Immunoendocrine modulation and stimulation of hematopoiesis with the ionophore copolymer T150R1

T150R1, an 8000-dalton copolymer with sodium ionophore activity, has been shown to modulate cellular responses in multiple systems. In this article, we studied its effects on lymphoid and hematopoietic organs in the context of the adrenal-pituitary axis. When injected in mice as an oil in water emulsion, T150R1 caused a rapid, profound, and dose-dependent thymic involution accompanied by splenic hyperplasia. Time course experiments with a 2.5-mg dose revealed that the thymus size was minimal at Day 2, rose to normal by Day 14, then enlarged and gradually returned to normal by Week 6 postinjection. Thymic involution was due to cellular depletion of the cortical area, whereas thymic enlargement was due to cortical hyperplasia. Splenomegaly was seen as early as Day 4, peaked by Day 14, and gradually returned to normal by Week 6. The splenic enlargement was due to hyperplasia of the red pulp, with evidence of proliferating erythropoietic, myelopoietic, and megakaryopoietic precursors. In addition, the bone marrow was stimulated and extramedullary hematopoiesis was present in the liver. The effects of T150R1 on the thymus appeared to be mediated by corticosteroids while the effects on hematopoiesis were not. Corticosterone and ACTH levels were increased in treated animals. Adrenalectomy diminished the T150R1-induced thymic involution but enhanced the splenic hyperplasia. Hypophysectomy did not prevent thymic involution, suggesting that T150R1 has endocrine stimulatory effects. These data suggest that T150R1 represents a new class of ionophores which may act on excitable cells within the endocrine, immune, and hematopoietic systems.     

Intrinsic Protein Fluorescence Interferes with Detection of Tear Glycoproteins in SDS-Polyacrylamide Gels Using Extrinsic Fluorescent Dyes

Intrinsic protein fluorescence may interfere with the visualization of proteins after SDS-polyacrylamide electrophoresis. In an attempt to analyze tear glycoproteins in gels, we ran tear samples and stained the proteins with a glycoprotein-specific fluorescent dye. The fluorescence detected was not limited to glycoproteins. There was strong intrinsic fluorescence of proteins normally found in tears after soaking the gels in 40% methanol plus 1-10% acetic acid and, to a lesser extent, in methanol or acetic acid alone. Nanograms of proteins gave visible native fluorescence and interfere with extrinsic fluorescent dye detection. Poly-L-lysine, which does not contain intrinsically fluorescent amino acids, did not fluoresce.     

Gill area, permeability and Na+ ,K+ -ATPase activity as a function of size and salinity in the blue crab, Callinectes sapidus

Juvenile blue crabs, Callinectes sapidus, extensively utilize oligohaline and freshwater regions of the estuary. With a presumptively larger surface-area-to-body weight ratio, juvenile crabs could experience osmo- and ionoregulatory costs well in excess of that of adults. To test this hypothesis, crabs ranging over three orders of magnitude in body weight were acclimated to either sea water (1,000 mOsm) or dilute sea water (150 mOsm), and gill surface area, water and sodium permeabilities (calculated from the passive efflux of 3H2O and 22Na+), gill Na+, K+ -ATPase activity and expression were measured. Juveniles had a relatively larger gill surface area; weight-specific gill surface area decreased with body weight. Weight-specific water and sodium fluxes also decreased with weight, but not to the same extent as gill surface area; thus juveniles were able to decrease gill permeability slightly more than adults upon acclimation to dilute media. Crabs < 5 g in body weight had markedly higher activities of gill Na+ ,K+ -ATPase than crabs > 5 g in both posterior and anterior gills. Acclimation to dilute medium induced increased expression of Na+, K+ -ATPase and enzyme activity, but the increase was not as great in juveniles as in larger crabs.The increased weight-specific surface area for water gain and salt loss for small crabs in dilute media presents a challenge that is incompletely compensated by reduced permeability and increased affinity of gill Na+, K+ -ATPase for Na+. Juveniles maintain osmotic and ionic homeostasis by the expression and utilization of extremely high levels of gill Na+, K+ -ATPase, in posterior, as well as in anterior, gills.