Peter Ingram

Pulmonary Alveolar Proteinosis in Workers at an Indium Processing Facility

Two cases of pulmonary alveolar proteinosis, including one death, occurred in workers at a facility producing indium-tin oxide (ITO), a compound used in recent years to make flat panel displays. Both workers were exposed to airborne ITO dust and had indium in lung tissue specimens. One worker was tested for autoantibodies to granulocytemacrophage-colonystimulating factor (GM-CSF) and found to have an elevated level. These cases suggest that inhalational exposure to ITO causes pulmonary alveolar proteinosis, which may occur via an autoimmune mechanism.

Saccharomyces cerevisiae Vacuole in Zinc Storage and Intracellular Zinc Distribution

ABSTRACT Previous studies of the yeast Saccharomyces cerevisiae indicated that the vacuole is a major site of zinc storage in the cell. However, these studies did not address the absolute level of zinc that was stored in the vacuole nor did they examine the abundances of stored zinc in other compartments of the cell. In this report, we describe an analysis of the cellular distribution of zinc by use of both an organellar fractionation method and an electron probe X-ray microanalysis. With these methods, we determined that zinc levels in the vacuole vary with zinc status and can rise to almost 100 mM zinc (i.e., 7 × 108 atoms of vacuolar zinc per cell). Moreover, this zinc can be mobilized effectively to supply the needs of as many as eight generations of progeny cells under zinc starvation conditions. While the Zrc1 and Cot1 zinc transporters are essential for zinc uptake into the vacuole under steady-state growth conditions, additional transporters help mediate zinc uptake into the vacuole during “zinc shock,” when zinc-limited cells are resupplied with zinc. In addition, we found that other compartments of the cell do not provide significant stores of zinc. In particular, zinc accumulation in mitochondria is low and is homeostatically regulated independently of vacuolar zinc storage. Finally, we observed a strong correlation between zinc status and the levels of magnesium and phosphorus accumulated in cells. Our results implicate zinc as a major determinant of the ability of the cell to store these other important nutrients.

Frontiers in electron probe microanalysis: Application to cell physiology

The application of electron probe microanalysis techniques, using X-ray and electron energy loss instruments, to problems in cell physiology is reviewed. The details of the special methodological requirements for the analysis of cryosections at high spatial resolution in an analytical electron microscope are discussed together with a comprehensive review of data obtained on major organ systems and cell types.

Real-time quantitative elemental analysis and mapping: microchemical imaging in cell physiology.

Recent advances in widely available microcomputers have made the acquisition and processing of digital quantitative X‐ray maps of one to several cells readily feasible. Here we describe a system which uses a graphics‐based microcomputer to acquire spectrally filtered X‐ray elemental image maps that are fitted to standards, to display the image in real time, and to correct the post‐acquisition image map with regard to specimen drift. Both high‐resolution quantitative energy‐dispersive X‐ray images of freeze‐dried cyrosections and low‐dose quantitative bright‐field images of frozen‐hydrated sections can be acquired to obtain element and water content from the same intracellular regions. The software programs developed, together with the associated hardware, also allow static probe acquisition of data from selected cell regions with spectral processing and quantification performed on‐line in real time. In addition, the unified design of the software program provides for off‐line processing and analysing by several investigators at microcomputers remote from the microscope. The overall experimental strategy employs computer‐aided imaging, combined with static probes, as an essential interactive tool of investigation for biological analysis. This type of microchemical microscopy facilitates studies in cell physiology and pathophysiology which focus on mechanisms of ionic (elemental) compartmentation, i.e. structure‐function correlation at cellular and subcellular levels; it allows investigation of intracellular concentration gradients, of the heterogeneity of cell responses to stimuli, of certain fast physiological events in vivo at ultrastructural resolution, and of events occurring with low incidence or involving cell‐to‐cell interactions.

