Cytosolic copper-binding proteins in rat and mouse hepatocytes incubated continuously with Cu(II).

The proteins that bind copper when it first enters cells are likely to play roles in its intracellular distribution and utilization. When hepatocytes were incubated with 64Cu(II), the time-dependence of the subcellular distribution of 64Cu was consistent with one or more cytosolic proteins distributing copper to the mitochondrial and nuclear fractions. Cytosolic copper was reproducibly distributed among four protein fractions from Sephadex G-150 columns at the earliest time (1 min) and at the lowest concentration used 2 microM-64Cu(II)] with both rat and mouse hepatocytes. Copper binding to proteins in these functions was sensitive to copper metabolic status. Hepatocytes from nutritionally copper-deficient rats or neonatal (9-30 days old) developing rats showed an inverse correlation between copper binding to metallothionein and copper binding to proteins in fraction I (approximately 88 kDa apparent) and fraction II (approximately 38 kDa apparent). The distribution of cytosolic 64Cu from the brindled-mouse model of Menkes disease indicated decreased binding by a protein in fraction I. Brindled-mouse hepatocytes also contain decreased levels of a approximately 55 kDa protein or subunit, which most likely represents a liver-specific secondary response to the primary defect. The results are consistent with one or more copper-binding proteins in fractions I and II having significant functions in intracellular copper metabolism.