Detection of hybridization between two loach species (<Emphasis Type="Italic">Paramisgurnus dabryanus</Emphasis> and <Emphasis Type="Italic">Misgurnus anguillicaudatus</Emphasis>) in wild populations

Artificial interspecific hybrids between large scale loach P. dabryanus and tetraploid pond loach M. anguillicaudatus (Cobitidae, Cypriniformes) are viable. To detect the occurrence of possible natural hybridization, genetic analyses by using microsatellite markers were performed for natural populations of large scale loach and pond loach, the reciprocal laboratory hybrids, and “supposed hybrids” with ambiguous morphology. The fertility of the artificial hybrids was also tested. At one diagnostic microsatellite (Mac50), one out of 20 “supposed hybrids” was identified to be F₁ hybrid between the two loach species because it had the same genotype as that of the laboratory hybrids. The triploid hybrids between the two species were confirmed to be female-sterile. The results show that rare hybridization has occurred between diploid large scale loach and tetraploid pond loach in nature although it may have little effect in genetic introgression. This study is helpful for fish conservation and encourages further investigation on natural hybridization and introgression of loaches.     

Geographic variability in mitochondrial introgression among hybridizing populations of Golden-winged (<Emphasis Type="Italic">Vermivora chrysoptera</Emphasis>) and Blue-winged (<Emphasis Type="Italic">V.opinus</Emphasis>) Warblers

The rapidly declining Golden-winged Warbler (Vermivora chrysoptera) is of conservation concern owing in part to hybridization with the closely related Blue-winged Warbler (V. pinus). These species hybridize extensively in eastern North America and over the past century the Blue-winged Warbler has displaced the Golden-winged Warbler from substantial regions of its historic breeding range. A previous study suggested that these genetic interactions result in rapid and asymmetric introgression of Blue-winged Warbler mitochondrial DNA (mtDNA) into Golden-winged phenotype populations within the zones of contact, but more recent and extensive surveys have documented a more complex pattern of genetic interchange between these taxa. We surveyed mtDNA/phenotype associations in 104 individuals of known phenotype drawn from two locations with different histories of contact and found substantial variation between sites in the extent of introgression. Where both species have co-existed for more than a century, we found evidence of bi-directional introgression and the long-term persistence of Golden-winged mtDNA haplotypes. At the leading edge of the northward expansion of Blue-winged Warblers, we found predominantly Golden-winged Warbler mtDNA haplotypes in both Golden-winged and hybrid-phenotype individuals. Across both sites, genetic swamping does not appear to be occurring via the early immigration of Blue-winged Warbler females into populations dominated by Golden-winged Warbler phenotypes. Instead, the differing patterns of mitochondrial introgression may be driven by the relative local population sizes of the parental species coupled with subtle between-species differences in mate choice and habitat preferences.     

Introgressive hybridization between the Atlantic and Pacific herring (<Emphasis Type="Italic">Clupea harengus</Emphasis> and <Emphasis Type="Italic">Clupea pallasii</Emphasis>) in the White Sea,Barents and Kara Seas evidenced by microsatellites

In the North of Europe two sister species of herring—the Atlantic Clupea harengus and Pacific Clupea pallasii have post-glacially come into secondary contact. Although the breeding areas of the two species are thought to be separate, previous genetic studies based on allozyme and mitochondrial DNA data have supported the existence of introgression from the Atlantic herring to the Pacific herring. In this study, we employed microsatellite markers to explore the extent of introgressive hybridization between these fishes. Bayesian methods for assigning individuals to populations and identifying admixture proportions were applied to the genetic data based on ten microsatellites. Results indicated that 18 out of 464 Pacific herring (3.88%) were likely admixed. Some of the hybrid individuals contained genotypes suggesting that introgressive hybridization is an ongoing process. Despite some admixture, the Atlantic and Pacific herring gene pools remain sharply distinct (the average proportions of membership to “Atlantic” and “Pacific” clusters were Q_A = 0.998 and Q_P = 0.974, respectively), suggesting that hybridization was not frequent. The discovery of introgression among herring species opens new questions about the mechanisms underlying the observed pattern of genetic population differentiation in the North European Pacific herring.     