Mitochondrial localization and characterization of 99Tc-sestamibi in heart cells by electron probe x-ray microanalysis and 99Tc-NMR spectroscopy

As the development of targeted intracellular magnetic resonance contrast agents proceeds, techniques for the quantitative analysis of the subcellular compartmentation and characterization of metallopharmaceuticals must also advance. To this end, the subcellular distribution and chemical state of hexakis (2-methoxyisobutyl isonitrile) technetium-99 (99Tc-SESTAMIBI), the ground state of the organotechnetium radiopharmaceutical used for the noninvasive evaluation of myocardial perfusion and viability by scintigraphy, has been determined by a novel application of electron probe X-ray microanalysis (EPXMA) and 99Tc-NMR spectroscopy. In cryopreserved cultured chick heart cells equilibrated in 36 microM 99Tc-SESTAMIBI, EPXMA imaging of mitochondria yielded a respiratory uncoupler-sensitive characteristic 99Tc X-ray peak representing 32.0 +/- 2.9 nmoles Tc/mg dry weight, while EPXMA of cytoplasm or nucleus showed no peak significantly greater than the threshold detectability limit of approximately 1 nmole/mg dry weight. Technetium-99 NMR spectroscopy of heart cells equilibrated with 99Tc-SESTAMIBI showed a single peak at -45.5 ppm with no evidence of significant line broadening or chemical shift compared to aqueous chemical standards, indicating that the majority of the complex exists unbound within the mitochondrial matrix. These data quantitatively demonstrate the localization of this lipophilic cationic organometallic complex within mitochondria in situ, consistent with a sequestration mechanism dependent on membrane potentials. Furthermore, this study establishes the general feasibility of combined EPXMA and NMR spectroscopy for the direct subcellular localization and characterization of metallopharmaceuticals, techniques that are readily applicable to MR contrast agents.

Scanning Electron Microscopic Study of the Airways in Normal Children and in Patients with Cystic Fibrosis and Other Lung Diseases

Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) were used to examine pulmonary tissue from 9 patients with cystic fibrosis (CF), 12 patients with diseases other than CF, and from two surgically resected specimens with no known airways disease. A region of the human airways, the transition zone, was observed between the end of the terminal bronchiole and the type II alveolar cell lining of the respiratory bronchioles. This region was lined predominantly by nonciliated bronchiolar (NCB) cells. Patients with CF exhibited indistinct transition zones, epidermoid metaplasia, large dilated bronchial glands, copious surface mucus, alveolar destruction, and unusual microvilli; no single lesion specific for cystic fibrosis was identified.

Principles and instrumentation

Electron microscopy is analytical to some extent. Analytical electron microscopy (AEM) can be defined as the observation of the interaction of electrons with matter at a resolution smaller than that which could be seen with the naked eye. This obviously includes all images in general; however, the term “microprobe analysis” has evolved to make it essentially a form of microchemistry in particular. The wavelength of X-rays can be measured using a wavelength dispersive spectrometer, or the characteristic energies can be measured by means of an energy dispersive spectrometer. Each instrumental configuration has its own advantages and limitations, and the choice of instrumentation depends not only on user preference but also on the particular task at hand. For example, analytical transmission electron microscopy can allow the user to obtain crystallographic information about the sample by means of selected area electron diffraction, whereas analytical scanning electron microscopy permits the elemental analysis of bulk samples and, more recently, the potential to determine the microcrystallographic characteristics of mineral specimens. This approach is particularly useful for the analysis of clinical specimens when combined with backscattered electron imaging, which enhances the ability to detect inorganic particulates of relatively high atomic number in an organic matrix of low atomic number.

