Optimization of sulfide production by an indigenous consortium of sulfate-reducing bacteria for the treatment of lead-contaminated wastewater

Bioprocess and Biosystems Engineering - Biological treatment with sulfate-reducing bacteria (SRB) is considered to be an excellent option to remove heavy metals from wastewater. In this study, the...     

CagI is an essential component of the Helicobacter pylori Cag type IV secretion system and forms a complex with CagL

Helicobacter pylori, the causative agent of type B gastritis, peptic ulcers, gastric adenocarcinoma and MALT lymphoma, uses the Cag type IV secretion system to induce a strong proinflammatory response in the gastric mucosa and to inject its effector protein CagA into gastric cells. CagA translocation results in altered host cell gene expression profiles and cytoskeletal rearrangements, and it is considered as a major bacterial virulence trait. Recently, it has been shown that binding of the type IV secretion apparatus to integrin receptors on target cells is a crucial step in the translocation process. Several bacterial proteins, including the Cag-specific components CagL and CagI, have been involved in this interaction. Here, we have examined the localization and interactions of CagI in the bacterial cell. Since the cagI gene overlaps and is co-transcribed with the cagL gene, the role of CagI for type IV secretion system function has been difficult to assess, and conflicting results have been reported regarding its involvement in the proinflammatory response. Using a marker-free gene deletion approach and genetic complementation, we show now that CagI is an essential component of the Cag type IV secretion apparatus for both CagA translocation and interleukin-8 induction. CagI is distributed over soluble and membrane-associated pools and seems to be partly surface-exposed. Deletion of several genes encoding essential Cag components has an impact on protein levels of CagI and CagL, suggesting that both proteins require partial assembly of the secretion apparatus. Finally, we show by co-immunoprecipitation that CagI and CagL interact with each other. Taken together, our results indicate that CagI and CagL form a functional complex which is formed at a late stage of secretion apparatus assembly.     

Pneumococcal vaccination decreases atherosclerotic lesion formation: molecular mimicry between Streptococcus pneumoniae and oxidized LDL

During the progression of atherosclerosis, autoantibodies are induced to epitopes of oxidized low-density lipoprotein (oxLDL) and active immunization of hypercholesterolemic mice with oxLDL ameliorates atherogenesis. We unexpectedly found that many autoantibodies to oxLDL derived from 'naive' atherosclerotic mice share complete genetic and structural identity with antibodies from the classic anti-phosphorylcholine B-cell clone, T15, which protect against common infectious pathogens, including pneumococci. To investigate whether in vivo exposure to pneumococci can affect atherogenesis, we immunized Ldlr(-/-) mice with Streptococcus pneumoniae. This induced high circulating levels of oxLDL-specific IgM and a persistent expansion of oxLDL-specific T15 IgM-secreting B cells primarily in the spleen, which were cross-reactive with pneumococcal determinants. Pneumococcal immunization decreased the extent of atherosclerosis, and plasma from these mice had an enhanced capacity to block the binding of oxLDL to macrophages. These studies show molecular mimicry between epitopes of oxLDL and S. pneumoniae and indicate that these immune responses can have beneficial effects.     

Osmotic Regulation Is Required for Cancer Cell Survival under Solid Stress

For a solid tumor to grow, it must be able to support the compressive stress that is generated as it presses against the surrounding tissue. Although the literature suggests a role for the cytoskeleton in counteracting these stresses, there has been no systematic evaluation of which filaments are responsible or to what degree. Here, using a three-dimensional spheroid model, we show that cytoskeletal filaments do not actively support compressive loads in breast, ovarian, and prostate cancer. However, modulation of tonicity can induce alterations in spheroid size. We find that under compression, tumor cells actively efflux sodium to decrease their intracellular tonicity, and that this is reversible by blockade of sodium channel NHE1. Moreover, although polymerized actin does not actively support the compressive load, it is required for sodium efflux. Compression-induced cell death is increased by both sodium blockade and actin depolymerization, whereas increased actin polymerization offers protective effects and increases sodium efflux. Taken together, these results demonstrate that cancer cells modulate their tonicity to survive under compressive solid stress.     

