The expression of chloride channels is essential for the stabilization of membrane potential in skeletal muscle. Myotonia congenita is a skeletal muscle disorder associated with mutations in the CLCN1 gene (chromosome 7q), which encodes the voltage-gated chloride channel, CLC-1. Previous studies from our lab have demonstrated that despite the presence of a diminished whole-cell current density, the myotonia-related CLC-1 mutant A531V displays no detectable gating defects. Yet the A531V mutant is associated to a defective endoplasmic reticulum export and a reduction in the total protein expression that can be attributed to enhanced proteasomal degradation. Co-expression with Ub-K0 or dominant negative (DN)-CUL4A/4B increased the protein expression level of CLC-1, suggesting that the CRL4 E3 ligase system may mediate the ubiquitination and thus the proteasome degradation of CLC-1 proteins. Furthermore, over-expression of Hsc70, FKBP8, Aha1, or HOP also promoted CLC-1 expression, implying that the Hsp70-Hsp90 system may contribute to CLC-1 protein folding and stability. Elevated expression level of CLC-1 proteins, however, does not prove that the recued CLC-1 proteins are trafficked to cell surface and display proper chloride channel function. Hence, in this study, we aim to apply electrophysiological techniques to determine whether the Hsp70-Hsp90 and the CRL4 proteasome degradation systems modulate functional CLC-1 expression. Our results show that Aha1, FKBP8, HOP, Hsp90α/β, or Hsc/Hsp70 enhanced the functional expression WT and A531V CLC-1 channels. CLC-1 currents were also increased upon suppression of CRL4 function (by MLN4924 or DN-CUL4A/4B) or ubiquitin chain formation (by Ub-K0). Together, our data suggest that the Hsp70-Hsp90 system and the CRL4 proteasome degradation systems can indeed modulate the functional expression CLC-1 channels through the regulation of the biosynthesis of the channel protein.