Trends in Chemical Composition of Global and Regional Population-Weighted Fine Particulate Matter Estimated for 25 Years.

We interpret in situ and satellite observations with a chemical transport model (GEOS-Chem, downscaled to 0.1° × 0.1°) to understand global trends in population-weighted mean chemical composition of fine particulate matter (PM2.5). Trends in observed and simulated population-weighted mean PM2.5 composition over 1989-2013 are highly consistent for PM2.5 (-2.4 vs -2.4%/yr), secondary inorganic aerosols (-4.3 vs -4.1%/yr), organic aerosols (OA, -3.6 vs -3.0%/yr) and black carbon (-4.3 vs -3.9%/yr) over North America, as well as for sulfate (-4.7 vs -5.8%/yr) over Europe. Simulated trends over 1998-2013 also have overlapping 95% confidence intervals with satellite-derived trends in population-weighted mean PM2.5 for 20 of 21 global regions. Over 1989-2013, most (79%) of the simulated increase in global population-weighted mean PM2.5 of 0.28 µg m-3yr-1 is explained by significantly (p < 0.05) increasing OA (0.10 µg m-3yr-1), nitrate (0.05 µg m-3yr-1), sulfate (0.04 µg m-3yr-1), and ammonium (0.03 µg m-3yr-1). These four components predominantly drive trends in population-weighted mean PM2.5 over populous regions of South Asia (0.94 µg m-3yr-1), East Asia (0.66 µg m-3yr-1), Western Europe (-0.47 µg m-3yr-1), and North America (-0.32 µg m-3yr-1). Trends in area-weighted mean and population-weighted mean PM2.5 composition differ significantly.

Long-Term Trends Worldwide in Ambient NO2 Concentrations Inferred from Satellite Observations.

BACKGROUND: Air pollution is associated with morbidity and premature mortality. Satellite remote sensing provides globally consistent decadal-scale observations of ambient nitrogen dioxide (NO2) pollution. OBJECTIVE: We determined global population-weighted annual mean NO2 concentrations from 1996 through 2012. METHODS: We used observations of NO2 tropospheric column densities from three satellite instruments in combination with chemical transport modeling to produce a global 17-year record of ground-level NO2 at 0.1° × 0.1° resolution. We calculated linear trends in population-weighted annual mean NO2 (PWMNO2) concentrations in different regions around the world. RESULTS: We found that PWMNO2 in high-income North America (Canada and the United States) decreased more steeply than in any other region, having declined at a rate of -4.7%/year [95% confidence interval (CI): -5.3, -4.1]. PWMNO2 decreased in western Europe at a rate of -2.5%/year (95% CI: -3.0, -2.1). The highest PWMNO2 occurred in high-income Asia Pacific (predominantly Japan and South Korea) in 1996, with a subsequent decrease of -2.1%/year (95% CI: -2.7, -1.5). In contrast, PWMNO2 almost tripled in East Asia (China, North Korea, and Taiwan) at a rate of 6.7%/year (95% CI: 6.0, 7.3). The satellite-derived estimates of trends in ground-level NO2 were consistent with regional trends inferred from data obtained from ground-station monitoring networks in North America (within 0.7%/year) and Europe (within 0.3%/year). Our rankings of regional average NO2 and long-term trends differed from the satellite-derived estimates of fine particulate matter reported elsewhere, demonstrating the utility of both indicators to describe changing pollutant mixtures. CONCLUSIONS: Long-term trends in satellite-derived ambient NO2 provide new information about changing global exposure to ambient air pollution. Our estimates are publicly available at http://fizz.phys.dal.ca/~atmos/martin/?page_id=232.

Use of satellite observations for long-term exposure assessment of global concentrations of fine particulate matter.

