SParticle,an algorithm for the analysis of filamentous microorganisms in submerged cultures

Streptomycetes are filamentous bacteria that produce a plethora of bioactive natural products and industrial enzymes. Their mycelial lifestyle typically results in high heterogeneity in bioreactors, with morphologies ranging from fragments and open mycelial mats to dense pellets. There is a strong correlation between morphology and production in submerged cultures, with small and open mycelia favouring enzyme production, while most antibiotics are produced mainly in pellets. Here we describe SParticle, a Streptomyces Particle analysis method that combines whole slide imaging with automated image analysis to characterize the morphology of submerged grown Streptomyces cultures. SParticle allows the analysis of over a thousand particles per hour, offering a high throughput method for the imaging and statistical analysis of mycelial morphologies. The software is available as a plugin for the open source software ImageJ and allows users to create custom filters for other microbes. Therefore, SParticle is a widely applicable tool for the analysis of filamentous microorganisms in submerged cultures.     

Extracellular enzyme production and fungal mycelia degradation of antagonistic Streptomyces induced by fungal mycelia preparation of cucurbit plant pathogens

Streptomyces are beneficial soil microorganisms and potential candidates for biocontrol agents against soilborne pathogenic fungi of cucurbit plants. Extracellular enzymes such as cellulase, chitinase and glucanase produced by Streptomyces are important components of actinomycete-fungus antagonism. This study aimed to investigate the influence on extracellular enzymes production and fungal mycelia degradation by antagonistic Streptomyces of mycelia preparation of pathogenic fungi (MPPF) of cucurbit plants. The results showed that the antagonistic Streptomyces displayed high extracellular enzyme activities to varying degrees when MPPF was used as the sole carbon source. The MPPF from Fusarium proliferatum, Fusarium oxysporum f. sp. niveum and Alternaria tenuissima were the most effective carbon sources in enhancing the cellulase activity of Streptomyces globisporus C7, Streptomyces globisporus subsp. globisporus C28 and Streptomyces kanamyceticus C49, respectively. S. globisporus subsp. globisporus C28, Streptomyces pactum A12 and S. kanamyceticus C49 cultured in the medium containing MPPF from Fusarium equiseti showed the highest chitinase activity (12.35, 12.50 and 15.06 U, respectively) of all the MPPF treatments. Glucanase activity of Streptomyces carnosus A11 was enhanced greatly (9.26 U) when MPPF from A. tenuissima was used as the sole carbon source. A hyphal intertwining and degradation phenomenon was observed when the antagonistic Streptomyces came across the pathogenic fungal mycelia, which was due to a synergistic effect of the extracellular enzymes produced by the antagonistic Streptomyces.     

Biochemical and functional characterization of three types of coated vesicles in bovine adrenocortical cells: implication in the intracellular traffic

Three populations of pure coated vesicles from adrenocortical cells, differing in their density, i.e., 1.125-1.155, 1.155-1.175, and 1.175-1.210 g/cm3, are obtained after separation on two successive sucrose-2H2O gradients. They are involved in LDL internalization and in the receptor cycle as confirmed by the presence, in each population, of the LDL receptor. Electron micrographs confirm the existence of three homogeneous populations exhibiting the typical polygonal structure of the clathrin coat. They differ in their size distribution (small, congruent to 70-nm diameter; medium, congruent to 90-nm diameter; large, congruent to 110-nm diameter) and in the organization of clathrin and of the coat proteins as evidenced on electrophoreses carried out under nondenaturing and denaturing conditions. Activity measurements of marker enzymes, phosphodiesterase and galactosyltransferase, suggest that medium coated vesicles might originate from plasma membranes and small ones from the Golgi complex. Large coated vesicles exhibit phosphokinase enzyme and substrate polypeptides different from those of the two other populations, tubulins being the preferred kinase substrates for the small and medium coated vesicles. These kinases are autophosphorylating enzymes and are revealed, by nondenaturing electrophoreses, as different high molecular mass complexes in the three populations. Clathrin and coat proteins are not part of these complexes.     

Population fragmentation may reduce fertility to zero in Banksia goodii — a demonstration of the Allee effect

All individuals of all known populations of Banksia goodii were assessed for seed production. Small populations produced no or only a few seeds per unit canopy area. Effects of population size on seed production per unit area and seed production per plant were present over the whole range of population sizes, indicating that even in large populations seed production may still not be at its maximum. Resource differences could not explain this disproportionate decrease in seed production with decline in population size, because there were no differences in soil properties and understorey or overstorey cover between the small and large populations. Although plants in small and large populations were similar in size, seed production per plant was much lower in small populations. This was not because plants in small populations produced fewer cones but because the fraction of these cones that was fertile was much lower. Five of the nine smallest populations (<200 m²) produced no fertile cones over the last 10 years. The number of seeds per fertile cone did not depend on population size. The results are discussed in relation to pollination biology.     

