Rocky Mountain species of Paronychia (Caryophyllaceae): A morphological,cytological, and chemical study

Data derived from a morphological, cytological, flavonoid, and greenhouse study indicate thatParonychia pulvinata (2n = 32) andP. sessiliflora (2n = 64) should be distinguished in specific rank rather than in subspecific rank as recently proposed. Additionally, new evidence is brought to bear onP. depressa var.brevicuspis, which is shown to be synonymous withP. sessiliflora.     

FISH and GISH analysis of the genomic relationships amongPanax species

Ginseng is a well-known medicinal plant that has been used as an anti-aging agent for many years in East Asia. In the genusPanax, only three species,P. ginseng (Oriental ginseng),P. quinquefolius (American ginseng) andP. notoginseng (Chinese ginseng), are currently considered to be important medicinal herbs. Despite the increase in their breeding value, molecular cytogenetic information on the species is not available. To analyze the genomic relationships among thePanax species, FISH (fluorescencein situ hybridization) and GISH (genomicin situ hybridization) techniques were applied. FISH analysis revealed that the 45S and 5S rRNA genes ofP. notoginseng (2n=2x=24) andP. ginseng (2n=4x=48) cluster on a single locus on different chromosomes, whileP. quinquefolius (2n=4x=48),P. japonicus (2n=4x=48), and Korean wild ginseng (2n =4x= 48) had one locus of the 45S rRNA gene and two loci of the 5S rRNA gene, respectively. GISH analysis using genomic DNA as a probe detected strong cross-hybridization of genomes betweenP. ginseng andP. quinquefolius. GISH analysis of other species showed weak or no distinct signals on the chromosomes. Our data revealed thatP. ginseng andP. quinquefolius showed the highest degree of homology, indicating that these species diverged in most recent years.     

Chromosome studies in species and hybrids ofPetrorhagia sect.Kohlrauschia (Caryophyllaceae)

Cytogenetic investigations have been made in the fourPetrorhagia species and hybrids of the sectionKohlrauschia. The three diploid species show close similarities in chromosome number, size and morphology, with the exception ofP. velutina, where one pair of metacentric chromosomes is represented by a pair of telocentrics. Meiotic studies in hybrids indicate close genomic homology between the diploid species and also between the two floral forms ofP. prolifera. The tetraploidP. nanteuilii behaves as an allotetraploid forming only bivalents at meiosis and results suggest thatP. velutina andP. prolifera are the diploid progenitors of this species. Since meiosis in diploid and triploid hybrids results in extensive intergenomic pairing it is concluded that the natural tetraploid has a bivalent promoting mechanism that prevents pairing between the genomes of its diploid progenitors.     

Vicia johannis and wild relatives of the faba bean: a taxonomic study

Preliminary taxonomic and agronomic investigation was made of close relatives of the faba bean (Vicia faba) to aid future plant breeding. Cluster analysis of 2 yr’s morphometric data showed thatV. johannis is clearly separable from other members of theV. narbonensis complex. AlsoV. faba was much more distinct from eitherV. narbonensis orV. johannis than they are from each other. Petal colours at anthesis provided a rapid method of field identification forV. faba, V. narbonensis, andV. johannis. The 2 varieties ofV. johannis can also be distinguished by their petal colours: var. procumbens shows a marked colour change at anthesis and var. johannis does not. The geographical distribution of the plant material studied suggests thatV. johannis is found in Turkey and Europe despite being omitted from the major published floras. BothV. johannis andV. narbonensis possess agronomically useful characters of importance to faba bean breeders, including increased frost tolerance and resistance to bothAphis fabae andBotrytis fabae.     

Revision of the genus philactis (Compositae)

Philactis (Compositae-Heliantheae) is a genus of three species, all of limited distribution. A revision is presented, based upon herbarium specimens and field work. Cytological data are from bud material fixed in the field, and from root tips of seedlings. The basic chromosome number appears to be 14.P. nelsonii andP. liebmannii are tetraploid (2n = 56), andP. zinnioides is hexaploid (2n = 84).     

Philactis fayi (Compositae) : A new species from Mexico

The new species is the fourth member of the genus. Morphologically, it is most closely allied toP. liebmannii, but there are ample qualitative and quantitative differences between them. The chromosome numbers ofP. liebmannii andP. nelsonii are 2n = 56 whileP. zinnioides is 2n = 84.Philactis fayi is 2n = 28 and is considered to represent the diploid complement that was probably involved in the production of the other species through hybridization and chromosome doubling.     

