Pamela J. Fraker

Protein and cell membrane iodinations with a sparingly soluble chloroamide, 1,3,4,6-tetrachloro-3a,6a-diphenylglycoluril

1978 tetrachloro-3a,6a-diphenylglycoluril (conveniently els from methylene chloride solution) react rapidly aqueous mixtures of Iand proteins to yield iodinated ied, this reagent brings about iodination of cell rently, at a somewhat lesser rate than in iodinations dase-glucose oxidase. The stability and sparing lycoluril in water can account for the minimal damage lls observed in these iodinations; further, these nation of the reduction step employed at the close of chloroamides such as chloramine-T.

The Dynamic Link between the Integrity of the Immune System and Zinc Status

The results of more than three decades of work indicate that zinc deficiency rapidly diminishes antibody- and cell-mediated responses in both humans and animals. The moderate deficiencies in zinc noted in sickle cell anemia, renal disease, chronic gastrointestinal disorders and acrodermatitis enteropathica; subjects with human immunodeficiency virus; children with diarrhea; and elderly persons can greatly alter host defense systems, leading to increases in opportunistic infections and mortality rates. Conversely, short periods of zinc supplementation substantially improve immune defense in individuals with these diseases. Mouse models demonstrate that 30 d of suboptimal intake of zinc can lead to 30-80% losses in defense capacity. Collectively, the data clearly demonstrate that immune integrity is tightly linked to zinc status. Lymphopenia and thymic atrophy, which were the early hallmarks of zinc deficiency, are now known to be due to high losses of precursor T and B cells in the bone marrow. This ultimately leads to lymphopenia or a failure to replenish the lymphocytic system. Glucocorticoid-mediated apoptosis induced by zinc deficiency causes down-regulation of lymphopoiesis. Indeed, zinc itself can modulate death processes in precursor lymphocytes. Finally, there is substantial evidence that zinc supplementation may well reduce the impact of many of the aforementioned diseases by preventing the dismantling of the immune system. The latter represents an important area for research.

Evaluation of glucocorticoid-induced DNA fragmentation in mouse thymocytes by flow cytometry

Abstract. The ability of glucocorticoids to induce apoptosis or programmed cell death in mouse thymocytes is well‐established. Measurement of apoptosis‐associated internucleosomal DNA fragmentation through determination of the percentage of fragmented DNA by electrophoresis or centrifugation of whole cell lysates is by far the most common means of quantifying apoptosis. Since these methods measure DNA fragmentation in whole cell lysates rather than intact cells, they have severe limitations, particularly with heterogeneous cell populations. When mouse thymocytes were incubated with glucocorticoids, fixed, stained with propidium iodide and analysed flow cytometrically for cell cycle distribution, a distinct subpopulation of cells was observed to form below the Go/G1 region, denoted as the A0 region. The presence of cells in this region was consistent with the presence of internucleosomal DNA fragments as determined by gel electrophoresis. Inhibitors of transcription, translation and endonuclease activity, and a glucocorticoid receptor antagonist prevented accumulation of cells in this region. Irradiation of mouse thymocytes also produced a population in the A0 region. Cells in this region are believed to have undergone glucocorticoid‐induced DNA fragmentation. This method represents a useful alternative to whole cell lysate assays, since apoptosis can be evaluated on an individual cell basis.

Alterations in cell membrane properties caused by perfluorinated compounds.

The recent detection of perfluorinated compounds (PFCs) in wildlife from even remote locations has spurred interest in the environmental occurrence and effects of these chemicals. While the global distribution of PFCs is increasingly understood, there is still little information available on their effects on wildlife. The amphiphillic nature of PFCs suggests that their effects could be primarily on cell membranes. In this study we measured the effects of PFCs on membrane fluidity and mitochondrial membrane potential using flow cytometry and effects on membrane permeability using cell bioassay procedures (H4IIE, MCF-7, PLHC-1). Of the PFCs tested, only perfluorooctane sulfonic acid (PFOS) increased the permeability of cell membranes to the hydrophobic ligands used. Three PFCs were tested in the membrane fluidity assay: PFOS, perfluorohexane sulfonic acid (PFHS), and perfluorobutane sulfonic acid (PFBS). PFOS increased membrane fluidity in fish leukocytes in a dose-dependent fashion, while PFHS and PFBS had no effect in the concentration range tested. The lowest effective concentrations for the membrane fluidity effects of PFOS were 5-15 mg/l. Effects on mitochondrial membrane potential occurred in the same concentration range as effects on membrane fluidity. This suggests that PFOS effects membrane properties at concentrations below those associated with other adverse effects.

