Self-tolerance of human natural killer cells lacking self-HLA-specific inhibitory receptors.

Natural killer (NK) cells identify cells with altered human leucocyte antigen (HLA) expression as targets through lacking engagement of self-HLA-specific inhibitory receptors (e.g. killer cell immunoglobulin-like receptor, KIR). Thus, they eliminate cells with 'missing self' because of viral or malignant transformation. We performed analysis of HLA, KIR genotypes and KIR receptor expression patterns at single cell level in NK cells in 17 donors. The function of NK cell subsets is determined by degranulation assays using target cells expressing self, cognate, control or no HLA class I. Donors could be grouped into three groups: their NK cells possess potential for alloreactivity, autoreactivity based on the presence of NK cells expressing particular KIR only (mono-KIR) in the absence of its ligand or lack alloreactivity. All donors possess NK cells lacking all detectable inhibitory receptors. Both potential autoreactive subpopulations did not respond to HLA class I-positive target cells. They retain partial reactivity against HLA class I-negative tumour target cells. Mono-KIR NK cells without the corresponding ligands in the individuals and NK cells lacking all inhibitory receptors behave self-tolerant. Our results suggest alternative mechanisms than HLA-specific inhibitory receptors to control NK cell activity. But HLA seems to be involved in shaping effector function of the NK cell repertoire.

Resistance against natural killer cell cytotoxicity: analysis of mechanisms.

Target cell resistance against natural killer (NK) cell-mediated cytotoxicity obstructs NK cell-based immunotherapy of leukaemia. Several mechanisms of resistance have been described. Because of lack of simple assays for analysing these mechanisms, their relative impact on a given effector-target pair is mostly unknown. We here analysed the combination of the Granzyme B (GrB) enzyme-linked immunospot assay (ELISPOT) for the assessment of NK cell reactivity and cytotoxicity assays to estimate target cell escape mechanisms. Target cell recognition failure leads to negative GrB ELISPOT results, whereas target cell resistance shows positive GrB ELISPOT results in the absence of cytotoxicity. We confronted NK cells with the sensitive target cell line K562, and with the resistant cell lines ML2, SupB15 and Raji. ML2 cells sufficiently activated GrB-release whilst being resistant against cytotoxic granules of NK cells. Partial resistance of Raji results from the interaction of HLA class I with inhibitory killer immunglobulin-like receptors (KIR) on the NK cells. Failure of target recognition by HLA class I-KIR interaction, lacking ligands to stimulatory NK cell receptors and partial resistance to cytotoxic granules all contributed to resistance of SupB15. In conclusion, revealing the mechanisms of resistance against NK cell-mediated cytotoxicity may allow improving the results of NK-based immunotherapy.

Real-time analysis of methanol in air and water by membrane introduction mass spectrometry.

We present results for the near-real-time, on-line detection of methanol in both air and water using membrane introduction mass spectrometry (MIMS). In these experiments, we compare the sensitivity of a poly(dimethylsiloxane) (PDMS) membrane and an allyl alcohol (AA) membrane to the detection of methanol. In MIMS, the membrane serves as the interface between the sample and the vacuum of the mass spectrometer. Membrane-diffused water was used as the reagent ion (H3O+) for chemical ionization of methanol in an ion trap mass spectrometer. Linear calibration curves have been obtained for methanol using both PDMS and AA membranes. For PDMS, detection limits of methanol are 14 ppmv and 5 ppm in air and water, respectively. For AA, detection limits are 3.3 ppmv and 2 ppm in air and water, respectively. We demonstrate that the sensitivity of the analysis can be altered by the chemistry of the membrane. When the AA membrane is used, the sensitivity of MIMS is enhanced over that of PDMS by a factor of 8.5 for methanol in air and by a factor of 23.4 for methanol in water.

Monitoring biodegradation of VOCs using high-speed gas chromatography with a dual-point sampling system.

