SEGREGATION IN NEW ALLOPOLYPLOIDS OF GOSSYPIUM. V. MULTIVALENT FORMATION IN NEW WORLD X ASIATIC AND NEW WORLD X WILD AMERICAN HEXAPLOIDS

The New World tetraploid cottons, G. hirsutum and G. barbadense, are natural amphidiploids (genome formula, 2[AD]) combining species of the cultivated Asiatic (2A) and wild American (2D) groups of diploid cottons. Multivalent frequency, per cell, for 2 New World X Asiatic synthetic hexaploids, G. hirsutum X G. arboreum and G. barbadense X G. arboreum, is 6.68 and 7.80, respectively. Multivalents per cell for a series of New World X wild American synthetic hexaploids are: New World X G. harknessii, 3.65;— X G. armourianum, 3.96;— X G. aridum, 3.48;— X G. lobatum, 3.66; — X G. gossypioides, 1.13. The expected correlation between multivalent frequency and genetic segregation (e.g., high multivalent frequency = high recovery of recessives, and vice versa) for these hexaploids is realized for the near-allopolyploids (New World X wild American) but only approximated for the near-autopolyploid combinations, New World X Asiatic. This is explained on the basis that different homogenetic:heterogenetic bivalent ratios are expected in autopolyploids as compared to allopolyploids.     

MOLECULAR EVIDENCE FOR HOMOPLOID RETICULATE EVOLUTION AMONG AUSTRALIAN SPECIES OF GOSSYPIUM

Interspecific hybridization and introgression are important evolutionary processes in plants, but their full significance with respect to speciation at the diploid level remains unresolved. In this study, molecular markers from the plastid and nuclear genomes were used to document an unusual evolutionary history of Gossypium bickii Prokh. (Malvaceae). This species is one of three morphologically similar Australian cottons (along with G. austrate F. Muell. and G. nelsonii Fryx.) in section Hibiscoidea. In contrast to expectations based on previous morphological data, cladistic analysis of maternally inherited cpDNA restriction site mutations unites G. bickii with G. sturtianum J. H. Willis, a morphologically distant species in a different taxonomic section (Sturtia). Few restriction site mutations distinguish the plastomes of G. bickii and G. sturtianum, but these two cpDNAs are differentiated from those of G. australe and G. nelsonii by a minimum of 33 mutations (out of 640 sites scored). These two highly distinct clades are not supported by phylogenetic analyses of allozyme markers (from 58 populations) and restriction site mutations in nuclear ribosomal DNAs. Rather, phylogenies based on 83 nuclear markers indicate that G. bickii shares a more recent common ancestor with G. australe and G. nelsonii than it does with G. sturtianum. We suggest that the striking discrepancy between independent molecular phylogenies from two different genomes indicates a biphyletic ancestry of G. bickii. Our preferred hypothesis involves an ancient hybridization, in which G. sturtianum, or a similar species, served as the maternal parent with a paternal donor from the lineage leading to G. australe and G. nelsonii. Because we detected no G. sturtianum nuclear genes in G. bickii, we suggest that the nuclear genomic contribution of the maternal parent was subsequently eliminated from the hybrid or its descendent maternal lineage. Several possible mechanisms of cytoplasm transfer are suggested, including repeated backcrossing of the hybrid, as female, into the paternal donor lineage, selection against recombinant nuclear genomes and a form of apomixis known as semigamy. This example, and several others in Gossypium as well as other genera, attest to the evolutionary possibility of interspecific cytoplasmic transfer, and perhaps the origin of diploid species via reticulate speciation. In addition, this study offers an example of natural cytoplasmic introgression without long-term survival of nuclear genes from the maternal progenitor.     

THE CYTOLOGY AND PHYLOGENETICS OF THE DIPLOID SPECIES OF GOSSYPIUM

Meiotic chromosome behavior of 11 inter-genomic hybrids of Gossypium (2n = 26) were investigated. Per cell univalent frequencies at meiotic metaphase I in these hybrids were: A genome × Cgenome—G. herbaceum × sturtianum, 10.53; G. herbaceum × australe, 18.05. A genome × E genome—G. smnalense × arboreum, 21.82. B genome × C genome—G. anomalum × sturtianum, 9.23; G. anomalum × australe, 13.11. B genome × D genome—G. anomalum × klotzschianum, 17.45; G. anomalum × raimondii, 18.83. C genome × D genome—G. robinsonii × davidsonii, 12.77; G. sturtianum (armourianum × thurberi), 8.63. C genome × E genome—G. somalense × australe, 23.78; G. somalense × bickii, 25.58. Trivalent and quadrivalent frequencies were relatively high for those hybrids involving a C genome species, indicating that a reciprocal translocation differentiates the C genome from the A, B, D, and E genomes. The results of this study and the data of similar studies cited from the literature on Gossypium cytogenetics are discussed relative to the phylogenetics and evolution of the major (genome) groups of Gossypium and their constituent taxa.     

