Ammi Visnaga Lam.—A medicinal plant

Extensive investigation has shown that khellin, an active principle obtained from this plant, is of value in treating angina pectoris and bronchial asthma.     

Is Sedum acre L. a CAM plant?

Summary Sedum acre L. collected from its natural stands south of Darmstadt (Germany) showed ¹³C values typical for C₃ plants. This suggests that in situ at the natural stand CO₂ was fixed mainly via the C₃ mode of photosynthesis rather than via the CAM mode. However, experimental water stress shifts the CO₂ exchange pattern from the C₃ type to CAM type. Simultaneously, a diurnal rhythm of malic acid oscillation, typical for CAM, and increase of PEP-carboxylase and malic enzyme activities developed. Hence, Sedum acre is obviously to be classified as a facultative CAM plant. Because of the temperature characteristics of CO₂ exchange in Sedum acre, in situ CO₂ should be harvested from the atmosphere mainly during the seasons where water stress situations capable of inducing CAM are unlikely to occur.     

Micropropagation of the threatened Nepalese medicinal plant Swertia chirata Buch.–Ham. ex Wall.

 Multiplication by adventitious shoot regeneration from root explants was found to be the most suitable method for the propagation of Swertia chirata. A two-step system consisting of an initial 3-week cultivation on modified Murashige and Skoog medium supplemented with 3 μM 6-benzylaminopurine (BAP), followed by another period of 3 weeks on hormone-free medium was used. After rooting and acclimatization micropropagated plants could be successfully cultivated in Nepal. Received: 28 July 1997 / Revision received: 10 February 1998 / Accepted: 16 February 1999     

Cellulose in cyanobacteria. Origin of vascular plant cellulose synthase?

Although cellulose biosynthesis among the cyanobacteria has been suggested previously, we present the first conclusive evidence, to our knowledge, of the presence of cellulose in these organisms. Based on the results of x-ray diffraction, electron microscopy of microfibrils, and cellobiohydrolase I-gold labeling, we report the occurrence of cellulose biosynthesis in nine species representing three of the five sections of cyanobacteria. Sequence analysis of the genomes of four cyanobacteria revealed the presence of multiple amino acid sequences bearing the DDD35QXXRW motif conserved in all cellulose synthases. Pairwise alignments demonstrated that CesAs from plants were more similar to putative cellulose synthases from Anabaena sp. Pasteur Culture Collection 7120 and Nostoc punctiforme American Type Culture Collection 29133 than any other cellulose synthases in the database. Multiple alignments of putative cellulose synthases from Anabaena sp. Pasteur Culture Collection 7120 and N. punctiforme American Type Culture Collection 29133 with the cellulose synthases of other prokaryotes, Arabidopsis, Gossypium hirsutum, Populus alba x Populus tremula, corn (Zea mays), and Dictyostelium discoideum showed that cyanobacteria share an insertion between conserved regions U1 and U2 found previously only in eukaryotic sequences. Furthermore, phylogenetic analysis indicates that the cyanobacterial cellulose synthases share a common branch with CesAs of vascular plants in a manner similar to the relationship observed with cyanobacterial and chloroplast 16s rRNAs, implying endosymbiotic transfer of CesA from cyanobacteria to plants and an ancient origin for cellulose synthase in eukaryotes.     

The plant pathogen Rhodococcus fascians. History,disease symptomatology,host range,pathogenesis and plant–pathogen interaction

Since 1927, outbreaks of the leafy gall disease caused by Rhodococcus fascians on annual and perennial herbaceous plants have put the ornamental plant industry at risk. More recently, Pistachio Bushy top syndrome (PBTS), a serious disease emerging in the Western United States, has been declared as a natural disaster by the U.S. Department of Agriculture. Recent developments indicate that the taxonomic position of R. fascians should be re-evaluated and circumscribed from other members of the genus. Due to the broad host range of this bacterium, economically important crops are in a vulnerable position especially with new members within the genus becoming able to interact synergistically with R. fascians to cause symptom development. The virulence strategies employed by R. fascians and the involvement of cytokinins (CKs) in its pathogenicity have been the subject of much controversy in the last years. Additionally, the detection of virulent strains of R. fascians from symptomatic tissues has been problematic for many researchers. This review focuses on plant–pathogen interaction in context with more recent findings on the association of CKs in virulence of R. fascians. Current knowledge on the worldwide distribution of the pathogen, a historical recap of its discovery and the economic impact of the disease caused by R. fascians are also described here.     

TNF-α inhibitory diterpenoids from the Chinese mangrove plant Excoecaria agallocha L.

Chemical examination of the stems and twigs of the mangrove plant Excoecaria agallocha L. resulted in the isolation of six ent-kaurane diterpenoids named agallochaols K–P (1–6), an atisane-type diterpenoid agallochaol Q (7), along with eight known diterpenoids (8–15). Their structures were elucidated on the basis of extensive spectroscopic analysis and by comparison of their NMR spectroscopic data with those reported in literature, in association with the biogenetic relationship with the X-ray structure of 9. Compounds 1, 5–7, 9–10, and 13 showed anti-inflammatory potency to suppress expression of NF-κB and AP-1 targeted genes including TNF-α and IL-6 induced by lipopolysaccharide (LPS) in mouse macrophages Raw 264.7 cells. In addition, compounds 1, 5–7, 9–10, and 13 block NF-κB activation, while compounds 1 and 7 block AP-1 activation dramatically, indicating these compounds possess an anti-inflammatory potential in vitro.     