A new sampling system has been designed and interfaced with high-speed gas chromatography (HSGC) to monitor and assess the performance of a trickle-bed bioreactor designed for the removal of volatile organic compounds from air. A portion of a gas stream containing styrene and toluene was sampled both before and after passing through the bioreactor by means of a dual-loop sampling system. With a frequency of as high as 2 per minute, treated and untreated samples were alternately transferred on-line to the cryofocusing injection system of a HSGC and analyzed. This analytical system generated data with less than 2% relative standard deviations for standard samples, and residual contamination of subsequent analyses from a highly concentrated sample (2,000 microg/L) was not observed. A bench-scale bioreactor with a fiber mat support was used in these studies, resulting in residence times for analytes in the bioreactor of as little as 1 s. Rapid monitoring of this system detected subtle changes in the concentration of analytes with 30 s temporal resolution. Measurements showed a statistically significant increase in the removal of styrene from 22% to 27% when water was sprayed over the immobilized bacteria for 30 min. Overall, the bioreactor removed styrene from the air stream with a specific elimination capacity of 1,700 g of styrene (m3 of biocatalyst)-1 h(-1) at a space velocity of 3,400 h(-1).

Rapid aqueous sample extraction of VOCs: effect of physical parameters.

Rapid aqueous sample extraction (RASE) devices were constructed and characterized using m-xylene as a test analyte. Extraction of m-xylene from aqueous samples was studied under many different conditions, independently varying extractor volume, extraction gas flow rate, temperature, pressure, sample volume, and sample concentration. Gas samples were analyzed as controls to determine the non-extraction (transport) component of the analyte pulse width. The extraction of analyte from water to the gas phase took proportionately longer (compared to transport) for RASE apparatus that had a volume greater than 10 ml. An order of magnitude change in RASE volume resulted in larger than an order of magnitude change in extraction time and total analyte pulse width. The flow rate of the extraction gas had a much larger effect on a RASE apparatus with a volume greater than 10 ml. For these large extractors, both extraction time and total analyte pulse width decreased by a factor of 4 for a flow increase from 40 to 120 ml min(-1). There was little change at higher flow rates, or for extractors with smaller volumes. Temperatures below 40 degrees C resulted in large increases in the pulse duration due to broadening during transport. The temperature effect on extraction time was only a factor of 2 over a range from 25 to 85 degrees C. Pressure also had only a relatively small effect, increasing extraction time and total pulse width by a factor of 2 over a range from 12 to 34 PSI. There was no observed change in either extraction time or total pulse width when the sample volume injected varied from 10 to 1000 mul, or over a concentration range from 170 to 17 000 mug l(-1). RASE apparatus were capable of complete extraction of analyte from water in less than 5 s under optimized conditions.

Rapid aqueous sample extraction of volatile organic compounds: effect of sample matrix and analyte properties.

Studies have been done using a rapid aqueous sample extraction (RASE) system to characterize the effects of chemical properties on the time required for removal of volatile organic compounds (VOCs) to the gas phase. These analyses include determinations of the effects that different analytes, and modifications to the matrix, have on extraction time. Experiments were performed to determine the distinct contributions of analyte removal from water and gas-phase transport to the duration of the extracted pulse of analytes. These measured durations were correlated with known values of Henry's law constants (K(H)), boiling points, relative volatilities from modified matrixes, and aqueous diffusion coefficients for cyclohexane, toluene, o-xylene, isopropylbenzene (IPB), and o-dichlorobenzene. Transport time, which was the most significant contributor to the overall duration, correlated well with analyte boiling point. Analyte removal from water correlated better with a modified relative volatility measurement than either K(H) or D(L). IPB extraction was studied in a number of modified matrixes. A 0.1% methanol in water matrix resulted in a 35% decrease in the extraction time of IPB relative to pure water. Extraction time decreased by 22% with the addition of 0.1% NaCl to the aqueous matrix. The addition of 0.01% sodium dodecyl sulfate to the matrix resulted in a 13% increase in the extraction time of IPB relative to water. The RASE system was directly interfaced to a cryofocussing high-speed gas chromatography system to analyze VOCs in wastewater at the low mug l(-1) level.