Somatic embryogenesis and plant regeneration from different wild diploid cotton (Gossypium) species

Calli were successfully induced from hypocotyls of eight wild diploid cotton species (Gossypium) on MSB (MS salts and B₅ vitamins) medium supplemented with 0.09 μM 2,4-D (2,4-dichlorophenoxyacetic acid) and 2.32 μM KT (kinetin). Plant growth regulator (PGR) combinations, adding GA₃ (Gibberellic acid), high inorganic salt stress, and PGR-free media were used to induce embryogenic calli from nonembryogenic calli. Embryogenic cultures were induced from G. aridum S. (D₄ genome), G. davidsonii K. (D₃-d genome), G. klotzschianum A. (D₃-k genome), G. raimondii U. (D₅ genome), and G. stocksii M. (E₁ genome). We then observed somatic embryogenesis in the five species while calli of G. africanum V. (A₁-2 genome), G. anomalum W. (B₁ genome), and G. bickii P. (G genome) remained nonembryogenic. Somatic embryogenesis was adjusted by changing sugar sources, regulating combinations of PGRs, and using cell suspension culture. Embryos at various developmental stages produced mature and germinating embryos when cultured on filter paper placed on the media containing different sugar sources. The utility of different sugar sources promoted globular embryos developing into cotyledonary stage and increased the frequency of cotyledonary embryos developing into normal plants. Normal plantlets were regenerated from G. davidsonii, G. klotzschianum, G. raimondii, and G. stocksii. Only abnormal plantlets were obtained in G. aridum. This work will contribute to broadening the number of regenerable cotton species and provide foundations for somatic hybridization in cotton to create new germplasm.     

SEGREGATION IN NEW ALLOPOLYPLOIDS OF GOSSYPIUM. IV. SEGREGATION IN NEW WORLD × ASIATIC AND NEW WORLD × WILD AMERICAN HEXAPLOIDS

Phillips , Lyle L. (North Carolina State Coll., Raleigh.) Segregation in new allopolyploids of Gossypium. IV. Segregation in New World × Asiatic and New World × wild American hexaploids. Amer. Jour. Bot. 49(1): 51–57. 1962.—The New World tetraploid cottons, G. hirsutum and G. barbadense, are natural amphidiploids (genome formula, 2 [AD]) combining species of the cultivated Asiatic (2A) and wild American (2D) groups of diploid cottons. Genetic segregation for marker alleles in New World × Asiatic and New World × wild American synthetic hexaploids have been determined. Average segregation for several loci in New World × Asiatic hexaploids is close to the autoploid 5:1 ratio, ranging from 5.1 to 6.8:1. Average segregation for 3 loci (L, Rd, and R₁) common to a series of New World × wild American hexaploids is: New World × G. raimondii, 9.3:1;–× G. harknessii, 16.4:1;–× G. armourianum, 17.4:1;–× G. aridum, 20.3:1;–× G. lobatum, 21.4:1–× G. thurberi, 32.9:1;–× G. gossypioides, 66.5:1. These data are discussed, and the method by which they were derived is compared with other cytogenetical means of discerning phylelic interrelationships among Gossypium species.     

Triploid and tetraploid hybrids from diploid x tetraploid crosses in Grindella (compositae)

Crosses between the diploids G. oxylepis var. eligulata Steyermark (Mexico) and G. havardii Steyermark (New Mexico) and the tetraploid G. aphanactis Rydb. (New Mexico) were made. With G. aphanactis as the pistillate parent and G. havardii as the pollen parent a triploid hybrid was obtained in which the maximum meiotic configuration observed was 6m. The plant was 10 % fertile. Two triploid hybrid plants were also obtained when G. aphanactis was used as the pistillate parent and G. oxylepis var. eligulata was the pollen parent. One plant was about 20 % fertile and the other had a maximum configuration of 3_II + 4_III. The reciprocal cross produced a tetraploid which had a maximum configuration of 6_II + 3_IV and was 8 % fertile. The tetraploid plant undoubtedly resulted from the union of an unreduced gamete from the 2n parent and a normally reduced gamete from the tetraploid. Morphology of the hybrids was usually intermediate when compared with the parental species, although some characters in the triploids were those of the diploid parent. Chromosome end arrangements of the respective genomes and putative pairing relationships are presented and phylogenetic implications are discussed. It is concluded that G. aphanactis is more closely related to G. havardii than to G. oxylepis var. eligulata.     

