A wall of funnels concentrates swimming bacteria

Randomly moving but self-propelled agents, such as Escherichia coli bacteria, are expected to fill a volume homogeneously. However, we show that when a population of bacteria is exposed to a microfabricated wall of funnel-shaped openings, the random motion of bacteria through the openings is rectified by tracking (trapping) of the swimming bacteria along the funnel wall. This leads to a buildup of the concentration of swimming cells on the narrow opening side of the funnel wall but no concentration of nonswimming cells. Similarly, we show that a series of such funnel walls functions as a multistage pump and can increase the concentration of motile bacteria exponentially with the number of walls. The funnel wall can be arranged along arbitrary shapes and cause the bacteria to form well-defined patterns. The funnel effect may also have implications on the transport and distribution of motile microorganisms in irregular confined environments, such as porous media, wet soil, or biological tissue, or act as a selection pressure in evolution experiments.     

Coding sequence polymorphism in avian mitochondrial genomes reflects population histories

Nucleotide sequence diversity at mitochondrial protein-coding loci from 72 species of birds from different geographical regions was analysed in order to test the hypothesis that temperate zone species show population genetic effects of past glaciation. Temperate zone species showed reduced nucleotide diversity in comparison to tropical mainland species, suggesting that the latter have long-term effective population sizes due to population bottleneck effects during the most recent glaciation. This hypothesis was further supported by evidence of an unusually high estimated rate of population growth in species breeding in North America and wintering in the New World tropics (Nearctic migrants), consistent with population expansion after a bottleneck. Nearctic migrants also showed evidence of an abundance of rare nonsynonymous (amino acid-altering) polymorphisms, a pattern suggesting that slightly deleterious polymorphisms drifted to high frequencies during a bottleneck and are now being eliminated by selection. Because the shape of the North American land mass limited the area available for refugia during glaciation, the bottleneck effects are predicted to have been particularly strong in Nearctic migrants, and this prediction was supported. The reduced genetic diversity of Nearctic migrants provides an additional basis for concern for the survival of these species, which are threatened by loss of habitat in the winter range and by introduced disease.     

Targeted quantum dot conjugates for siRNA delivery

Treatment of human diseases such as cancer generally involves the sequential use of diagnostic tools and therapeutic modalities. Multifunctional platforms combining therapeutic and diagnostic imaging functions in a single vehicle promise to change this paradigm. in particular, nanoparticle-based multifunctional platforms offer the potential to improve the pharmacokinetics of drug formulations, while providing attachment sites for diagnostic imaging and disease targeting features. We have applied these principles to the delivery of small interfering RNA (siRNA) therapeutics, where systemic delivery is hampered by rapid excretion and nontargeted tissue distribution. Using a PEGlyated quantum dot (QD) core as a scaffold, siRNA and tumor-homing peptides (F3) were conjugated to functional groups on the particle's surface. We found that the homing peptide was required for targeted internalization by tumor cells, and that siRNA cargo could be coattached without affecting the function of the peptide. Using an EGFP model system, the role of conjugation chemistry was investigated, with siRNA attached to the particle by disulfide cross-linkers showing greater silencing efficiency than when attached by a nonreducible thioether linkage. Since each particle contains a limited number of attachment sites, we further explored the tradeoff between number of F3 peptides and the number of siRNA per particle, leading to an optimized formulation. Delivery of these F3/siRNA-QDs to EGFP-transfected HeLa cells and release from their endosomal entrapment led to significant knockdown of EGFP signal. By designing the siRNA sequence against a therapeutic target (e.g., oncogene) instead of EGFP, this technology may be ultimately adapted to simultaneously treat and image metastatic cancer.     

Androgens drive divergent responses to salt stress in male versus female rat kidneys

Dahl-Iwai (DI) salt-sensitive rats were studied using microarrays to identify sex-specific differences in the kidney, both basal differences and differences in responses to a high-salt diet. In DI rat kidneys, gene expression profiles demonstrated inflammatory and fibrotic responses selectively in females. Gonadectomy of DI rats abrogated sex differences in gene expression. Gonadectomized female and gonadectomized male DI rats both responded to high salt with the same spectrum of gene expression changes as intact female DI rats. Androgens dominated the sex-selective responses to salt. Several androgen-responsive genes with roles potentiating the differential responses to salt were identified, including increased male expression of angiotensin-vasopressin receptor and prolactin receptor, decreased 5 alpha-reductase, and mixed increases and decreases in expression of Cyp4a genes that can produce eicosanoid hormones. These sex differences potentiate sodium retention by males and increase kidney function during gestation in females.     

PLEK2 promotes the proliferation and migration of non-small cell lung cancer cells in a BRD4-dependent manner

Molecular Biology Reports - It has been reported that Pleckstrin 2 (PLEK2) acts as an oncogene in non-small cell lung cancer (NSCLC). Bromodomain containing protein 4 (BRD4), an important...     

