Dissolved oxygen saturation controls PAH biodegradation in freshwater estuary sediments.

Polycyclic aromatic hydrocarbons (PAHs) are common contaminants in terrestrial and aquatic environments and can represent a significant constituent of the carbon pool in coastal sediments. We report here the results of an 18-month seasonal study of PAH biodegradation and heterotrophic bacterial production and their controlling biogeochemical factors from 186 sediment samples taken in a tidally influenced freshwater estuary. For each sampling event, measurements were averaged from 25-45 stations covering approximately 250 km(2). There was a clear relationship between bacterial production and ambient temperature, but none between production and bottom water dissolved oxygen (DO) % saturation or PAH concentrations. In contrast with other studies, we found no effect of temperature on the biodegradation of naphthalene, phenanthrene, or fluoranthene. PAH mineralization correlated with bottom water DO saturation above 70% (r(2) > 0.99). These results suggest that the proportional utilization of PAH carbon to natural organic carbon is as much as three orders of magnitude higher during cooler months, when water temperatures are lower and DO % saturation is higher. Infusion of cooler, well-oxygenated water to the water column overlying contaminated sediments during the summer months may stimulate PAH metabolism preferentially over non-PAH organic matter.

Biological laser printing of genetically modified Escherichia coli for biosensor applications.

One of the primary requirements of cell- or tissue-based sensors is the placement of cells and cellular material at or near the sensing elements of the device. The ability to achieve precise, reproducible and rapid placement of cells is the focus of this study. We have developed a technique, biological laser printing or BioLP, which satisfies these requirements and has advantages over current technologies. BioLP is capable of rapidly depositing patterns of active biomolecules and living cells onto a variety of material surfaces. Unlike ink jet or manual spotting techniques, this process delivers small volume (nl to fl) aliquots of biomaterials without the use of an orifice, thus eliminating potential clogging issues and enabling diverse classes of biomaterials to be deposited. This report describes the use of this laser-based printing method to transfer genetically-modified bacteria capable of responding to various chemical stressors onto agar-coated slides and into microtiter plates. The BioLP technology enables smaller spot sizes, increased resolution, and improved reproducibility compared to related technologies.

Generation of mesoscopic patterns of viable Escherichia coli by ambient laser transfer.

We have generated mesoscopic patterns of viable Escherichia coli on Si(1 1 1), glass, and nutrient agar plates by using a novel laser-based transfer process termed matrix assisted pulsed laser evaporation direct write (MAPLE DW). We observe no alterations to the E. coli induced by the laser-material interaction or the shear forces during the transfer. Transferred E. coli patterns were observed by optical and electron microscopes, and cell viability was shown through green fluorescent protein (GFP) expression and cell culturing experiments. The transfer mechanism for our approach appears remarkably gentle and suggests that active biomaterials such as proteins, DNA and antibodies could be serially deposited adjacent to viable cells. Furthermore, this technique is a direct write technology and therefore does not involve the use of masks, etching, or other lithographic tools.

Fabrication of patterned DNA surfaces.

Two photolithographic methods are described for the formation of patterned single or multiple DNA species on SiO2 substrates. In the first approach, substrates are treated with a photochemically labile organosilane monolayer film. Irradiation of these surfaces with patterned deep UV (193 nm) light results in patterned chemically reactive groups which are then reacted with heterobifunctional crosslinking molecules. Covalent attachment of modified synthetic DNA oligomers to the crosslinker results in stable DNA patterns. Alternatively, a photoresist is spin-coated over a silane film which had been previously modified with the heterobifunctional crosslinker. Upon patterned irradiation and subsequent development, the underlying crosslinker-modified layer is revealed, and is then reacted with a chemically modified DNA. Feature dimensions to 1 micron are observed when a single fluorescent DNA is attached to the surface. By performing sequential exposures, we have successfully immobilized two distinguishable DNA oligomers on a single surface. Synthetic DNA immobilized in this manner retains the ability to hybridize to its complementary strand, suggesting that these approaches may find utility in the development of miniaturized DNA-based biosensors.

Effects of alkanols, alkanediols and glycerol on red blood cell shape and hemolysis.