A REAPPRAISAL OF THE ROLE OF ZINC IN LIFE AND DEATH DECISIONS OF CELLS

Abstract There is a great deal of interest in chemicals and biochemicals that can modulate apoptosis. As will be discussed, zinc, an essential trace element, can induce as well as block apoptosis. High concentrations of extracellular zinc (500-1000 μM) have frequently been used to block apoptosis or programmed cell death in a variety of systems. Early investigators provided evidence that this concentration of zinc could block DNA fragmentation that is often associated with apoptosis. Since zinc plays a role in many aspects of cell function, there are probably many sites in a death pathway that zinc could potentially modulate. In the case of glucocorticoid-mediated apoptotic death, new evidence presented herein indicates that high zinc can also block the binding of steroids to the glucocorticoid receptor thereby inhibiting the death signal itself. In this case, zinc probably binds to the vicinal cysteines in the receptor ligand binding site thereby blocking binding of glucocorticoid. Indeed, glucocorticoid-induced apoptosis in thymocytes has become one of the most frequently studied systems and is a focal point of this review. Studies herein will show that unlike zinc other trace-like metals such as nickel, copper, cadmium, and gold do not afford thymocytes protection against the DNA fragmentation induced by glucocorticoid-mediated cell death. Interestingly, in attempting to determine if lower or more physiological concentrations of zinc could provide protection against apoptosis, it was found that 80-200 μM zinc could actually induce death in 40% of CD4+ CD8+αβTCR10CD310 thymocytes. From these experiments one might have been optimistic that zinc could, indeed, be a modulator of cell death. However, this thought has been overshadowed by growing evidence that zinc does not provide long-term protection to so-called surviving cells.

Quantification of apoptotic events in pure and heterogeneous populations of cells using the flow cytometer.

The rapid and highly quantitative nature of flow cytometric cell cycle analysis for determining the proportion of apoptotic cells in a population makes it the method of choice for a variety of studies requiring quantitative information about cell death. Furthermore, by employing multiparameter analysis including phenotypic labeling, FACS makes it possible to study apoptosis in specific subsets of cells within a heterogeneous population. Live sorting of cells in the apoptotic region offers the possibility of studying the effects of this form of cell death on key biochemical functions of the cell. Nonetheless, further modification of the fixing-staining methods presented here will be needed to make FACS useful for analysis of apoptosis in human cells.

A role for leptin in sustaining lymphopoiesis and myelopoiesis.

Although leptin is known for its regulation of food intake, it has many emerging roles in immune function. To better define the role of leptin in hematopoietic processes, a leptin-deficient obese mouse (ob/ob) and C57BL/6 lean wild-type controls were compared. Despite their large size and consumption of substantial amounts of nutrients, the ob/ob mice had only 60% as many nucleated cells in their marrow as controls. The greatest impact of leptin deficiency was on the B cell compartment that had 70% fewer cells, reducing the absolute number of pre-B and immature B cells to 21% and 12% of normal, respectively, and indicating a significant reduction in lymphopoiesis in ob/ob mice. Whereas the proportion of myeloids remained nearly normal in the obese mice, they also exhibited a reduction of 40% and 25%, respectively, in absolute numbers of granulocytes and monocytes. Seven days of provision of recombinant leptin promoted substantial lymphopoiesis, increasing the numbers of B cells in the marrow of the obese mice twofold, while doubling and tripling, respectively, the numbers of pre-B and immature B cells. Twelve days of supplementation brought these subpopulations to near-normal proportions. Leptin treatment also facilitated myelopoiesis such that the marrow of the obese mice contained normal numbers of monocytes and granulocytes after 7 days. Taken together, the data support an important role for leptin in sustaining lymphopoiesis and myelopoiesis.

