In situ quantification of fish‐cage fouling by underwater photography and image analysis

Close‐up underwater photography and image analysis were used to quantify mesh occlusion by biofouling of salmon‐cage netting. This technique allows fast, non‐destructive sampling of cages in situ for the determination of temporal and spatial changes in fouling. The area of net blockage can be easily determined, allowing rapid evaluation of cleaning or antifouling performance.     

137 DNA nanostructure serum stability: greater than the sum of their parts

DNA cages hold tremendous potential to encapsulate and selectively release therapeutic drugs, and can provide useful tools to probe the size and shape dependence of nucleic acid delivery (McLaughlin & Sleiman, H. F., 2011). These structures have been shown to site-specifically present ligands, small molecule drugs, or antisense/siRNA motifs, in order to increase their therapeutic efficiency (Li & Fan, C. 2012). One of the major barriers towards their in vivo applications is the susceptibility of their strands towards nuclease degradation. A number of chemical strategies have been used to block nuclease digestion of oligonucleotides and improve potency, such as the use of a phosphorothioate backbone, 2´-O-methyl, locked nucleic acids, and short hybrid gapmers. However, the synthesis of these oligonucleotides is often complicated and expensive, driving the need for simple modifications to enhance serum stability and address in vivo biodistribution. We show here a simple method to significantly enhance the nuclease stability of DNA strands, through introduction of commercially available, single-endmodifications (Conway & Sleiman 2013). We use these oligonucleotides to construct DNA cages in a single step and in quantitative yields. Even in single-stranded form, these cages stabilize their component strands towards nucleases, with mean lifetimes as long as 62?h in 10 % (v/v) fetal bovine serum (FBS). We examine the effect of other DNA-end modifications on nuclease susceptibility. Finally, we show the ligation of these single-stranded cages into topologically interesting catenane ‘necklaces,’ with mean lifetimes in serum of ～200?h.     

47 Incorporation of alternative nucleic acid chemistries into G-quadruplex structure

Nucleic acids that form G-quadruplex (G4) structure have found applications in a host of research and technology regimes. Numerous G4 based aptamer drugs have been identified with pharmacological activity against cancer, HIV, prions, and blood coagulation (1). In the field of nanotechnology, G4 based sensors and nano-machines have also received much attention. The ability to synthesize nucleic acid ex-vivo allows for the site-specific incorporation of non-natural chemistries into nucleic acids that can be used to tune their physical and pharmacological properties. We summarize the results of a series of studies investigating the effective incorporation of alternative nucleic acid chemistries into G4 DNA. These modified chemistries include C8-modified guanine bases, as well as 2′-F, 2′-F-ANA, and Locked nucleic acid (LNA) modifications to the ribose sugar. We report primarily on the effect of these modifications on G-quadruplex folding topology, thermal stability, and structure. The substitution of LNA-guanosine into the core guanine tetrads disrupts structure in specific structural environments. On the other hand, 2′-F- and 2′-F-ANA guanosine can generally be incorporated without disrupting the structure when substituted into guanine bases in certain structural conformations. We find that 2′-F-ANA-guanosine and 2′-F-guanosine are powerful tools for controling the conformation of G4 structures (2). Functionalization at the C8 of the guanine base stabilizes in a manner dependent on the glycosidic conformation of the base, with different modification chemistries stabilizing to varying extents (3). The results of these studies provide useful insight on how to effectively incorporate some useful chemical tools from the growing toolbox of modified nucleic acid chemistries into G-quadruplex nucleic acid.     

Improved Chiral SFC Screening for Analytical Method Development

In this study we describe the evaluation of a recently developed supercritical fluid chromatography (SFC) instrument for automated chiral SFC method development. The greatly improved gradient dwell volume and liquid flow control of the new instrument in combination with the use of shorter columns containing smaller stationary phase particles affords chiral SFC method development that is faster and more universal than previous systems. Chirality 25:799–804, 2013. © 2013 Wiley Periodicals, Inc.     

