Contributions to the Cytotaxonomy of the Commelinaceae. Gibasis linearis and its allies

Species of the Gibasis linearis alliance collected in Mexico in 1976 are shown to have a chromosome constitution of x = 6, but x = 5 has also been found in some populations of G. rhodantha and G. speciosa. These two basic numbers are associated with distinctive karyotypes, 2M + 4A and 3M + 2A respectively, which show a Robertsonian relationship with each other. The existence of 2n = 22 in G. speciosa , combining both basic numbers at the amphidiploid level provides evidence of pairing between metacentrics and acrocentrics in such a way as to substantiate the view that fusion or fission of chromosomes is responsible for the modification of basic number. This survey provides a basis for other studies which will determine the chromosome relationships of the species irrespective of chromosome number in this family.     

Contributions to the cytotaxonomy of the Commelinaceae. Chromosome evolution in Tradescantia section Cymbispatha

The five species of Tradescantia section Cymbispatha studied, including one species T. poelliae D. R. Hunt, have chromosome numbers of In = 12, 14, 16, 22, 28, 30 and 36 and karyotypes of acrocentric, metacentric or telocentric chromosomes, or mixtures of both acrocentric and metacentric chromosomes. The numbers of major chromosome arms of these cytotypes give a nombre fondamentaP series of 14, 28, 42 and 56 which, in combination with meiotic analyses, indicates plants which, in genetical terms at least, are diploid, tetraploid, hexaploid and octoploid. This series has evolved from a 2 n = 14 acrocentric or telocentric karyotype by a combination of Robertsonian fusion and polyploidy. Pseudo-iso-chromosomes are sometimes formed in this evolutionary development and can persist as stable members of normal complements.     

Chromosome evolution in the Gibasis linearis group (Commelinaceae)

Karyotypes, DNA amounts, and meiotic behaviour were examined in population samples of two closely related species, Gibasis venustula and G. heterophylla, and their F₁ hybrids. All samples were diploid (2n=12). DNA amount was similar in G. heterophylla, G. venustula ssp. robusta, and some populations of G. venustula ssp. venustula but in 13 samples of the latter, it showed as much as a 60% difference despite karyotypic uniformity. Although DNA levels were related to the altitude of the habitat, there was some variation within two morphological and ecological races of subspecies venustula. Analysis of hybrid meiosis and pollen fertility demonstrated the cytogenetical discreteness of populations, races, and subspecies. Populations and races were concluded still to be evolving following ecological isolation. The significance of quantitative and qualitative genome changes in evolution and their bearing on the classification of these species is discussed.     

Chromosome evolution in the Gibasis linearis alliance (Commelinaceae)

Two related species of Gibasis, G. venustula (x = 6) and G. speciosa (x = 5) have been shown to be differentiated by a Robertsonian fusion. Meiotic analysis of the F₁ hybrids has revealed further chromosome differentiation of the parent species, involving several interchanges and inversions. These rearrangements tend to be concentrated in the Robertsonian group, and give rise to unusual meiotic configurations. The sets of the two species are nonetheless highly homologous as shown by high chiasma frequency and as much as 65% stainable pollen in the F₁. Models are proposed suggesting the possible evolutionary pathways of this karyotypic differentiation. The results are discussed in terms of chromosome evolution and its consequences for these species.     

Robertsonian change in allies ofZebrina (Commelinaceae)

Meiotic pairing inTradescantia soconuscana 2n=26 (6M+16A+4T) suggests that it has a tetraploid constitution which is not apparent in its chromosome number. Its nombre fondamental of 32 indicates that it could have evolved from an ancestor with x=8 by a combination of Robertsonian fusion, hybridization and polyploidy. The 2n=16 (8A+8T) karyotype of a closely related diploid supports this. The allied genusZebrina may have followed a similar method of chromosome evolution.     