Using genetic and morphological analysis to distinguish endangered taxa from their hybrids with the cultivated exotic pest plant <Emphasis Type="Italic">Lantana strigocamara</Emphasis> (syn: <Emphasis Type="Italic">Lantana camara</Emphasis>)

Because highly invasive species can rapidly assimilate rare taxa, we questioned whether two Florida endangered Lantana depressa varieties existed 21 years after Sanders documented their widespread hybridization with exotic Lantana strigocamara, and whether morphological traits could accurately discriminate genetic individuals. Stepwise discriminant analysis of morphological characters discriminated the three taxa, correctly classifying 98, 91, 89% of L. strigocamara, L. depressa var. depressa, and var. floridana. Hybrids blurred taxonomic distinctions of varieties and reduced classification accuracy by 7–17%. Species-specific Random Fragment Length Polymorphism (RFLP-PCR) confirmed hybridization has occurred. Intersimple Sequence Repeat (ISSR) fingerprints analyzed with STRUCTURE identified three groups indicating introgression. Morphological traits significantly, but weakly correlated with q ratios (P = 0.0001; r ² = 0.45). Although L. strigocamara introgression is widespread and ongoing, wild populations contain individuals that are predominantly L. depressa genome, supporting actions to remove adventive L. strigocamara, prevent its sale, and promote sales of genetically confirmed natives.     

Hybridization between the threatened plant, <Emphasis Type="Italic">Lespedeza leptostachya</Emphasis> Englem. and its co-occurring congener <Emphasis Type="Italic">Lespedeza capitata</Emphasis> Michx.: morphological and molecular evidence

Natural hybridization is common in the genus Lespedeza. No hybrids between Lespedeza leptostachya Englem. and Lespedeza capitata Michx. are formally recognized in any of the current floras, however observations in the field suggest that hybridization might occur in many of their shared habitats. Putative hybrids were compared to L. leptostachya and L. capitata using morphological measurements and screened for the presence of species-specific trnL-F gene region (cpDNA) and the ITS gene region (nrDNA). A discriminate analysis of 10 morphological measurements identified the hybrids as intermediate to both parents with two PCA axes explaining 99% of the variation between taxa. The presence of hybrids was confirmed by genetic markers with individuals morphologically identified as hybrids having cpDNA trnL-F genotypes identical to L. leptostachya and the ITS (nrDNA) phenotypes in most cases contain the ITS genotype of both parents, however, some putative hybrid individuals contained the ITS genotype of only one parents. Those individuals with L. leptostachya ITS and trnL-F could be a case of misclassification, but the presence of both L. capitata ITS genotypes and L. leptostachya trnL-F genotypes suggest segregation has occurred, which may result from either selfing or backcrossing.     

RFLP mapping of loci controlling self-incompatibility in <Emphasis Type="Italic">Brassica campestris</Emphasis> and their comparative mapping with <Emphasis Type="Italic">B. napus</Emphasis> and <Emphasis Type="Italic">B. oleracea</Emphasis>

RFLP analysis of a cDNA probe SLG6, governing self incompatibility (SI) in Brassica oleracea, using a recombinant inbred population of Brassica campestris followed by genetic linkage analysis led to the detection of two marker loci, SLG6a and SLG6b controlling SI. SLG6a was mapped in linkage group (LG) 9 and was flanked by the RFLP markers ec4f10 (6.4 cM) and wg5b9 (4.2 cM). SLG6b positioned in LG 2 and was flanked by the RFLP markers wg2d11 (9.9 cM) and ec4e7 (26.9 cM). These results indicated the scope of marker-aided introgression of these genes into self-compatible genotypes for production of SI lines suitable for hybridization in B. campestris. Comparative mapping of LG 9 containing SLG6b with corresponding linkage groups of B. oleracea (BO 2) and B. napus (BN 16) led to the detection of small homologous regions with SLG6 locus linked with another RFLP locus. This evidenced for homology of the SLG genes across Brassica species and possibility of using any single cloned SLG gene for development of SI lines in any Brassica species.     

