Kinetics and mechanism for reversible chloride transfer between mercury(II) and square-planar platinum(II) chloro ammine, aqua, and sulfoxide complexes. Stabilities, spectra, and reactivities of transient metal-metal bonded platinum-mercury adducts.

The Hg2+aq- and HgCl+aq-assisted aquations of [PtCl4]2- (1), [PtCl3(H2O)]- (2), cis-[PtCl2(H2O)2] (3), trans-[PtCl2(H2O)2] (4), [PtCl(H2O)3]+ (5), [PtCl3Me2SO]- (6), trans-[PtCl2(H2O)Me2SO] (7), cis-[PtCl(H2O)2Me2SO]+ (8), trans-[PtCl(H2O)2M32SO]+ (9), trans-[PtCl2(NH3)2] (10), and cis-[PtCl2(NH3)2] (11) have been studied at 25.0 degrees C in a 1.00 M HClO4 medium buffered with chloride, using stopped-flow and conventional spectrophotometry. Saturation kinetics and instantaneous, large UV/vis spectral changes on mixing solutions of platinum complex and mercury are ascribed to formation of transient adducts between Hg2+ and several of the platinum complexes. Depending on the limiting rate constants, these adducts are observed for a few milliseconds to a few minutes. Thermodynamic and kinetics data together with the UV/vis spectral changes and DFT calculations indicate that their structures are characterized by axial coordination of Hg to Pt with remarkably short metal-metal bonds. Stability constants for the Hg2+ adducts with complexes 1-6, 10, and 11 are (2.1 +/- 0.4) x 10(4), (8 +/- 1) x 10(2), 94 +/- 6, 13 +/- 2, 5 +/- 2, 60 +/- 6, 387 +/- 2, and 190 +/- 3 M-1, respectively, whereas adduct formation with the sulfoxide complexes 7-9 is too weak to be observed. For analogous platinum(II) complexes, the stabilities of the Pt-Hg adducts increase in the order sulfoxide << aqua < ammine complex, reflecting a sensitivity to the pi-acid strength of the Pt ligands. Rate constants for chloride transfer from HgCl+ and HgCl2 to complexes 1-11 have been determined. Second-order rate constants for activation by Hg2+ are practically the same as those for activation by HgCl+ for each of the platinum complexes studied, yet resolved contributions for Hg2+ and HgCl+ reveal that the latter does not form dinuclear adducts of any significant stability. The overall experimental evidence is consistent with a mechanism in which the accumulated Pt(II)-Hg2+ adducts are not reactive intermediates along the reaction coordinate. The aquation process occurs via weaker Pt-Cl-Hg or Pt-Cl-HgCl bridged complexes.

Characterization of intracellular copper pools in rat hepatocytes using the chelator diamsar.

When hepatocytes are incubated with the chelator diamsar, two pools can be identified, which we have termed extractable and nonextractable. On entering the hepatocyte, 67Cu first associates with the extractable pool and, after approximately 2 h, moves to the nonextractable pool. Both pools demonstrate saturation and are filled as a function of Cu concentration and incubation time. Using the Michaelis-Menten equation, we have estimated the size of the pools after incubation with 67Cu for 30 min and 4 h. During this period the extractable pool decreases in size from 200 +/- 27 to 116 +/- 5 pmol/microgram DNA, whereas the nonextractable pool increases from 28 +/- 9 to 77 +/- 11 pmol/microgram DNA. Movement of Cu from the nonextractable pool to the extractable pool is slow and incomplete. Using [3H]diamsar, we demonstrate that uptake of the chelator is not rate limiting and probably does not occur by pinocytosis. Incubation with diamsar does not affect the activity of superoxide dismutase or cytochrome-c oxidase, although it does prevent the incorporation of 67Cu into ceruloplasmin. Incubation with zinc, which induces metallothionein, results in an increase in 67Cu associated with the nonextractable pool, suggesting that 67Cu-metallothionein constitutes at least part of the nonextractable pool.

Effects of cellular copper content on copper uptake and metallothionein and ceruloplasmin mRNA levels in mouse hepatocytes.

The intracellular copper content of mouse hepatocytes has been altered by incubating with either increasing amounts of extracellular copper or increasing amounts of diamsar, a copper chelator. Metallothionein 1 (MT1) and MT2 mRNA levels in the cells increased in proportion to the intracellular copper concentration. The degree of stimulation was similar for both MT1 and MT2, with mRNA levels increasing approximately fourfold for a six- to eightfold increase in intracellular copper levels. In contrast, neither copper uptake nor ceruloplasmin mRNA showed any response to intracellular copper levels. Unlike the situation in the rat, there was no clear evidence for saturation of copper uptake. Incubating cells with increasing amounts of 64Cu resulted in a linear increase in the amount taken up over 2 h. The amount of 64Cu accumulated was the same in control and copper-depleted cells, which suggests that neither ceruloplasmin production nor copper uptake is regulated by intracellular copper levels. However, other possibilities, such as the chelators not being able to deplete the pool(s) responsible for the control of ceruloplasmin production or copper uptake, must also be considered.

Effect of chelators on copper metabolism and copper pools in mouse hepatocytes.

Disorders of copper storage are usually treated by chelation therapy. It is generally thought that the chelators act by mobilizing copper from the liver, hence allowing excretion in the urine. This paper has examined the effect of chelators on copper uptake and storage in mouse hepatocytes. Penicillamine, a clinically important chelator, does not block the uptake of copper or remove copper from hepatocytes. Two other copper chelators, sar and diamsar, which form very stable and kinetically inert Cu2+ complexes by encapsulating the metal ion in an organic cage, were shown to block copper accumulation by the cells and to remove up to 80% of cell-associated copper. They also removed most (approximately 80%) of the 64Cu accumulated by the cells in 30 min, but released only a small percentage (less than 20%) of that accumulated over 18 h. The results show that copper in the hepatocyte can be divided into at least two pools, an easily accessible one, and another, not removable even after long-term incubation with any of the chelators. Most of the copper normally found in the cell appeared to be associated with the former pool.