BACKGROUND: More than a decade of satellite observations offers global information about the trend and magnitude of human exposure to fine particulate matter (PM2.5). OBJECTIVE: In this study, we developed improved global exposure estimates of ambient PM2.5 mass and trend using PM2.5 concentrations inferred from multiple satellite instruments. METHODS: We combined three satellite-derived PM2.5 sources to produce global PM2.5 estimates at about 10 km × 10 km from 1998 through 2012. For each source, we related total column retrievals of aerosol optical depth to near-ground PM2.5 using the GEOS-Chem chemical transport model to represent local aerosol optical properties and vertical profiles. We collected 210 global ground-based PM2.5 observations from the literature to evaluate our satellite-based estimates with values measured in areas other than North America and Europe. RESULTS: We estimated that global population-weighted ambient PM2.5 concentrations increased 0.55 µg/m3/year (95% CI: 0.43, 0.67) (2.1%/year; 95% CI: 1.6, 2.6) from 1998 through 2012. Increasing PM2.5 in some developing regions drove this global change, despite decreasing PM2.5 in some developed regions. The estimated proportion of the population of East Asia living above the World Health Organization (WHO) Interim Target-1 of 35 µg/m3 increased from 51% in 1998-2000 to 70% in 2010-2012. In contrast, the North American proportion above the WHO Air Quality Guideline of 10 µg/m3 fell from 62% in 1998-2000 to 19% in 2010-2012. We found significant agreement between satellite-derived estimates and ground-based measurements outside North America and Europe (r = 0.81; n = 210; slope = 0.68). The low bias in satellite-derived estimates suggests that true global concentrations could be even greater. CONCLUSIONS: Satellite observations provide insight into global long-term changes in ambient PM2.5 concentrations. Satellite-derived estimates and ground-based PM2.5 observations from this study are available for public use.

Protein oxidative modifications during electrospray ionization: solution phase electrochemistry or corona discharge-induced radical attack?

The exposure of solution-phase proteins to reactive oxygen species (ROS) causes oxidative modifications, giving rise to the formation of covalent +16 Da adducts. Electrospray ionization (ESI) mass spectrometry (MS) is the most widely used method for monitoring the extent of these modifications. Unfortunately, protein oxidation can also take place as an experimental artifact during ESI, such that it may be difficult to assess the actual level of oxidation in bulk solution. Previous work has demonstrated that ESI-induced oxidation is highly prevalent when operating at strongly elevated capillary voltage V(0) (e.g., +8 kV) and with oxygen nebulizer gas in the presence of a clearly visible corona discharge. Protein oxidation under these conditions is commonly attributed to OH radicals generated in the plasma of the discharge. On the other hand, charge balancing oxidation reactions are known to take place at the metal/liquid interface of the emitter. Previous studies have not systematically explored whether such electrochemical processes could be responsible for the formation of oxidative +16 Da adducts instead of (or in combination with) plasma-generated ROS. Using hemoglobin as a model system, this work illustrates the occurrence of extensive protein oxidation even under typical operating conditions (e.g., V(0) = 3.5 kV, N(2) nebulizer gas). Surprisingly, measurements of the current flowing in the ESI circuit demonstrate that a weak corona discharge persists for these relatively gentle settings. On the basis of comparative experiments with nebulizer gases of different dielectric strength, it is concluded that ROS generated under discharge conditions are solely responsible for ESI-induced protein oxidation. This result is corroborated through off-line electrolysis experiments designed to mimic the electrochemical processes taking place during ESI. Our findings highlight the necessity of using easily oxidizable internal standards in biophysical or biomedical ESI-MS studies where knowledge of protein oxidation in bulk solution is desired. Strategies for eliminating ESI-induced oxidation artifacts are discussed.

Formation of monomeric S100B and S100A11 proteins at low ionic strength.

The S100 proteins comprise a group of EF-hand proteins that undergo a calcium-induced conformational change allowing them to interact with other proteins and produce a biological response. A unique feature of these proteins is the fact that they can form both homo- and heterodimers independent of calcium binding. The reported dissociation constants for several S100 proteins span a very large range, from 1-4 microM to <<1 nM, suggesting that differing interface surface areas could govern the strength of the binding affinity. In this work, we examine the dimerization mechanism of S100B and S100A11 in the absence of calcium. Using electrospray mass spectrometry, we demonstrate that the monomer-dimer equilibrium in these S100 proteins is strongly dependent on the ionic strength of the solution. At higher ionic strengths (>or=22 mM), both S100A11 and S100B exist predominantly as homodimers. For apo-S100A11, a K(dimer) near 0.01 microM is estimated, while concentration-dependent experiments under these conditions show the K(dimer) for apo-S100B must be even lower. In contrast, lowering the ionic strength results in the formation of monomeric proteins with poorer dimer propensity. For example, the estimated K(dimer) for apo-S100A11 is more than 400 microM at 0.1 mM NH(4)Ac. (1)H-(15)N HSQC NMR experiments in combination with circular dichroism studies show that monomeric S100B and S100A11 proteins are alpha-helical and retain a significant amount of tertiary structure. Our results indicate that apo-S100B has at least a 10-fold stronger propensity to form dimers than does apo-S100A11 in line with a 400 A(2) greater buried surface area for apo-S100B at its dimer interface. These experiments are the first to show that folded monomeric S100 proteins can be isolated, thus paving the way for future experiments aimed at examining the possible role of these monomers in folding and calcium signaling.