Assessing introgressive hybridization between blue wildebeest (<Emphasis Type="Italic">Connochaetes taurinus</Emphasis>) and black wildebeest (<Emphasis Type="Italic">Connochaetes gnou</Emphasis>) from South Africa

Introgressive hybridization poses a threat to the genetic integrity of black wildebeest (Connochaetes gnou) and blue wildebeest (Connochaetes taurinus) populations in South Africa. Black wildebeest is endemic to South Africa and was driven to near extinction in the early 1900s due to habitat destruction, hunting pressure and disease outbreaks. Blue wildebeest on the other hand are widely distributed in southern and east Africa. In South Africa the natural distribution ranges of both species overlap, however, extensive translocation of black wildebeest outside of its normal distribution range in South Africa have led to potential hybridization between the two species. The molecular identification of pure and admixed populations is necessary to design viable and sustainable conservation strategies, since phenotypic evidence of hybridization is inconclusive after successive generations of backcrossing. The aim of this study was to assess levels of hybridization in wildebeest using both species-specific and cross-species microsatellite markers. Black wildebeest (157) and blue wildebeest (122) from provincial and national parks and private localities were included as reference material, with 180 putative hybrid animals also screened. A molecular marker panel consisting of 13 cross-species and 11 species-specific microsatellite markers was developed. We used a Bayesian clustering model to confirm the uniqueness of blue- and black wildebeest reference groups, assign individuals to each of the two clusters, and determine levels of admixture. Results indicated a clear partition between black wildebeest and blue wildebeest (the average proportions of membership to black wildebeest and blue wildebeest clusters were QI?=?0.994 and QI?=?0.955 respectively). From the putative hybrid samples, only five hybrid individuals were confirmed. However, high levels of linkage disequilibrium were observed in the putative hybrid populations which may indicate historical hybridization. Measures of genetic diversity in the black wildebeest populations were found to be lower than that of the blue wildebeest. The observed lower level of genetic diversity was expected due to the demographic history of the specie. This study will make a significant contribution to inform a national conservation strategy to conserve the genetic integrity of both species.     

Specialist <Emphasis Type="Italic">Osmia</Emphasis> bees forage indiscriminately among hybridizing <Emphasis Type="Italic">Balsamorhiza</Emphasis> floral hosts

Pollinators, even floral generalists (=polyleges), typically specialize during individual foraging bouts, infrequently switching between floral hosts. Such transient floral constancy restricts pollen flow, and thereby gene flow, to conspecific flowers in mixed plant communities. Where incipient flowering species meet, however, weak cross-fertility and often similar floral traits can yield mixed reproductive outcomes among pollinator-dependent species. In these cases, floral constancy by polyleges sometimes serves as an ethological mating barrier. More often, their foraging infidelities instead facilitate host introgression and hybridization. Many other bee species are oligolectic (taxonomic specialists for pollen). Oligoleges could be more discriminating connoisseurs than polyleges when foraging among their limited set of related floral hosts. If true, greater foraging constancy might ensue, contributing to positive assortative mating and disruptive selection, thereby facilitating speciation among their interfertile floral hosts. To test this Connoisseur Hypothesis, nesting females of two species of oligolectic Osmia bees were presented with randomized mixed arrays of flowers of two sympatric species of their pollen host, Balsamorhiza, a genus known for hybridization. In a closely spaced grid, the females of both species preferred the larger flowered B. macrophylla, evidence for discrimination. However, both species’ females showed no floral constancy whatsoever during their individual foraging bouts, switching randomly between species proportional to their floral preference. In a wider spaced array in which the bouquets reflected natural plant spacing, foraging oligolectic bees often transferred pollen surrogates (fluorescent powders) both between conspecific flowers (geitonogamy and xenogamy) and between the two Balsamorhiza species. The Connoisseur Hypothesis was therefore rejected. Foraging infidelity by these oligolectic Osmia bees will contribute to introgression and hybridization where interfertile species of Balsamorhiza meet and flower together. A literature review reveals that other plant genera whose species hybridize also attract numerous oligolectic bees, providing independent opportunities to test the generality of this conclusion.     

