In vivo human melanoma cytokine production: inverse correlation of GM-CSF production with tumor depth.

Melanomas produce multiple cytokines which may influence their growth in vivo. Experimental evidence suggests that granulocyte macrophage-colony stimulating factor (GM-CSF) can induce a potent anti-melanoma response. whereas interleukin-8 (IL-8) may act as a growth factor in human melanoma. Little is currently known regarding the production of these cytokines by human melanoma in vivo. In this study we tested the hypothesis that endogenous production of GM-CSF and IL-8 can be correlated with the depth of human malignant melanoma surgical specimens. We examined 45 melanocytic human tissue samples consisting of 27 primary cutaneous melanomas, 9 metastatic melanomas, and 9 dysplastic nevi for in vivo GM-CSF and IL-8 production using immunohistochemistry. The majority of thin melanomas (< or = 0.76 mm) stained highly positive for GM-CSF with little or no staining for IL-8 whereas the medium (>0.76- < or = 4.0 mm) and thick (>4.0 mm) melanoma specimens showed little or no staining for GM-CSF and significant amounts of IL-8 staining. Metastatic melanoma as well as dysplastic nevi specimens had little or no GM-CSF and IL-8 staining. These results support the hypothesis that endogenous melanoma cytokines such as GM-CSF and IL-8 with opposing effects on tumor progression play an important role in melanoma growth and regulation.

Environmental and human monitoring of Americium-241 utilizing extraction chromatography and alpha-spectrometry.

Recent developments in extraction chromatography have simplified the separation of americium from complex matrices in preparation for alpha-spectroscopy relative to traditional methods. Here we present results of procedures developed/adapted for water, air, and bioassay samples with less than 1 g of inorganic residue. Prior analytical methods required the use of a complex, multistage procedure for separation of americium from these matrices. The newer, simplified procedure requires only a single 2 mL extraction chromatographic separation for isolation of Am and lanthanides from other components of the sample. This method has been implemented on an extensive variety of "real" environmental and bioassay samples from the Los Alamos area, and consistently reliable and accurate results with appropriate detection limits have been obtained. The new method increases analytical throughput by a factor of approximately 2 and decreases environmental hazards from acid and mixed-waste generation relative to the prior technique. Analytical accuracy, reproducibility, and reliability are also significantly improved over the more complex and laborious method used previously.

Rapid redistribution and inhibition of renal sodium transporters during acute pressure natriuresis.

Acute arterial hypertension provokes a rapid decrease in proximal tubule (PT) Na+ reabsorption, increasing flow to the macula densa, the signal for tubuloglomerular feedback. We tested the hypothesis, in rats, that Na+ transport is decreased due to rapid redistribution of apical Na+/H+ exchangers and basolateral Na+ pumps to internal membranes. Arterial pressure was increased 50 mmHg by constricting various arteries. We also tested whether transporter internalization occurred when PT Na+ reabsorption was inhibited with the carbonic anhydrase inhibitor benzolamide. Five minutes after initiating either natriuretic stimuli, cortex was removed, and membranes were fractionated by density gradient centrifugation. Urine output and endogenous lithium clearance increased threefold in response to either stimuli. Acute hypertension provoked a redistribution of apical Na+/H+ exchanger NHE3, alkaline phosphatase, and dipeptidyl peptidase IV to higher density membranes enriched in the intracellular membrane markers. Basolateral membrane Na(+)-K(+)-adenosinetriphosphatase (Na(+)-K(+)-ATPase) activity decreased 50%, 25-30% of the alpha 1-and beta 1-subunits redistributed to higher density membranes, and the remainder is attributed to decreased activity of the transporters. Benzolamide did not alter Na+ transporter activity or distribution, implying that decreasing apical Na+ uptake does not initiate redistribution or inhibition of basolateral Na(+)-K(+)-ATPase. We conclude that PT natriuresis provoked by acute arterial pressure is mediated by both endocytic removal of apical Na+/H+ exchangers and basolateral Na+ pumps as well as decreased total Na+ pump activity.

Amiodarone decreases Na,K-ATPase alpha 2 and beta 2 expression specifically in cardiac ventricle.

