Are endophytic fungi from Rhododendron tomentosum preadapted for its essential oil?

Endophytic fungi have to cope with various secondary metabolites produced by their host plant. Rhododendron tomentosum is an evergreen shrub with a high content of essential oil showing antimicrobial effects. The first aim of our study was to reveal the diversity of culturable endophytic fungi colonizing leaves of R. tomentosum. We isolated and identified 30 species, mostly ubiquitous species colonizing various plants as endophytes and later turning into saprotrophs. The second aim was to explore whether strains obtained from R. tomentosum (RT-strain) are better adapted to growth in environments with essential oils, compared to strains of the same species obtained from different substrates. In five of the six species pairs tested, the growth of RT-strains was more inhibited by three components of the essential oil added to the medium, compared to the corresponding strains. Only the RT-strain of Desmazierella acicola was less susceptible compared to its corresponding strain. Our results show that the essential oil in leaves of R. tomentosum do not represent a selective barrier that can be crossed only by preadapted strains.     

Phytoconstituents from the root of Streptocaulon tomentosum and their chemotaxonomical relevance for separation from S. juventas

A new cardenolide, 17β-H-periplogenin-3-O-β-d-digitoxoside (1), and a new pregnane glycoside, Δ⁵-pregnene-3β,16α-diol-d-O-[2,4-O-diacetyl-β-digitalopyranosyl-(1 → 4)-β-d-cymaropyranoside]-16-O-[β-d-glucopyranoside] (2) were isolated from the roots of Streptocaulon tomentosum (Asclepiadaceae) together with a series of known compounds. Their chemotaxonomic significance for the separation of S. tomentosum from Streptocaulon juventas is discussed, suggesting a rather clear distinction of these species.     

Incipient Genome Differentiation in Gossypium. II. Comparison of 12 Chromosomes in G. HIRSUTUM, G. MUSTELINUM and G. TOMENTOSUM Using Heterozygous Translocations

Eight homozygous translocation lines (TT) of G. hirsutum marking 3 chromosomes of the A genome and 9 chromosomes of the D genome were crossed with G. hirsutum, G. mustelinum and G. tomentosum, all homozygous for the standard end arrangements (tt). Chiasma frequencies in the G. hirsutum Tt controls were compared with those in the G. hirsutum x G. mustelinum and the G. hirsutum x G. tomentosum Tt hybrids. Both nucleus-wide and region-specific chiasma frequencies were compared.—Some genome differentiation appears to have arisen between G. hirsutum and G. mustelinum. The G. hirsutum x G. mustelinum hybrids had a 1.8 to 1.9% reduction in the nucleus-wide chiasma frequency. Four of the eight TT lines showed a 3.4 to 10.5% reduction in chiasmata in the hybrid translocation quadrivalents, suggesting that chromosomes 1, 21, 23 and 24 may have undergone localized genome differentiation. The two species may differ naturally in the end arrangement of two chromosomes, since a quadrivalent not due to experimentally introduced translocations was observed in 13% of the PMC's of two G. hirsutum x G. mustelinum hybrids.—Very little genome differentiation has occurred between G. hirsutum and G. tomentosum. In the G. hirsutum x G. tomentosum hybrids, the nucleus-wide estimates showed only a very small (0.1 to 0.2%), though statistically significant, lowering of the chiasma frequency, and there was no reduction in chiasma frequency in the more sensitive readings for specific translocation quadrivalents.     

Screening and evaluation of different algal extracts and prospects for controlling the disease vector mosquito Culex pipiens L.