Hybridization between <Emphasis Type="Italic">Schoenoplectus</Emphasis> sedges across Chesapeake Bay marshes

Hybridization is an evolutionary mechanism capable of enhancing adaptive potential, especially among species in fragmented or disturbed ecosystems like coastal marshes. In this study, we evaluated whether hybridization might influence adaptive responses in coastal marshes that are susceptible to the effects of global environmental change. To do so, we examined the extent and nature of hybridization between Schoenoplectus americanus and S. pungens, two ecologically dominant sedges in low-lying marshes across Chesapeake Bay (USA). Observed patterns of variation at genetically based morphological traits, cpDNA and nuclear microsatellite markers confirm that introgressive hybridization occurs between the two species. Comparisons of microsatellite and cpDNA profiles found that hybridization is reciprocal, although a disproportionate number of hybrids exhibit genomic asymmetries favoring S. americanus. AIC model selection consistently identified latitude as the strongest explanatory variable for the distribution of parental species, although discriminant analysis indicated that distributions also correspond to variation in environmental conditions. Discriminant analysis further indicated that ecological correlates of hybrid and S. americanus genotypes are similar, but not uniformly so. These findings indicate that the boundary between S. americanus and S. pungens is porous, and that hybridization could influence responses of one or both species to changing environmental regimes.     

Hares in Corsica: high prevalence of <Emphasis Type="Italic">Lepus corsicanus</Emphasis> and hybridization with introduced <Emphasis Type="Italic">L. europaeus</Emphasis> and <Emphasis Type="Italic">L. granatensis</Emphasis>

The Italian hare, Lepus corsicanus, was first described in Corsica more than 100 years ago, but the knowledge on the status of the species in this island remains scarce. Moreover, frequent introductions of thousands of individuals from other hare species, namely Lepus europaeus and Lepus granatensis, into Corsica are known to have occurred and an updated assessment of the prevalence of L. corsicanus in Corsica is therefore of utmost importance. Here, to estimate the relative prevalence of the hare species present in Corsica, we conducted a molecular analysis on 67 samples collected by hunters between 2002 and 2007 in 36 Corsican communes. Sequencing of portions of the nuclear gene transferrin and of the control region of the mitochondrial DNA allowed classifying most of the collected samples as belonging to L. corsicanus (70.1%). Of the sampled Corsican communes, 86.1% contained this species, while only in 11.1%, L. europaeus was present. Three of the analyzed specimens showed an inconsistent molecular assignment between markers suggesting a hybrid origin: L. corsicanus × L. europaeus, L. corsicanus × L. granatensis, and L. europaeus × L. granatensis. The first two cases of hybridization had never been described in nature, even in studies focusing on hares from Italy where L. corsicanus and L. europaeus are often sympatric. These results stress the real risk of corrosion of the native gene pool of L. corsicanus via hybridization with introduced species. We highlight the need of urgently rethinking the management plan of hare populations in Corsica.     

Hybridization of <Emphasis Type="Italic">Motacilla alba</Emphasis> Linnaeus, 1758, and <Emphasis Type="Italic">M. (a.) personata</Emphasis> Gould, 1861, in the south of Siberia

The authors attempt to estimate the level of hybridization of Motacilla alba and M. (a.) personata in the area of their secondary contact in the south of Siberia. Processing of the materials in several museum collections (n = 424) and author’s own collections (n = 347) resulted in conclusion on the presence of introgression, in spite of limited hybridization. The data on pair composition and breeding success in the hybridization zone as well as data on habitat preferences are given. The possible reasons for the limited hybridization are discussed.     