Improvement of transglutaminase production by extending differentiation phase of Streptomyces hygroscopicus: mechanism and application

Streptomyces transglutaminase (TGase) is an important industrial enzyme that catalyzes cross-linking of proteins. It is secreted as a zymogene and then is activated by proteases under physiological conditions. Although the activation process of TGase has been well investigated, the physiological function of TGase in Streptomyces has not been revealed. In this study, physiological function of TGase from Streptomyces hygroscopicus was found to be involved in differentiation by construction of a TGase gene interruption mutation strain (Δtg). The mutant Δtg showed an absence of differentiation compared with the parent strain. Furthermore, the production of TGase was found to be increased with the extending growth arrest phase of mycelium in submerged cultures. Thus, to enhance yield of TGase, the mycelium differentiation of Streptomyces was regulated via low temperature stress in a 3-L stirred-tank fermenter. The production of TGase increased by 39 % through extending the growth arrest phase for 4 h. This study found that TGase is involved in Streptomyces differentiation and proposed an approach to improve TGase production by regulation of mycelium differentiation in submerged cultures.     

<Emphasis Type="Italic">Streptomyces thermoalkaliphilus</Emphasis> sp. nov., an alkaline cellulase producing thermophilic actinomycete isolated from tropical rainforest soil

During an investigation exploring potential sources of novel thermophilic species and natural products, a novel thermophilic and alkaliphilic actinomycete with alkaline cellulase producing ability, designated strain 4-2-13^T, was isolated from soil of a tropical rainforest in Xishuangbanna, Yunnan province, China. The morphological and chemotaxonomic characteristics of strain 4-2-13^T are consistent with those of the members of the genus Streptomyces. The strain forms extensively branched aerial mycelia and substrate mycelia. Spiral spore chains were observed on aerial mycelia; spores were oval to cylindrical, with smooth surfaces. The organism was found to contain ll-diaminopimelic acid as the diagnostic diamino acid in the cell wall peptidoglycan. The whole cell hydrolysates were found to contain glucose and ribose. The cellular fatty acid profile mainly consists of anteiso-C_17:0 and iso-C_16:0. The menaquinones were identified as MK-9(H₈), MK-10(H₆) and MK-9(H₆). The polar lipids profile were found to consist of diphosphatidylglycerol, phosphatidylmethylethanolamine, a ninhydrin-positive glycophospholipid, phosphatidylinositol, phosphatidylglycerol and unidentified glycolipids. The 16S rRNA gene sequence analysis showed that the organism belongs to the genus Streptomyces and in the 16S rRNA gene tree it formed a distinct phyletic line together with the closely related type strain Streptomyces burgazadensis Z1R7^T (95.2% sequence similarity). However, the phenotypic characteristics of strain 4-2-13^T are significantly different from those of S. burgazadensis Z1R7^T. Based on the phenotypic, chemotaxonomic and phylogenetic characteristics, strain 4-2-13^T represents a novel species in the genus Streptomyces, for which the name Streptomyces thermoalkaliphilus sp. nov. is proposed. The type strain is 4-2-13^T (= DSM 42159^T = CGMCC 4. 7205^T).     

Imaging secondary metabolism of Streptomyces sp. Mg1 during cellular lysis and colony degradation of competing Bacillus subtilis

Soil streptomycetes are saprotrophic bacteria that secrete numerous secondary metabolites and enzymes for extracellular functions. Many streptomycetes produce antibiotics thought to protect vegetative mycelia from competing organisms. Here we report that an organism isolated from soil, Streptomyces sp. Mg1, actively degrades colonies and causes cellular lysis of Bacillus subtilis when the organisms are cultured together. We predicted that the inhibition and degradation of B. subtilis colonies in this competition depends upon a combination of secreted factors, including small molecule metabolites and enzymes. To begin to unravel this complex competitive phenomenon, we use a MALDI imaging mass spectrometry strategy to map the positions of metabolites secreted by both organisms. In this report, we show that Streptomyces sp. Mg1 produces the macrolide antibiotic chalcomycin A, which contributes to inhibition of B. subtilis growth in combination with other, as yet unidentified factors. We suggest that efforts to understand competitive and cooperative interactions between bacterial species benefit from assays that pair living organisms and probe the complexity of metabolic exchanges between them.     