Revision and affinities ofGalium (Rubiaceae) in Madagascar

The only representatives ofRubiaceae-Rubieae in Madagascar are five species ofGalium. G. thunbergianum andG. chloroionanthum are essentially afromontane species, ± widely distributed in both the African mainland and Madagascar. The new speciesG. andringitrense andG. ankaratrense are endemic to Madagascar but show close affinities to two afromontane—afroalpine groups from the African mainland, theG. simense—G. ruwenzoriense andG. glaciale complex respectively.G. polyacanthum (new combination) exhibits certain primitive morphological traits and appears to be an old Madagascan endemic without close allies. New chromosome counts for populations from the African mainland demonstrate thatG. chloroionanthum andG. simense are 4x (x=11). Distribution patterns and origins of theGalium species in Madagascar and their relationships with African taxa are discussed.     

Bounds on the total population for species governed by reaction-diffusion equations in arbitrary two-dimensional regions

Analysis based on the integration of differential inequalities is employed to derive upper and lower bounds on the total populationN(t) = ∫ _R θ(x ₁,x ₂,t) dx ₁ dx ₂ of a biological species with an area-density distribution function θ=θ(x ₁,x ₂,t) (≥0) governed by a reaction-diffusion equation of the form ∂θ/∂t =D∇²θ +fθ −gθ ⁿ⁺¹ whereD (>0),n (>0),f andg are constant parameters, θ=0 at all points on the boundary ∂R of an (arbitrary) two-dimensional regionR, and the initial distribution (θ(_{x 1},x ₂, 0) is such thatN(0) is finite. Forg≥0 withR the entire two-dimensional Euclidean space, a lower bound onN(t) is obtained, showing in particular thatN(∞) is bounded below by a finite positive quantity forf≥0 andn>1. An upper bound onN(t) is obtained for arbitrary bounded or unbounded)R withn=1,f andg negative, and ∫ _R θ(x ₁,x ₂, 0)² dx ₁ dx ₂ sufficiently small in magnitude, implying that the population goes to extinction with increasing values of the time,N(∞)=0. Forg≥0 andR of finite area, the analysis yields upper bounds onN(t), predicting eventual extinction of the population if eitherf≤0 or if the area ofR is less than a certain grouping of the parameters in cases for whichf is positive. These results are directly applicable to biological species with distributions satisfying the Fisher equation in two spatial dimensions and to species governed by certain specialized population models.     

In situ monitoring of biofilm formations ofEscherichia coli andPseudomonas putida by use of lux and GFP reporters

A plasmid vector containing two reporter genes,mer-lux andlac-GFP, was transformed to bothEscherichia coli andPseudomonas putida. Their cellular activities and biofilm characteristics were investigated in flow-cell units by measuring bioluminescent lights and fluorescent levels of GFP. Bioluminescence was effective to monitor temporal cell activities, whereas fluorescent level of GFP was useful to indicate the overall cell activities during biofilm development. The light production rates ofE. coli andP. putida cultures were dependent upon concentrations of HgCl₂. Mercury molecules entrapped inP. putida biofilms were hardly washed out in comparison with those inE. coli biofilms, indicating thatP. putida biofilms may have higher affinity to mercury molecules thanE. coli biofilms. It was observed thatP. putida expressed GFP cDNA in biofilms but not in liquid cultures. This may indicate that the genetic mechanisms ofP. putida were favorably altered in biofilm conditions to make a foreign gene expression possible.     

New species of Pectis (Asteraceae) from the West Indies,Mexico, and South America

Four new species ofPectis are described:P. ericifolia from Barbuda,P. luckoviae from west-central Mexico,P. arida from Ecuador and Peru, andP. cajamarcana from Peru. Chromosome counts forP. ericifolia (n=48) andP. luckoviae (n=12) are presented. Relationships of the newly described taxa are discussed.     

