The DNA sequence on bacteriophage G4 recognized by the Escherichia coli B restriction enzyme.

Bacteriophage G4 possesses a single EcoB site located in the overlap between restriction fragments HinfI-12 and HaeIII-6. The sequence 5′-T-G-A … 8N … T-G-C-T occurs once in this segment and nowhere else in the DNA sequence of G4. Four independent G4 mutants that were not restricted by Escherichia coli B possessed the sequence 5′-T-G-A … 8N … T-G-C-C. The common sequence shared by the previously mapped EcoB sites on φXsB1, simian virus 40, f1, and fd DNAs is 5′-T-G-A … 8N … T-G-C-T … 9N … T. However, the sequence in the region of the G4 EcoB site contains an A instead of the final T conserved in these other examples. When the G4 EcoB site is aligned with the other EcoB sites, there are no conserved residues within 50 bases of the common sequence, 5′-T-G-A … 8N … T-G-C-T, except for those seven residues. The analysis of the EcoB site on G4 provides further evidence that only those seven bases are recognized by the E. coli B restriction enzyme.     

Enumerative and binomial sequential sampling plans for the multicolored Asian lady beetle (Coleoptera: Coccinellidae) in wine grapes

To develop a practical integrated pest management (IPM) system for the multicolored Asian lady beetle, Harmonia axyridis (Pallas) (Coleoptera: Coccinellidae), in wine grapes, we assessed the spatial distribution of H. axyridis and developed eight sampling plans to estimate adult density or infestation level in grape clusters. We used 49 data sets collected from commercial vineyards in 2004 and 2005, in Minnesota and Wisconsin. Enumerative plans were developed using two precision levels (0.10 and 0.25); the six binomial plans reflected six unique action thresholds (3, 7, 12, 18, 22, and 31% of cluster samples infested with at least one H. axyridis). The spatial distribution of H. axyridis in wine grapes was aggregated, independent of cultivar and year, but it was more randomly distributed as mean density declined. The average sample number (ASN) for each sampling plan was determined using resampling software. For research purposes, an enumerative plan with a precision level of 0.10 (SE/X) resulted in a mean ASN of 546 clusters. For IPM applications, the enumerative plan with a precision level of 0.25 resulted in a mean ASN of 180 clusters. In contrast, the binomial plans resulted in much lower ASNs and provided high probabilities of arriving at correct "treat or no-treat" decisions, making these plans more efficient for IPM applications. For a tally threshold of one adult per cluster, the operating characteristic curves for the six action thresholds provided binomial sequential sampling plans with mean ASNs of only 19-26 clusters, and probabilities of making correct decisions between 83 and 96%. The benefits of the binomial sampling plans are discussed within the context of improving IPM programs for wine grapes.     

Genetically alterable transport of amethopterin in Diplococcus pneumoniae. II. Impairment of the system associated with various mutant genotypes

Six mutations determining resistance to amethopterin were examined for their effects on the active transport of the drug. In strains bearing each of the mutations and exhibiting resistance levels varying from 10- to 100-fold, transport at limiting concentrations of H(3)-amethopterin was reduced from 2.5 to 10 times the rate characteristic of the wild type. Kinetic analysis of transport showed an increase in the value for K(m) of the system in all of the mutants. Values for the wild-type system were 0.9 x 10(-6)m and for the mutants varied between 2.5 x 10(-6)m and 9.0 x 10(-6)m. Values for V(max) were approximately the same for each system. The mutant transport systems also exhibited a shift in pH optimum from near 6.0 (wild-type) to below 5.0. The results were interpreted as an alteration in the binding properties of the permease in the mutant strains.     

The chemical ecology of <Emphasis Type="Italic">Harmonia axyridis</Emphasis>

We review the chemical ecology of the ladybird beetle Harmonia axyridis from the perspective of its invasiveness and the deleterious effects it exerts in the regions it has colonised. We outline the nature and quantification of its chemical defence, and discuss the protection this provides against natural enemies, particularly intraguild predators. We consider the role of infochemicals in location of prey, intraspecific communication and intraguild interactions. We also discuss the role of prey allelochemicals in relation to H. axyridis extreme dietary generalism. Harmonia axyridis poses a number of practical problems for human health and well-being, including “ladybug taint” wine contamination and problems resulting from large aggregations overwintering in buildings. We consider chemical insights into these issues and, in particular, how attractants and repellents might help manage H. axyridis populations through a push–pull strategy. We conclude by discussing future perspectives for research.