Molecular phylogenetics of Kosteletzkya (Malvaceae,Hibisceae) reveals multiple independent and successive polyploid speciation events

Kosteletzkya s.s. is a genus of 17 species (excluding the endemic species of Madagascar), found in the New World, continental Africa, Madagascar, and Southeast Asia. Recent chromosome counts revealed diploid, tetraploid, and hexaploid species. To estimate the history of the genus, we sequenced nuclear and plastid loci for nearly all Kosteletzkya spp., in the majority of cases, with multiple accessions per species. The African species form a paraphyletic grade relative to a New World clade. Polyploidy has occurred only in some African species, resulting in the relatively ancient formation of one putative autotetraploid species (K. semota), one recent allotetraploid species (K. borkouana), two relatively ancient allotetraploid species (K. begoniifolia and K. rotundalata) and one recent allohexaploid species (K. racemosa). Our inferences regarding the hypothesized parentage of the polyploids mostly corroborate previous work based on chromosome‐pairing patterns in artificial hybrids, highlighting the utility of these complementary data sources. © 2015 The Linnean Society of London, Botanical Journal of the Linnean Society, 2015, 179 , 421–435.     

Phylogenetics and taxonomy of the New World leafy spurges,Euphorbia section Tithymalus (Euphorbiaceae)

The 480 species of leafy spurges, Euphorbia subgenus Esula, represent the main temperate radiation in the large genus Euphorbia. This group is distributed primarily in temperate Eurasia, but with smaller, disjunct centres of diversity in the mountains of the Old World tropics, in temperate southern Africa and in the New World. The majority of New World diversity (32 species) occurs in a single section, section Tithymalus. We analysed sequences of the nrITS and plastid ndhF, trnH‐psbA, trnS‐trnG and trnD‐trnT regions to reconstruct the phylogeny of section Tithymalus and to examine the origins and diversification of the species native to the New World. Our results indicate that the New World species of section Tithymalus form a clade that is sister to the widespread, weedy E. peplus. The New World species fall into two primary groups: a ‘northern annual clade’ from eastern North America and a diverse clade of both annual and perennial species that is divided into three subgroups. Within the second group, there is a small ‘southern annual clade’ from Texas and northern Mexico, a perennial ‘Brachycera clade’ from the western United States and northern Mexico, and a perennial ‘Esuliformis clade’ from montane areas of Mexico, Guatemala, Honduras and the Caribbean island of Hispaniola. Ancestral state reconstructions indicate that the annual habit probably evolved in the ancestor of E. peplus and the New World clade, with a subsequent reversal to the perennial habit. In conjunction with this phylogenetic framework, the New World species of section Tithymalus are comprehensively reviewed. © 2014 The Linnean Society of London, Botanical Journal of the Linnean Society, 2014, 175 , 191–228.     

Chromosome painting in<Emphasis Type="Italic"> Callicebus lugens</Emphasis>, the species with the lowest diploid number (2<Emphasis Type="Italic">n</Emphasis>=16) known in primates

Cytogenetic studies have shown that New World primates are karyologically diverse and highly derived. The genus Callicebus is the best example of this karyological diversity, with diploid numbers ranging from 2n=50 to 2n=16. We report on Callicebus lugens, which has the lowest diploid number (2n=16) yet found in the primate order and represents a striking example of extreme karyotypic shuffling. To better understand the genomic rearrangements that have resulted in this extremely low diploid number, we mapped chromosome homologies between C. lugens and humans by in situ hybridization. The total number of hybridization signals was 42, excluding the Y chromosome, with a total of 34 syntenic associations not found in humans. This species has one of the most derived karyotypes among the Platyrrhini. Fusion has been the predominant mode of karyological evolution, although fissions and inversions have also transformed the C. lugens karyotype. Remarkably in such a highly rearranged karyotype, the synteny of 11 human chromosomes (4, 5, 9, 12, 13, 14, 17, 18, 20, 21, and X) was maintained intact, even if most of these human-homologous gene clusters were translocated. Other human syntenies, such as homologues to human chromosomes 10 and 16, were highly fragmented. Comparisons of the C. lugens-human homology map with those of other New World primates have not yet helped establish a phylogenic arrangement between congeneric species or link Callicebus with any other genus.Communicated by S. Henikoff     