Chromosome observations on some eastern North American Eleocharis (Cyperaceae)

Chromosome numbers are reported forEleocharis obtusa var.ellipsoidalis (2n = 10),E. obtusa var.peasei (2n =10),E. engelmannii (2n =10),E. olivacea f.olivacea (2n = 20),E. olivacea f.reductiseta (2n = 20),E. flavescens (2n = 30),E. tenuis var.verrucosa (2n = 20),E. tenuis var.tenuis (2n = 24),E. tenuis var.pseudoptera (2n = 39), a possible hybrid betweenE. tenuis var.pseudoptera and var.tenuis (2n = ca. 34 & 68),E. intermedia (2n = 22),E. tuberculosa (2n = 30),E. smallii (2n = 36), andE. ambigens (2n = 46). Noticeable chromosome size differences inE. tenuis, E. smallii, andE. ambigens are consistent with size differences previously reported by other authors. Variable meiotic pairing configurations were observed inE. flavescens, E. intermedia, andE. tenuis. Chromosome data help verify taxonomic relationships of some taxa and indicate the need for further investigation of others.     

Notes on Mexican grasses IX. Miscellaneous chromosome numbers—3

Chromosome numbers are reported for 105 collections which represent 59 species belonging to 35 genera. For two of these genera:Blepharoneuron andTriniochloa no documented chromosome counts have been published to date. Records for the following species:Aristida arizonica, A. pansa, A. schiedeana, Blepharoneuron tricholepis, Deschampsia pringlei, Eragrostis palmeri,Leptochloa viscida, Munroa squarrosa, Panicum vaseyanum, Setaria grisebachii, andTriniochloa stipoides are the first for these taxa. Counts of 2n = 28 forAgrostis perennans, 2n = 20 forAegopogon cenchroides, 2n = 20 forBuchloË dactyloides, 2n = 54 forDigitaria filiformis, 2n = 60 and 2n = ca. 74 forEragrostis intermedia, 2n = 32 forErioneuron grandiflorum andE. pilosum, 2n = 44 forHilaria cenchroides, 2n = 38 and 2n = ca. 180 forHilaria mutica, 2n = 40 forPereilema crinitum, 2n = 28 forScleropogon brevifolius, 2n = ca. 108 forSetaria leucopila, and 2n = 36 forOplismenus burmannii are different from any published report for these species. Cytological information on Mexican material of the following ten species:Agrostis perennans, Aristida hamulosa,Bouteloua aristidoides, Eragrostis cilianensis, Sporobolus nealleyi, Tridens muticus,Digitaria filiformis, Hackelochloa granularis, Oplismenus burmannii, andPennisetum ciliare is here presented for the first time.     

Chromosome numbers of dominican compositae

Chromosome numbers of 34 species of Dominican Compositae in 26 genera and nine tribes are reported. First counts are given forCoreopsis buchii (2n = 64),Lagascea mollis (2n = 34),Spilanthes urens (n = 16),Liabum subacaule (n = 18),Eupatorium sciatraphes (2n = 40),Hieracium gronovii (2n = 18),Vernonia buxifolia (2n = 34),V. sprengeliana (2n = 34),V. racemosa (2n = 28), andChaptalia leiocarpa (2n = 48,ca. 58). Our report forNarvalina domingensis (2n = 120) is the first for any species of this genus.     

Natural intersectional hybridization in perityle (Compositae)

A small number of supposed F₁ hybrids was discovered in an isolated sympatric population ofP. parryi (n = 17) andP. rupestris var.albiflora (n = 17) in the Chisos Mts. of Texas. Although the parental species are morphologically quite distinct, being assigned to separate taxonomic sections ofPerityle, their hybrids displayed relatively high fertility. Origin of the presumed natural hybrids was documented by the production of artificial hybrids betweenP. parryi andP. rupestris var.albiflora. Fertility data based on pollen stainability were accumulated for the available natural hybrids, and for artificial hybrids through F₃ and backcross generations. A brief discussion of biosystematic implications is included.     