Effects of habitat fragmentation on the reproductive success of the nectar-producing orchid Gymnadenia conopsea and the nectarless Orchis mascula

Habitat fragmentation decreases plant population sizes and increases spatial isolation, which hampers the exchange of seeds and pollen between fragmented populations. This may result in decreased population viability. We compared the effects of population size and isolation on the reproductive success of two orchid species, Gymnadenia conopsea (nectar-producing) and Orchis mascula (nectarless) growing in highly fragmented calcareous grassland in southern Belgium. We expected that the nectar-producing species would be more susceptible to the negative reproductive consequences of habitat fragmentation compared to the nectarless species. Nectar production has been associated with increased geitonogamous pollination and, therefore, with lower seed viability. Our results show that seed viability increased with increasing population size in O. mascula, whereas it was always low in G. conopsea, even in large populations. In contrast, percentage fruit set was positively related to population size in the nectar-producing G. conopsea, but no such effect was observed in the nectarless O. mascula, where fruit set was low even in large populations. Population isolation was not related to reproductive success for either species. Our results suggest that even in large populations, where pollinators are expected to be more abundant, increased geitonogamous pollination reduces seed viability in the nectar-producing G. conopsea. In contrast, seed viability in O. mascula seems to benefit from increased pollinator availability in larger populations. For the latter species, however, fruit set remains low, even in large populations, compared to G. conopsea. This may be explained by the relatively low attractiveness of nectarless orchid species for pollinators. Our results indicate that small population size may negatively influence reproductive success in both nectarless and nectar-producing orchids by reducing seed viability and fruit set, respectively.     

Streptomyces tunisiensis sp. nov., a novel Streptomyces species with antibacterial activity

A novel actinomycete strain designated CN-207^T was isolated from northern Tunisian soil. This strain exhibited potent broad spectrum antibacterial activity against clinical isolates of methicillin-resistant Staphylococcus species and several other Gram-positive and Gram-negative bacteria. Strain CN-207^T developed greyish aerial mycelium and pale grey substrate mycelium on yeast extract/malt agar. The isolate produced branching vegetative mycelia with sporangiophores bearing sporangia developing at a late stage of growth. The sporangia contained smooth, non-motile spores. Chemotaxonomic characteristics of strain CN-207^T were typical of the Streptomyces genus. Phylogenetic analysis based on 16S rRNA gene sequences indicated that strain CN-207^T belonged to the genus Streptomyces, and was most closely related to Streptomyces griseoincarnatus DSM 40274^T, Streptomyces variabilis DSM 40179^T, Streptomyces labedae DSM 41446^T and Streptomyces erythrogriseus DSM 40116^T. Low DNA–DNA relatedness values were recorded between strain CN-207^T and its closest phylogenetic neighbours. Strain CN-207^T was also distinguished from the nearest phylogenetic neighbours using a combination of morphological and phenotypic characteristics. On the basis of its phenotypic and molecular properties, strain CN-207^T is considered as a novel species of the Streptomyces genus, for which the name Streptomyces tunisiensis sp. nov. is proposed. The type strain is CN-207^T (=JCM 17589^T = DSM 42037^T).     

Genomic analysis reveals Lactobacillus sanfranciscensis as stable element in traditional sourdoughs

Background

The Ala-Pro-rich O-glycoprotein known as the 45/47 kDa or APA antigen from Mycobacterium tuberculosis is an immunodominant adhesin restricted to mycobacterium genus and has been proposed as an alternative candidate to generate a new vaccine against tuberculosis or for diagnosis kits. In this work, the recombinant O-glycoprotein APA was produced by the non-pathogenic filamentous bacteria Streptomyces lividans, evaluating three different culture conditions. This strain is known for its ability to produce heterologous proteins in a shorter time compared to M. tuberculosis.

Results

Three different shake flask geometries were used to provide different shear and oxygenation conditions; and the impact of those conditions on the morphology of S. lividans and the production of rAPA was characterized and evaluated. Small unbranched free filaments and mycelial clumps were found in baffled and coiled shake flasks, but one order of magnitude larger pellets were found in conventional shake flasks. The production of rAPA is around 3 times higher in small mycelia than in larger pellets, most probably due to difficulties in mass transfer inside pellets. Moreover, there are four putative sites of O-mannosylation in native APA, one of which is located at the carboxy-terminal region. The carbohydrate composition of this site was determined for rAPA by mass spectrometry analysis, and was found to contain different glycoforms depending on culture conditions. Up to two mannoses residues were found in cultures carried out in conventional shake flasks, and up to five mannoses residues were determined in coiled and baffled shake flasks.