Biogeochemical Implications of Episodic Impoundment in a Restored Tidal Marsh of San Francisco Bay,California

Impounded tidal conditions often compromise coastal marsh restoration goals, through vegetation loss and other biogeochemical feedbacks. To determine if episodic marsh impoundments could be partially responsible for the observed cordgrass (Spartina foliosa) dieback at Crissy Field, Golden Gate National Recreation Area, we examined sulfur chemistry and plant stress along transects between and during tidal inlet closure events from 2007 to 2008. During closures, porewater sulfide (PW S^2?) concentrations did not respond consistently among sites, nor did they increase to levels likely to cause stress damage to cordgrass (>1 mM). However, sediment solid‐phase total reduced sulfur (TRS) concentrations did respond strongly to closures both at surface and subsurface depth intervals, and they were greatest in sites with high organic matter content (>5%). The temporal patterns of both PW S^2? and TRS suggest that while sulfate reduction may be enhanced during closure events, the free sulfide produced is largely precipitated into solid‐phase minerals. Even without millimolar levels of PW S^2?, plant stress was observed during closures, as indicated by a buildup of ethanol in root tissues, a by‐product of fermentative respiration brought on by limited oxygen availability. Further, enhanced sulfate reduction may be related to the higher relative concentrations of methylmercury in low intertidal surface sediments observed during closure events. These data suggest that, in support of vegetated tidal marsh restoration goals, tidal flows should be maintained actively to reduce the impact of impoundment events on marsh biogeochemistry and productivity.     

Rat neurophysiological taste responses to salt solutions

1. Neurophysiological studies on the chemoresponsive tongueunits of the rat geniculate ganglion readily detected and furthercharacterized the two major functional neural groups designatedas ‘acid’ and ‘salt’ units by otherinvestigators in chorda tympani recordings. Units belongingto either of these groups were initially identified on the basisof their responses to a series of chemical solutions (a TestSeries) developed to distinguish unit groups in the geniculateganglion of the cat, dog and goat. 2. The nature of active ionicspecies effective in stimulating the units of the two differentgroups was further elaborated by studying their responses toa variety of salt solutions. From these studies, it was concludedthat the optimum molecular species for the acid units is anacid, where an acid is defined as a Br0nsted acid or protondonating molecule. A variety of molecular species may be activein solution, including some nitrogen compounds. Responses tosalt solutions by acid units are determined in part by the actionof the cation functioning as a Brønsted acid (NH₄), orin promoting proton donor molecules in water (mainly H₃O⁺).The salt units, on the other hand, are almost exclusively responsiveto solutions containing Na ⁺ and Li⁺. All other solutions werevirtually inactive. It was concluded that under a wide varietyof environmental conditions, Na+ would be the exclusive stimulusfor the salt units. Na⁺ and Li⁺ were found to be highly stimulatingwhen accompanied by a wide variety of solute anions, althoughthose containing the halogens (Cl^–, F^–, I^–,Br^–) were among the most stimulatory compounds tested.3. The establishment that the stimulus is a proton donor moleculefor the acid units and the Na⁺ and Li⁺ for the salt units hasprofound theoretical implications for the taste receptor. Biophysicalmodels of taste receptors are reviewed with respect to thisimproved understanding of the stimuli for the two types of units.It is suggested, after consideration of certain basic biochemicalaspects of the situation, that the acid receptor (possibly animidazole group) forms, as part of a protein, a proton conductingcircuit for driving an intracellular energy process devotedto proton sensing transmission. It is further suggested, inlight of the extreme specificity shown to Na ⁺, that receptorattachment is of the multidentate ligand variety and is probablylinked to Na⁺, K⁺ transport across the cell membrane, as proposedby DeSimone et al. (1981).