The physicochemical effects of a series of alkanols, alkanediols and glycerol on erythrocyte shape and hemolysis at 4 and 20 degrees C were examined. We calculated the dielectric constant of the incubation medium, Ds, and the dielectric constant of the erythrocyte membrane Dm in the presence of organic solutes. The ratio Ds/Dm = -38.48 at 20 degrees C defines the normal biconcave shape in a medium without hemolytic agents. A decrease in Ds/Dm favors externalization or internalization with consequent hemolysis. Alkanols and alkanediols convert biconcave erythrocytes into echinocytes, which is accompanied by an increase in the projected surface area. Glycerol converts biconcave erythrocytes into stomatocytes, which was accompanied by a marginal decrease in the projected surface area. Progressive externalization in alkanols and alkanediols or internalization in glycerol resulted in a decrease in the projected surface area and the formation of smooth spheres. The degree of shape change induced was related to the degree of hemolysis and the ratio Ds/Dm. A decrease in temperature reduced both the degree of shape change and hemolysis. Our results suggest that physicochemical toxicity may be a result of a temperature dependent hydrophobic interaction between the organic solutes and the membrane and is best interpreted by the ability of the solutes to change Ds and Dm. These results are discussed with respect to the physicochemical constants of the organic solutes.

Fabrication and selective surface modification of 3-dimensionally textured biomedical polymers from etched silicon substrates.

A new method is described for producing biomedically relevant polymers with precisely defined micron scale surface texture in the x, y, and z planes. Patterned Si templates were fabricated using photolithography to create a relief pattern in photoresist with lateral dimensions as small as 1 micron. Electroless Ni was selectively deposited in the trenches of the patterned substrate. The Ni served as a resilient mask for transferring the patterns onto the Si substrate to depths of up to 8.5 microns by anisotropic reactive ion etching with a fluorine-based plasma. The 3-dimensional (3-D) textured silicon substrates were used as robust, reusable molds for pattern transfer onto poly (dimethyl siloxane), low density poly (ethylene), poly (L-lactide), and poly (glycolide) by either casting or injection molding. The fidelity of the pattern transfer from the silicon substrates to the polymers was 90 to 95% in all three planes for all polymers for more than 60 transfers from a single wafer, as determined by scanning electron microscopy and atomic force microscopy. Further, the 3-D textured polymers were selectively modified to coat proteins either in the trenches or on the mesas by capillary modification or selective coating techniques. These selectively patterned 3-D polymer substrates may be useful for a variety of biomaterial applications.

Controlled release of transforming growth factor-beta from lipid-based microcylinders.

The release of transforming growth factor-beta (TGF-beta) from a lipid microstructure has been demonstrated. Lipid microcylinders, with dimensions of 100 x 0.5 microns and composed of a diacetylenic lipid, have been loaded with 25 ng TGF-beta/mg lipid. Physical and bioactive release characteristics of TGF-beta from these microcylinders and from microcylinders embedded in an agarose hydrogel are reported. Release of TGF-beta from lipid microcylinders follows typical diffusion-limited characteristics, where 10-12% of the TGF is released in the first 10 h at 37 degrees C. The release rate is shown to be temperature controlled and dependent on the integrity of the lipid microcylinder. Immobilization of the lipid microcylinder in a hydrogel matrix composed of agarose and gelatin does not impair the diffusion of TGF-beta from the lipid microcylinders. The utilization of microcylinders as release vehicles in wound repair is discussed.

Histopathologic study following administration of liposome-encapsulated hemoglobin in the normovolemic rat.

Liposome encapsulated hemoglobin is being developed as an artificial resuscitative fluid for in vivo oxygen delivery. In the present report, we examine the effect of accumulation of liposome encapsulated hemoglobin on the structure of reticuloendothelial organs following administration of liposome encapsulated bovine hemoglobin in the normovolemic rat. We have also examined the administration of the liposome vehicle, tetrameric bovine hemoglobin, and liposome encapsulated bovine hemoglobin that had been lyophilized with 300 mM trehalose and rehydrated just before injection. Following injection into the tail vein, rats were sacrificed and liver, spleen, kidney, and lung harvested at 2 h, 24 h, 1 week, and 2 weeks for analysis. Gross pathologic findings of animals injected with liposome encapsulated hemoglobin showed statistically significant splenomegaly with a waxy parenchymal pallor at early time points. Microscopic findings indicate that the liver and spleen are principally involved with liposome encapsulated hemoglobin removal over the course of 24 h with transient cytoplasmic vacuolization in tissue resident phagocytes as evidenced by both light and electron microscopic examination. Presence of liposome encapsulated hemoglobin in these vacuoles was confirmed by oil red O and prussian blue stains. Splenic weight was observed to decline after 24 h but still remained significant above sham-treated controls at 2 weeks and could be correlated with increased hematopoietic activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Spatially controlled adhesion, spreading, and differentiation of endothelial cells on self-assembled molecular monolayers.