Conclusions

The shear and/or oxygenation parameters determine the bacterial morphology, the productivity, and the O-mannosylation of rAPA in S. lividans. As demonstrated here, culture conditions have to be carefully controlled in order to obtain recombinant O-glycosylated proteins with similar "quality" in bacteria, particularly, if the protein activity depends on the glycosylation pattern. Furthermore, it will be an interesting exercise to determine the effect of shear and oxygen in shake flasks, to obtain evidences that may be useful in scaling-up these processes to bioreactors. Another approach will be using lab-scale bioreactors under well-controlled conditions, and study the impact of those on rAPA productivity and quality.     

When bigger is not better: intraspecific competition for pollination increases with population size in invasive milkweeds

One of the essential requirements for an introduced plant species to become invasive is an ability to reproduce outside the native range, particularly when initial populations are small. If a reproductive Allee effect is operating, plants in small populations will have reduced reproductive success relative to plants in larger populations. Alternatively, if plants in small populations experience less competition for pollination than those in large populations, they may actually have higher levels of reproductive success than plants in large populations. To resolve this uncertainty, we investigated how the per capita fecundity of plants was affected by population size in three invasive milkweed species. Field surveys of seed production in natural populations of different sizes but similar densities were conducted for three pollinator-dependent invasive species, namely Asclepias curassavica, Gomphocarpus fruticosus and G. physocarpus. Additionally, supplemental hand-pollinations were performed in small and large populations in order to determine whether reproductive output was limited by pollinator activity in these populations. Reproductive Allee effects were not detected in any of the study species. Instead, plants in small populations exhibited remarkably high levels of reproductive output compared to those in large populations. Increased fruit production following supplemental hand-pollinations suggested that the lower reproductive output of naturally pollinated plants in large populations is a consequence of pollen limitation rather than limitation due to abiotic resources. This is consistent with increased intraspecific competition for pollination amongst plants in large populations. It is likely that the invasion of these milkweed species in Australia has been enhanced because plants in small founding populations experience less intraspecific competition for pollinators than those in large populations, and thus have the ability to produce copious amounts of seeds.     

高山被孢霉发酵生产花生四烯酸的宏观形态

采用图像处理技术对高山被孢霉(Mortierella alpina)发酵过程中的不同形态进行分析,并对其产花生四烯酸(ARA)能力进行了比较。研究发现:复合N源中蛋白胨与酵母粉比例是影响高山被孢霉宏观形态的重要因素,球形形态生长的菌体中ARA产量较分散,菌丝体中ARA产量高;在球形形态中,空心球的菌体生物量低,ARA比例低,蓬松球可以兼顾菌体高生物量、高油脂比例及高ARA比例。产ARA能力由生物量、油脂比例及油脂中ARA比例共同决定。结果表明:直径大约4 mm、成核区域面积大约为43.6%、紧密度为71.36的蓬松球形态,是高山被孢霉一种相对较佳的发酵形态,其菌体产ARA能力分别是空心球和分散丝状菌体产ARA能力的2.01和2.70倍。     

Repeatability of adaptation in experimental populations of different sizes

The degree to which evolutionary trajectories and outcomes are repeatable across independent populations depends on the relative contribution of selection, chance and history. Population size has been shown theoretically and empirically to affect the amount of variation that arises among independent populations adapting to the same environment. Here, we measure the contribution of selection, chance and history in different-sized experimental populations of the unicellular alga Chlamydomonas reinhardtii adapting to a high salt environment to determine which component of evolution is affected by population size. We find that adaptation to salt is repeatable at the fitness level in medium (N_e = 5 × 10⁴) and large (N_e = 4 × 10⁵) populations because of the large contribution of selection. Adaptation is not repeatable in small (N_e = 5 × 10³) populations because of large constraints from history. The threshold between stochastic and deterministic evolution in this case is therefore between effective population sizes of 10³ and 10⁴. Our results indicate that diversity across populations is more likely to be maintained if they are small. Experimental outcomes in large populations are likely to be robust and can inform our predictions about outcomes in similar situations.     