Polymorphic Microsatellite Markers Transferable Across <Emphasis Type="Italic">Capsicum</Emphasis> Species

Pepper (Capsicum annuum L.) is one of the most important crops in the family Solanaceae. However, the number of polymorphic molecular loci detected in this important crop is far behind that of other cultivated plant species. In the present study, a total of 45 microsatellite primer pairs were developed using Capsicum expressed sequence tags databases. Microsatellite primer pairs were tested using several species of Capsicum and several genera in the family Solanaceae including tomato, potato, eggplant, and tobacco. Results indicated that microsatellite primer pairs amplified genomic targets of C. annuum L., Capsicum baccatum L., Capsicum chacoense L., Capsicum chinense L., Capsicum frutescens L., and Capsicum pubescens Ruiz et Pavon, indicating species transferability within Capsicum. Further analyses revealed that amplicons of these primer pairs segregated 1:2:1 or 3:1 Mendelian fashions in 38 F₂ individuals of pepper. It was also noted that markers derived from sequences containing dinucleotide repeats were generally more polymorphic at the intraspecific level than sequences containing trinucleotide repeats. All the microsatellite primer pairs developed in this study will be useful for marker-assisted selection and mapping studies in pepper.     

Potential for interspecific hybridization between <Emphasis Type="Italic">Zizina emelina</Emphasis> and <Emphasis Type="Italic">Zizina otis</Emphasis> (Lepidoptera: Lycaenidae)

Environmental changes such as global warming and biological invasion caused by human activities raise the possibility of secondary contact between the endangered butterfly species Zizina emelina and its sibling species Zizina otis in Japan. To assess the possible risks from their habitats overlapping, we investigated the potential for hybridization and the development of F1 individuals. We observed successful mating of the two sibling species under artificial conditions. The presence of a postzygotic hybridization barrier was supported by the delay of larval development only in females; a delay did not occur in males. Existence of the barrier was also supported by a decreased egg hatching rate in one brood; this was likely associated with infection with Wolbachia, a bacterium manipulating the reproductive capability of its host. The size and wing markings of F1 hybrid individuals were intermediate between those of the two species. These results suggest that, if Z. emelina and Z. otis are distributed sympatrically in the future, there is a possibility of introgression and reproductive interference between the two species, which would increase the risk of decline of each species.     

Isolation and characterization of polymorphic microsatellite markers in <Emphasis Type="Italic">Cupressus </Emphasis><Emphasis Type="Italic">chenggiana</Emphasis> S. Y. Hu (Cupressaceae)

Cupressus chenggiana S. Y. Hu (Cupressaceae) is an endemic and endangered conifer species in southwest China. In order to study the population genetics and design the effective conservation methods, we aimed to develop microsatellite primers for this species in the present study. We developed eight new microsatellite loci for this species through biotin capture method. Polymorphism of each locus was further assessed in 18 individuals from three geographically distant populations. The number of alleles per locus ranged from 6 to 11 with an average of 8.13. The observed and expected heterozygosities ranged from 0.219 to 0.296 and from 0.374 to 0.470, with averages of 0.254 and 0.417, respectively. We further found that three of nine microsatellite loci developed previously for another congeneric species showed polymorphic banding patters. We performed primer-crossing tests of these loci in the other two congeneric species which are closely related to C. chenggiana (C. gigantea and C. duclouxiana). These microsatellite markers would be effective for analyzing genetic diversity and population genetic structure of this species and its morphological differentiation with the close relatives.     