Chemically modified glass substrates were used to demonstrate differential adhesion, growth, and differentiation of endothelial cells. Endothelial cells were examined for adhesion and growth on glass, glass treated with N-(2-aminoethyl)-3-aminopropyl trimethoxysilane (EDA), or EDA with a subsequent treatment with physically adsorbed extracellular matrix components human fibronectin and heparin sulfate. EDA and EDA/human fibronectin showed similar abilities to support adhesion, spreading, and proliferation of endothelial cells. In contrast, heparin sulfate inhibited endothelial cell adhesion to EDA. Differentiation of endothelial cells resulting in precapillary cord formation was triggered by addition of basic fibroblast growth factor (bFGF). On EDA and EDA/human fibronectin bFGF causes confluent endothelial cell monolayers to differentiate and form cords, which resulted in a large-scale spatial redistribution of cells on the surface. Formation of organized neovascular assemblies was demonstrated on coplanar molecular patterns of EDA and a nonadhesive perfluorinated alkylsilane (tridecafluoro-1,1,2,2-tetrahydrooctyl)-1-dimethylchloros ilane (13F). Endothelial cells preferentially adhered to the EDA lines and after 24-48 hr, microfilaments aligned with the long axes of the patterned EDA region. Finally, endothelial cells that became confluent within the confines of the EDA region (bound by the nonadhesive, 13F domains) were observed to differentiate into neovascular cords in long-term culture (7-10 days) with bFGF.

Interaction of cord factor (alpha, alpha'-trehalose-6,6'-dimycolate) with phospholipids.

We previously reported that cord factor (alpha,alpha'-trehalose-6,6'-dimycolate) isolated from Nocardia asteroides strain GUH-2 strongly inhibits fusion between unilamellar vesicles containing acidic phospholipid. We chose to study the effects of this molecule on liposome fusion since the presence of N. asteroides GUH-2 in the phagosomes of mouse macrophages had been shown to prevent phagosomal acidification and inhibit phagosome-lysosome fusion. A virtually non-virulent strain, N. asteroides 10905, does not prevent acidification or phagosome-lysosome fusion and, further, contains only trace amounts of cord factor. In the present paper, we have investigated the effects of cord factor on phospholipid bilayers that could be responsible for the inhibition of fusion. We show that cord factor increases molecular area, measured by isothermal compression of a monolayer film, in a mixed monolayer more than would be expected based in its individual contribution to molecular area. Cord factor, as well as other glycolipids investigated, increased the overall hydration of bilayers of dipalmitoylphosphatidylcholine by 50%, as estimated from the unfrozen water fraction measured by differential scanning calorimetry. The effect of calcium on this increased molecular area and headgroup hydration was measured by fluorescence anisotropy and FTIR spectroscopy of phosphatidylserine liposomes. Both techniques showed that cord factor, incorporated at 10 mol%, increased acyl chain disorder over controls in the presence of Ca2+. However, FTIR showed that cord factor did not prevent headgroup dehydration by the Ca2+. The other glycolipids tested did not prevent either the Ca(2+)-induced chain crystallization or headgroup dehydration of phosphatidylserine bilayers. These data point to a possible role of the bulky mycolic acids of cord factor in preventing Ca(2+)-induced fusion of liposomes containing acidic phospholipids.

Transient changes in the mononuclear phagocyte system following administration of the blood substitute liposome-encapsulated haemoglobin.