Contributions to the cytotaxonomy of the Commelinaceae. Chromosome evolution in Tradescantia section Cymbispatha

The five species of Tradescantia section Cymbispatha studied, including one species T. poelliae D. R. Hunt, have chromosome numbers of In = 12, 14, 16, 22, 28, 30 and 36 and karyotypes of acrocentric, metacentric or telocentric chromosomes, or mixtures of both acrocentric and metacentric chromosomes. The numbers of major chromosome arms of these cytotypes give a nombre fondamentaP series of 14, 28, 42 and 56 which, in combination with meiotic analyses, indicates plants which, in genetical terms at least, are diploid, tetraploid, hexaploid and octoploid. This series has evolved from a 2 n = 14 acrocentric or telocentric karyotype by a combination of Robertsonian fusion and polyploidy. Pseudo-iso-chromosomes are sometimes formed in this evolutionary development and can persist as stable members of normal complements.     

The effect of B chromosome number on chiasma frequency within and between individuals of Gibasis linearis (Commelinaceae)

Meiotic analysis of 21 plants from a single population of Gibasis linearis which contained from 0 to 6 apparently identical B chromosomes showed that the mean chiasma frequencies were significantly higher with increasing numbers of Bs. It was also found that those meiotic cells of a 5B plant which contained fewer than five B chromosomes showed a marked fall in chiasma frequency, demonstrating that the influence of B chromosomes on chiasma formation in A chromosomes acts at a cellular rather than a whole-anther level.     

Contributions to the cytòtaxonomy of the Commelinaceae

Representatives of the Tradescantia geniculata alliance (genus Gibasis Rafin.) in cultivation at Kew display considerable cytological and morphological diversity. Chromosome complements consist of either large or small chromosomeS. Plants with small chromosomes have either 2 n = 16 or 2 n = 32, and all form only bivalents at meiosis and have presumed basic numbers of x – 8 and x = 8 or 16 respectively. The 2 n = 32 accessions are considered to represent T.geniculata in its strict sense; the identity of the 2 n =16 plant is uncertain. Plants with large chromosomes have either 2 n = 16 or 2n = 20 and each forms quadrivalents to the extent that they can be considered as cytological autotetraploidS. Basic numbers are then x = 4 and x =5, the lowest yet recorded for the Commelinaceae. The identity of the x = 4 species is uncertain. The x = 5 plants are readily identified as T.karwinskyana.     

Cytotaxonomy of Commelinaceae: chromosome numbers of some African and Asiatic species

Chromosome counts are reported for 32 taxa (31 species and 1 subspecies) belonging to 10 genera of Commelinaceae from seven African and Asiatic countries. Counts for 13 species and 1 subspecies are recorded for the first time. Published chromosome numbers for Anhicopsis and Polyspatha are confirmed. It is suggested that Pdisota, Pollia and Stanfieldidla each has a single basic number (x = 20, 16 and 11, respectively). The known cytological diversity in Floscopa is extended. The third continental African species of Coleolrype is found to have the same chromosome number (2n = 36) as the other two. The preponderance of the basic number x = 15 in Commelina is supported. The uncommon basic number x = 13 is reported in four taxa of Cyanotis together with karyotypic differences. The basic number x = 6 is found in a second species of Murdannia . Karyotypic data in addition to chromosome numbers are presented for 24 of the 32 taxa investigated. Karyotypes are found to be useful in assessing relationships in the family, and evolutionary trends in the karyotype are noted.     

Identification of Renner complexes and duplications in permanent hybrids of Gibasis pulchella (Commelinaceae)

Discovery of permanent hybridity in the very large chromosomes of Gibasis pulchella (Commelinaceae) has allowed specific identification of segmental interchanges in complex heterozygotes. The interchanges are confined to terminal regions, are sometimes very small, and may be unequal in size. Breakpoints have occurred close to major C-bands, probably at euchromatin/heterochromatin boundaries. Complete and disjunctional ring formation at meiosis results in the segregation of two Renner complexes, each of which can be specifically identified with C-banding. The complex carrying the interchanges is usually transmitted through the pollen. Certain chromosomes that have undergone more extensive change than the rest of the complement may have some special significance. There is evidence of small duplications within heterozygous genomes. Permanent hybridity in different organisms may have quite different origins, possibly initiated by major karyotype repatterning following the activation of transposons that generate chromosome breakage.Abbreviations p Short arm - q long arm - M metacentric - SM submetacentric - BS bisatellited chromosome in population 4 - UB unbanded chromosome in population 4 - II bivalent; closed meiotic ring configuration, e.g., 10, ring of ten - ch open chain configuration - NOR nucleolus organising region     