Continual application of synthetic insecticides in controlling mosquito larvae has resulted in several problems as build-up of mosquito resistance beside to negative impacts on human health and environment. Discovering new and affordable bio-insecticidal agents with high efficiency, cost effective and target specific become a crucial need. The current study assessed the larvicidal activity of eight methanolic algal extracts belong to three different algal divisions against the 3^rd larval instar of Culex pipiens L. (Diptera: Culicidae). Comparative studies showed that four species of red and green algal extracts exhibited good larvicidal activity. Galaxaura elongata and Jania rubens (Rhodophyta), Codium tomentosum and Ulva intestinales (Chlorophyta) showed higher larvicidal potencies than Padina boryana, Dictyota dichotoma, and Sargassum dentifolium (Phaeophyta) and Gelidium latifolium (Rhodophyta). The maximum level of toxicity was achieved by exposure to G. elongata extract with LC₅₀ (31.13 ppm), followed by C. tomentosum (69.85 ppm) then J. rubens (84.82 ppm) and U. intestinalis (97.54 ppm), while the lowest toxicity exhibited by G. latifolium (297.38 ppm) at 72 h post- treatment. The application of LC₅₀ values of G. elongate, J. rubens, C. tomentosum, and U. intestinalis extracts affected the activities of antioxidant enzymes viz. superoxide dismutase, catalase and glutathione peroxidase as oxidative stress markers. An increase of antioxidant enzymes activities was recorded. Therefore, a significant elimination of free radicals, causing toxic effects. Overall, this study casts light on the insecticidal activity of some algal extracts, suggesting the possibility of application of these bio- agents as novel and cost- effective larvicides.     

Construction of microsatellite-based linkage map and mapping of nectarilessness and hairiness genes in Gossypium tomentosum

Gossypium tomentosum, a wild tetraploid cotton species with AD genomes, possesses genes conferring strong fibers and high heat tolerance. To effectively transfer these genes into Gossypium hirsutum, an entire microsatellite (simple sequence repeat, SSR)-based genetic map was constructed using the interspecific cross of G. hirsutum × G. tomentosum (HT). We detected 1800 loci from 1347 pairs of polymorphic primers. Of these, 1204 loci were grouped into 35 linkage groups at LOD?≥?4. The map covers 3320.8 cM, with a mean density of 2.76 cM per locus. We detected 420 common loci (186 in the At subgenome and 234 in Dt) between the HT map and the map of TM-1 (G. hirsutum) and Hai 7124 (G. barbadense; HB map). The linkage groups were assigned chromosome numbers based on location of common loci and the HB map as reference. A comparison of common markers revealed that no significant chromosomal rearrangement exist between G. tomentosum and G. barbadense. Interestingly, however, we detected numerous (33.7%) segregation loci deviating from 3:1 ratio (P?<?0.05) in HT, mostly clustering on eight chromosomes in the Dt subgenome, with some on three chromosomes in At. Two morphological traits, leaf hairiness and leaf nectarilessness were mapped on chromosomes 6 (A6) and 26 (D12), respectively. The SSR-based map constructed in this study will be useful for further genetic studies on cotton breeding, including mapping loci controlling quantitative traits associated with fiber quality, stress tolerance and developing chromosome segment specific introgression lines from G. tomentosum into G. hirsutum using marker-assisted selection.     

Bioreactor shoot cultures of <Emphasis Type="Italic">Rhododendron tomentosum</Emphasis> (<Emphasis Type="Italic">Ledum palustre</Emphasis>) for a large-scale production of bioactive volatile compounds

Rhododendron tomentosum Harmaja (Ledum palustre), a peat bog plant from Ericaceae family, has been used in traditional medicine as the anti-arthritis agent. Although modern researches confirm its anti-inflammatory properties, it remains threatened by habitat degradation and possibilities to collect this endangered species from its natural environment for further biological activity studies are limited. Therefore, R. tomentosum liquid in vitro cultures were established as the alternative source of that valuable plant material. Schenk–Hildebrandt medium with 24.60 μM 2-isopentenyladenine and 592.02 μM adenine provides intensive growth and proper morphology of the obtained microshoots. The R. tomentosum biomass was scaled up using the various bioreactors (immersion, temporary immersion and spraying systems) for better growth and improved volatile oil production. The largest biomass accumulation (fresh weight?=?250 g l^?1, growth index?=?280, dry weight?=?20 g l^?1) and essential oil content (0.5% v/m) were achieved with application of commercially available RITA^® bioreactor. GC/MS analysis revealed the high content of p-cymene (6.9%), alloaromadendrene (5.5%), shyobunone (8.2%) and ledene oxide (II) (13.0%) in the volatile fraction obtained from RITA^® system. The biomass growth parameters and production profile in terms of essential oil and selected terpenoid compounds were determined during the 2 month period. The influence of culture conditions and bioreactor construction on the growth and volatile oil production in R. tomentosum biomasses was discussed.     