We have examined the effects of administration of the blood substitute, liposome-encapsulated haemoglobin (LEH), in the normovolaemic rat. Test groups included LEH, lyophilized EH, the liposome vehicle, unencapsulated haemoglobin and normal saline, which were injected into the tail vein (n = 6; n = 3 for sham and saline groups). Administration of LEH (2.5 g phospholipid, 1.25 g haemoglobin/kg rat) was followed by blood sampling at 2 h, 24 h, 1 wk and 2 wk. Blood samples were analysed for alanine aminotransferase, aspartate aminotransferase, alkaline phosphatase, gamma-glutamyltransferase, total and indirect bilirubin, serum creatinine, albumin, total protein, lipase, cholesterol, blood urea nitrogen, haematocrit, haemoglobin and differential white blood cell counts. Observed effects following injection were mild and transient, with baseline values recovered at 1 wk. Alanine aminotransferase increased moderately in the LEH group at 24 h to 601 +/- 143 IU/dl (P < 0.0001), with a return to baseline at 1 wk. Aspartate aminotransferase showed a smaller increase from 46 +/- 5 to 162 +/- 40 at 24 h and also returned to baseline at the 1 wk measurement (P < 0.001). The transient increase in serum transaminases was not observed for the lyophilized LEH group. Tissue sections showed accumulation of liposome groups in resident macrophages of the liver and spleen. Incubation of an adherent population of human peripheral blood monocytes with LEH in culture did not elicit the production of the inflammatory cytokine, tumour necrosis factor. Pre-incubation of monocytes with LEH prior to exposure to endotoxin did, however, result in a reduced expression of this inflammatory cytokine.

Recruitment of tissue resident cells to hydrogel composites: in vivo response to implant materials.

A model of local cellular recruitment was established using hydrogel matrices composed of alginate implanted subcutaneously into mice. Cells which trafficked to the matrix blocks were recovered and characterized for surface phenotype using fluorescently labelled antibodies and flow cytometry (fluorescence activated cell sorting). Temporal information of the differential recruitment of cells was determined. The basic pattern of recruitment in response to the hydrogels was established and mimicked that seen in a local inflammatory response. Neutrophils (PMN) were rapidly recruited (1 d) followed by macrophages and lymphocytes (1-3 d). Cell surface phenotype studies included the determination of CD3+, CD4+ and CD8+ cells, Mac-1+ cells, and immunoglobulin bearing cells. Microscopic analysis revealed numerous activated PMNs and monocyte derived foamy macrophages. Fluorescence immunocytochemistry of frozen sections of the block revealed that macrophages, CD3+ and natural killer cells were all recruited to the interior of the block. Ultrastructural analysis (transmission electron microscopy) showed highly activated macrophages, with abundant rough endoplasmic reticulum and secretory vesicles. Cells which remained on the surface of the matrix block were CD44 positive migratory cells. Electron microscopic evidence showed foamy macrophages with a varying degree of involvement with the hydrogel material. Surface scanning electron microscopy revealed numerous fibroblast-like cells coating the surface of the block. We suggest that these methods may be used to address the inflammatory response elicited with a a variety of implanted materials such as hydrogels, silicones, ceramics and metals. Furthermore, this model has been useful in determining cellular responses to cytokines and growth factors under similar conditions.

Biocompatibility of lipid microcylinders: effect on cell growth and antigen presentation in culture.

The authors are developing a lipid-based microcylinder for the controlled release of biological response modifiers and as templates for cellular migration and differentiation. These structures are comprised of a photopolymerizable phosphatidylcholine (1,2-ditricosa-10,12-diynoyl-sn-glycero-3-phosphocholine) and form spontaneously as a result of a thermotropic phase transition in aqueous solution or in a cosolvent solution of 70:30 ethanol:water. The hollow cylinders are helically wrapped lipid bilayers, variable in length (50-250 microns, depending on conditions of formation) and are 0.5-1.0 microns in diameter. The interaction has been examined of three types of lipid microcylinders: (1) monomeric, (2) photopolymerized by exposure to 254 nm light, and (3) surface-modified by incorporation of 6 mol% gangliosides, with different human cell lines and peripheral blood leucocytes to evaluate the biocompatibility of these structures. The proliferative status of U937 (a histiocytic monocyte), K562 (an erythroleukaemic cell), and Jurkat's derivative (a T-lymphoblast) as measured by pulsed tritiated thymidine was unaffected by the presence of up to 100 micrograms/ml of lipid microcylinders after 3 d in culture. Adherent human peripheral blood monocytes were shown to form adhesive contacts with the lipid microcylinders. An 'association' index from this interaction shows that after 3 d in culture, the association was much lower for those microcylinders that had incorporated ganglioside compared with monomeric or polymerized structures. The lipid microcylinders do not activate T-cells isolated from human peripheral blood, nor do they inhibit the activation of T-cells by phorbol esters or other mitogens.(ABSTRACT TRUNCATED AT 250 WORDS)

Cord factor (alpha,alpha-trehalose 6,6'-dimycolate) inhibits fusion between phospholipid vesicles.