FLORAL PIGMENTATION STUDIES IN THE GENUS GOSSYPIUM. III. QUALITATIVE ANALYSIS OF TOTAL FLAVONOL CONTENT FOR TAXONOMIC STUDIES

Despite the potential contribution suggested from chromatographic studies of many groups, taxonomic conclusions based on paper chromatography alone may carry some inherent errors. In many instances chemical differences between taxa cannot be characterized by two-dimensional chromatography of crude extracts. Pigment diversity may go unnoticed in such a study, and conclusions based on simple chromatographic results may show too much similarity between the taxa being compared. The resolution of chromatographic separations of the often very complex mixtures encountered in crude plant extracts can be greatly improved by a preliminary column separation, and in this study a method of pigment analysis employing both preliminary column and subsequent paper chromatography is used. While it is usually impractical to identify all of the components of a flavonoid complex, each member should be characterized to the degree that it can be distinguished from all others. Here, the characterization of a component includes its rate of movement in the column, relative position and color under ultraviolet light on the chromatogram, the absorption spectrum in ethanol and the change in the absorption spectrum when a reagent is added to the ethanol which has a particular effect on the spectral properties of that flavonoid. With very few exceptions no one criterion of characterization is definitive for any component. More than 20 flavonoid pigments have been observed in the two tetraploid Gossypium species, G. barbadense and G. hirsutum. Only 10 of the constituents were common to the two species. The results of a previous study based on two-way paper chromatography of crude extracts makes the two species appear much more similar in flavonoid composition than is indicated by the more detailed column-paper chromatography presented here. The degree of difference between G. hirsutum and G. barbadense is surprisingly large in light of the generally accepted theory of their common origin. The value of chromatographic-chemotaxonomic studies is greatly increased if the chemical systems involved are characterized.     

PARTHENOGENESIS IN THE TROPICAL GEKKONID LIZARD,NACTUS ARNOUXII (SAURIA: GEKKONIDAE)

As currently diagnosed, Nactus arnouxii includes unisexual and bisexual populations. The geographic distribution of each type was estimated by sex-ratio analysis of samples from southwestern Pacific islands. Males were absent from southern Vanuatu (excluding Aneityum), New Caledonia, and all islands to the east that have been sampled. Both types of populations appear to be present on Aneityum. Chromosome and protein analyses showed that the bisexual populations are highly polytypic and probably consist of more than one biological species. The unisexual N. arnouxii were diploid, highly heterozygous, and showed no genetic segregation. The absence of segregation suggests clonal reproduction, substantiating parthenogenesis. The high heterozygosity of the unisexuals indicates their origin through hybridization. One parent was genetically similar to the extant bisexual population from northern Vanuatu. The other parent has not been identified, but its genetic characteristics are predicted by phylogenetic analysis.     

EXPERIMENTAL HYBRIDIZATION,CHROMOSOMAL DIVERSITY,AND PHYLOGENY WITHIN GAURA (ONAGRACEAE)

Patterns of interfertility for intersectional hybridizations in Gaura are generally consistent with current taxonomic hypotheses regarding the sectional division of the genus. Crossability is generally lower for intersectional crosses than for intrasectional, interspecific crosses. Average intersectional cross-success ranged from 0–14% among the eight sections, and a total of 54 intersectional hybrids were produced from 1,872 intersectional pollinations. Low rates of capsule-set and no intersectional hybrids were produced by G. mutabilis (section Gauridium), an early offshoot of a primitive ancestor of Gaura. Two species of section Xerogaura that are regarded as relicts of the primitive ancestor of all other Gaura showed low averages for cross-success, but did produce hybrids in combination with three relatively advanced sections (Campogaura, Stipogaura, Pterogaura). Low capsule-set and no intersectional hybrids were produced by G. parviflora (section Schizocarya). Extreme morphological specialization for autogamous reproduction has been accompanied by reproductive isolation of G. parviflora. Only three hybrids resulted from crosses using G. coccinea (section Campogaura), a polyploid complex. Each successful cross paired G. coccinea with a putative progenitor, either a species of section Xerogaura or G. villosa of section Stipogaura. Hybrids of G. coccinea with odd ploidy number showed reduced pollen staining. Species of Stipogaura produced only three hybrids, one each in combination with species of sections Xerogaura, Campogaura, and Pterogaura. Gaura drummondii (section Xenogaura) registered the highest average cross-success despite being a tetraploid. All 25 hybrids of G. drummondii resulted from crosses with G. suffulta, and were triploids that showed reduced pollen staining. Intersectional crosses fail to support the hypothesized relationships of G. drummondii either to G. coccinea or to species of section Stipogaura. Section Gaura produced moderate averages of cross-success, but all 20 hybrids resulted from crosses with G. suffulta. Fifty of the 54 intersectional hybrids were descended from a species of section Pterogaura. Crosses that used G. suffulta as one parent produced 49 of these hybrids. Four hybrids were from crosses with G. macrocarpa (section Xerogaura), and the remaining 45 were due to the recurrent success of crosses that paired G. suffulta as maternal parent with either G. drummondii or a species of section Gaura.     