Quantification of proton budgets in soils of cropland and adjacent forest in Thailand and Indonesia

Mechanisms for tolerance and avoidance of salinity at germination were examined in five self-regenerating annual pasture legumes of Mediterranean origin (Medicago polymorpha, Melilotus siculus, Trifolium subterraneum, T. michelianum and T. tomentosum). The maximum NaCl concentrations, for which no reduction in germination percentage occurred, were 300 mM for M. siculus, 240 mM for M. polymorpha and 120 mM for T. michelianum, T. subterraneum and T. tomentosum. Following 21 days exposure to 300 mM NaCl, imbibed seeds of T. subterraneum showed reduced germinability upon transfer to non-saline solution, whereas those of the four other species recovered full germinability. Following exposure to 600 mM NaCl, however, only T. michelianum and Melilotus siculus had some degree of recovery, with 38% and 31% germinability, respectively. Na⁺ in imbibed seed tissues of all species increased markedly with increasing NaCl concentration, while K⁺ decreased in all but Melilotus siculus. Seed coat impermeability (‘hard seeds’) acted as protection against the toxic effects of salinity. Melilotus siculus, Medicago polymorpha and T. tomentosum showed a delay in hard-seed breakdown (‘seed softening’) over the summer–autumn period, compared to T. subterraneum and T. michelianum, which acts to defer germination until soil surface salinity levels are likely to be lower. These three species also had higher levels of residual hard seeds. The results from this study support field observations that Melilotus siculus and Medicago polymorpha are the best adapted annual pasture legumes for highly saline soils in southern Australia, T. tomentosum and T. michelianum have some adaptation to moderately and mildly saline soils, respectively, whereas T. subterraneum has no adaptive traits for even mildly saline environments. A model for annual legume germination on saline land in southern Australia is also presented.     

Gossypium tomentosum genome and interspecific ultra-dense genetic maps reveal genomic structures,recombination landscape and flowering depression in cotton

The high-quality reference-grade genome for Gossupium tomentosum can greatly promote the progress in biological research and introgression breeding for the mainly cultivated species, G. hirsutum. Here, we report a high-quality genome assembly for G. tomentosum by integrating PacBio and Hi-C technologies. Comparative genomic analysis revealed a large number of genetic variations. Two re-sequencing-based ultra-dense genetic maps were constructed which comprised 4,047,199 and 6,009,681 SNPs, 4120 and 4599 bins and covering 4126.36 cM and 4966.72 cM in the EMF₂ (F₂ from G. hirsutum × G. tomentosum) and GHF₂ (F₂ from G. hirsutum × G. barbadense). The EMF₂ exhibited lower recombination rate at the whole-genome level as compared with GHF₂. We mapped 22 and 33 QTL associated with crossover frequency and predicted Gh_MRE11 and Gh_FIGL1 as the candidate genes governing crossover in the EMF₂ and GHF₂, respectively. We identified 13 significant QTL that regulate the floral transition, and revealed that Gh_AGL18 was associated with the floral transition. Therefore, our study provides a valuable genomic resource to support a better understanding of cotton interspecific cross and recombination landscape for genetic improvement and breeding in cotton.     

Modulation of naphthodianthrone biosynthesis in hairy root-derived <Emphasis Type="Italic">Hypericum tomentosum</Emphasis> regenerants

The results of the current study represent the first report on an efficient regeneration protocol for Hypericum tomentosum L. hairy root cultures. Six out of ten hairy root clones of H. tomentosum obtained by Agrobacterium rhizogenes-mediated transformation differentiated shoots on Murashige and Skoog medium containing a urea-based cytokinin thidiazuron in combination with the auxin inhibitor p-chlorophenoxyisobutyric acid. The whole plant regeneration of this species in vitro was achieved by further cultivation of shoots on medium containing benzyladenine. All transformed plants were successfully acclimated to ex vitro conditions. Most of the adapted clones exhibited typical hairy root phenotype with stunted growth, small wrinkly leaves and shortened internodes. Increased number of dark nodules, the sites of hypericins accumulation, was observed in the leaves of all transgenic clones. The capability of naphthodianthrone production was also modulated leading to a significant 28- and 5-fold increase of total hypericin content in two transgenic clones. The qPCR analysis revealed seven rolC integrations in two transgenic clones and one integration in four clones. The clones with multiple rolC copies synthesized the highest and the lowest amount of naphthodianthrones, respectively. The chromosome number in all analysed samples was determined as 2n?=?18 suggesting a revision of the cytogenetic characterization of H. tomentosum.     