Inoculum Density and Population Dynamics of Suppressive and PathogenicStreptomycesStrains and Their Relationship to Biological Control of Potato Scab

SeveralStreptomycesstrains are capable of suppressing potato scab caused byStreptomyces scabies.Although these strains have been successful in the biocontrol of potato scab in the field, little is known about how populations of pathogenicStreptomycesin the potato rhizosphere are influenced by inoculation of the suppressive strains. The effects of inoculum densities of pathogenic and suppressiveStreptomycesstrains on their respective populations on roots and in rhizosphere soil were examined during the growing season. The relationships between inoculum density or rhizosphere population densities and disease severity were also investigated. Populations of suppressiveStreptomycesstrain 93 increased significantly on roots with increasing inoculum dose. At its highest inoculum dose, the suppressive strain reached a population density greater than 10⁶CFU/g root 14 weeks after planting. The ability of the suppressive strain to increase its populations with increasing inoculum density was hindered at high inoculum doses of the pathogen, suggesting that density-dependent competitive interactions may be occurring between the two antagonists. Strain 93 was most effective at preventing scab early in the growing season (8 weeks after planting), when tubers were most susceptible to the scab disease. Population densities of the suppressive strain in soil were more highly negatively correlated with scab severity than were populations on roots, suggesting that rhizosphere soil rather than potato roots may be the primary source of inoculum of the suppressive strain for tubers.     

Resuscitation-Promoting Factors Are Cell Wall-Lytic Enzymes with Important Roles in the Germination and Growth of Streptomyces coelicolor

Dormancy is a common strategy adopted by bacterial cells as a means of surviving adverse environmental conditions. For Streptomyces bacteria, this involves developing chains of dormant exospores that extend away from the colony surface. Both spore formation and subsequent spore germination are tightly controlled processes, and while significant progress has been made in understanding the underlying regulatory and enzymatic bases for these, there are still significant gaps in our understanding. One class of proteins with a potential role in spore-associated processes are the so-called resuscitation-promoting factors, or Rpfs, which in other actinobacteria are needed to restore active growth to dormant cell populations. The model species Streptomyces coelicolor encodes five Rpf proteins (RpfA to RfpE), and here we show that these proteins have overlapping functions during growth. Collectively, the S. coelicolor Rpfs promote spore germination and are critical for growth under nutrient-limiting conditions. Previous studies have revealed structural similarities between the Rpf domain and lysozyme, and our in vitro biochemical assays revealed various levels of peptidoglycan cleavage capabilities for each of these five Streptomyces enzymes. Peptidoglycan remodeling by enzymes such as these must be stringently governed so as to retain the structural integrity of the cell wall. Our results suggest that one of the Rpfs, RpfB, is subject to a unique mode of enzymatic autoregulation, mediated by a domain of previously unknown function (DUF348) located within the N terminus of the protein; removal of this domain led to significantly enhanced peptidoglycan cleavage.     

Production,long term preservation and synchronous germination of aerial spores of Streptomyces

Vigorous vegetative growth of various Streptomyces species (S. auroefaciens, S. collinus and S. granaticolor) was achieved in a new semisynthetic liquid medium. Unlike the media commonly used for the cultivation of the submerged mycelia of different streptomycetes, this one does not contain insoluble material which enables direct and reliable measurement of net production of biomass. The medium was formulated to meet the nutritional requirements of all the three species. Is also supported production of antibiotic in each of the strains. A method for bulk preparation of Streptomyces aerial spores, involving cultivation on agar plates covered with cellophane, was developed. Advantage of this method lies in higher yields of spores, their higher purity and easier harvesting. The spores were activated by amild treatment with an Ultra-Turrax homogenizer resulting in the breakage of fibrous sheath, suspended in 20% glycerol, and stored at ?60°C. Thus, treated spores germinated synchronously even after several months of the storage. Hence, such spore material may be used for precise inoculation in a large series of experiments implying synchronous germination, and the inoculations can be carried out from the same batch over a long period.     

Oil and air dispersion in a simulated fermentation broth as a function of mycelial morphology

The culture conditions of a multiphase fermentation involving morphologically complex mycelia were simulated in order to investigate the influence of mycelial morphology (Trichoderma harzianum) on castor oil and air dispersion. Measurements of oil drops and air bubbles were obtained using an image analysis system coupled to a mixing tank. Complex interactions of the phases involved could be clearly observed. The Sauter diameter and the size distributions of drops and bubbles were affected by the morphological type of biomass (pellets or dispersed mycelia) added to the system. Larger oil drop sizes were obtained with dispersed mycelia than with pellets, as a result of the high apparent viscosity of the broth, which caused a drop in the power drawn, reducing oil drop break-up. Unexpectedly, bubble sizes observed with dispersed mycelia were smaller than with pellets, a phenomenon which can be explained by the segregation occurring at high biomass concentrations with the dispersed mycelia. Very complex oil drops were produced, containing air bubbles and a high number of structures likely consisting of small water droplets. Bubble location was influenced by biomass morphology. The percentage (in volume) of oil-trapped bubbles increased (from 32 to 80%) as dispersed mycelia concentration increased. A practically constant (32%) percentage of oil-trapped bubbles was observed with pelleted morphology at all biomass concentrations. The results evidenced the high complexity of phases interactions and the importance of mycelial morphology in such processes.     