Genetic variation among endangered Irish red grouse (<Emphasis Type="Italic">Lagopus lagopus hibernicus</Emphasis>) populations: implications for conservation and management

Extant populations of Irish red grouse (Lagopus lagopus hibernicus) are both small and fragmented, and as such may have an increased risk of extinction through the effects of inbreeding depression and compromised adaptive potential. Here we used 19 microsatellite markers to assay genetic diversity across 89 georeferenced samples from putatively semi-isolated areas throughout the Republic of Ireland and we also genotyped 27 red grouse from Scotland using the same markers. The genetic variation within Ireland was low in comparison to previously published data from Britain and the sample of Scottish red grouse, and comparable to threatened European grouse populations of related species. Irish and Scottish grouse were significantly genetically differentiated (F_ST = 0.07, 95% CI = 0.04–0.10). There was evidence for weak population structure within Ireland with indications of four distinct genetic clusters. These correspond approximately to grouse populations inhabiting suitable habitat patches in the North West, Wicklow Mountains, Munster and Cork, respectively, although some admixture was detected. Pair-wise F_ST values among these populations ranged from 0.02 to 0.04 and the overall mean allelic richness was 5.5. Effective population size in the Munster area was estimated to be 62 individuals (95% CI = 33.6–248.8). Wicklow was the most variable population with an AR value of 5.4 alleles/locus. Local (Munster) neighbourhood size was estimated to 31 individuals corresponding to an average dispersal distance of 31 km. In order to manage and preserve Irish grouse we recommend that further fragmentation and destruction of habitats need to be prevented in conjunction with population management, including protection of the integrity of the existing population by refraining from augmenting it with individuals from mainland Britain to maximise population size.     

Analysis of alien introgression in coffee tree (<Emphasis Type="Italic">Coffea</Emphasis><Emphasis Type="Italic">arabica</Emphasis> L.)

The transfer of desired traits from related wild diploid Coffea species into the cultivated allotetraploid C. arabica is essential in coffee breeding to develop pest/disease-resistant cultivars. The present work is an attempt to gain insights into alien introgression in C. arabica. An F2 population derived from a cross between T5296 and Et6 was analysed with simple sequence repeat (SSR; microsatellite) and amplified fragment length polymorphism (AFLP) molecular markers. The T5296 is a derivative of an interspecific hybrid introgressed by the diploid C. canephora species and Et6 is a wild Ethiopian accession of C. arabica. The origin of the revealed polymorphism was determined by comparisons using representative accessions from C. arabica and its two diploid parental species, C. eugenioides and C. canephora. The number and mode of inheritance of canephora-introgressed segments were investigated, as well as their sub-genome localisation and rate of recombination. The results suggested that the transfer of desirable genes into C. arabica from C. canephora is not limited by the ploidy level differences or the suppression of recombination between the different genomes.     

Assessment of hybridisation between the endangered Chatham Island black robin (<Emphasis Type="Italic">Petroica traversi</Emphasis>) and the Chatham Island tomtit (<Emphasis Type="Italic">Petroica macrocephala chathamensis</Emphasis>)

Hybridisation between an endangered species and a more common species can facilitate population decline and extinction of the endangered species due to wasted reproductive effort, outbreeding depression and/or swamping of alleles due to widespread or complete admixture. The Chatham Island black robin (Petroica traversi) is an endangered songbird species, which was reduced to only five individuals in 1980. Intensive cross-fostering, whereby black robin offspring were placed into nests of the closely related Chatham Island tomtit (Petroica macrocephala chathamensis) to increase reproductive output, contributed to the rapid recovery of the species within 10 years. Several hybridisation events occurred and although those hybrids were successfully eliminated from the population, concerns remained for the possibility of introgression between the two species that may have gone unnoticed. In this study, we genotyped seven microsatellite loci in both species from the two islands where they coexist, to assess the level of hybridisation and the extent of introgression between the two species. The two species shared no alleles at five of the seven loci genotyped, and cluster analysis, AMOVA and admixture analysis of a total of 174 black robins and 78 Chatham Island tomtits showed no evidence of hybridisation or introgression on either of the two islands where they co-exist. As a result, there is no evidence that black robins are currently in any danger of population decline or extinction through hybridisation with tomtits, although small population size and skewed sex ratio, particularly in the smaller of the two populations, may facilitate future hybridisation events.     