Xanthones and triterpenes of Calophyllum tomentosum

The bark, branch timber, sapwood and heartwood extractives of Calophyllum tomentosum contain friedelin, friedelan-3β-ol, betulinic acid, taraxero     

Comparative alkane chemistry of Parthenium argentatum (guayule) and some F1 hybrids

The leaf alkanes of Parthenium argentatum (guayule), P. tomentosum var. stramonium, P. fruticosum var. trilobatum, and the first filial (F₁) generations obtained from crosses with guayule were investigated by GC and mass spectrometry and shown to be useful in chemotaxonomic studies. The identified n-alkanes ranged from C₁₉ to C₄₀ with either n-C₂₉ or n-C₃₁ as the main component. The alkane chemistry of guayule with n-C₃₁ being the main component predominated in most of the F₁ hybrids. The presence of iso-branched alkanes (C₂₇, C₂₉, C₃₁) in P. tomentosum and its hybrids could be detected by GC/MS. These preliminary investigations indicate that epicuticular wax alkanes can be useful in inheritance studies of guayule and its hybrids.     

GENETIC DIVERSITY AND ORIGIN OF THE HAWAIIAN ISLANDS COTTON,GOSSYPIUM TOMENTOSUM

Gossypium tomentosum is the only member of the cotton genus endemic to the Hawaiian archipelago. It is morphologically distinct from other allopolyploid Gossypium species, and its phylogenetic relationships with them are uncertain. Chloroplast and ribosomal DNA restriction site variation were used to estimate the phylogeny of the allopolyploids. Gossypium mustelinum is resolved as sister to the remaining allopolyploid species, which include two species-pairs, G. barbadense-G. darwinii and G. hirsutum (including G. lanceolatum)-G. tomentosum. This indication that G. tomentosum is sister to G. hirsutum is supported by allozyme data. Gossypium tomentosum is proposed, based on biogeographic evidence and molecular data, to have originated by transoceanic dispersal from a Mesoamerican progenitor. Few restriction site variants were observed among the allopolyploids, suggesting that present lineages diverged relatively rapidly following polyploidization. Allozyme analysis of 30 G. tomentosum accessions collected from seven islands revealed relatively low levels of genetic diversity: 11 of 50 loci were polymorphic, mean number of alleles per locus was 1.24, and mean panmictic heterozygosity was 0.033. Little geographic patterning of allelic distributions was observed. Despite historical cultivation of G. barbadense and G. hirsutum in Hawaii and the existence of their naturalized derivatives, no allozyme evidence of interspecific introgression into G. tomentosum was detected.     

Use of Tanacetum tomentosum and Ta. dolichophyllum essential oils as botanical repellents and insecticidal agents against storage pest Tribolium castaneum (Coleoptera: Tenebrionidae)

In this study, repellent and fumigant activities of Tanacetum tomentosum and Ta. dolichophyllum essential oils were investigated against Tribolium castaneum. Results showed that both oils had effective fumigant and repellent activities. Tanacetum tomentosum oil emerged as more potent than Ta. dolichophyllum oil with LC₅₀ values of 6.85 and 4.32 μL/0.25 L air after 24 and 48 h of exposure, respectively. Ta. tomentosum oil also showed more repellent activity than Ta. dolichophyllum oil by exhibiting repellent activity in the range of 38.70–82.35%. Chemical analysis of both oils revealed that β‐bisabolene (50.0%) was the major component of Ta. tomentosum oil and that β‐eudesmol (31.4%) and α‐bisabolol (10.7%) were the major components of Ta. dolichophyllum oil. Doses of 40 and 80 μL/0.5 L air of both oils significantly protected 500 g of wheat grains for up to 6 months from insect infestation, without causing any side effects in the germination rates; the order of germination rates was Ta. tomentosum (89.45%) > Ta. dolichophyllum (86.78%). Thus, this study suggests that essential oils from Ta. tomentosum and Ta. dolichophyllum can be used as potential alternative botanical fumigants for controlling Tr. castaneum.     