Effects of zinc binding on the structure and dynamics of the intrinsically disordered protein prothymosin alpha: evidence for metalation as an entropic switch.

Prothymosin alpha (ProTalpha) is a small acidic protein that is highly conserved among mammals. The human form has 110 amino acid residues (M.W. 12.1 kDa; pI approximately 3.5) and is found to be expressed in a wide variety of tissues. ProTalpha plays an essential role in cell proliferation and apoptosis, and it is involved in transcriptional regulation of oxidative stress-protecting genes. Despite the multiple biological functions ProTalpha has, the protein does not adopt a well-defined three-dimensional structure under physiological conditions. Previous studies have shown that the interaction between ProTalpha and some of its protein targets is significantly enhanced in the presence of zinc ions, suggesting that zinc binding plays a crucial role in the protein's function. In this work, we use nuclear magnetic resonance spectroscopy and electrospray ionization mass spectrometry to characterize the structure and dynamics of ProTalpha and its complexation with Zn2+. We found that zinc binding causes partial folding of the C-terminal half of ProTalpha, especially the Glu-rich region, while the N-terminal portion of the protein remains largely unstructured. The metalated protein also exhibits a significantly reduced flexibility. ProTalpha shows a high specificity for Zn2+, and the interactions with other divalent cations (Ca2+, Mg2+) are much weaker. On the basis of the site-specific information obtained here, as well as the results from previous studies, we propose that the conformational and dynamic changes upon zinc binding may act as an entropic switch that greatly facilitates the binding to other proteins.

Symmetric behavior of hemoglobin alpha- and beta- subunits during acid-induced denaturation observed by electrospray mass spectrometry.

This work employs electrospray mass spectrometry (ESI-MS) and UV-vis spectroscopy for monitoring the mechanism of acid-induced hemoglobin (Hb) denaturation. The protein for these experiments has been freshly prepared from bovine blood. All three Hb derivatives studied (oxyHb, metHb, and cyanometHb) respond to gradual changes from pH 6.8 to 2.1 in a manner that can be described by a stepwise sequential unfolding mechanism: (alphahbetah)2 --> 2 alphahbetah --> 2 alphahfolded + 2 betahfolded --> 2 alphaaunfolded + 2 betaaunfolded + 4 heme (superscripts "h" and "a" refer to holo- and apo-forms, respectively). The results obtained on these freshly prepared samples are significantly different from those of similar experiments previously conducted on metHb obtained commercially as lyophilized powder. Those earlier experiments suggested a highly asymmetric behavior of the two globin chains, involving a heme-deficient dimer (alphahbetaa) as a mechanistically important intermediate on the (dis)assembly pathway. Importantly, heme-deficient dimers are virtually undetectable for the freshly prepared Hb derivatives studied herein at any pH. This apparent discrepancy is attributed to the occurrence of oxidative modifications in the commercial protein. Liquid chromatography and tandem mass spectrometry reveal significant levels of sulfoxide formation for all four methionine residues in commercially obtained metHb. The extent of these modifications for freshly prepared protein is lower by at least a factor of 10. It is concluded that the acid-induced denaturation of Hb follows a highly symmetric mechanism. The occurrence of other mechanisms (possibly involving asymmetric elements) under different solvent conditions cannot be ruled out.

Analysis of protein mixtures by electrospray mass spectrometry: effects of conformation and desolvation behavior on the signal intensities of hemoglobin subunits.

