A Regional Multiple-Stressor Rank-Based Ecological Risk Assessment for the Fjord of Port Valdez,Alaska

We conducted an ecological risk assessment of the marine environment of Port Valdez, a fjord in south-central Alaska. Because the assessment was regional rather than site-specific and contained a large number of different stressors in a variety of environments, we required a nontraditional method to estimate risks. We created a Relative Risk Model to rank and sum individual risks numerically within each subarea, from each source, and to each habitat. Application of this model involved division of Port Valdez into 11 subareas containing specific ecological and anthropogenic structures and activities. Within each subarea, the stressor sources were analyzed to estimate exposure of receptors within habitats leading to effects relevant to the chosen assessment endpoints. The subareas were analyzed and compared to form a Port-wide perspective of ecological risk. Available chemical concentrations from sediment and mussels collected from the Port were compared to various toxicological benchmarks as a partial confirmation of the risk analysis. An estimation of the risk of polycyclic aromatic hydrocarbons (PAHs) to marine invertebrates indicated low risk. The municipal boat harbor had the highest estimate, which reflected our relative risk rankings. The Relative Risk Model approach appears robust and has potential for use in situations where multiple stressors are of concern and for assessments covering broad geographic areas. In the Port Valdez assessment the approach provided relative risk rankings for chemical and physical stressors from various sources. But data were available for confirmation of risk estimates only for the chemical stressors. The rankings are relative, and extrapolation beyond the scenario in which they were developed is not warranted. Uncertainty is large, and the numerical scores collapse a multidimensional space into a single value. Use of just the numerical score out of context is more valid than with other indexes. The value of the approach lies in the relative rankings and the accounting of the components of the relative risk score.     

Location of the active site of the bean {alpha}-amylase inhibitor and involvement of a Trp, Arg, Tyr triad

Seeds of the common bean contain three homologous proteins:phytohaemagglutinin E, phytohaemagglutinin L and the lectin-likeprotein     

Design and synthesis of orally-active and selective azaindane 5HT2c agonist for the treatment of obesity

Based on our original pyrazine hit, CP-0809101, novel conformationally-restricted 5HT2c receptor agonists with 2-piperazin-azaindane scaffold were designed. Synthesis and structure–activity relationship (SAR) studies are described with emphasis on optimization of the selectivity against 5HT2a and 5HT2b receptors with excellent 2c potency. Orally-active and selective compounds were identified with dose–responsive in vivo efficacy in our pre-clinical food intake model.     

Orally active and brain permeable proline amides as highly selective 5HT2c agonists for the treatment of obesity

Brain-penetrable proline amides were developed as 5HT2c agonists with more than 1000-fold binding selectivity against 5HT2b receptor. After medicinal chemistry optimization and SAR studies, orally active proline amides with robust efficacy in a rodent food intake inhibition model were uncovered.     

Fungal network responses to grazing

Mycelial networks operate on scales from microscopic to many m² and naturally persist for extended periods. As fungi exhibit highly adaptive development, it is important to test behavioural responses on natural substrata with realistic nutrient levels across a range of spatial scales and extended time periods. Here we quantified network responses over 7.5 months in large (57 × 57 cm) microcosms to test whether grazing shifts the network to a more resilient architecture. Resource limitation constrained any ability to respond at all, with both grazed and ungrazed networks gradually thinning out over time. Added resources sustained further exploratory growth, but only transiently increased cross-connectivity and network resilience, when tested by simulated damage in silico. Grazed networks were initially weaker and emergence of new exploratory growth was curtailed. However, increased interstitial proliferation led to new cross-links, consolidating the existing mycelial network and increasing the resilience of the network to further attack.     

Heterologous Expression of the Oxytetracycline Biosynthetic Pathway in Myxococcus xanthus