A transgenic model of acetaldehyde overproduction accelerates alcohol cardiomyopathy.

Chronic alcohol consumption produces alcoholic heart muscle disease (AHMD), a prevalent form of congestive heart failure. Several hypotheses have been proposed to explain the damaging effects of alcohol on the heart, but neither the mechanism nor the ultimate toxin has been established. In this study, we use transgenic overexpression of alcohol dehydrogenase to elevate cardiac exposure to acetaldehyde, the major and most reactive metabolite of alcohol. Overexpression of alcohol dehydrogenase by 40-fold produced no detectable deleterious effects to the heart in the absence of alcohol. In the presence of alcohol, transgenic hearts contained 4-fold higher acetaldehyde than control hearts. Chronic alcohol exposure produced many changes similar to AHMD in transgenic hearts. Compared with control hearts, these pathological changes occurred more rapidly and to a greater extent: alcohol-exposed transgenic hearts were almost twice as large as control hearts. They demonstrated ultrastructural damage consistent with AHMD and had much lower contractility than alcohol-exposed control hearts. In addition, the transgenic hearts showed greater changes in mRNA expression for alpha-skeletal actin and atrial natriuretic factor than alcohol-exposed control hearts. Alterations in NAD(+)/NADH levels were insufficient to account for such severe damage in cardiomyopathic hearts. The increased damage produced in transgenic hearts suggests an important role for acetaldehyde in AHMD.

A Comparison of Cryofocusing Injectors for Gas Sampling and Analysis in Fast GC.

The performance of two cryofocusing injectors for fast gas chromatography has been studied. The first system traps analytes onto bare metal tubes and rapidly vaporizes them upon ballistically heating the tube using a capacitance discharge. The second is a microloop injector in which analytes are cryotrapped onto short lengths of narrow-bore fused silica tubing with various coatings. The ballistically heated injector is capable of sampling and injecting compounds from air faster than the microloop system, because the metal tube can be heated and cooled more rapidly. Both systems are capable of cryotrapping compounds as volatile as butane at -90 °C, and the microloop system can trap ethane when a section of a porous layer open-tubular (PLOT) column is used as the sample loop. In addition, the microloop injector can be used without cryointegration to analyze compounds regardless of their volatility, as long as they are present in the samples at detectable concentrations. Because the ballistically heated injector is flushed prior to injection, it can introduce only compounds that are adsorbed onto its metal trap. Comparison of chromatograms obtained using the two injectors show similar chromatographic resolution. Both traps are susceptible to freezing during the cryotrapping step, but the use of an inline Nafion dryer allows air saturated with water vapor to be sampled using both systems for 3 min without plugging the trap. Thermal decomposition during the injection step can occur for labile species in the ballistically heated trap, but even the highly unstable compound ethyl diazoacetate may be injected without breakdown in the microloop system.

Effect of tautomerization on the fast-atom bombardment tandem mass spectra of azo dyes.

The effect of tautomerization on the collision-induced dissociation of negative ions produced from sulfonated azo dyes by fast-atom bombardment (FAB) was studied by analyzing the product ion spectra of several related compounds. The mechanisms by which azo dyes fragment were found to depend on the formation and stability of tautomers. The extent of tautomerization was affected by the number and location of hydroxy groups on the dye, as well as by the FAB matrix. Ions that retained a sodium were often inhibited from forming tautomers and gave different product ions. Substitution of deuterium for hydrogen on the hydroxy groups aided in the identification of ions having more than one possible structure and provided verification of proposed mechanisms. Mechanisms involving ions retaining a sodium were verified by substituting potassium for the sodium.