Studies have suggested that chronic amiodarone treatment (a class III antiarrhythmic) may have effects on the myocardium that resemble those of hypothyroidism. Since hypothyroidism is associated with decreased expression of Na,K-ATPase alpha 1, alpha 2 and beta 1 subunits in heart and alpha 2 subunit in skeletal muscle, we aimed to test the hypothesis that chronic in vivo administration of amiodarone would result in changes in the expression of Na,K-ATPase isoforms that resembled those seen in hypothyroid rat. Rats were treated with 40 micrograms/g body weight amiodarone for 3 and 6 weeks. Na,K-ATPase alpha 1, alpha 2, beta 1 mRNA and protein levels and beta 2 mRNA were measured in cardiac ventricle and skeletal muscle. After 3 weeks of amiodarone cardiac alpha 1, alpha 2 and beta 1 protein levels were decreased to 0.65, 0.42, and 0.54 of control, respectively. After 6 weeks of treatment, cardiac alpha 1 and beta 1 levels returned to control and alpha 2 remained depressed. At the mRNA level alpha 2 and beta 2 decreased to 0.6-fold of control after 6 weeks treatment. There was no effect of amiodarone on skeletal muscle Na,K-ATPase expression at either time point. We conclude that the effects of amiodarone on myocardial Na,K-ATPase expression are similar to those of hypothyroidism after 3 weeks of amiodarone treatment, but by 6 weeks the similarities are limited to the decrease in alpha 2 and beta 2 expression.(ABSTRACT TRUNCATED AT 250 WORDS)

Complex subcellular distribution of sodium-dependent amino acid transport systems in kidney cortex and LLC-PK1/Cl4 cells.

To characterize the amino acid transport system in basolateral membranes and to test for possible intracellular loci of amino acid transport activity, we surveyed the distribution of L-alanine transport activity in rabbit proximal tubular cells and LLC-PK1/Cl4 cells. A three-dimensional separation procedure based on differential sedimentation, density gradient centrifugation, and counter-current distribution resolved 21 physically and biochemically distinct membrane populations from rabbit cortex. Inhibition of L-alanine transport by phenylalanine and N-(methylamino)isobutyric acid was used to delineate parallel amino acid transport pathways. Population n was identified as brush border membranes by virtue of its 16-fold maltase enrichment; 94% of its Na(+)-dependent alanine transport activity was mediated by systems previously shown to be characteristic of brush border membranes. Two populations, c' and c", which accounted for 25% of the total Na,K-ATPase activity, were identified as basalateral membranes on the basis of Na,K-ATPase cumulative enrichment factors of 15 and 21; 82% of the total alanine transport in these populations was mediated by a Na(+)-independent system similar to the classical system L. Na,K-ATPase, Na(+)-independent and Na(+)-dependent alanine transport activities were associated with intracellular membrane populations as well as with the plasma membranes. The major intracellular locus of Na,K-ATPase activity, population i accounted for roughly 31% of the Na,K-ATPase, maximally enriched ninefold; it contained 29% of the total system L transport activity. Population l, which was identified as endoplasmic reticulum because it was the major locus of membrane-bound NADPH cytochrome c reductase activity, contained 44% of the total system A transport. Three distinct Golgi-derived populations, m', m", and o, accounted for 39% of the total system A transport. A survey of the amino acid transport systems in LLC-PK1/Cl4 cells showed that the majority of system A-mediated amino acid transport was present in membranes of intracellular and possibly apical origin. The presence of large intracellular pools of amino acid transport activities might reflect newly synthesized transport proteins, ongoing membrane recycling or, perhaps, intracellular reserves available for rapid recruitment to the plasma membrane.

Thyroid hormone specifically regulates skeletal muscle Na(+)-K(+)-ATPase alpha 2- and beta 2-isoforms.

