Agrobacterium-mediated transformation and assessment of factors influ-encing transgene expression in loblolly pine (Pinus taeda L.)

INTRODUCTIONRecombinant DNA technology is a powerful toolfor the introduction of foreign genes into longlivedperennials and fOr fundamelltal studies of gene expression. Using such techniques, we can overcomethe difficulties associated with the breeding of a long-lived perennial. At present, although considerablereseaxch effort has been devoted to the genetic en-gineering of fOrest trees, it has lagged behind ad-vances made in herbaceous crops due both to eco-nomics and the recalcitrant n…     

SNL fibroblast feeder layers support derivation and maintenance of human induced pluripotent stem cells

Induced pluripotent stem(iPS) cells can be derived from human somatic cells by cellular reprogramming.This technology provides a potential source of non-controversial therapeutic cells for tissue repair,drug discovery,and opportunities for studying the molecular basis of human disease.Normally,mouse embryonic fibroblasts(MEFs) are used as feeder layers in the initial derivation of iPS lines.The purpose of this study was to determine whether SNL fibroblasts can be used to support the growth of human iPS cell...     

Effects of land use on the structure and function of leaf‐litter microbial communities in boreal streams

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Anaerobic Biotransformation of High Concentrations of Chloroform by an Enrichment Culture and Two Bacterial Isolates

A fermentative enrichment culture (designated DHM-1) was developed that is capable of cometabolically biotransforming high concentrations of chloroform (CF) to nontoxic end products. Two Pantoea spp. were isolated from DHM-1 that also possess this dechlorination capability. Following acclimation to increasing levels of CF, corn syrup-grown DHM-1 was able to transform over 500 mg/liter CF in the presence of vitamin B₁₂ (approximately 3% of CF on a molar basis) at a rate as high as 22 mg/liter/day in a mineral salts medium. CO, CO₂, and organic acids were the predominant biodegradation products, suggesting that hydrolytic reactions predominate during CF transformation. DHM-1 was capable of growing on corn syrup in the presence of high concentrations of CF (as may be present near contaminant source zones in groundwater), which makes it a promising culture for bioaugmentation. Strains DHM-1B and DHM-1T transform CF at rates similar to that of the DHM-1 enrichment culture. The ability of these strains to grow in the presence of high concentrations of CF appears to be related to alteration of membrane fluidity or homeoviscous and homeophasic adaptation.Chloroform (CF) is a toxic organic compound that is frequently detected in groundwater. In the 2007 “CERCLA Priority List of Hazardous Substances,” CF ranks eleventh overall and is the third highest among chlorinated organics after vinyl chloride and polychlorinated biphenyls (4). When present at hazardous waste sites, CF is often a focal point for evaluating the feasibility of bioremediation, since it is toxic to many obligate anaerobic prokaryotes (44). For example, 1 mg/liter of CF completely inhibited dechlorination of tetrachloroethene (PCE) by a chlororespiring anaerobic isolate (32). Inhibition of reductive dechlorination of chloroethenes by CF is a general problem for sites cocontaminated with CF, which can only be overcome by first removing the CF (6).In spite of major recent advances in bioremediation of chlorinated organic compounds, treatment of CF, especially at high concentrations (e.g., >100 mg/liter), remains challenging. Although aerobic biotransformation of CF is possible (e.g., cometabolism by a butane-grown strain) (14), CF is more difficult to cometabolize than trichloroethene (42). Biotransformation of CF by mixed or pure cultures under methanogenic (5, 21) and sulfate-reducing (20) conditions has been reported, however, only at low-mg/liter CF concentrations.Corrinoids such as vitamin B₁₂ (i.e., cyanocobalamin) are effective catalysts for increasing the rate of halomethane biotransformation under anaerobic conditions. Addition of vitamin B₁₂ also shifts the pathway away from reductive dechlorination and toward hydrolytic and substitutive reactions, forming CO, CO₂, and organic acids as the major products (8, 23, 24). With low levels of B₁₂ added (3 to 5% molar ratios of CF), an enrichment culture grown on dichloromethane (DCM) as the sole substrate (8) and a lactate-grown sulfate-reducing enrichment culture (18) were able to biotransform up to 260 mg/liter and 270 mg/liter CF, respectively. However, use of a DCM-grown culture is not feasible for in situ bioremediation since DCM is also a regulated contaminant and the culture grows well only at 35°C. A major drawback with using a lactate-grown culture is the accumulation of DCM during CF transformation. Organohalide respiration of CF by a Dehalobacter population was recently reported (19), although DCM is the end product. Further treatment of the DCM would be necessary for bioremediation to be successful, although bioaugmentation cultures for this purpose are not yet available. It is apparent that a strategy for bioremediation of high concentrations of chloroform is still lacking.In a recent microcosm study using soil and groundwater from an industrial site, we demonstrated that bioaugmentation is a technically feasible remediation strategy for high concentrations of chloroform as well as carbon tetrachloride (CT) and trichlorofluoromethane (35). High rates of transformation were achieved with a fermentative enrichment culture that grows on corn syrup, supplemented with B₁₂ (1.3 to 1.4 mol%). The objectives of this study were to characterize the fermentative culture in terms of its maximum rate of CF transformation, its dependence on B₁₂ for transformation of CF, and its ability to grow on corn syrup in the presence of CF; to identify the transformation products from CF; to isolate and identify the microbes in the enrichment culture that are responsible for CF biotransformation; and to investigate the adaptation mechanisms used by the isolates to tolerate the toxicity of high concentrations of CF.     

Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring

The Lost Hammer (LH) Spring is the coldest and saltiest terrestrial spring discovered to date and is characterized by perennial discharges at subzero temperatures (−5°C), hypersalinity (salinity, 24%), and reducing (≈−165 mV), microoxic, and oligotrophic conditions. It is rich in sulfates (10.0%, wt/wt), dissolved H₂S/sulfides (up to 25 ppm), ammonia (≈381 μM), and methane (11.1 g day⁻¹). To determine its total functional and genetic potential and to identify its active microbial components, we performed metagenomic analyses of the LH Spring outlet microbial community and pyrosequencing analyses of the cDNA of its 16S rRNA genes. Reads related to Cyanobacteria (19.7%), Bacteroidetes (13.3%), and Proteobacteria (6.6%) represented the dominant phyla identified among the classified sequences. Reconstruction of the enzyme pathways responsible for bacterial nitrification/denitrification/ammonification and sulfate reduction appeared nearly complete in the metagenomic data set. In the cDNA profile of the LH Spring active community, ammonia oxidizers (Thaumarchaeota), denitrifiers (Pseudomonas spp.), sulfate reducers (Desulfobulbus spp.), and other sulfur oxidizers (Thermoprotei) were present, highlighting their involvement in nitrogen and sulfur cycling. Stress response genes for adapting to cold, osmotic stress, and oxidative stress were also abundant in the metagenome. Comparison of the composition of the functional community of the LH Spring to metagenomes from other saline/subzero environments revealed a close association between the LH Spring and another Canadian high-Arctic permafrost environment, particularly in genes related to sulfur metabolism and dormancy. Overall, this study provides insights into the metabolic potential and the active microbial populations that exist in this hypersaline cryoenvironment and contributes to our understanding of microbial ecology in extreme environments.     

Fluorescence polarization in studies of bacterial cytoplasmic membrane fluidity under environmental stress

The integrity of the bacterial cytoplasmic membrane is critical in maintaining the viability of cells and their metabolic functions, particularly under stress. Bacteria actively adjust membrane fluidity through changes in lipid composition in response to variations in temperature, pressure, ion concentrations, pH, nutrient availability, and xenobiotics. Fluorescence polarization methods are valuable for measuring bacterial cytoplasmic membrane fluidity. In this review we discuss the mechanisms of bacterial membrane adaptations and present data from research using 1,6-diphenyl-1,3,5-hexatirene (DPH) as a measure of membrane fluidity and phase transitions. We illustrate the range of fluidity in viable cells, extracted membranes, and liposomes under optimal and stressed physiological conditions.     

Immunoproteomic analysis of the murine antibody response to successful and failed immunization with live anti-Francisella vaccines

Francisella tularensis subspecies tularensis is one of the most virulent of bacterial pathogens for humans. Protective immunity against the pathogen can be induced in humans and some, but not all, mouse strains by vaccination with live, but not killed, vaccines. In mice, this protection is mediated predominantly by CD4+ and CD8+ T cells. This is thought to be the case too for humans. Nevertheless, it is possible that successful vaccination elicits antigen-specific antibodies that can serve as correlates of protection. To test this hypothesis we examined the repertoire of antibodies induced following successful immunization of BALB/c and CH3/HeN mice versus unsuccessful vaccination of C57BL/6 and DBA\2 mice with F. tularensis Live Vaccine Strain or following unsuccessful vaccination of BALB/c mice with highly related subspecies, F. novicida. The results showed that successful vaccination elicited antibodies to at least six proteins that were not recognized by antisera from vaccinated but unprotected mice.     

Plagiarism of the host immune system: lessons about chemokine immunology from viruses

In their attempts to evade the host immune response, mammalian viruses have evolved a wide range of strategies. These include the expression and modification of various host cytokines and receptors. Understanding the mechanism of action of these virally encoded proteins will clearly deepen our insights into immunology. In the past few months several new virally encoded chemokines have been described which can modify both the host immune and antiviral response. Their manipulation of the cytokine structure-function relationship may also be useful in the development of reagents for treating immune and proliferative diseases.