Determinants of variations in initial treatment strategies for stable ischemic heart disease

Background:

The ratio of revascularization to medical therapy (referred to herein as the revascularization ratio) for the initial treatment of stable ischemic heart disease varies considerably across hospitals. We conducted a comprehensive study to identify patient, physician and hospital factors associated with variations in the revascularization ratio across 18 cardiac centres in the province of Ontario. We also explored whether clinical outcomes differed between hospitals with high, medium and low ratios.

Methods:

We identified all patients in Ontario who had stable ischemic heart disease documented by index angiography performed between Oct. 1, 2008, and Sept. 30, 2011, at any of the 18 cardiac centres in the province. We classified patients by initial treatment strategy (medical therapy or revascularization). Hospitals were classified into equal tertiles based on their revascularization ratio. The primary outcome was all-cause mortality. Patient follow-up was until Dec. 31, 2012. Hierarchical logistic regression models identified predictors of revascularization. Multivariable Cox proportional hazards models, with a time-varying covariate for actual treatment received, were used to evaluate the impact of the revascularization ratio on clinical outcomes.

Results:

Variation in revascularization ratios was twofold across the hospitals. Patient factors accounted for 67.4% of the variation in revascularization ratios. Physician and hospital factors were not significantly associated with the variation. Significant patient-level predictors of revascularization were history of smoking, multivessel disease, high-risk findings on noninvasive stress testing and more severe symptoms of angina (v. no symptoms). Treatment at hospitals with a high revascularization ratio was associated with increased mortality compared with treatment at hospitals with a low ratio (hazard ratio 1.12, 95% confidence interval 1.03–1.21).

Interpretation:

Most of the variation in revascularization ratios across hospitals was warranted, in that it was driven by patient factors. Nonetheless, the variation was associated with potentially important differences in mortality.Stable ischemic heart disease is a common manifestation of cardiovascular disease, the leading cause of death in the world.^1,2 The treatment strategies for stable ischemic heart disease include medical therapy alone or in combination with revascularization by percutaneous coronary intervention (PCI) or coronary artery bypass grafting (CABG).A tremendous amount of research has examined the best initial treatment strategy for stable ischemic heart disease.^3–5 Randomized controlled trials have not shown a difference in major adverse events between optimal medical therapy and revascularization.⁶ Some argue that revascularization should be reserved only for symptom relief.^5,7,8 Criteria for the appropriate use of revascularization have been developed to aid in clinical decision-making; however, a substantial proportion of revascularization procedures for stable ischemic heart disease are performed under clinical circumstances deemed as “uncertain.”^9,10 Reflecting this uncertainty, there is wide regional variation in the rate of coronary revascularization,^11–13 which suggests different thresholds for invasive therapy for stable ischemic heart disease.Studies have predominantly examined the determinants of variations in the type of revascularization modality used.^13,14 There is a paucity of data exploring the determinants of variations in the earlier decision to treat with medical therapy alone or with revascularization. A study published nearly a decade ago did not examine outcomes.⁷ Accordingly, our primary research objective was to determine whether the variations in initial treatment strategies for stable ischemic heart disease are warranted. We conducted a comprehensive population-based study to identify patient, physician and hospital factors associated with variations in treatment strategies within 90 days after angiography. We also explored whether clinical outcomes differed between hospitals with high, medium and low ratios of revascularization to medical therapy (hereafter referred to as the revascularization ratio).     

tRNA‐dependent alanylation of diacylglycerol and phosphatidylglycerol in Corynebacterium glutamicum

Aminoacyl‐phosphatidylglycerol synthases (aaPGSs) are membrane proteins that utilize aminoacylated tRNAs to modify membrane lipids with amino acids. Aminoacylation of membrane lipids alters the biochemical properties of the cytoplasmic membrane and enables bacteria to adapt to changes in environmental conditions. aaPGSs utilize alanine, lysine and arginine as modifying amino acids, and the primary lipid recipients have heretofore been defined as phosphatidylglycerol (PG) and cardiolipin. Here we identify a new pathway for lipid aminoacylation, conserved in many Actinobacteria, which results in formation of Ala‐PG and a novel alanylated lipid, Alanyl‐diacylglycerol (Ala‐DAG). Ala‐DAG formation in Corynebacterium glutamicum is dependent on the activity of an aaPGS homolog, whereas formation of Ala‐PG requires the same enzyme acting in concert with a putative esterase encoded upstream. The presence of alanylated lipids is sufficient to enhance the bacterial fitness of C. glutamicum cultured in the presence of certain antimicrobial agents, and elucidation of this system expands the known repertoire of membrane lipids acting as substrates for amino acid modification in bacterial cells.