The purpose of this study was to determine the pattern of thyroid hormone (triiodothyronine, T3) regulation of the Na(+)-K(+)-adenosinetriphosphatase (Na(+)-K(+)-ATPase) alpha- and beta-subunit expression in skeletal muscle, which expresses alpha 1-, alpha 2-, beta 1-, and beta 2-subunits, and compare it with that seen in kidney, which expresses only alpha 1 and beta 1. Three steady states were studied: hypothyroid, euthyroid, and hyperthyroid (hypothyroids injected daily with 1 microgram T3/g body wt for 2-16 days). Protein and mRNA abundance, determined by Western and Northern analysis, were normalized to a constant amount of homogenate protein and total RNA, respectively. In skeletal muscle, there was no change in alpha 1- or beta 1-mRNA or protein levels in the transition from hypothyroid to hyperthyroid. However, alpha 2 was highly regulated; mRNA reached a new steady-state level of fivefold over hypothyroid by 8 days of T3 treatment and protein abundance increased threefold. In addition, beta 2-mRNA and protein were detected in skeletal muscle and were also highly regulated by T3; beta 2-mRNA increased nearly fourfold over hypothyroid level, and beta 2-protein abundance increased over twofold. In kidney in the transition from hypothyroid to hyperthyroid, there were coordinate 1.6-fold increases in both alpha 1- and beta 1-mRNA abundance that predicted the observed changes in alpha 1- and beta 1-protein levels and Na(+)-K(+)-ATPase activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Liver dysfunction and energy source: results of a randomized clinical trial.

Controversy still exists regarding the role of the carbohydrate:fat ratio on liver function abnormalities associated with the administration of total parenteral nutrition (TPN). We designed a prospective clinical trail comparing standard carbohydrate-based TPN (8.5% amino acids, 50% dextrose, 7.5% of total calories from lipids) with an isocaloric lipid-based TPN (8.5% amino acids, 30% dextrose, 40% of total calories from lipids) in 43 patients exclusively receiving TPN > or = 2 weeks. Energy needs were calculated as basal energy expenditure x 1.5. The mean daily calorie intake for patients who obtained carbohydrate-based TPN (CHO) was 2227 kcal, whereas the lipid-based TPN (LIP-CHO) group achieved a mean of 2310 kcal. Patients with preexisting liver disease were excluded. There was no significant difference in age or diagnosis between the groups. We monitored total bilirubin, direct bilirubin, alkaline phosphatase, gamma-glutamyl transferase, lactic dehydrogenase, serum glutamic oxaloacetic transaminase, and serum glutamic pyruvic transaminase. Initial liver-associated tests did not vary significantly between groups. Group mean values after 2 weeks of TPN were significantly different for total bilirubin (1.5 mg/dL in the CHO group compared with 0.7 in the LIP-CHO group, p < .05) and direct bilirubin (0.8 mg/dL in the CHO group compared with 0.3 mg/dL in the mixed substrate group, p < .05). Differences in mean values between groups were also noted for serum glutamic oxaloacetic transaminase, serum glutamic pyruvic transaminase, and lactic dehydrogenase. In conclusion, this prospective trial reveals that the use of a balanced energy source TPN solution prevents the abnormalities in liver-associated tests commonly associated with TPN.(ABSTRACT TRUNCATED AT 250 WORDS)

Physiologic rationale for multiple sodium pump isoforms. Differential regulation of alpha 1 vs alpha 2 by ionic stimuli.

A number of important themes emerge from our compartmental analyses of Na,K-ATPase biosynthesis in response to ionic stimuli. The ubiquitous alpha 1 beta 1 type sodium pump evolved to generate and maintain transmembrane Na+ and K+ gradients, and there are cell-type specific mechanisms of increasing synthesis and decreasing degradation to control surface expression of this important "housekeeping" enzyme. Expression of alpha 2 beta-type sodium pumps may have evolved in cells designated as K+ storehouses to facilitate maintenance of extracellular K+ in the presence of K+ restriction. Finally, the specialized distribution of Na,K-ATPase (and related E1-E2 type pumps) along the renal epithelia allows for monitoring and fine control of extracellular K+ and Na+ (volume). Many interesting questions remain to be answered, and we now have the probes and techniques needed to answer them.

Thyroid hormone induction of rat myocardial Na(+)-K(+)-ATPase: alpha 1-, alpha 2-, and beta 1-mRNA and -protein levels at steady state.

