Potential pathogenic bacteria in metalworking fluids and aerosols from a machining facility

The metalworking and machining industry utilizes recirculating metalworking fluids for integral aspects of the fabrication process. Despite the use of biocides, these fluids sustain substantial biological growth. Subsequently, the high-shear forces incurred during metalworking processing aerosolize bacterial cells and may cause dermatologic and respiratory effects in exposed workers. We quantified and identified the bacterial load for metalworking fluid and aerosol samples of a machining facility in the US Midwest during two seasons. To investigate the presence of potentially pathogenic bacteria in fluid and air, we performed 16S rRNA gene surveys. The concentration of total bacterial cells (including culturable and nonculturable cells) was relatively constant throughout the study, averaging 5.1 × 10? cells mL?1 in the fluids and 4.8 × 10? cells m?3 in the aerosols. We observed bacteria of potential epidemiologic significance from several different bacterial phyla in both fluids and aerosols. Most notably, Alcaligenes faecalis was identified through both direct sequencing and culturing in every sample collected. Elucidating the bacterial community with gene surveys showed that metalworking fluids were the source of the aerosolized bacteria in this facility.     

Epidermal Growth Factor Receptor Activation Remodels the Plasma Membrane Lipid Environment To Induce Nanocluster Formation

Signal transduction is regulated by the lateral segregation of proteins into nanodomains on the plasma membrane. However, the molecular mechanisms that regulate the lateral segregation of cell surface receptors, such as receptor tyrosine kinases, upon ligand binding are unresolved. Here we used high-resolution spatial mapping to investigate the plasma membrane nanoscale organization of the epidermal growth factor (EGF) receptor (EGFR). Our data demonstrate that in serum-starved cells, the EGFR exists in preformed, cholesterol-dependent, actin-independent nanoclusters. Following stimulation with EGF, the number and size of EGFR nanoclusters increase in a time-dependent manner. Our data show that the formation of EGFR nanoclusters requires receptor tyrosine kinase activity. Critically, we show for the first time that production of phosphatidic acid by phospholipase D2 (PLD2) is essential for ligand-induced EGFR nanocluster formation. In accordance with its crucial role in regulating EGFR nanocluster formation, we demonstrate that modulating PLD2 activity tunes the degree of EGFR nanocluster formation and mitogen-activated protein kinase signal output. Together, these data show that EGFR activation drives the formation of signaling domains by regulating the production of critical second-messenger lipids and modifying the local membrane lipid environment.The epidermal growth factor (EGF) receptor (EGFR) is a single transmembrane domain protein that possesses intrinsic tyrosine kinase (TK) activity. Ligand binding to the extracellular domain induces conformational changes that promote activation of the intracellular TK domain. The kinase domain then autophosphorylates a number of tyrosine residues in the C-terminal region of the protein, creating docking sites for adapter and effector proteins. Thus, the active form of the EGFR could reasonably be expected to be a dimer. However, recent studies using single-molecule imaging, image correlation spectroscopy (ICS), fluorescence correlation spectroscopy (FCS), and immunoelectron microscopy (immuno-EM) show that the EGFR is, in fact, nonrandomly organized into oligomers on the plasma membrane (6, 7, 16, 34, 44). ICS measurements estimate that, in the absence of ligand, there are, on average, 2.2 EGFRs per cluster, which increases to 3.7 receptors per cluster upon stimulation (7). Single-molecule tracking experiments also suggest that unliganded EGFRs continually fluctuate between monomers and dimers that are primed for activation (5). Furthermore, the organization of the EGFR is dynamic and clustering of the EGFR increases over time after EGF stimulation (7, 16). However, neither the precise role of EGFR oligomerization in signal transduction nor the mechanisms driving oligomer formation have been resolved.The organization of the EGFR into oligomers is dependent upon cellular cholesterol. Saffarian et al., using FCS, estimated that 70% of EGFRs exist as monomers, 20% as dimers, and 10% as oligomers (34). However, depletion of cholesterol decreases the percentage of monomeric receptors and increases the proportion of oligomeric receptors. Cholesterol depletion and actin depolymerization also alter the diffusion coefficient of the EGFR and the confinement area size (22). The finding that EGFR membrane organization is dependent upon cholesterol is of particular interest because a number of studies have demonstrated that EGFR activity is negatively regulated by cholesterol (4, 23, 28, 32).Phospholipase D2 (PLD2) hydrolyzes phosphatidylcholine (PC) to produce choline and phosphatidic acid (PA). PLD2 is localized to the plasma membrane (10), associates with the EGFR (39), and is rapidly activated upon EGF stimulation, leading to increased production of PA (15, 38, 39). A number of lines of evidence suggest that PA is an important mediator of EGFR action. First, exogenous PA is mitogenic when incubated with cells (17, 19, 42, 45). Second, direct interaction with membrane PA regulates the activity of a number of components downstream of the EGFR, including Sos (47) and Raf (12, 13, 30, 31).In the current study, we used high-resolution spatial analysis techniques to investigate EGFR plasma membrane organization. Using these approaches, we identified PA as the key molecular component responsible for driving EGFR nanocluster formation in response to EGF binding and demonstrated that the level of PLD2 activity regulates the duration of mitogen-activated protein kinase (MAPK) signal output.     