The determination of solution-phase protein concentration ratios based on ESI-MS intensity ratios is not always straightforward. For example, equimolar mixtures of hemoglobin alpha- and beta-subunits consistently result in much higher peak intensities for the alpha-chain. The current work explores the origin of this effect. Under mildly acidic conditions (pH 3.4) alpha-globin is extensively unfolded, whereas beta-globin retains residual structure. Because of its greater nonpolar character, the more unfolded alpha-subunit can more effectively compete for charge. This leads to suppression of beta-globin signals under conditions where the protein ion yield is limited by the charge concentration on the initially formed ESI droplets. More balanced intensities are observed when operating under charge excess conditions and/or in a solvent environment where both proteins are unfolded to a similar degree (pH 2.2). However, even in these cases the overall alpha-globin peak intensity is still twice as high as that of the beta-subunit. The persistent imbalance under these conditions originates from the different declustering behaviors of the two proteins. A considerable fraction of beta-globin undergoes incomplete desolvation during ESI, thereby reducing the intensity of bare [beta + zH](z+) ions. When including the contributions of incompletely desolvated species, the overall alpha:beta ion intensity ratio is close to unity. The alpha:beta intensity imbalance can also be eliminated by a strongly elevated declustering potential in the ion sampling interface. In conclusion, important factors that have to be considered for the ESI-MS analysis of protein mixtures are (1) conformational effects, resulting in differential surface activities, and (2) dissimilarities in the protein desolvation behavior.

Folding and assembly of hemoglobin monitored by electrospray mass spectrometry using an on-line dialysis system.

The native structure of hemoglobin (Hb) comprises two alpha- and two beta-subunits, each of which carries a heme group. There appear to be no previous studies that report the in vitro folding and assembly of Hb from highly unfolded alpha- and beta-globin in a "one-pot" reaction. One difficulty that has to be overcome for studies of this kind is the tendency of Hb to aggregate during refolding. This work demonstrates that denaturation of Hb in 40% acetonitrile at pH 10.0 is reversible. A dialysis-mediated solvent change to a purely aqueous environment of pH 8.0 results in Hb refolding without any apparent aggregation. Fluorescence, Soret absorption, circular dichroism, and ESI mass spectra of the protein recorded before unfolding and after refolding are almost identical. By employing an externally pressurized dialysis cell that is coupled on-line to an ESI mass spectrometer, changes in heme binding behavior, protein conformation, and quaternary structure can be monitored as a function of time. The process occurs in a stepwise sequential manner, leading from monomeric alpha- and beta-globin to heterodimeric species, which then assemble into tetramers. Overall, this mechanism is consistent with previous studies employing the mixing of folded alpha- and beta-globin. However, some unexpected features are observed, e.g., a heme-deficient beta-globin dimer that represents an off-pathway intermediate. Monomeric beta-globin is capable of binding heme before forming a complex with an alpha-subunit. This observation suggests that holo-alpha-apo-beta globin does not represent an obligatory intermediate during Hb assembly, as had been proposed previously. The on-line dialysis/ESI-MS approach developed for this work represents a widely applicable tool for studying the folding and self-assembly of noncovalent biological complexes.

A temperature-jump stopped-flow system for monitoring chemical kinetics triggered by rapid cooling.

This work reports the implementation of a stopped-flow system for studying the kinetics of protein folding triggered by rapid cooling. The transition from denaturing temperatures to ambient conditions is achieved by rapid mixing of pre-heated protein solution with cold refolding buffer. The estimated dead-time of the apparatus is 8ms. Folding kinetics are monitored by fluorescence spectroscopy. Careful tuning of the solution mixing ratio is required for the elimination of baseline artifacts that could mask fluorescence signals originating from protein conformational changes. The viability of the rapid cooling method is demonstrated by applying it to monitor the refolding of thermally denatured cytochrome c. Following a heat exposure time of 3min, the protein shows multi-exponential folding kinetics, ultimately resulting in a fluorescence level that is virtually indistinguishable from that of the native state. In contrast, incomplete refolding is observed when the heat exposure time is extended to 30min. This effect may be due to aggregation phenomena affecting the thermally denatured protein. It appears that the rapid cooling approach reported in this work may become a useful tool for temperature-jump studies in various areas of chemistry and biochemistry.

The reconstitution of unfolded myoglobin with hemin dicyanide is not accelerated by fly-casting.

This study explores how the kinetics of a coupled folding/binding reaction depend on the initial conformation of the protein. Stopped-flow spectroscopy is used to monitor the reaction of apo-myoglobin (aMb) with hemin dicyanide at pH 7.2. Different initial aMb conformations are tested. In the case of acid-denatured aMb, the observed kinetics are consistent with a "fly-casting" scenario [Shoemaker et al., Proc. Natl. Acad. Sci. USA 97 (2000) 8868-8873]. However, the formation of a compact complex proceeds more rapidly in the case of prefolded aMb. This finding is opposite to what would be expected based on predictions of the fly-casting model.