华中植物区系新资料

该文报道了产鄂西和湘西北的双子叶植物省级分布新记录1个属和8个种。湖北分布新记录有龙珠(Tubocapsicum anomalum)、直梗高山唐松草(Thalictrum alpinum var. elatum)、虫莲(Sanguisorba filiformis)、腺地榆(S. officinalis var. glandulosa)、平叶酸藤子(Embelia undulata)、广西地海椒(Physaliastrum chamaesarachoides)、东北薄荷(Mentha sachalinensis)、黄鼠狼花(Salvia tricuspis),其中龙珠对应的龙珠属(Tubocapsicum)是湖北新记录属;湖南分布新记录有宝兴藨寄生(Gleadovia mupinense)。根据IUCN标准,宝兴藨寄生属濒危(EN)物种。这些新记录的发现丰富了华中植物区系资料,在植物保护方面也有一定意义。     

ASSESSMENT OF EVOLUTIONARY AFFINITIES IN GOSSYPIUM BY PROTEIN ELECTROPHORESIS

Protein band patterns from 25 species of Gossypium were obtained by electrophoresis of crude seed extracts on polyacrylamide gel. Band homologies between species were verified by electrophoresis of a mixture of their extracts. The patterns were found to be largely consistent with the conventional classification of the diploids into 6 genomic groups, A–F. However, G. triphyllum and G. bickii showed unique patterns differing respectively from those of the B and C groups, and G. australe showed closer affinity with the Arabian E- than with the Australian C-genome species. Affinities among the D-genome species were different from those implied by their former grouping into taxonomic sections but remarkably similar to those indicated in the most recent taxonomic revision of the genus. They were classifiable into two subgroups, β and ɛ. The clustering pattern of the diploids based on correlation coefficients calculated from densitometer curves of the electrophoretic spectra suggested that the genomic groups were derived from an African progenitor type, and that the American β and ɛ subgroups, most closely related to the African B- and the Arabian E-genome groups respectively, evolved under comparative mutual isolation, possibly separated by the Tertiary Amazonas basin.     

A REAPPRAISAL OF THE SUBGENUS GLYCINE

The genus Glycine Willd. is divided into three subgenera, Glycine Willd., Soja (Moench) F. J. Herm., and Bracteata Verdc. Six species are currently recognized in the subgenus Glycine: G. canescens F. J. Herm., G. clandestina Willd., G. falcata Benth., G. latrobeana (Meissn.) Benth., G. tabacina (Labill.) Benth., and G. tomentella Hayata. Distribution of the subgenus extends from south China to Tasmania and includes several Pacific islands. A collection of these species was examined cytologically and morphologically in an attempt to evaluate existing variability between and within taxa. Chromosome counts confirmed G. canescens, G. clandestina and G. falcata to be diploid with 2n = 40. Both tetraploids (2n = 80) and diploids were found in G. tabacina, the latter restricted to Australia. Glycine tomentella accessions were primarily tetraploid, but several collections from New South Wales, Australia, were found to be aneuploid with 78 chromosomes. One collection was aneuploid at the diploid level with 38 chromosomes. Meiosis appeared normal in the aneuploids with regular bivalent formation. Several accessions previously identified as G. tomentella were diploid. Seed of G. latrobeana was not available for analysis. Numerical techniques in the form of cluster analysis and principal components analysis were applied to morphological data on vegetative and inflorescence characters obtained from each collection. Numerical analysis grouped the accessions essentially according to current species delimitations with some exceptions. Glycine tabacina specimens from Taiwan approached G. clandestina in several characteristics. The diploid G. tomentella specimens formed a separate cluster and appeared morphologically distinct from the remaining taxa.     