Carbon dioxide assimilation in the flowerhead of Arctium

Summary The gas exchange of flowerheads was determined in Arctium tomentosum and A. lappa during their development. The light, temperature and CO₂ responses were used to estimate flowerhead photosynthesis and the in situ contribution of carbon assimilation to the carbon requirement of the plant for supporting a flowerhead. Changes in vapour pressure deficit had no effect on flowerhead photosynthesis rates and were not included in the model.In both species assimilatory capacity correlated with total bract chlorophyll content. Light, temperature and CO₂ response curves were very similar in form between species, differing only in absolute rates. During all stages of development, flowerheads always exhibited a net carbon loss, which was mainly determined by temperature. The respiration rate decreased in the light, the difference of CO₂ exchange in the dark and in the light was interpreted as photosynthesis. This rate was larger in A. lappa than in A. tomentosum. 30% of the total C requirement of A. lappa flowerheads was photosynthesized by its bracts, the total contribution offlowerhead photosynthesis in A. tomentosum was only 15%. The potential competitive advantages of variation in flowerhead photosynthesis are discussed.     

The long day leaf as a source of cold hardiness inhibitors

Short photoperiods followed by low temperatures induced cold hardiness in Acer negundo, Viburnum plicatum tomentosum, and Weigela florida. Hardiness was also obtained under long days and natural fall temperatures if the leaves were removed, either manually or by low temperature. Similarly, removal of leaves from plants exposed to long days at 5° brought about an accelerated rate of hardening. These observations suggested the presence of a hardiness inhibitor in the leaves which was counteracted by short days or removal of the leaves.     

Root porosity and oxygen movement in waterlogging-tolerant Trifolium tomentosum and -intolerant Trifolium glomeratum

Trifolium tomentosum and T. glomeratum are small (< 0·5 mg) seeded pasture legumes which are considered to be waterlogging tolerant and intolerant, respectively. The root porosity of the two species was compared for plants raised for 10 d in aerated nutrient solution and then transferred to either aerated (0·25 mol O₂ m^–3) or ‘hypoxic’ (0·031–0·069 mol O₂ m^–3) solutions for a further 7 and 21 d. After 21 d, T. tomentosum developed a root porosity of 11·2% in ‘hypoxic’ solution, which was significantly higher than the 6·1% developed by T. glomeratum. When grown in aerated solution, T. tomentosum also had a larger constitutive porosity (6·7%) than T. glomeratum (3·9%). Cylindrical root-sleeving O₂ electrodes were used to measure the rates of radial O₂ loss (ROL) from roots of the two species when in an O₂-free medium. In general, roots previously grown in ‘hypoxic’ solution had higher rates of ROL than roots grown in aerated solution. Moreover, the rates of ROL along the main root of T. tomentosum were ≈ 5-fold faster than from equivalent locations along roots of T. glomeratum. Manipulations of the shoot O₂ concentration resulted in rapid changes in ROL near the root tip of T. tomentosum plants raised in aerated or ‘hypoxic’ solutions, whereas for T. glomeratum ROL only increased for roots of plants raised in ‘hypoxic’ solution. Thus, the cortical air spaces in roots of both species raised in ‘hypoxic’ solution formed a continuous, low resistance pathway for O₂ diffusion from the shoots to the roots. ROL from the lateral roots was also evaluated and it was 3-fold faster from T. tomentosum than from T. glomeratum. Moreover, ROL from lateral roots of T. tomentosum was 10–20-fold higher than from a position on the primary root axis the same distance from the root/shoot junction. Relatively, high rates of ROL were also recorded for young (40 mm in length) lateral roots of T. glomeratum which were previously grown in ‘hypoxic’ solution, but the ROL was low for the older lateral roots of this species. The substantial amounts of ROL from the lateral roots may limit O₂ supply to the lower parts of the primary root axis, so that the laterals probably become the main functional root system in waterlogged soils.     

New taxa and combinations in Malvastrum A. Gray (Malvaceae: Malveae)

The genusMalvastrum A. Gray is interpreted to include 22 taxa in 14 species. Seven taxa are here described as new, namely:M. americanum var.stellatum,M. tomentosum subsp.pautense,M. bicuspidatum subsp.campanulatum,M. bicuspidatum subsp.oaxacanum, M. bicuspidatum subsp.tumidum var.tumidum, M. bicuspidatum subsp.tumidum var.glabrum, andM. coromandelianum subsp.fryxellii. In addition, two new combinations are proposed, namely:M. tomentosum andM. coromandelianum subsp.capitato-spicatum.     