In this study, we measured the time courses of change in Na(+)-K(+)-ATPase alpha 1-, alpha 2-, and beta 1-subunit mRNA and protein abundance in cardiac myocytes isolated from euthyroid, hypothyroid, and hyperthyroid (hypothyroids injected daily with 1 microgram T3/g body wt) rats. In hypothyroids, alpha 1-, alpha 2-, and beta 1-protein levels were decreased to 0.55, 0.42, and 0.57 of euthyroids, predicting the decrease in Na(+)-K(+)-ATPase activity to 0.53 of control. There was no change in these subunits' mRNA levels, indicating that the decreases in protein levels were not due to decreased subunit transcription rates. In hyperthyroids, the alpha 1-mRNA increased to a steady state of threefold over hypothyroid by 1 day of T3 treatment, and the alpha 1-protein levels increased to twofold over hypothyroid by 4 days of T3. alpha 2-mRNA increased to 5-fold over hypothyroid by 2 days, whereas the alpha 2-protein levels increased to 14-fold above hypothyroid by 4 days of T3. Beta 1-mRNA increased to 12-fold above hypothyroid by 1 day of T3 treatment, whereas beta 1-protein increased to only 2.5-fold over hypothyroid by 4 days of T3. The discoordinate changes in alpha 2- and beta 1-mRNA vs. protein can be reconciled with the hypothesis that beta 1 is rate limiting for assembly in eu- and hypothyroids, and favors assembly with alpha 1, while excess unassembled alpha 2 is degraded. In the hyperthyroids we predict beta 1 is not rate limiting and there is increased alpha 2 beta 1-assembly. We calculate that T3 decreases the alpha 1-to-alpha 2 ratio from 24:1 in hypothyroid to 3.4:1 in hyperthyroid cardiomyocytes.

Hypokalemia decreases Na(+)-K(+)-ATPase alpha 2- but not alpha 1-isoform abundance in heart, muscle, and brain.

K+ deficiency has been linked to a loss of K+ from muscle associated with a decrease in ouabain binding and K(+)-dependent phosphatase activity. This study aimed to quantitate the Na(+)-K(+)-ATPase alpha- and beta-isoform-specific responses to hypokalemia in vivo in heart, skeletal muscle, and brain at pre- and posttranslational levels. Two-week dietary K+ restriction resulted in decreases in alpha 2-mRNA in heart and skeletal muscle to 0.60 and 0.65, and in alpha 2-protein abundance to 0.38 and 0.18 of control, respectively. The decrease in alpha 2-protein was greater than the decrease in mRNA in both tissues, suggesting translational and/or posttranslational mechanism(s) of regulation as well as pretranslational regulation in response to hypokalemia. K(+)-dependent p-nitrophenyl phosphatase (pNPPase) activity decreased in heart and skeletal muscle to 0.67 and 0.58, respectively. There were no changes in alpha 1-. or beta-mRNA or protein levels in skeletal muscle or heart. In brain, there was a similar pattern of regulation. While brain alpha 2-mRNA did not change in hypokalemia, protein levels decreased to 0.72 of control. In conclusion, hypokalemia is associated with a large decrease in expression of the alpha 2-isoform of Na(+)-K(+)-ATPase. These results support the hypothesis that in skeletal and heart muscle hypokalemia induces a decrease in Na(+)-K(+)-ATPase activity (measured as K(+)-dependent pNPPase activity) by specifically decreasing the expression of the alpha 2-isoform of Na(+)-K(+)-ATPase.(ABSTRACT TRUNCATED AT 250 WORDS)

Low K+ increases Na,K-ATPase abundance in LLC-PK1/Cl4 cells by differentially increasing beta, and not alpha, subunit mRNA.