Rapid changes in the lymphopoietic and granulopoietic compartments of the marrow caused by stress levels of corticosterone

Exposure to concentrations of glucocorticoids analogous to those produced during stress, trauma and malnutrition had rapid but varying effects on the major classes of cells within the marrow. Corticosterone (CS) was given as a subdermal implant in young mice and generated 60–95 µg CS/dl of blood compared to 5–15 µg CS/dl for sham controls over a period of 36 hr. Within 24 hr CS had caused losses of 30–70% among the early pro‐B, pre‐B and immature B cells. The pre‐B cells were virtually eliminated by 36 hr and the capacity of surviving pro‐ and pre‐B cells to cycle was reduced by 70–80%. Interestingly, the earliest of B cells, the prepro‐B cells, showed considerable resistance to CS, being reduced by only 20% at 36 hr. Thus, the pattern of survival within the B‐cell compartment paralleled the expression of Bcl‐2. At the 36‐hr time‐point there were no changes in the proportion of progenitor cells, erythroid or monocytic cells, or number of nucleated cells in the marrow. By contrast, 36 hr after exposure to CS there was an increase of 30% in the proportion and absolute number of cells in the granulocytic compartment. Chronic production of CS appears to reprogramme lymphopoiesis and myelopoiesis, perhaps to preserve the first line of immune defence at the expense of the lymphoid branch. Resistance to apoptosis and modifications in the activity of the glucocorticoid receptor and cytokines produced by stromal cells are postulated as targets for CS‐driven changes.

Natural glucocorticoids induce expansion of all developmental stages of murine bone marrow granulocytes without inhibiting function

Natural glucocorticoids (Gc) produced during stress have profound effects on the immune system. It is well known that Gc induce apoptosis in precursor T and B cells, markedly altering lymphopoiesis. However, it has been noted that marrow myeloid cells expanded both in proportion and absolute numbers in the mouse after Gc exposure. Mice were implanted with a corticosterone (CS) tablet that increased serum Gc and caused atrophied thymuses, both classic signs of activation of the stress axis. Blood neutrophil counts were elevated (4.8×), whereas lymphocyte counts declined. Flow cytometric analysis of the marrow revealed that the phenotypic distribution of the various major classes of cells was shifted by Gc exposure. As expected, marrow lymphocyte numbers declined >40% after 3 days of exposure to Gc. Conversely, in the myeloid compartment, both monocytes and granulocytes increased in number by >40%. Further, all granulocyte developmental stages showed large increases in both total number and percentage of cells. To investigate the functional capacity of mature granulocytes from Gc-treated mice, an improved granulocyte isolation method was developed. Gc exposure had little effect on the ability of granulocytes to produce superoxide or undergo chemotaxis or phagocytose bacteria. These results indicate that Gc treatment shifts bone marrow composition and provides evidence that granulocytes and their progenitors are selectively preserved under stressful conditions without losing function.

Possible roles for glucocorticoids and apoptosis in the suppression of lymphopoiesis during zinc deficiency: a review.

Thymic atrophy and lymphopenia are immunological hallmarks of many forms of malnutrition including deficiencies in zinc. Extreme thymic atrophy (70-80%) along with a 50% loss of splenocytes in mice maintained on a zinc deficient diet (ZD) for 30 days suggested that the deficiency might be altering lymphopoiesis or the production of new lymphocytes by the bone marrow. As shown herein, mice who were marginally zinc deficient being 72-75% the body weight of adequately fed controls, exhibited a 50% decline in pre B-cells and a 25% decline in immature B-cells. The mature B-cells of the marrow appeared fairly resistant to effects of suboptimal zinc intake. Interesting, this pattern was similar to results obtained by treating bone marrow cells with levels of glucocorticoids analogous to those found in nutritionally deficient rodents. Furthermore, these same concentrations of steroids were shown to induce significant levels of apoptosis or cell death among pre and immature B-cells which accounted for their declining numbers subsequent to exposure to glucocorticoid. In order to better ascertain the potential role of glucocorticoids generated during zinc deficiency on lymphopoietic processes, adrenalectomies were performed in an attempt to remove glucocorticoids from the equation. Subsequently, adrenalectomized and sham operated mice were placed on a ZD or zinc adequate diet (ZA). Levels of steroids at the time of sacrifice were elevated six fold in non-adrenalectomized ZD mice compared to ZD adrenalectomized mice. Removal of the adrenal gland protected the thymus of ZD mice from atrophy and also provided substantial protection of lymphopoietic processes.(ABSTRACT TRUNCATED AT 250 WORDS)