Karyomorphology and relationships of Celtidaceae and Ulmaceae (Urticales)

Based on karyomorphological features, six (examined in this study) of nine genera of Celtidaceae are divided into three groups: 1)Celtis, Parasponia, Pteroceltis andTrema; 2)Aphananthe; 3)Gironniera, and six genera of Ulmaceae into two: 1)Holoptelea andPhyllostylon; 2)Hemiptelea, Planera, Ulmus andZelkova. The first four genera share the simple chromocenter type at the resting stage andx-10, with all chromosomes with submedian or median centromeres (frequency of chromosomes with subterminal or terminal centromeres 0%, although uncertain inTrema).Aphananthe hasx=13, but resembles the above four genera in other features.Gironniera is distinct from all other Celtidaceae in having the diffuse-complex chromocenter type andx=14, features which occur in Ulmaceae. InGironniera the frequency of chromosomes with subterminal or terminal centromeres is 43%, a proportion similar to those inHoloptelea (36%) andPhyllostylon (58%) of Ulmaceae. All six genera of Ulmaceae havex=14, yetHemiptelea, Planera, Ulmus andZelkova are distinct fromHoloptelea andPhyllostylon (with the simple chromocenter type) in having the diffuse-complex chromocenter type and in predominantly possessing chromosomes with subterminal or terminal centromeres (93%). Evidence from karyomorphology, as well as from other sources, suggests 1) thatAphananthe (x=13) is most distantly related to all genera withx=10 within Celtidaceae, 2) thatGironniera may have a key role for understanding evolutionary relationships between Celtidaceae and Ulmaceae, and 3) thatHoloptelea andPhyllostylon represent derivatives of a line that diverged early from a common ancestor or all Ulmaceae. On the basis of comparisons with other Urticales and the putative outgroups of the order, it is also suggested that the chromosome morphology of Ulmaceae represents the more derived state in Urticales.     

Evidence for the hybrid origin of Flaveria latifolia (Compositae)

Investigations of natural populations, cytological studies, and comparisons of herbarium specimens have been used to clarify the taxonomy of the Florida species ofFlaveria. These studies indicate thatF. latifolia is a hybrid betweenF. linearis andF. floridana. Apparently the “latifolia” plants represent stabilized populations that have become adapted to the fill material dredged from the ocean and used in road building and land development in southern Florida. The wide variation noted in populations ofF. linearis andF. floridana is attributed to introgression. The paper includes a taxonomic treatment of the six species which occur in Florida. AU taxa are diploid with 2n = 36.     

Cytogenetic analyses inKengyilia laxiflora (Poaceae, Triticeae)

Kengyilia laxiflora (2n = 42) was cytogenetically studied with testersK. hirsuta (2n = 42, PPStStYY) andRoegneria kamoji (2n = 42, HHStStYY). Our data suggested thatK. laxiflora may possess a modified P genome, the P¹. Its St and Y genomes may also contain some structural changes and are more closely related to the St and Y genomes ofK. hirsuta than to those ofR. kamoji. Kengyilia laxiflora is reproductively separated from bothK. hirsuta andR. kamoji. These results indicated thatK. laxiflora is a good species in the genusKengyilia.     

Inter- and intra-genomal chromosome pairing in an interspecific hybrid and its bearing on basic chromosome number inPennisetum

Meiosis in the interspecific hybrid betweenPennisetum typhoides (2n=14; genomeAA) andP. purpureum (2n=28; genomesA′A′BB) has been studied with particular reference to allosyndetic and autosyndetic pairing of chromosomes. Although up to nine bivalents occurred in the hybrid, never more than five were observed to be (heteromorphic)AA′ bivalents (range 1–5). It has been concluded thatA andA′ genomes are onlypartially homologous. It has further been inferred that the two genomes are evolutionarily related and could have arisen from a common progenitor withx=5 chromosomes or from related species withx=5 chromosomes. Autosyndetic pairing of chromosomes within thetyphoides complement (A genome) and within theA′ genome ofpurpureum have been reported here for the first time. Intra-haploid pairing to a probable maximum of two bivalents within each of the three genomes of the hybrid, viz.,A, A′ andB, further suggestsx=5 as the phyletically basic number in the genusPennisetum. It has been inferred thatx=7 is a secondarily basic number, having been derived fromx=5. The occurrence of a species withn=5 inPennisetum, viz.,P. ramosum, substantiates this view. Further support in favour of this conclusion comes from the secondary association of bivalents in dipoidP. typhoides. Thus, the apparently diploid species,Pennisetum typhoides with2n=14 chromosomes is considered to be a “secondary diploid” having a secondarily balanced number ofx=7. On the basis of the results obtained by the author is conjunction with the available evidence from the literature, it is suggested thatx=5 may be the original basic number for the entire grass family and seven, the most preponderant number in it, and other higher numbers derived from it subsequently during the course of evolution.