In this paper we establish the response of LLC-PK1/Cl4 cells, a pig kidney cell line, to incubation in medium containing 0.25 mM K+. The amounts of the Na,K-ATPase alpha and beta subunits, determined by Western blot, increase coordinately to greater than 2-fold over control by 24 h in low K+ and remained elevated for the duration of the study period (48 h). Na,K-ATPase activity, measured enzymatically, increased 1.4-fold by 24 h and remained elevated. In order to determine if this response was initiated pretranslationally, alpha and beta subunit mRNA levels were determined by Northern blot analysis. While there was no change in alpha-mRNA levels, beta levels increased significantly, to 1.9-fold over control by 6 h of treatment and remained elevated. This selective increase in beta-mRNA was accompanied by 1.6- and 3.1-fold increases in the respective rates of accumulation of newly synthesized alpha and beta subunits, assessed by immunoprecipitating subunits from pulse-labeled cells. The degradation rates of mature Na,K-ATPase subunits did not change during 16 h of exposure to low K+, but after 16 h there was a selective decrease in the alpha degradation rate, relative to control. These results suggest that increased pretranslational regulation of the beta subunit alone is sufficient to increase accumulation of both alpha and beta subunits. These findings support the notion that in LLC-PK1 cells newly synthesized beta is rate-limiting and thus regulates, through alpha beta assembly, the number of pumps transported to the plasma membrane.

Differential regulation of Na,K-ATPase alpha 1, alpha 2, and beta subunit mRNA and protein levels by thyroid hormone.

The purpose of this study was to determine the effect of thyroid status on the Na,K-ATPase alpha isoforms and beta in rat heart, skeletal muscle, kidney, and brain at the levels of mRNA, protein abundance, and enzymatic activity. Northern and dot-blot analysis of RNA (euthyroid, hypothyroid, and triiodothyronine-injected hypothyroids = hyperthyroids) and immunoblot analysis of protein (euthyroid and hypothyroid) revealed isoform-specific regulation of Na,K-ATPase by thyroid status in kidney, heart, and skeletal muscle and no regulation of sodium pump subunit levels in the brain. In general, in the transition from euthyroid to hypothyroid alpha 1 mRNA and protein levels are unchanged in kidney and skeletal muscle and slightly decreased in heart, while alpha 2 mRNA and protein are decreased significantly in heart and skeletal muscle. In hypothyroid heart and skeletal muscle, the decrease in alpha 2 protein levels was much greater than the decrease in alpha 2 mRNA levels relative to euthyroid indicating translational or post-translational regulation of alpha 2 protein abundance by triiodothyronine status in these tissues. The regulation of beta subunit by thyroid status is tissue-dependent. In hypothyroid kidney beta mRNA levels do not change, but immunodetectable beta protein levels decrease relative to euthyroid, and the decrease parallels the decrease in Na,K-ATPase activity. In hypothyroid heart and skeletal muscle beta mRNA levels decrease; beta protein decreases in heart and was not detected in the skeletal muscle. These findings demonstrate that the euthyroid levels of expression of alpha 1 in heart, alpha 2 in heart and skeletal muscle, and beta in kidney, heart, and skeletal muscle are dependent on the presence of thyroid hormone.

Subcellular distribution of Na+/H+ antiport activity in rat renal cortex.

Phase partitioning analyses of a brush border membrane preparation obtained with a divalent cation precipitation procedure (Am J Physiol 246:F853-F858, 1984) confirmed that Na+/H+ antiport activity was localized primarily to the brush border membrane of the rabbit proximal tubular epithelial cell. This analysis also indicated that antiport activity was associated with membrane populations that appeared to be derived from cytoplasmic structures. However, since the starting point of the analysis was a partially-purified brush border sample rather than a total membrane sample, it was not possible to discern the magnitude of the potential cytoplasmic pool of antiport activity. We have now used a three dimensional analytical fractionation procedure, based on differential centrifugation, equilibrium density gradient centrifugation, and partitioning in an aqueous polymer 2-phase system, to survey the subcellular distribution of Na/H antiport activity in rat kidney cortex. Roughly 53% of the recovered antiport activity could be assigned to a population of brush border membrane vesicles characterized by a 15-fold enrichment of maltase. An additional 26% of the recovered activity could be assigned to a group of three membrane populations whose biochemical characteristics appeared equally consistent with origins in distinct microdomains of the brush border membrane and with origins in microdomains of the Golgi complex involved in the assembly or recycling of brush border membrane constituents. Therefore, depending on the identities of membranes which contained the secondary pool of Na+/H+ antiport activity, no more than one-third of the total recoverable Na+/H+ antiport activity could be assigned to cytoplasmic membranes of the proximal tubular epithelium.

Parathyroid hormone-induced translocation of Na-H antiporters in rat proximal tubules.