Plant-emitted semi-volatiles shape the infochemical environment and herbivore resistance of heterospecific neighbors

Plant-emitted volatiles have been reported to shape ecological interactions occurring among species within single or between multiple trophic levels. The ecological contribution of volatiles to plant-herbivore, plant-pathogen, plant-to-plant and multitrophic interactions can be mutualistic, or may either favor or disfavor the players involved in the infochemical network. Emitting, perceiving or being passively engaged with airborne volatiles can result in ecological costs and/or benefits, render competitive advantage and shape population dynamics. We recently demonstrated a cost-effective way for plants to take advantage of volatile-based defense: by adsorbing neighbor-emitted compounds to defend against herbivory. We found that specific semi-volatiles emitted by Rhododendron tomentosum Harmaja are adsorbed to neighboring birch (Betula spp.) foliage in a natural habitat, in a field set-up and in the laboratory. These semi-volatiles were found to deter certain birch herbivores, and may thus confer associational resistance to birch. Here we show the relative change in the volatile profile of birch that occurs when neighbored by R. tomentosum. We further discuss the potential wider role of biogenic semi-volatiles for ecological interactions in natural environments and suggest how they might be utilized for pest management in agricultural crop production.Key words: associational resistance, Betula sp., herbivory, Rhododendron tomentosum Harmaja, semi-volatilesPlant-emitted, airborne volatiles are an ingenious way for plants to send and receive information on their surrounding environment. Plant volatiles are influenced by a multitude of internal and external factors¹ and have a range of ecological roles such as defense against biotic² and abiotic stressors³ and attraction of pollinators.⁴ Their ability to confer increased resistance has been suggested to create the plasticity plants need to survive in changing environments.⁵ As plant populations are dynamically changing systems, complexly influenced by the biotic and abiotic environment, volatiles emitted by plants growing in heterogeneous associations will become intermingled. The mixture of chemicals emitted by different plants may appear chaotic, but the effects of emissions by neighboring species on the indirect defense of another may be definable. Background volatiles may mask, enhance or be irrelevant to foraging insects in their search for valuable resources that are indicated by volatile plant emissions.⁶ The persistence of plant-emitted volatiles—partly based on their chemical structure⁷—is of great significance to their effects on other neighboring plants. Slowly vaporizing semi-volatiles are of particular interest since they may be quick to condense on neighboring plant surfaces and significantly alter the chemical profile of the exposed plant.We have recently shown that birch foliage adsorbs specific semi-volatiles emitted from wild rosemary Rhododendron tomentosum Harmaja.⁸ Three R. tomentosum-specific semi-volatiles (ledol, palustrol and ledene) formed 24.5 ± 6.6% and 16.1 ± 7.9% of the total terpenoids emitted by two birch species, B. pendula and B. pubescens, respectively, when they were exposed to neighboring R. tomentosum in a field set-up (B. pendula) or in a natural habitat (B. pubescens) (Fig. 1). This shows a significant difference in the field experiment to the control treatment [p < 0.001 (Mann-Whitney U test)], from which these R. tomentosum-specific compounds were not found. Four hours after removing the B. pendula seedlings from the mixed association, the percentage of these three compounds had decreased to 8.8 ± 2.0%, but they still differed significantly from the control treatment (p < 0.001, Mann-Whitney U test). As the plants were first sampled before noon (10:00 a.m.) and then again 4 h after removing them from the associations (at ca. 2:00 p.m.), part of the loss probably indicates the temperature dependent release of semi-volatile compounds from surfaces.⁹ Therefore, the next step to understanding the ecological function of sticky semi-volatiles is to test how temperature affects the volatility of the adsorbed semi-volatiles and how the patterns of semi-volatiles staying adsorbed or volatilizing into the surrounding air correspond to the activity of herbivores.Open in a separate windowFigure 1Relative proportion (mean, % of total emission) of sesquiterpenoids (SQT), R. tomentosum-specific ledol, palustrol and ledene and other terpenoids from volatile profiles of control and R. tomentosum-neighboring birches. (A–D) Emissions of B. pendula grown in con-specific association (A: 10 min after removing the plants from the treatments and B: 4 h post-exposure) and R. tomentosum mixed association (C: 10 min post-exposure and D: 4 h post-exposure). n = 12. E and F: Emissions of B. pubescens growing in a natural habitat, with R. tomentosum growing at E: >5 m and F: <0.5 m distance. n = 6.In herbivore assays, two species out of five tested were shown to be either repelled by R. tomentosum volatiles or found in lower incidence on R. tomentosum-exposed birches.⁸ Thus, wider screens to test the effectiveness of R. tomentosum specific semi-volatiles against various insects and also important agricultural pests, would help reveal their exploitation potential e.g., for pest control in organic farming.¹⁰ A recent meta-analysis¹¹ on factors leading to differences in insect responses towards volatiles (e.g., attraction versus repellence) revealed that factors including the sex, feeding guild, taxonomic group and diet breadth of insects can be used to explain patterns of behavior. Furthermore, the complexity of volatile blend, habitat type and other mixing factors may complicate the actual effect. This makes it even more challenging to investigate whether associational resistance¹² by volatiles is an ecologically meaningful interaction in natural environments.¹³Associational resistance through volatiles would firstly require a significant effect on a particular pest herbivore (and its herbivorous growth stage), the presence of the emitter and receiver at the same habitat and some degree of persistence of the repellent volatiles on receiver foliage. The mechanism of resistance could take several routes (see