Robertsonian differentiation and preferential pairing revealed in species and F1 hybrids of theGibasis linearis group (Commelinaceae)

Three closely related species of theG. linearis group are differentiated by their basic numbers and ploidy levels. The change in basic number involves Robertsonian fusion, but the species also differ by interchange and cryptic structural changes revealed by meiotic pairing in F₁ hybrids.Chromosome Evolution in theGibasis linearis Group (Commelinaceae), II.—Part I:Kenton (1981a).     

The fate of multivalents during meiotic prophase in the hybrid Gibasis consobrina x G. karwinskyana Rafin. (Commelinaceae)

The chromosomes of the two closely related diploid species, Gibasis consobrina and G. karwinskyana (Commelinaceae; 2n=2x=10), are morphologically alike, yet form few chiasmate associations at metaphase I in the f₁ hybrid. During meiotic prophase, however, synaptonemal complexes join the majority of the chromosomes of the complement in complex multiple pairing configurations. The F₁ hybrid between different tetraploid genotypes of the same two species similarly forms multivalents during meiotic prophase, which are subsequently eliminated in favour of strictly homologous bivalents before metaphase I. One quadrivalent comprising interchange chromosomes inherited from one of the parents, usually persists to first metaphase. Evidently the resolution of multivalents to bivalents at first metaphase, which accounts for diploidisation, is not attributable to the elimination of multivalents per se, but of multivalents comprising chromosomes of limited homology.     

Contributions of rpb2 and tef1 to the phylogeny of mushrooms and allies (Basidiomycota, Fungi)

A phylogeny of the fungal phylum Basidiomycota is presented based on a survey of 160 taxa and five nuclear genes. Two genes, rpb2, and tef1, are presented in detail. The rpb2 gene is more variable than tef1 and recovers well-supported clades at shallow and deep taxonomic levels. The tef1 gene recovers some deep and ordinal-level relationships but with greater branch support from nucleotides compared to amino acids. Intron placement is dynamic in tef1, often lineage-specific, and diagnostic for many clades. Introns are fewer in rpb2 and tend to be highly conserved by position. When both protein-coding loci are combined with sequences of nuclear ribosomal RNA genes, 18 inclusive clades of Basidiomycota are strongly supported by Bayesian posterior probabilities and 16 by parsimony bootstrapping. These numbers are greater than produced by single genes and combined ribosomal RNA gene regions. Combination of nrDNA with amino acid sequences, or exons with third codon positions removed, produces strong measures of support, particularly for deep internodes of Basidiomycota, which have been difficult to resolve with confidence using nrDNA data alone. This study produces strong boostrap support and significant posterior probabilities for the first time for the following monophyletic groups: (1) Ustilaginomycetes plus Hymenomycetes, (2) an inclusive cluster of hymenochaetoid, corticioid, polyporoid, Thelephorales, russuloid, athelioid, Boletales, and euagarics clades, (3) Thelephorales plus the polyporoid clade, (4) the polyporoid clade, and (5) the cantharelloid clade. Strong support is also recovered for the basal position of the Dacrymycetales in the Hymenomycetidae and paraphyly of the Exobasidiomycetidae.     

宽叶金粟兰及其近缘类群的修订

在标本室研究和野外考察的基础上,对宽叶金粟兰Chloranthus henryi及其近缘种进行了分类学修 订。确认了宽叶金粟兰、及己C．serratus、华南金粟兰C．sessilifolius和台湾金粟兰C．oldhami,将单穗金 粟兰C．monostachys、湖北金粟兰C．hupehensis 、C. philippinensis、C．verticillatus和台湾及己C．serratus var．taiwanensis处理为新异名。通过研究合模式及有关照片,指定了宽叶金粟兰、多穗金粟兰C.multis-tachys和湖北金粟兰的后选模式。     