Parathyroid hormone (PTH) is believed to inhibit bicarbonate reabsorption by inhibiting Na-H antiport activity in proximal tubular brush-border membranes. The sequence of events triggered by PTH was investigated in a crude preparation of proximal tubules obtained by mechanical disruption and filtration through nylon mesh filters. Tubule samples were subjected to analytical subcellular fractionation after 2-, 5-, and 30-min treatments with 1 IU/ml PTH. These PTH-treatment intervals caused 54, 63, and 68% decreases in the Na-H antiport activity of a population of brush-border membrane vesicles that was resolved from a PTH-unresponsive brush-border population by density-gradient centrifugation. The rapid loss of Na-H antiport activity from the responsive population was accompanied by a transient increase in the Na-H antiport activity of a region of the density gradient, designated density window III, which was shown to contain two distinct membrane populations; these populations were both enriched in acid phosphatase activity, and one of them was also an important locus of galactosyltransferase activity. The increase in the Na-H antiport activity of window III accounted for 52% of the activity lost from the PTH-responsive population after 2 min, and for 43% of the activity lost after 5 min, but it was completely abolished after 25 more minutes in the presence of PTH. These observations suggest that PTH triggers a rapid translocation of Na-H antiporters from the microvillus membrane to a distinct membrane domain, where they are subsequently inactivated.

Na+/H+ antiporter in lacrimal acinar cell basal-lateral membranes.

The first step in the formation of lacrimal gland fluid is believed to depend on transport systems which couple a flux of Cl- ions to the passive influx of Na+ ions across the acinar cell basal-lateral plasma membrane. The transport systems which mediate these fluxes have not yet been characterized, but a review of previous studies (Parod and Putney, Am J Physiol 239:G106, 1980) raises the possibility that Na+/H+ antiporters might represent a major pathway for Na+ influx. This conclusion is of interest, because antiporter mediated Na+ fluxes can, potentially, drive net Cl- fluxes. We have now examined a sample of basal-lateral membrane vesicles from rat exorbital lacrimal gland to verify the presence of a Na+/H+ antiporter activity. Imposition of an outward H+ gradient caused a 4.4-fold increase in the 22Na influx rate, while imposition of an outward Na+ gradient accelerated H+ uptake as determined by changes in acridine orange absorbance. All transport experiments were done in the presence of valinomycin and symmetrical K+ concentrations, eliminating the possibility of conductive Na+ or H+ fluxes driven by diffusion potentials. The pH gradient dependent Na+ influx was completely inhibited by 1 mM amiloride, indicating that it was mediated by a Na+/H+ antiporter similar to those described in other tissues. Comparison of the density distributions of Na+/H+ antiport and standard membrane marker enzyme activities confirmed that the antiporter was primarily localized to the basal-lateral membranes.

Mapping subcellular distribution of Na+-K+-ATPase in rat parotid gland.

Recent subcellular fractionation studies have raised the possibility that Na+-K+-ATPase might be present in both the apical and the basal-lateral membranes of exocrine gland acinar cells. Analytical fractionation and immunofluorescence microscopy studies of rat parotid glands were performed to confirm this interpretation. The distributions of biochemical markers after analyses based on differential sedimentation, equilibrium density-gradient centrifugation, and partitioning in an aqueous polymer two-phase system defined a total of 15 physically and biochemically distinct membrane populations. Among these populations, it was possible to select one (designated population i) with the characteristics expected of acinar cell basal-lateral plasma membranes. It contained Na+-K+-ATPase enriched 33-fold, and gamma-glutamyl transpeptidase enriched 23-fold with respect to the initial homogenate. A second population (designated population c) had the characteristics expected of acinar cell apical plasma membranes; it contained Na+-K+-ATPase enriched 28-fold, and gamma-glutamyl transpeptidase enriched 53-fold with respect to the initial homogenate. Although the identification of population c remains provisional, immunofluorescence studies verified that Na+-K+-ATPase is present in both the apical and the basal-lateral acinar cell plasma membranes. In view of these results, it is likely that the apical Na+-K+-ATPase would participate in series with basal-lateral sodium- and chloride-entry pathways in driving the secretory electrolyte fluxes.