Cordeauxia edulis and Rhododendron tomentosum extracts disturb orientation and feeding behavior of Hylobius abietis and Phyllodecta laticollis

The use of plant‐based compounds to control insect pests is an alternative to the use of synthetic pesticides. We evaluated the repellent and antifeedant effects of Cordeauxia edulis Hemsley (Fabaceae) and Rhododendron tomentosum Harmaja (Ericaceae) extracts against Hylobius abietis L. (Coleoptera: Curculionidae) and Phyllodecta laticollis Suffrian (Coleoptera: Chrysomelidae). Repellent properties were evaluated by monitoring responses of adult insects toward the odor from extracts or extraction solvents (controls) in a Y‐tube olfactometer, and choice or no‐choice feeding tests were conducted by applying extracts or extraction solvents on stems of Scots pine [Pinus sylvestris L. (Pinaceae)] and European aspen [Populus tremula L. (Salicaceae)], host plants of H. abietis and P. laticollis, respectively. Extracts of R. tomentosum repelled adults of both insect species effectively. However, extracts of C. edulis did not repel H. abietis although its ethyl acetate extract showed repellence against the adults of P. laticollis. Feeding by H. abietis was significantly reduced by a methanol extract of C. edulis, and methanol and hexane extracts of R. tomentosum. Feeding by the adults and larvae of P. laticollis was significantly reduced by extracts from both plant species. Concomitant with less feeding, larval growth was retarded by ethyl acetate extracts of both plant species. Gas chromatography‐mass spectrometry analyses of the volatile components of the extracts showed that extracts from both plant species were mixtures of various terpene and non‐terpene compounds, which showed quantitative and/or qualitative variations between plant species and extraction solvents. This experiment showed that extracts from both plant species effectively manipulated the orientation and/or feeding behavior of the two beetle species. Hence, they may be considered as potential alternatives to synthetic chemical pesticides.     

Partitioning of 14C Labelled Assimilates in Arctium tomentosum

Plants of the biennial Arctium tomentosum were grown from seedto seed-set in an open field under three different treatments:control plants receiving full light intensity, plants with aleaf area reduced by 45 per cent, and shaded plants receivingonly 20 per cent of natural illumination. At various stagesof development the youngest fully expanded leaf of one plantin each treatment was exposed to ¹⁴CO₂ for half an hour. Subsequentdistribution of labelled assimilates in various plant partswas determined after eight hours. In the first year, the mostdominant sink was the tap root irrespective of variation inassimilate supply. During the production of new vegetative growthin the second season, a larger amount of radioactive photosynthatewas recovered from above ground parts, especially during formationof lateral branches. Seed filling consumed 80–90 per centof labelled carbon exported from the exposed leaf. In the secondyear, the most pronounced difference between treatments wasin the degree of apical dominance, being highest in shaded plantsand lowest in the plants with cut leaves. Results from ¹⁴C experimentsagreed fairly well with a ‘partitioning coefficient’derived from a growth analysis of plants grown independentlyunder the same experimental conditions. Reasons for discrepanciesbetween the ¹⁴C results and the partitioning coefficient arediscussed. Arctium tomentosum, burdock, variation in assimilate supply, assimilate distribution, ¹⁴CO₂, labelling, growth analysis