Faculty Bibliography

Inhalation is the most prevalent route of human exposure to insoluble pentavalent vanadium(V) oxides and soluble salts in urban/occupational settings. While initial pulmonary clearance of both soluble and insoluble forms of V is fairly rapid, complete clearance/degree of absorption of any V agent is ultimately a function of its solubility. Nevertheless, there are still several general toxicologic outcomes that arise from lung deposition of various V agents (as pure compounds or V-contaminated dusts). Workers exposed to V-bearing dusts or fumes display an. increased incidence of several lung diseases (e.g., asthma, bronchitis, pneumonia). Similarly, after deposition of urban particulate matter (PM) or residual oil fly ash (ROFA), animals develop states of immunomodulation (inflammation, neutrophilic alveolitis, modified resistance to infection) that correlate with the levels of V in the particles. This presentation focused on how general (and in some cases agent-specific) mechanisms have been formulated to explain how entrained V agents induce toxicity and immunomodulation in the lungs

The extent of adverse health effects, including induction/exacerbation of infectious lung disease, arising from entrainment of equivalent amounts (or exposure to a fixed increment) of fine particulate matter (PM(2.5)) can vary from region to region or city to city in a region. To begin to explain how differing effects on host resistance might arise after exposure to PM(2.5) from various sites, we hypothesized that select metals (e.g., V, Al, and Mn) in each PM(2.5) caused changes in alveolar macrophage (AM) Fe status that, ultimately, would lead to altered antibacterial function. To test this, iron-response protein (IRP) binding activity in a rat AM cell line was assessed after exposure to Fe alone and in conjunction with V, Mn, and/or Al at ratios of V:Fe, Al:Fe, or Mn:Fe encountered in PM(2.5) samples from New York City, Los Angeles, and Seattle. Results indicated that V and Al each significantly altered IRP activity, though effects were not consistently ratio-(i.e., dose-) dependent; Mn had little impact on activity. We conclude that the reductions in Fe status detected here via the IRP assay arose, in part, from effects on transferrin-mediated Fe(3 +) delivery to the AM. Ongoing studies using this assay are allowing us to better determine: (1) whether mass (and/or molar) relationships between Fe and V, Al, and/or Mn in any PM(2.5) sample consistently govern the extent of change in AM Fe status; (2) how much any specified PM(2.5) constituent (metal or nonmetal) contributes to the overall disruption of Fe status found induced by an intact parent sample; and (3) whether induced changes in binding activity are relatable to other changes expected to occur in the AM, that is, in IRP-dependent mRNA/levels of ferritin/transferrin receptor and Fe-dependent functions. These studies demonstrate that pollutant-induced effects on lung cell Fe status can be assessed in a reproducible manner using an assay that can be readily performed by investigators who might otherwise have no access to other very costly analytical equipment, such as graphite atomic absorption or x-ray fluorescence spectro(photo)meters

The in situ reactions of metal ions/complexes are important in understanding the mechanisms by which environmental and occupational metal particles alter lung immune responses. A better understanding of these reactions in situ will also allow for the improved specificity and controlled toxicity of novel metallocompounds to be used as inhaled diagnostics or therapeutics. Our previous work showed that inhalation of metals (e.g., chromium, vanadium, nickel) caused altered lung immune cell function and host resistance. The data also suggested that the degree of immunomodulation induced depended not only on the amount of metal deposited, but also the compound used. If specificity governs pulmonary immunomodulatory potential, it follows that physicochemical properties inherent to the metal have a role in the elicited effects. We hypothe-size that major determinants of any metal compound's potential are its redox behavior, valency (generally referred to as oxidation state and considered speciation in chemical literature), and/or solubility. In accord with the extensive work carried out with vanadium (chemical symbol V) compounds showing the importance of form used, differences in potential for a range of V agents (pentavalent [V(V)] insoluble vanadium pentoxide and soluble sodium metavanadate, tetravalent [V(IV)] vanadyl dipicolinate, and trivalent [V(III)] bis(dipicolinato)vanadium) were quantified based on induced changes in local bacterial resistance after host inhalation of each agent at 100 mu g V/m(3) (5 hr/d for 5 d). Differences in effect between V(V) forms indicated that solubility was a critical property in in situ pulmonary immunotoxicity. Among the soluble forms, oxidizing vanadate had the greatest impact on resistance; reducing V(III) altered resistance to a lesser extent. Both the V(IV) and insoluble V(V) had no effect. When data was analyzed in the context of pre-infection lung V burdens, soluble V agents with different oxidation states induced varying responses, supporting the hypothesis that differences in immunomodulatory potential might be attributed to redox behavior or valency. Our findings both provide a basis for understanding why some metals could be a greater health risk than others (when encountered in equal amounts) and will assist in the design of inhalable metallopharmaceuticals by allowing researchers to preempt selection of certain metal ions or complexes for use in such products

