indicated that five speciesof Dalbergia formed two major clusters. The first clusterconsisted of D. spinosa, D. latifolia and D.sisso. The second cluster was represented by two species, i.e.D. paniculata and D. assamica.A maximum similarity of 60% was observed in D. paniculata andD. assamica and they formed a minor cluster.Dalbergia latifolia and D. sissoformed another minor cluster with more than 50% similarity. Dalbergiaspinosa shared up to 40% similarity with D.latifolia and D. sisso. All the species sharemore than 20% similarity among themselves. The closest genetic distance existedwithin populations of different Dalbergia species. Thus,these RAPD markers have the potential for conservation of identified clones andcharacterization of genetic relatedness among the species. This is also helpful intree breeding programs and provides an important input into conservation biology.     

Molecular phylogeny in Indian Tinospora species by DNA based molecular markers

The phylogenetic relationships among the three species of Tinospora found in India are poorly understood. Morphology does not fully help to resolve the phylogeny and therefore a fast approach using molecular analysis was explored. Two molecular approaches viz Random Amplified Polymorphic DNA (RAPD) assay and restriction digestion of ITS1-5.8S-ITS2 rDNA (PCR-RFLP) were used to evaluate the genetic similarities between 40 different accessions belonging to three species. Of the 38 random primers used only six generated the polymorphism, while as three out of 11 restriction enzymes used gave polymorphic restriction patterns. The average proportion of polymorphic markers across primers was 95%, however restriction endonucleases showed 92% polymorphism. RAPD alone was found suitable for the species diversions. In contrast PCR- RFLP showed bias in detecting exact species variation. The correlation between the two markers was performed by Jaccard's coefficient of similarity. A significant (r= 0.574) but not very high correlation was obtained. Further to authenticate the results obtained by two markers, sequence analysis of ITS region of ribosomal DNA (ITS1 and ITS2, including 5.8S rDNA) was performed. Three independent clones of each species T. cordifolia, T. malabarica and T. crispa were sequenced. Phylogenetic relationship inferred from ITS sequences is in agreement with RAPD data.     

Detection of Low Genetic Variation in a Critically Endangered Chinese Pine, Pinus squamata, Using RAPD and ISSR Markers

With only 32 individuals in the northeastern corner of Yunnan Province, China, Pinus squamata is one of the most endangered conifers in the world. Using two classes of molecular markers, RAPD and ISSR, its very low genetic variation was revealed. Shannon's index of phenotypic diversity (I) was 0.030, the mean effective number of alleles per locus (A_e) was 1.032, the percentage of polymorphic loci (P) was 6.45, and the expected heterozygosity (H_e) was 0.019 at the species level based on RAPD markers. The results of ISSR were consistent with those detected by RAPD but somewhat higher (I = 0.048, A_e = 1.042, P = 12.3, H_e = 0.029). The genetic variation of the subpopulation on the southwest-facing slope was much higher than that of the subpopulation on the northeast-facing slope, which may be attributed to the more diverse environment on the southwest-facing slope. The genetic differentiation between the two subpopulations was very low. The between-subpopulation variabilities, Φ_ST, calculated from RAPD and ISSR data were 0.011 and 0.024. Because of the lack of fossil records and geological historical data, it was difficult to explain the extremely low genetic diversity of the species. We postulate that this ancient pine might have experienced strong bottlenecks during its long evolutionary history, which caused the loss of genetic variation. Genetic drift and inbreeding in post-bottlenecked small populations may be the major forces that contribute to low genetic diversity. Human activities such as logging may have accelerated the loss of genetic diversity in P. squamata.     

Comparison of RAPD and RFLP genetic markers in determining genetic similarity among Brassica oleracea L. genotypes

Genetic similarity among 45 Brassica Oleracea genotypes was compared using two molecular markers, random amplified polymorphic DNA (RAPD) and restriction fragment length polymorphisms (RFLPs). The genotypes included 37 broccolis (var. italica), five cauliflowers (var. botrytis) and three cabbages (var. capitata) which represented a wide range of commercially-available germplasm, and included open-pollinated cultivars, commercial hybrids, and inbred parents of hybrid cultivars. Fifty-six polymorphic RFLP bands and 181 polymorphic RAPD bands were generated using 15 random cDNA probes and 62 10-mer primers, respectively. The objectives were to compare RFLP and RAPD markers with regard to their (1) sampling variance, (2) rank correlations of genetic distance among sub-samples, and (3) inheritance. A bootstrap procedure was used to generate 200 random samples of size n (n=2,3,5,... 55) independently from the RAPD and RFLP data sets. The coefficient of variance (CV) was estimated for each sample. Pooled regressions of the coefficient of variance on bootstrap sample size indicated that the rate of decrease in CV with increasing sample size was the same for RFLPs and RAPDs. The rank correlation between the Nei-Li genetic similarity values for all pairs of genotypes (990) based on RFLP and RAPD data was 0.745. Differences were observed between the RFLP and RAPD dendrograms of the 45 genotypes. Overlap in the distributions of rank correlations between independent sub-samples from the RAPD data set, compared to correlations between RFLP and RAPD sub-samples, suggest that observed differences in estimation of genetic similarity between RAPDs and RFLPs is largely due to sampling error rather than due to DNA-based differences in how RAPDs and RFLPs reveal polymorphisms. A crossing algorithm was used to generate hypothetical banding patterns of hybrids based on the genotypes of the parents. The results of this study indicate that RAPDs provide a level of resolution equivalent to RFLPs for detemination of the genetic relationships among genotypes.