Tissue-specific regulation of zinc metabolism and metallothionein genes by interleukin 1.

Interleukin 1 (IL 1) production is stimulated by infection, cellular injury, and inflammation. This cytokine directs a wide spectrum of host responses. Human interleukin 1 alpha (IL 1 alpha) was used to examine the time course of effects on zinc metabolism as part of the acute phase response. IL 1 produced a transient depression in the serum zinc concentration and increased serum ceruloplasmin. Metallothionein levels were increased in liver 14-fold after IL 1. Increased expression of metallothionein-1 and -2 genes following IL 1 were observed in liver, bone marrow, and thymus. Pulse-labeling experiments with i.v.-administered 65Zn showed that IL 1 drastically altered zinc distribution kinetics among tissues. More 65Zn was taken up (and/or retained) by the liver, bone marrow, and thymus 6 h after IL 1, whereas correspondingly less 65Zn was found in bone, skin, and intestine. Uptake by other tissues was not affected by IL 1. Chromatography of cytosol from tissues with increased 65Zn uptake suggests the IL 1-induced redistribution may be driven by enhanced metallothionein synthesis. Collectively, the results show that IL 1 regulates zinc metabolism and may direct its preferential, tissue-specific distribution via elevated metallothionein-1 and -2 gene expression.

Relationship of 65Zn absorption kinetics to intestinal metallothionein in rats: effects of zinc depletion and fasting.

Intestinal 65Zn transport and metallothionein levels were examined in rats fed zinc-adequate and zinc-deficient diets and in rats subjected to an overnight fast. 65Zn uptake by intestines perfused with 1.5 microM 65Zn was greater in both zinc-deficient and fasted groups than in the control group. Mucosal retention of 65Zn was also greater in the zinc-deficient group but not in the fasted group. The greater 65Zn uptake in the fasted group was associated with a compartment that readily released 65Zn back into the lumen. Kinetic analysis of the rate of 65Zn transfer to the vascular space (absorption) showed that 65Zn absorption involved approximately 3% of mucosal 65Zn in a 40-min perfusion period. The half-life (t1/2) of this mucosal 65Zn rapid transport pool corresponded directly to changes in intestinal metallothionein levels. Both metallothionein and t1/2 were higher in the fasted group and lower in the zinc-deficient group than in controls. While the rate of 65Zn transport from this rapid transport pool decreased with increasing metallothionein level, the predicted pool size increased when the metallothionein level was elevated by fasting. These results indicate that the rate of zinc absorption is inversely related to intestinal metallothionein levels, but the portion of mucosal 65Zn available for absorption is directly related to intestinal metallothionein.

Kinetic analysis of zinc uptake and serosal transfer by vascularly perfused rat intestine.

Transport kinetics were examined for uptake of 65Zn from the lumen and for transport of mucosal 65Zn subsequent to uptake in the isolated, vascularly perfused intestines of rats fed either a zinc-deficient or zinc-adequate diet. Zinc depletion influenced the intestinal transport of zinc by stimulating a saturable uptake mechanism, reducing secretion of mucosal 65Zn into the lumen, and increasing the rate of 65Zn turnover in a rapidly absorbed mucosal zinc compartment. Uptake of 65Zn involved both saturable and nonsaturable processes. The saturable process was stimulated by zinc depletion with the apparent maximal transport rate for the saturable mechanism increasing from 60 to 180 nmol Zn X g-1 X 30 min-1. Most of the 65Zn taken up was not involved in the short-term secretion or absorption, and mucosal 65Zn retention was independent of dietary zinc status. Absorption of mucosal 65Zn was nonsaturable, involved a rapid exchanging zinc compartment, and was stimulated by zinc depletion. The half-life for 65Zn in this mucosal zinc compartment was approximately 24 min in the zinc-adequate group and 13 min in the zinc-depleted group.

Portal copper transport in rats by albumin.

The distribution of newly absorbed copper among serum proteins obtained from the portal circulation of rats was examined by conventional and high-performance gel filtration chromatography, affinity chromatography, and Western blotting. Within 10-30 min after being administered by gavage or directly into the intestine, 67Cu and 64Cu, respectively, were recovered in the albumin fraction. By 8 h after administration of the radionuclides, virtually all of the radioactivity was found with ceruloplasmin. Affigel blue fractionation and subsequent Superose-6 chromatography further demonstrated that all of the copper in the albumin-containing fractions was in fact bound to this protein rather than high molecular weight moieties. Vascular perfusion of the isolated rat intestine, where 64Cu was infused into the lumen, showed that newly absorbed 64Cu in the vascular perfusate collected from the cannulated portal vein was associated with albumin. Uptake of radioactivity by isolated rat liver parenchymal cells from medium containing rat serum with 67Cu bound to albumin was demonstrated. In vitro binding of 64Cu to serum proteins that were transferred to nitrocellulose by Western blotting techniques showed that albumin is essentially the only protein that binds appreciable amounts of copper. The data suggest that albumin is the plasma protein that is responsible for the initial transport of copper after absorption.

Coordinate regulation of zinc metabolism and metallothionein gene expression in rats.

Regulation of zinc metabolism by dibutyryl cAMP, glucagon, and epinephrine was examined in rats fed adequate amounts of zinc. Dibutyryl cAMP, epinephrine, and glucagon each produced an increase in liver metallothionein levels by 10 h after they were first administered. The increase in liver metallothionein was inversely related to the serum zinc concentration. Treatment with dexamethasone, a glucocorticoid, accentuated these effects to some extent. Both metallothionein I and II were induced by dibutyryl cAMP and glucagon. Levels of metallothionein mRNA in total liver RNA extracts were measured by dot blot hybridization using a synthetic 21-base oligonucleotide complimentary to the 5' region of both the metallothionein I and II genes. Individual administration of dibutyryl cAMP, glucagon, and epinephrine increased the number of metallothionein mRNA molecules per cell by up to fourfold. The data suggest that glucagon and epinephrine are primary regulators of metallothionein gene expression acting at least in part via cAMP. In adrenalectomized rats, glucagon, dibutyryl cAMP, and epinephrine had a less potent effect in terms of metallothionein induction and depression of serum zinc concentrations. These effects were largely restored when dexamethasone was also given. Collectively these data suggest that changes in zinc metabolism associated with acute stress involve coordinate regulation mediated by many factors, including glucocorticoids and cAMP.