The persistence of numerous pathogenic bacteria important in disease states, such as tuberculosis, in humans and domestic animals has been ascribed to an inhibition of fusion between the phagosomal vesicles containing the bacteria and lysosomes in the host cells [Elsbach, P. & Weiss, J. (1988) Biochim. Biophys. Acta 974, 29-52; Thoen, C. O. (1988) J. Am. Vet. Med. Assoc. 193, 1045-1048]. In tuberculosis this effect has been indirectly attributed to the production of cord factor (alpha,alpha-trehalose 6,6'-dimycolate). We show here that cord factor is extraordinarily effective at inhibiting Ca2(+)-induced fusion between phospholipid vesicles and suggest a mechanism by which cord factor confers this effect. These findings are likely to be important in our understanding of the pathogenesis and treatment of many diseases of bacterial etiology.

Interactions of sugars with membranes.

Water profoundly affects the stability of biological membranes, and its removal leads to destructive events including fusion and liquid crystalline to gel phase transitions. In heterogeneous mixtures such as those found in biological membranes the phase transitions can lead to increases in permeability and lateral phase separations that often are irreparable. Certain sugars are capable of preventing these deleterious events by inhibiting fusion during drying and by maintaining the lipid in a fluid state in the absence of water. As a result, the increased permeability and lateral phase separations that accompany dehydration are absent. The weight of the evidence suggests strongly that there is a direct interaction between the sugars and lipids in the dry state. Although the evidence is less clear about whether these sugars can interact directly with hydrated bilayers, there are strong suggestions in the literature that sugars free in solution or covalently linked to membrane constituents can also affect the physical properties and presumably the stability of bilayers. Finally, we have far less evidence concerning the mechanism by which they do so, but the same sugars are also capable of preserving the structure and function of both membrane-bound and soluble proteins in the absence of water. We believe these effects may be important in the survival of intact cells and organisms such as seeds in the absence of water. Furthermore, in view of the practical importance of preserving biological structures we suspect that the results described here will ultimately have important applications in biology and medicine.

Preservation of dry liposomes does not require retention of residual water.

Certain sugars, particularly trehalose, dramatically alter physical properties of dry phospholipids in ways that mimic the presence of water. As a result, these sugars are capable of preserving the integrity of dry liposomes and membranes. Since these effects could conceivably be due to the presence of small amounts of water in the dry preparations of sugar and lipid, we have done careful measurements of the residual water contents in the dry samples and report the results here. Lyophilized liposomes composed of palmitoyloleoylphosphatidylcholine and phosphatidylserine (9:1) contain at most 0.2 mol of H2O per mol of lipid. When the trehalose concentration in the dry mixtures is increased, there is no increase in the apparent water content of the samples over a wide range of sugar concentrations. Over the same range of trehalose contents the maximal effect of trehalose on physical properties of the lipids and on stabilization of liposomes is achieved. We conclude that the stabilization does not require retention of residual amounts of water in the dry trehalose-phospholipid preparations. Similar studies with other sugars show a relationship between the amount of sugar interacting with the lipid and the ability of the same sugar to stabilize dry liposomes.

Zonal changes in renal structure and phospholipid metabolism during reversal of potassium depletion nephropathy.

Structural changes and membrane metabolism were studied in the enlarged kidney of potassium-depleted rats during dietary repletion with potassium. Transmission and scanning electron microscopy of kidneys revealed two patterns of involutionary change in the collecting tubules following potassium repletion. Autophagocytosis was observed within 3 hours in the hyperplastic cells of the inner red medulla, and progressive condensation and reduction in the number and size of lysosomes which had formed during potassium depletion were observed in the renal papilla. After 3 days of potassium repletion, all types of cells had a normal ultrastructural appearance. Alterations in membrane metabolism during autophagocytosis and organelle regression were assessed by measuring the in vivo breakdown of [14C]phosphatidylcholine, phospholipase A activity, and the rate of [14C]choline incorporation into phospholipid in papilla, inner red medulla, and inner cortex. In each tissue the rate of [14C]phosphatidylcholine breakdown increased and the rate of [14C]choline incorporation into phospholipid decreased during potassium repletion. Phospholipase A activity, which was depressed in potassium-depleted animals, increased in each renal zone by 12 hours after potassium repletion. The results indicate that reversal of potassium depletion nephropathy is associated with increased membrane phospholipid catabolism, loss of renal mass, and specific morphologic changes in different renal zones: lysosome regression in the papilla and autophagocytosis in the hyperplastic cells of the inner red medulla.