To assess potential immunomodulatory effects of a drug, pollutant, or natural product, an analysis of an exposed host's ability to resist challenge with a viable bacteria is one of the best gauges. Many factors govern whether a host exposed to a test agent and then infected becomes ill or dies at rates greater than infected control counterparts. Beyond the status of the host's immunocompetence, a bacterium's route of entry into the host and its inherent virulence are important variables determining how (and rate at which) an infection resolves. A pre-determination of endpoint(s) to be defined is critical during planning of resistance assays. If a study is to determine overall changes in immunocompetence due to exposure (regardless of regimen or dosage of test agent), then assessing shifts in morbidity/mortality at a defined lethal dose [LD(x)] value for the chosen route of infection would suffice. However, if a study is to define extent of immunomodulation in a particular body organ/cavity--or specific alterations in particular aspects of the humoral or cell-mediated immune responses--then careful selection of the pathogen, dose of the inoculum, means of infection of target site, and extent of the post-infection period to be examined, need to be made prior to host exposure to the test toxicant. This review will provide the Reader with background information about bacterial infections and how endpoint selection could be approached when designing resistance assays. An overview of protocols involved in the assays (e.g., bacterial preparation, host infection, post-infection endpoint analyses) and information about three bacteria that are among the most commonly employed in resistance assays is provided as well

Increasing the understanding of how metal ions/complexes react in situ will allow for the improved specificity and controlled toxicity of novel synthetic metallocompounds that will be used as inhaled diagnostics or therapeutics. Our previous work showed that inhalation of select metals (e.g., chromium, vanadium, nickel, iron) caused alterations in lung immune cell function and in local bacterial resistance. The data also suggested that variations in the degree of immuno-modulation induced were not solely dependent on the amount of metal deposited in the lung, but also on the specific compound. If specificity governs immunomodulatory potential, it follows that physicochemical properties inherent to the metal may have a role in the elicited effects. We hypothesize that major determinants of any metal compound's immunomodulatory potential in situ are its redox behavior, valency, and/or solubility. Using changes in local bacterial resistance as an endpoint, differences in immunotoxic potential in the lungs were quantified for a range of chromium agents (insoluble calcium chromate(VI), and soluble sodium chromate(VI), potassium bis(dipicolinato)chromate(III) and sodium bis(dipicolinato)chromate(II)). Results indicated that among the latter three forms of Cr, strongly oxidizing hexavalent Cr (Cr[VI]) had the greatest impact on resistance, while reducing divalent and fairly unreactive trivalent forms of Cr had no effect at an equal exposure level (i.e., 100 mug Cr/m(3), 5 hr/d, for 5 d). Insoluble Cr(VI) had a greater effect than its soluble form. When data was analyzed in the context of pre-infection lung Cr burdens, it was seen that immunomodulatory potentials for both Cr(VI) agents did not differ significantly; however, complexes with different oxidation states did induce varying responses, suggesting that differences in potential might be attributed to redox behavior. From this it was concluded that for Cr, certain physicochemical properties are likely more important to any in situ pulmonary immunotoxicity than others (i.e., redox behavior is more critical than solubility). Our findings, in part, will help provide a basis for understanding why certain metals could be a greater health risk than others, even when encountered in equal amounts. This, in turn, will help researchers in the design of inhalable diagnostic/therapeutic metallopharmaceuticals by pre-empting the selection of certain metal ions/complexes for potential use in these products

It was hypothesized that relative mass relationships among select constituent metals and iron (Fe3+) govern the pulmonary immunotoxic potential of any PM(2.5) sample, as these determine the extent to which Fe3+ binding by transferrin is affected (resulting in altered alveolar macrophage [AM] Fe status and subsequent antibacterial function). Iron response protein (IRP) binding activity is a useful indirect measurement of changes in Fe status, as reductions in cell Fe levels lead to increases in IRP binding. However, AM IRP activity can be affected by an increased presence of nitric oxide generated by inducible nitric oxide synthase (iNOS). This study sought to determine if any changes in AM IRP activity induced by PM(2.5) constituents V, Mn, or Al were independent from effects of the metals on cell NO formation. NR8383 rat AM were exposed to Fe3+ alone or combined with V, Mn, or Al at metal:Fe ratios representative of those in PM(2.5) collected in New York City, Los Angeles, and Seattle during fall 2001. Cells were then assessed for changes in IRP activity and iNOS expression. Phosphorylated extracellular signal-regulated kinase (ERK) 1 and 2 levels were also measured since activated ERKs are involved in signaling pathways that lead to increased iNOS expression. The results indicate that V and Al, and to a lesser extent Mn, altered IRP activity, though the effects were not consistently concentration dependent. Furthermore, while V and Mn treatments did not induce iNOS expression, Al did. These results confirmed our hypothesis that certain metals associated with PM(2.5) might alter the pulmonary immunocompetence of exposed hosts by affecting the Fe status of AM, a major class of deep lung defense cells

Several features of the clinical presentation and changes in physiology and pathology following exposure to many diverse ambient air pollution particles are comparable, suggesting a common mechanism for their biological effect. We propose that a mechanism of biological effect common to many ambient air pollution particles is a disruption of iron homeostasis in cells and tissues. Among traits shared by every particle-related lung injury is the introduction of a solid-liquid interface into the respiratory tract. All surfaces of particulate matter have some concentration of oxygen-containing functional groups. As a result of its electropositivity, Fe(3+) has a high affinity for oxygen-donor ligands and will react with these groups at the particle surface. Retained particles accumulate metal from available sources in a cell and tissue, and this complexed iron mediates oxidant generation. In addition to complexation onto the solid-liquid interface provided by the surface of particulate matter (PM), there are several alternative pathways by which metal homeostasis in the lower respiratory tract can be disrupted following exposure to ambient air pollution particles to affect an oxidative stress. Evidence suggests that disruption in iron homeostasis following exposures to ambient air pollution particles is an initial event in their biological effect. An association between metal equilibrium in the lower respiratory tract and biological effect in the lung could explain the observed differential toxicity of ultrafine, fine, and coarse particles and disparities in host susceptibility