Compartmental responses to acute osmotic stress in Leishmania major result in rapid loss of Na+ and Cl-:

The elemental composition of the cytoplasm, electron dense vacuoles, and heterochromatin and euchromatin regions of the nucleus of Leishmania major promastigotes was measured by electron probe X-ray microanalysis under iso-osmotic conditions (305 mOsM) and shortly after a sudden increase (to 615 mOsM) or decrease (to 153 mOsM) in the osmolality of the buffer in which they were suspended. In response to acute hypotonicity a complete loss of Na from the electron dense vacuoles and an approximately threefold decrease in the Na concentrations in the cytoplasm and the nuclear regions occurred, together with an approximately threefold decrease in Cl content in each compartment and a smaller (approx. 1.2-fold) decrease in K content. Thus, in addition to the rapid change in shape and release of amino acids known to occur in response to acute hypo-osmotic stress, a major efflux of Na and Cl, and, to a lesser extent, of K, also occurs. In response to acute hypertonicity Na in the acidocalcisomes did not change but Na content of the cytoplasm decreased by 33%. A small increase in the S content of the cytoplasm and the electron dense vacuolar compartments occurred. No changes were detectable in Ca or Zn content in any of the compartments examined in response to hypotonicity or hypertonicity.

Elemental composition of polyphosphate-containing vacuoles and cytoplasm of Leishmania major

Leishmania major promastigotes contain electron-dense vacuoles. The elemental composition of these vacuoles and of the cytoplasm was measured by electron probe X-ray microanalysis, using rapid cryopreservation techniques to prevent alterations in composition due to diffusion. The electron-dense vacuoles are rich in P, presumably present as polyphosphate (poly P). Mg is present at about 9 times its cytoplasmic level. There is sufficient Mg to largely neutralize most of the negative charge of the Poly P. The electron-dense vacuoles also contain appreciable amounts of Ca and Zn, which are not detectable in the cytoplasm, as well as Na, K, and Cl, the latter two at concentrations below that of the cytoplasm. These results suggest that the vacuolar membranes have at least one cation transport system. Incubation of the promastigotes for 1 h in the absence of phosphate in the presence or absence of glucose did not cause significant changes in the vacuolar contents of P, Mg, or Zn, but changes in K and Cl content were observed in both the electron-dense vacuoles and in the cytoplasm.

Effect of di(2‐ethylhexyl) phthalate on dna repair and lipid peroxidation in rat hepatocytes and on metabolic cooperation in Chinese hamster v‐79 cells

Experiments were conducted to test the hypothesis that the hepatocarcinogenicity of di(2-ethylhexyl) phthalate (DEHP) is due to its ability to produce DNA damage, either directly or as a result of the proliferation of peroxisomes and accompanying increased production of H2O2 and other DNA--damaging oxygen radicals induced by sustained exposure to the plasticizer. DNA repair, as assessed by the autoradiographic measurement of unscheduled DNA synthesis (UDS), was not observed in primary rat hepatocytes exposed in vitro to 10(-5)-10(-2) M DEHP or in vivo by a single gavage dose of 5 g DEHP/kg body weight administered 2, 15, or 24 h prior to the isolation of hepatocytes. Thus, DEHP does not appear to directly produce repairable DNA damage in rat hepatocytes. Sustained feeding of DEHP at a dietary concentration of 2% led to a marked proliferation of peroxisomes in the liver after 4 wk. Additional administration of a single gavage dose of 5 g DEHP/kg body weight to animals fed the 2% diet for 4 or 8 wk, as well as to 4-wk-fed animals that were also pretreated with 3-amino-1,2,4-triazole to inhibit endogenous catalase activity, did not induce any detectable DNA repair in hepatocytes isolated 15 h following the single gavage dose of DEHP. Lipid peroxidation measured in the 9000 X g supernatant of livers from animals treated with a single dose of 5 g DEHP/kg body weight or the 2% DEHP diet for 6 wk plus a single dose of 5 g/kg body weight did not differ from controls. These findings suggest that DEHP does not elicit DNA damage or lipid peroxidation in liver consequent to the proliferation of peroxisomes resulting from prolonged administration. In addition, at noncytotoxic concentrations DEHP failed to produce a positive response in the Chinese hamster V-79 metabolic cooperation assay for tumor promoters.