New natural products for drug discovery may be accessed by heterologous expression of bacterial biosynthetic pathways in metagenomic DNA libraries. However, a “universal” host is needed for this experiment. Herein, we show that Myxococcus xanthus is a potential “universal” host for heterologous expression of polyketide biosynthetic gene clusters.Bacterial natural products are excellent lead compounds for drug discovery and have played major roles in the development of pharmaceutical agents in nearly all therapeutic areas (1, 7, 9). Unfortunately, the rate of discovery of new bacterial natural products has decreased, due in part to frequent rediscovery of known compounds (7). An enormous and currently inaccessible reservoir of new natural products is located in the biosynthetic pathways found in the genomes of uncultivated bacteria (18). Heterologous expression of these biosynthetic gene clusters represents a powerful tool for discovering new natural products (20, 21). Herein, we demonstrate that the deltaproteobacterium Myxococcus xanthus is an effective host for heterologous expression of aromatic polyketide biosynthetic pathways. This work expands the scope of polyketide biosynthetic pathways which can be heterologously expressed in M. xanthus and suggests that M. xanthus may be a suitable general host for heterologous expression.Molecular phylogenetic studies have shown that bacterial diversity is enormous, and the vast majority of the diversity is found in uncultivated bacterial species (18). Estimates suggest that 99% of bacteria from the environment are uncultivatable using standard techniques (2, 15, 16). Culture-independent analyses of metagenomic DNA libraries from soil and marine environments indicate that there is a wealth of natural product diversity in these uncultivated strains. For example, analysis of a soil metagenome for a highly conserved region of polyketide synthase genes showed that none of the sequences found were present in the known public databases (5). Polyketide synthases are key enzymes responsible for the production of the polyketide family of natural products in proteobacteria, actinobacteria, and “low-G+C Gram-positive bacteria” (4, 12, 19). Polyketide natural products have been developed into antibiotic, anticancer, and immunosuppressant clinical agents (1, 6, 8). Based on these observations, metagenomic DNA libraries are expected to possess a large number of new polyketide biosynthetic pathways, representing substantial new chemical diversity for drug discovery.Heterologous expression of biosynthetic pathways can play a major role in interrogating metagenomic DNA libraries for new polyketide biosynthetic pathways. Heterologous production of polyketides in hosts such as Streptomyces coelicolor and Streptomyces lividans is an important tool in the identification and characterization of these pathways (6, 8, 17). Results from these studies have shown that Streptomyces strains are good hosts for heterologous production of many polyketides, particularly those from actinomycetes. However, Streptomyces strains have proved to be poor hosts for expression of deltaproteobacterial polyketide biosynthetic pathways, such as those in myxobacteria (10, 17). As polyketide biosynthetic pathways in metagenomic DNA libraries contain both actinomycete- and deltaproteobacterium-derived pathways, a heterologous expression host competent to express pathways of both origins is needed.We examined the ability of the deltaproteobacterium M. xanthus to act as a general heterologous expression host. M. xanthus is a predatory bacterium that undergoes multicellular development in response to nutrient starvation. During development, M. xanthus is known to be an effective host for the heterologous expression of the deltaproteobacterium-derived epothilone D biosynthetic pathway and has been used for the production of epothilone D for clinical trials (17). M. xanthus has also been shown to be an excellent host for the heterologous expression of several other myxobacterial metabolites, including myxothiazol and myxochromide S (3, 11, 22). We demonstrate that M. xanthus can also heterologously express the Streptomyces rimosus oxytetracycline biosynthetic pathway, producing oxytetracycline. This is the first example of a polyketide from a nonmyxobacterial species heterologously expressed in a myxobacterium.To generate an M. xanthus strain capable of heterologously expressing oxytetracycline, the Streptomyces rimosus oxytetracycline biosynthetic pathway (Fig. ​(Fig.1)1) was inserted via homologous recombination into the asgE locus of M. xanthus. The asgE locus of M. xanthus was amplified and inserted into the BglII site of pET28b (Novagen) to produce pMRH02. The oligonucleotides used for the amplification of the asgE locus were 5′-GACGAGATCTGTTGGAAGGTCGGCAACTGG-3′ and 5′-CTTAAGATCTTCCGTGAAGTACTGGCGCAC-3′. The asgE locus provides a chromosomal region for single-crossover homologous recombination into the M. xanthus chromosome. The 32-kb oxytetracycline pathway in S. rimosus was excised from pYT264 (24) and cloned into the EcoRI site of pMRH02 to produce pMRH08. M. xanthus DK1622 was electroporated under standard conditions (13) with pMRH08 to provide an M. xanthus ΔasgE Kan^r mutant. Positive selection for the chromosomal insertion was maintained throughout all experiments by use of kanamycin supplementation (40 μg/ml). This large genomic insertion significantly increased the doubling time for the strain (doubling time, ≈10 h).Open in a separate windowFIG. 1.Oxytetracycline biosynthetic pathway. (A) Enzymatic pathway responsible for formation of oxytetracycline. (B) Oxytetracycline biosynthesis gene cluster from S. rimosus.Oxytetracycline was heterologously produced in M. xanthus under standard rich medium culture conditions and detected in culture broth by liquid chromatography-mass spectrometry (LC-MS). A liquid culture of the mutant strain containing the oxytetracycline gene cluster was cultured for 10 days at 33°C in CTTYE (1.0% Casitone, 0.5% yeast extract, 10.0 mM Tris-HCl, 1.0 mM KH₂PO₄, and 8.0 mM MgSO₄; 100 ml). Acetone (10%, vol/vol) was added to the culture and vigorously mixed. The resulting mixture was extracted with 3 volumes of ethyl acetate to remove the organic soluble materials, including oxytetracycline. The organic extracts were concentrated in vacuo and resuspended in methanol (100 μl). LC-MS analyses were carried out using an Altima Hypersil C₁₈ column (3-μm particle size; 150 mm by 2.1 mm) with a linear gradient of water-acetonitrile (5 to 95%) with 0.05% formic acid over 90 min (0.20 ml/min), followed by positive-ion electrospray ionization (5,500 V) and analysis with a Shimadzu 2010A single quadrupole mass spectrometer. LC-MS analysis indicated that oxytetracycline was present in the fermentation broth (Fig. ​(Fig.2).2). The titer of oxytetracycline was determined to be approximately 10 mg per liter of fermentation broth. Quantification was performed in triplicate by LC-MS analysis using a standard curve generated from commercial oxytetracycline. Negative controls of M. xanthus DK1622 cultures processed under identical conditions did not contain detectable levels of oxytetracycline.Open in a separate windowFIG. 2.LC-MS ion extraction analysis of the molecular ion [M+H]⁺ of standard and culture extracts. (A) Oxytetracycline standard. (B) M. xanthus ΔasgE Kan^r mutant containing the oxytetracycline biosynthetic pathway. (C) Wild-type M. xanthus DK1622.These data indicate that M. xanthus can heterologously express the oxytetracycline polyketide synthase biosynthetic pathway in S. rimosus. Several factors affect the successful heterologous production of polyketide synthase pathways, including codon usage, mRNA stability, functionality of regulatory elements, and the presence of all necessary starter and extender units (14). As codon usages between M. xanthus and the genus Streptomyces are very similar and myxobacteria are known to produce polyketide products requiring a wide diversity of starter and extender units, neither codon usage nor starter and extender unit availability was considered likely to affect the ability of M. xanthus to heterologously express streptomycete biosynthetic pathways. As Streptomyces strains do not appear to be effective at heterologous expression of myxobacterial biosynthetic pathways, we were concerned that Myxococcus and Streptomyces strains may possess substantially different regulatory elements. Our data indicate that the regulatory elements present in streptomycete-derived biosynthetic pathways are sufficient to enable expression of the biosynthetic genes in M. xanthus. Further work exploring the regulatory elements present in myxobacterial polyketide biosynthetic gene clusters is needed to evaluate this hypothesis.This study demonstrates that M. xanthus can heterologously express streptomycete-derived polyketide biosynthetic pathways in addition to myxobacterial polyketide biosynthetic pathways. The observed titer of 10 mg/liter of culture broth is comparable to titers reported for the heterologous expression of myxobacterial polyketide biosynthetic pathways in myxobacteria (11) and streptomycete-derived polyketide biosynthetic pathways in Streptomyces (14, 23) and is sufficient for characterization of the polyketide product. Pseudomonas putida, which has a more favorable growth profile, has been shown to be a good host for heterologous expression of myxobacterial polyketide biosynthetic pathways, with product titers in the range of 0.6 to 40 mg/liter of culture broth (14, 21, 23). The observed breadth of polyketide pathways accessible and the titers of the polyketide products produced make M. xanthus an attractive potential candidate for a “universal” host for facilitating heterologous expression of polyketide biosynthetic pathways derived from environmental samples of metagenomic DNA.     