Conservation of Nuclear SSR Loci Reveals High Affinity of <Emphasis Type="Italic">Quercus infectoria</Emphasis> ssp. <Emphasis Type="Italic">veneris</Emphasis> A. Kern (Fagaceae) to Section <Emphasis Type="Italic">Robur</Emphasis>

Conservation of 16 nuclear microsatellite loci, originally developed for Quercus macrocarpa (section Albae), Q. petraea, Q. robur (section Robur), and Q. myrsinifolia, (subgenus Cyclobalanopsis) was tested in a Q. infectoria ssp. veneris population from Cyprus. All loci could be amplified successfully and displayed allele size and diversity patterns that match those of oak species belonging to the section Robur. At least in one case, limited amplification and high levels of homozygosity support the occurrence of “null alleles” caused by a possible mutation in the highly conserved primer areas, thus hindering PCR. The sampled population exhibited high levels of diversity despite the very limited distribution of this species in Cyprus and extended population fragmentation. Allele sizes of Q. infectoria at locus QpZAG9 partially match those of Q. alnifolia and Q. coccifera from neighboring populations. However, sequencing showed homoplasy, excluding a case of interspecific introgression with the latter, phylogenetically remote species. Q. infectoria ssp. veneris sequences at this locus were concordant to those of other species of section Robur, while sequences of Quercus alnifolia and Quercus coccifera were almost identical to Q. cerris.     

Incongruence among mitochondrial,chloroplast and nuclear gene trees in <Emphasis Type="Italic">Pinus</Emphasis> subgenus <Emphasis Type="Italic">Strobus</Emphasis> (Pinaceae)

Introgression has been considered to be one of main factors leading to phylogenetic incongruence among different datasets at lower taxonomic levels. In the plants of Pinaceae, the mtDNA, cpDNA, and nuclear DNA (nrDNA) may have different evolutionary histories through introgression because they are inherited maternally, paternally and biparentally, respectively. We compared mtDNA, cpDNA, and two low-copy nrDNA phylogenetic trees in the genus Pinus subgenus Strobus, in order to detect unknown past introgression events in this group. nrDNA trees were mostly congruent with the cpDNA tree, and supported the recent sectional and subsectional classification system. In contrast, mtDNA trees split the members of sect. Quinquefoliae into two groups that were not observed in the other gene trees. The factors constituting incongruence may be divided into the following two categories: the different splits within subsect. Strobus, and the non-monophyly of subsect. Gerardianae. The former was hypothesized to have been caused by the past introgression of cpDNA, mtDNA or both between Eurasian and North American species through Beringia. The latter was likely caused by the chimeric structure of the mtDNA sequence of P. bungeana, which might have originated through past hybridization, or through a horizontal transfer event and subsequent recombination. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Transferability and Level of Heterozygosity of Microsatellite Markers in <Emphasis Type="Italic">Citrus</Emphasis> Species

Microsatellite markers are a powerful tool for genetic studies, including germplasm conservation, cultivar identification, and integration of linkage maps. Several works have shown that primer pairs designed for one species can be used in related species to facilitate wider application because it reduces the costs for primer development. The objective of this study was to evaluate the transferability of microsatellite primers which was previously developed from the genomic library of Pêra sweet orange (Citrus sinensis L. Osbeck) and to determine the level of heterozygosity between citrus accessions and related genera. Twenty-four microsatellite loci were evaluated on 12 genotypes of Citrus, Poncirus, and an intergeneric hybrid. All analyzed markers were transferable across all genotypes. Seventeen loci were polymorphic, and the number of alleles per loci ranged from one to six. The lowest level of heterozygosity was observed for Poncirus trifoliata (L.) Raf. cultivars while the highest level was for Swingle citrumelo. In general, microsatellite markers showed wide genetic variation and demonstrated that they can be useful in citrus breeding programs.