Chemotaxonomy of Veroniceae and its allies in the Plantaginaceae

In a chemosystematic investigation of tribe Veroniceae (Plantaginaceae), representatives of Camptoloma, Sibthorpia, Veronica subg. Pentasepalae and subg. Hebe, Veronicastrum, Wulfenia, and the related Ellisiophyllum and Globularia were examined for non-flavonoid glycosides. From the 14 species studied, 28 different iridoid glucosides and 10 caffeoyl phenylethanoid glucosides (CPGs), as well as salidroside and arbutin were isolated and characterized by NMR; of these, five compounds were previously unknown. It was found that the representatives of Veroniceae, as well as Globularia, were characterized by mannitol, aucubin, catalpol and catalpol esters. Each of the three studied species of Veronica subg. Hebe contained at least one of the 6-O-catalpol esters typical for Veronica s. str. (verminoside), supporting the inclusion of Hebe in Veronica. However, their main constituents were esters of 6-O-rhamnopyranosylcatalpol; a CPG, hebeoside (2'-beta-xylopyranosyl-verbascoside) was isolated from V. (Hebe) salicifolia. The two species of Veronicastrum also contained 6-O-rhamnopyranosylcatalpol esters, including the previously unknown 2',3'- and 3',4'-dicinnamoyl derivatives and, in contrast to the earlier reports, they lacked 6-O-catalpol esters. The main iridoid constituents in the three investigated species of Wulfenia were 10-O-aucubin and 10-O-catalpol esters (isoscrophularioside or globularin) while baldaccioside (10-O-cinnamoyl asystasioside E) was isolated from W. baldaccii. Globularia vulgaris contained 10-O-catalpol esters (e.g., globularin) and, in addition, asperuloside together with its benzoyl analogue named besperuloside. The representatives of Sibthorpia and Ellisiophyllum were almost completely devoid of iridoids; this, however, together with the CPGs present implied a close relationship between the two genera. Camptoloma lyperiiflorum lacked hexitols but contained esters of 6-O-rhamnopyranosylcatalpol different from those found in Veroniceae but known from Buddleja, Scrophularia and Verbascum (Scrophulariaceae s. str.).     

Taxonomy of Senecio multilobatus and its allies

A revision is presented for ten closely related species of western North America. The assemblage approximates the sectionsBolanderiani Greenman andLobati Rydb. Two new infraspecific combinations are made:Senecio bolanderi Gray var.harfordii (Greenman) T. M. Barkley, andS. eurycephalus Torr. & Gray ex Gray var.Iewisrosei (J. T. Howell) T. M. Barkley.     

A contribution to the cyto-taxonomy of Brassica (Cruciferae) and its allies

Material of 85 species of Brassica and genera closely related to it was examined cytologically, and the chroiftosome counts are reported. These confirm records published by other workers for 42 species, two contradict earlier records, and 41 counts are believed to be new. Different species with the same chromosome number have been cross-pollinated, and those found to be interfertile have been grouped into cytodemes. For the most part species found to be interfertile have long been regarded as closely akin, but three cases of interfertile intergeneric hybrids are reported. Altogether the material has been classified into 45 cytodemes: 35 diploids with chromosome numbers ranging from n= 7 to n= 13, and 10 derived tetraploids. This enumeration is possibly not exhaustive of the world's genomes closely related to the crop Brassicas and a list is appended of the wild species which need examination before the enumeration might be considered to be complete.     

Flavonoids and chemotaxonomy of the Commelinaceae

Diverse schemes have been proposed for the classification of the Commelinaceae on the basis of different characters. The leaf flavonoids of 152 species have been analysed. The flavone C-glycosides are the dominant compounds, found in 78% of the species examined. Flavonol O-glycosides are present in 28% of the species, quercetin being the most frequent aglycone. 6-Hydroxyluteolin was found mainly in Tradescantia but also in other species (10%). Tricin has been detected sporadically in less than 5% of the species. In spite of these variations the pattern of the family is very uniform, because the presence of C-glycoflavones and the distribution of the other compounds supports the scheme proposed by Rohweder who divided the family into Commelinieae and Tradescantieae on the basis of inflorescence characters.