Home range,activity and sociality of a top predator,the dingo: a test of the Resource Dispersion Hypothesis

The idea that groups of individuals may develop around resource patches led to the formulation of the Resource Dispersion Hypothesis (RDH). We tested the predictions of the RDH, within a quasi‐experimental framework, using Australia’s largest terrestrial predator, the dingo Canis lupus dingo. Average dingo group sizes were higher in areas with abundant focal food sources around two mine sites compared with those in more distant areas. This supports the notion that resource richness favours larger group size, consistent with the RDH. Irrespective of season or sex, average home range estimates and daily activity for dingoes around the mine sites were significantly less than for dingoes that lived well away. Assuming that a territory is the defended part of the home range and that territory size is correlated with home range size, consistent with the RDH, the spatial dispersion of food patches therefore determined territory size for dingoes in our study. However, although sample size was small, some dingoes that accessed the supplementary food resource at the mines also spent a large proportion of their time away, suggesting a breakdown of territorial defence around the focal food resource. This, in combination with the large variation in home range size among dingoes that accessed the same supplementary food resource, limits the predictive capabilities of the RDH for this species. We hypothesize that constraints on exclusive home range occupancy will arise if a surfeit of food resources (in excess of requirements for homeostasis) is available in a small area, and that this will have further effects on access to mates and social structure. We present a conceptual model of facultative territorial defence where focal resources are available to demonstrate our findings.     

Observations of below-ground characteristics of young redwood trees (Sequoia sempervirens) from two sites in New Zealand – implications for erosion control

Aims

Radiata pine (Pinus radiata D. Don) plantations are widely used to control erosion in New Zealand. However, other species with similar growth but longer rotation lengths and ability to coppice may offer future alternatives to radiata pine. Comparing performance of alternative species to radiata thus becomes important if policy is to be developed to promote them.

Methods

The below-ground characteristics (roots) of young redwood (Sequoia sempervirens (D. Don) Endl.) trees from two established plantations in New Zealand were examined and compared with those of radiata pine, and selected poplar and New Zealand native species.

Results

Roots with diameters less than 10 mm comprised over 99 % of total root length in 3-yr-old trees and 98 % of total root length in 4-yr-old trees. For roots greater than 2 mm in diameter, total root length of young redwood trees was greater than that of young radiata pine, poplar and the best performing New Zealand native plant. Total root length at a given root collar diameter for young (1–4 year old) redwood trees was significantly greater than for radiata pine trees. Roots of redwoods were finer and more numerous than for radiata but the below-ground biomass for a given root collar diameter showed no statistical difference between the two species.

Conclusions

Redwood, because of its comparable growth rate and the production of many fine lateral roots, has the potential to become a keystone erosion-control species in New Zealand, especially on steep lands where there is an increased risk of post-harvest landsliding associated with moderate to severe rainstorm events.     

Induction of a ricinosomal-protease and programmed cell death in tomato endosperm by gibberellic acid

Several examples of programmed cell death (PCD) in plants utilize ricinosomes, organelles that appear prior to cell death and store inactive KDEL-tailed cysteine proteinases. Upon cell death, the contents of ricinosomes are released into the cell corpse where the proteinases are activated and proceed to degrade any remaining protein for use in adjacent cells or, in the case of nutritive seed tissues, by the growing seedling. Ricinosomes containing pro-SlCysEP have been observed in anther tissues prior to PCD and ricinosome-like structures have been observed in imbibed seeds within endosperm cells of tomato. The present study confirms that the structures in tomato endosperm cells contain pro-SlCysEP making them bona fide ricinosomes. The relative abundance of pro- versus mature SlCysEP is suggested to be a useful indicator of the degree of PCD that has occurred in tomato endosperm, and is supported by biochemical and structural data. This diagnostic tool is used to demonstrate that a sub-region of the micropylar endosperm surrounding the emerged radical is relatively long-lived and may serve to prevent loss of mobilized reserves from the lateral endosperm. We also demonstrate that GA-induced reserve mobilization, SlCysEP accumulation and processing, and PCD in tomato endosperm are antagonized by ABA.     

The plant Selaginella moellendorffii possesses enzymes for synthesis and hydrolysis of the compatible solutes mannosylglycerate and glucosylglycerate

A mannosylglycerate synthase (MgS) gene detected in the genome of Selaginella moellendorffii was expressed in E. coli and the recombinant enzyme was purified and characterized. A remarkable and unprecedented feature of this enzyme was the ability to efficiently synthesize mannosylglycerate (MG) and glucosylglycerate (GG) alike, with maximal activity at 50 °C, pH 8.0 and with Mg²⁺ as reaction enhancer. We have also identified a novel glycoside hydrolase gene in this plant’s genome, which was functionally confirmed to be highly specific for the hydrolysis of MG and GG and named MG hydrolase (MgH), due to its homology with bacterial MgHs. The recombinant enzyme was maximally active at 40 °C and at pH 6.0–6.5. The activity was independent of cations, but Mn²⁺ was a strong stimulator. Regardless of these efficient enzymatic resources we could not detect MG or GG in S. moellendorffii or in the extracts of five additional Selaginella species. Herein, we describe the properties of the first eukaryotic enzymes for the synthesis and hydrolysis of the compatible solutes, MG and GG.