Home range,movements, and density of the central stoneroller,Campostoma anomalum,in a small Ohio stream

Synopsis A population of central stonerollers, Campostoma anomalum, in Harker's Run, Butler County, Ohio U.S.A., was examined during autumn, 1980, to determine the species' movements, density, and home range size. During the study period, 170 fish were marked by fin clips and released into the specific pool or riffle where they were captured within the 187 m study section. Eighty percent of the recaptured, marked fish (20) were recaptured in their initial capture area (specific pool or riffle). No fish moved more than 135 m from its original capture area. Density estimates of C. anomalum for each pool and riffle within the study section ranged from 0.10–3.91 fish m⁻² (mean = 1.25 fish m⁻²). Home range size was estimated to be 35.2 ± 14.1 m (mean ± 95% CI) of stream length. Campostoma anomalum in Harker's Run occurred at densities similar to those reported for the species in other streams, and their home ranges in this system were of similar size to those of other small, stream-dwelling fishes.     

CYTOPLASMIC EFFECTS ON THE DIFFERENTIATION OF ANTHERS AND OVULES OF COTTON

Reciprocal crosses of Upland cotton with a hybrid derived from (Gossypium anomalum × G. thurberi) × G. hirsutum produced progenies differing significantly in anther development and in the production of supernumerary ovules outside the ovary. Plants with G. anomalum cytoplasm produced fewer anthers than the reciprocal hybrids with G. hirsutum cytoplasm, had a higher percentage of sterile anthers, and were far more likely to form external ovules on an abnormally thickened tip of the staminal tube. The number of locules and ovules within the ovary was not significantly affected by cytoplasm.     

POLYPLOIDY,DYSPLOIDY, AND CHROMOSOME PAIRING IN ECHEVERIA (CRASSULACEAE) AND ITS HYBRIDS

The 140+ species of Echeveria have more than 50 gametic chromosome numbers, including every number from 12 through 34 and polyploids to n = ca. 260. With related genera, they comprise an immense comparium of 200+ species that have been interconnected in cultivation by hybrids. Some species with as many as 34 gametic chromosomes include none that can pair with each other, indicating that they are effectively diploid, but other species with fewer chromosomes test as tetraploids. Most diploid hybrids form multivalents, indicating that many translocations have rearranged segments of the chromosomes. Small, nonessential chromosomal remnants can be lost, lowering the number and suggesting that higher diploid numbers (n = 30–34) in the long dysploid series are older. These same numbers are basic to most other genera in the comparium (Pachyphytum, Graptopetalum, Sedum section Pachysedum), and many diploid intergeneric hybrids show very substantial chromosome pairing. Most polyploid hybrids here are fertile, even where the parents belong to different genera and have very different chromosome numbers. This seems possible only if corresponding chromosomes from a polyploid parent pair with each other preferentially, strong evidence for autopolyploidy. High diploid numbers here may represent old polyploids that have become diploidized by loss, mutation, or suppression of duplicate genes, but other evidence for this is lacking. Most species occur as small populations in unstable habitats in an area with a history of many rapid climatic and geological changes, presenting a model for rapid evolution.     

Canary Grasses (Phalaris,Poaceae): biogeography,molecular dating and the role of floret structure in dispersal

Canary grasses (Phalaris, Poaceae) include 21 species, widely spread throughout the temperate and subtropical regions of the world with two centres of diversity: the Mediterranean Basin and western North America. The genus contains annual and perennial, endemic, cosmopolitan, wild, and invasive species with diploid, tetraploid and hexaploid cytotypes. As such, Phalaris presents an ideal platform to study diversification via historic hybridization and polyploidy events, and geographical dispersal in grasses. We present the first empirical phylogeographic study for Phalaris testing current, intuitive hypotheses on the centres of origin, historic dispersal events and diversification within a geological timeframe. Bayesian methods (beast , version 1.6.2) were used to establish divergence dates, and dispersal–vicariance analyses (rasp , version 2.1b) were implemented for ancestral node reconstructions. Our phylogeographic results indicate that the genus emerged during the Miocene epoch [20.6–8.4 Ma (million years ago)] in the Mediterranean basin followed by dispersal and vicariance events to Africa, Asia and the Americas. We propose that a diploid ancestor of P. arundinacea migrated to western North America via the Bering Strait, where further diversification emerged in the New World. It appears that polyploidy played a major role in the evolution of the genus in the Old World, while diversification in the New World followed a primarily diploid pathway. Dispersal to various parts of the Americas followed different routes. Fertile florets with hairy protruding sterile lemmas showed significant correlation with wider geographical distribution.