THE EFFECT OF DELAYED POPULATION GROWTH ON THE GENETIC DIFFERENTIATION OF LOCAL POPULATIONS SUBJECT TO FREQUENT EXTINCTIONS AND RECOLONIZATIONS

I investigated the effects of delayed population growth on the genetic differentiation among populations subjected to local extinction and recolonization, for two different migration functions; (1) a constant migration rate, and (2) a constant number of migrants. A delayed period of population growth reduces the size of the newly founded populations for one or several generations. Whether this increases differentiation among local populations depends on the actual pattern of migration. With a constant migration rate, fewer migrants move into small populations than into large, thus providing ample opportunity for drift to act within a population. A prolonged period of population growth thus makes the conditions for enhanced differentiation between local populations less restrictive and also inflates the actual levels of differentiation. The effect depends on the relative magnitudes of k_e, the effective number of colonizers and k, the actual number of colonizers. When there is a constant number of migrants into a population per generation, migration into small populations is increased. This increase of migration in small populations counteracts the effects of genetic drift due to small population size. It increases the rate by which populations approach equilibrium, as small populations are swamped by migrants from larger populations closer to genetic equilibrium, and overall levels of differentiation are thus reduced. I also discuss situations for which the results of this paper are relevant.     

The Abundance and Pollen Foraging Behaviour of Bumble Bees in Relation to Population Size of Whortleberry (Vaccinium uliginosum)

Habitat fragmentation can have severe effects on plant pollinator interactions, for example changing the foraging behaviour of pollinators. To date, the impact of plant population size on pollen collection by pollinators has not yet been investigated. From 2008 to 2010, we monitored nine bumble bee species (Bombus campestris, Bombus hortorum s.l., Bombus hypnorum, Bombus lapidarius, Bombus pascuorum, Bombus pratorum, Bombus soroensis, Bombus terrestris s.l., Bombus vestalis s.l.) on Vaccinium uliginosum (Ericaceae) in up to nine populations in Belgium ranging in size from 80 m² to over 3.1 ha. Bumble bee abundance declined with decreasing plant population size, and especially the proportion of individuals of large bumble bee species diminished in smaller populations. The most remarkable and novel observation was that bumble bees seemed to switch foraging behaviour according to population size: while they collected both pollen and nectar in large populations, they largely neglected pollen collection in small populations. This pattern was due to large bumble bee species, which seem thus to be more likely to suffer from pollen shortages in smaller habitat fragments. Comparing pollen loads of bumble bees we found that fidelity to V. uliginosum pollen did not depend on plant population size but rather on the extent shrub cover and/or openness of the site. Bumble bees collected pollen only from three plant species (V. uliginosum, Sorbus aucuparia and Cytisus scoparius). We also did not discover any pollination limitation of V. uliginosum in small populations. We conclude that habitat fragmentation might not immediately threaten the pollination of V. uliginosum, nevertheless, it provides important nectar and pollen resources for bumble bees and declining populations of this plant could have negative effects for its pollinators. The finding that large bumble bee species abandon pollen collection when plant populations become small is of interest when considering plant and bumble bee conservation.     

Comparison of crude lysate pellets from isogenic strains of yeast with different prion composition: Identification of prion-associated proteins

A new approach involving the comparative analysis of proteins of crude cell lysate pellets from isogenic strains of Saccharomyces cerevisiae distinguished by their prion composition permitted us to identify a large group of prion-associated proteins in yeast cells. 35 proteins whose aggregation state depends on prion content have been identified by 2D-electrophoresis followed by the MALDI analysis of a recipient [psi ⁻] strain and of [PSI ⁺] cytoductant. Approximately half of these proteins belong to functional groups of chaperones and enzymes involved in glucose metabolism. Other proteins are involved in translation, stress response and protein degradation. The data obtained are compared with the results of other groups who used different approaches to detect proteins involved in prion aggregates.