Abstract
Copper is an essential co-factor for several key metabolic processes. This requirement in humans is underscored by Menkes disease, an X-linked copper deficiency disorder caused by mutations in the copper transporting P-type ATPase, MNK. MNK is located in the trans-Golgi network where it transports copper to secreted cuproenzymes. Increases in copper concentration stimulate the trafficking of MNK to the plasma membrane where it effluxes copper. In this study, a Menkes disease mutation, G1019D, located in the large cytoplasmic loop of MNK, was characterized in transfected cultured cells. In copper-limiting conditions the G1019D mutant protein was retained in the endoplasmic reticulum. However, this mislocalization was corrected by the addition of copper to cells via a process that was dependent upon the copper binding sites at the N-terminal region of MNK. Reduced growth temperature and the chemical chaperone, glycerol, were found to correct the mislocalization of the G1019D mutant, suggesting this mutation interferes with protein folding in the secretory pathway. These findings identify G1019D as the first conditional mutation associated with Menkes disease and demonstrate correction of the mislocalized protein by copper supplementation. Our findings provide a molecular framework for understanding how mutations that affect the proper folding of the MNK transporter in Menkes patients may be responsive to parenteral copper therapy.
Highlights
Copper is essential for the growth and development of all organisms
We investigated the consequences of the G1019D mutation on the cell biology of the MNK copper transporter
In vitro mutagenesis was used to generate the G1019D mutation in a plasmid bearing the MNK cDNA. Both wild type MNK (WtMNK) and the G1019D mutant protein were stably expressed in the immortalized fibroblast cell line, Me32a
Summary
Copper is essential for the growth and development of all organisms. Several key metabolic processes are copper-dependent, including oxidative respiration, neurotransmitter synthesis, connective tissue formation, free radical detoxification, iron homeostasis, and pigmentation [1]. Our study reports the first conditional Menkes disease mutation that affects secretion and maturation of the transporter and demonstrates correction of this defect by copper supplementation. We further increased the media copper levels to an excess concentration of 100 M Cu, which is known to bring about copper-induced trafficking of MNK to the plasma membrane, as shown for the WtMNK protein (Fig. 2G).
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