Green Space Functionality Along an Urban Gradient in Karachi,Pakistan: A Socio-Ecological Study

An important component of urban green space functionality is the way in which such spaces are perceived and used by urban residents. Use is affected by many factors including the nature and dynamics of urban morphology at the city and neighbourhood scale. This paper demonstrates a method for conducting analyses of green space socio-ecological functionality and presents the results of its application to Karachi, Pakistan. The paper explores the use of the results of an urban gradient analysis for site selection and presents the results of an associated survey of functions using three case study green spaces. The results show that, although urban dwellers in the city use green spaces infrequently, when they do it tends to be for long periods of time and for a range of purposes. Levels of overcrowding at the more accessible sites indicate the value that urban dwellers place on these resources, and their importance to the city as a whole. The results of this study provide evidence for the need to protect green spaces from the competing demands associated with increasing urbanisation, especially if the wider goal of urban sustainability is to be achieved.     

Extracellular phospholipases in atherosclerosis

Phospholipases A2 (PLA2) are a family of enzymes that catalyze the hydrolysis of the sn-2 ester bond of glycerophospholipids liberating lysophospholipids and free fatty acids; important second messengers involved in atherogenesis. Plasma PAF-acetylhydrolase (PAF-AH) or Lp-PLA2 is a Ca²⁺-independent PLA2 which is produced by monocyte-derived macrophages and by activated platelets, and circulates in plasma associated with lipoproteins. PAF-AH catalyzes the removal of the acetyl/short acyl group at the sn-2 position of PAF and oxidized phospholipids produced during inflammation and oxidative stress. In humans, PAF-AH is mainly associated with small dense LDL and to a lesser extent with HDL and with lipoprotein(a). PAF-AH is N-glycosylated prior to secretion which diminishes its association with HDL raising the question of its distribution between the proatherogenic LDL vs the antiatherogenic HDL. Hypercholesterolemic patients have higher plasma PAF-AH activity which is reduced upon hypolipidemic therapy. PAF-AH specific inhibitor darapladib stabilizes human and swine plaques, therefore challenging the antiatherogenic potential of PAF-AH shown in small animal models.     

The RNA binding protein Larp1 regulates cell division,apoptosis and cell migration

The RNA binding protein Larp1 was originally shown to be involved in spermatogenesis, embryogenesis and cell-cycle progression in Drosophila. Our data show that mammalian Larp1 is found in a complex with poly A binding protein and eukaryote initiation factor 4E and is associated with 60S and 80S ribosomal subunits. A reduction in Larp1 expression by siRNA inhibits global protein synthesis rates and results in mitotic arrest and delayed cell migration. Consistent with these data we show that Larp1 protein is present at the leading edge of migrating cells and interacts directly with cytoskeletal components. Taken together, these data suggest a role for Larp1 in facilitating the synthesis of proteins required for cellular remodelling and migration.     

A comparison of populations of island and adjacent mainland species of Caribbean Selenops (Araneae: Selenopidae) spiders

The role of the landscape in structuring populations has been the focus of numerous studies, in particular, the extent to which islands provide opportunities for isolation, and the consistency of such an effect across lineages. The current study examines this phenomenon using a series of relatively widespread taxa, all within a single genus of spiders, Selenops. We focus on the Caribbean Islands and adjacent Mesoamerican mainland to examine how the islands per se dictate structure across lineages. We use molecular genetic data from mitochondrial and nuclear genes to examine the population structure of seven species of Selenops. Comparisons are made between species found in the Greater Antilles, Lesser Antilles, and adjacent mainland. Results indicate that geography has little effect on the population structure of mainland species. In contrast, population structure appears to be partitioned by island in the insular Caribbean. Within islands, the amount of population structure for each species is variable and may be dictated more by ecological or demographic parameters, rather than geographic location. The overall conclusion is that the extent to which a given lineage is structured is highly variable across species, with this variability overwhelming any general signal of geographical isolation.     

Mechanical loading modulates chondrocyte primary cilia incidence and length

The pathways by which chondrocytes of articular cartilage sense their mechanical environment are unclear. Compelling structural evidence suggests that chondrocyte primary cilia are mechanosensory organelles. This study used a 3D agarose culture model to examine the effect of compressive strain on chondrocyte cilia. Chondrocyte/agarose constructs were subjected to cyclic compression (0–15%; 1 Hz) for 0.5–48 h. Additional constructs were compressed for 48 h and allowed to recover for 72 h in uncompressed free‐swelling conditions. Incidence and length of cilia labelled with anti‐acetylated α‐tubulin were examined using confocal microscopy. In free‐swelling chondrocytes, these parameters increased progressively, but showed a significant decrease following 24 or 48 h compression. A 72 h recovery partially reversed this effect. The reduced cilia incidence and length were not due to increased cell division. We therefore propose that control of primary cilia length is an adaptive signalling mechanism in response to varying levels and duration of mechanical loads during joint activity.     

Substrate elasticity provides mechanical signals for the expansion of hemopoietic stem and progenitor cells

Surprisingly little is known about the effects of the physical microenvironment on hemopoietic stem and progenitor cells. To explore the physical effects of matrix elasticity on well-characterized primitive hemopoietic cells, we made use of a uniquely elastic biomaterial, tropoelastin. Culturing mouse or human hemopoietic cells on a tropoelastin substrate led to a two- to threefold expansion of undifferentiated cells, including progenitors and mouse stem cells. Treatment with cytokines in the presence of tropoelastin had an additive effect on this expansion. These biological effects required substrate elasticity, as neither truncated nor cross-linked tropoelastin reproduced the phenomenon, and inhibition of mechanotransduction abrogated the effects. Our data suggest that substrate elasticity and tensegrity are important mechanisms influencing hemopoietic stem and progenitor cell subsets and could be exploited to facilitate cell culture.