Rootstock genotype succession influences apple replant disease and root-zone microbial community composition in an orchard soil

Apple replant disease (ARD) is a soil-borne disease complex that affects young apple trees in replanted orchards, resulting in stunted growth and reduced yields. Newly developed rootstock genotypes with tolerance to ARD may help to control this disease. We determined the effects of rootstock genotype rotations during orchard renovation, by investigating root-zone soil microbial consortia and the relative severity of ARD on seven rootstock genotypes (M.9, M.26, G.30, G.41, G.65, G.935, and CG.6210) planted in soil where trees on four of those same rootstocks (M.9, M.26, G.30 and CG.6210) had grown for the previous 15 years. Rootstock genotyping indicated that genetic distances among rootstocks were loosely correlated with their differential responses to ARD. Root-zone fungal and bacterial community composition, assessed by DNA fingerprinting (T-RFLP), differed between M.26 and CG.6210. Soil bacterial communities were influenced most by which rootstock had grown in the soil previously, while fungal communities were influenced more by the current replanted rootstock. In a clone library of bacteria from M.26 and CG.6210 root-zone soil, β-Proteobacteria was the most abundant phylum (25% of sequences). Sequences representing the Burkholderia cepacia complex were obtained only from CG.6210 soil. Rootstock genotypes that were grown in the orchard soil previously affected subsequent ARD severity, but replanting with the same or closely related rootstocks did not necessarily exacerbate this disease problem. Our results suggest that genotype-specific interactions with soil microbial consortia are linked with apple rootstock tolerance or susceptibility to ARD.