Global pattern of plant utilization across different organisms: Does plant apparency or plant phylogeny matter?

The present study is the first to consider human and nonhuman consumers together to reveal several general patterns of plant utilization. We provide evidence that at a global scale, plant apparency and phylogenetic isolation can be important predictors of plant utilization and consumer diversity. Using the number of species or genera or the distribution area of each plant family as the island “area” and the minimum phylogenetic distance to common plant families as the island “distance”, we fitted presence–area relationships and presence–distance relationships with a binomial GLM (generalized linear model) with a logit link. The presence–absence of consumers among each plant family strongly depended on plant apparency (family size and distribution area); the diversity of consumers increased with plant apparency but decreased with phylogenetic isolation. When consumers extended their host breadth, unapparent plants became more likely to be used. Common uses occurred more often on common plants and their relatives, showing higher host phylogenetic clustering than uncommon uses. On the contrary, highly specialized uses might be related to the rarity of plant chemicals and were therefore very species‐specific. In summary, our results provide a global illustration of plant–consumer combinations and reveal several general patterns of plant utilization across humans, insects and microbes. First, plant apparency and plant phylogenetic isolation generally govern plant utilization value, with uncommon and isolated plants suffering fewer parasites. Second, extension of the breadth of utilized hosts helps explain the presence of consumers on unapparent plants. Finally, the phylogenetic clustering structure of host plants is different between common uses and uncommon uses. The strength of such consistent plant utilization patterns across a diverse set of usage types suggests that the persistence and accumulation of consumer diversity and use value for plant species are determined by similar ecological and evolutionary processes.     

Vegetation complexity—The influence of plant species diversity and plant structures on plant chemical complexity and arthropods

Vegetation complexity is characterized by two major traits, i.e., plant chemical and plant structural complexity. Plant species diversity strongly determines these traits. Furthermore, plant structures affect microclimatic conditions, which in turn influence the emission and dispersion of plant volatiles (e.g., chemical complexity). Plant volatile chemical complexity may significantly affect orientation of herbivorous and carnivorous arthropods. Therefore, the way in which plant chemical and plant structural complexity act “in concert” may influence foraging and mating success of arthropods, and thus, finally, community composition. This review emphasizes an integrative view on the relationship between plant species diversity, plant structural complexity, plant volatiles (chemical complexity) and their effects on arthropods. Three new hypotheses are raised, which predict possible relations between plant volatile complexity and plant species diversity: (1) saturation-, (2) step-by-step, (3) incoherence-hypothesis. We conclude that arthropod orientation in natural environments is strongly determined by the relationship between plant volatile diversity and plant species diversity. Furthermore, we emphasize that structural complexity of the vegetation affects plant volatile diversity and thus, arthropod orientation.We review available information on how insects actually respond to complexity during olfactory and visual search and ask for both laboratory and field studies to further unravel the mechanisms of interactions between vegetation traits and their impact on arthropod orientation.     

The vascular plant collections of R. S. Williams from Bolivia and Peru (1901–1902)

The life and career of Robert Statham Williams (1859–1945) is sketched. His trip to Bolivia and Peru in 1901–1902 is discussed at length and an itinerary, with dates, is provided. Details concerning the numbering and distribution of his vascular plant collections are given, and notes are provided concerning the typification of the new species that Henry Hurd Rusby (1855–1940) based on these collections. An annotated catalog of vascular plant species described from Williams' Bolivian and Peruvian plant collections is appended, as is a gazetteer of the place names cited in Williams' field books and publications based on Williams' vascular and cryptogamic plant collections. One new combination,Oxypetalum apoloensis, and one new name,Acalypha rusbyi, are proposed. Lectotypes are designated forGothofreda apoloensis andCedrela brunellioides.     

Can isotropy vs. anisotropy in the spatial association of plant species reveal physical vs. biotic facilitation?

In dryland ecosystems and other harsh environments, a large part of the vegetation is often clustered, appearing as ‘islands’. If ‘independent’ species, usually colonizers, can be distinguished from species which are ‘dependent’ on the presence of the colonizing species for successful establishment and/or persistence, the type of spatial pattern of the association ‐ isotropic (spatially symmetric) or anisotropic (spatially asymmetric) ‐ can give information on the underlying environmental factors driving the process of association. Modified spatial pattern analysis based on Ripley's K‐function can be applied to bivariate clustered patterns by cardinal direction in order to detect possible anisotropy in the pattern of association. The method was applied to mapped distribution patterns of two types of semi‐arid shrubland in southeastern Spain. In shrubland of Retama sphaerocarpa, low shrubs of Artemisia barrelieri were significantly clustered under the canopy of the Retama shrubs in all four cardinal directions, suggesting an isotropic facilitation effect. In low shrubland dominated by Anthyllis cytisoides and Artemisia barrelieri, Anthyllis shrubs occurred more frequently than expected on the eastern side (and downslope) of an Artemisia shrub. The possible environmental factors driving the two association patterns are discussed and recommendations for further applications of the analytical method are given.