Myotonia congenita, a hereditary neuromuscular disorder that disrupts skeletal muscle relaxation, is caused by mutations in the human CLCN1 gene on chromosome 7. The function of human CLC-1 chloride channels (CLC-1) is to regulate the membrane excitability of skeletal muscles. Myotonia congenita-related mutations are known to alter the voltage dependence and open probability of CLC-1 channels, as well as the biogenesis and the subcellular distribution of the Cl- channel. Recent evidence further indicates that myotonia congenita mutation may enhance the degradation of CLC-1 channels. In this thesis, we aim to decipher the proteasomal degradation mechanism of CLC-1 channels by studying the wild type (WT) and the mutant A531V. The substrate specificity of the ubiquitin-conjugation system is mainly mediated by E3 ligases. By treating with MLN4924, we examine the E3 ligase of CLC-1 belongs to CRLs. To find E3 ligases of CLC-1, we choose CUL constructs that has dominant-negative effects to co-express with CLC-1. We find that DN-CUL4A and DN-CUL4B increase the total protein expression level of CLC-1. DN-CUL4A also reduced the ubiquitination level of CLC-1. We further find the adaptor, DDB1, and the substrate receptor, CRBN, of CRL4s by using co-immunoprecipitation. Furthermore, we find that DN-CRBN could increase the total protein expression level of CLC-1 as well as reduce the ubiquitination level of CLC-1by, prolong the protein half-life via cycloheximide treatment. Moreover, we discover that co-expression CLC-1 with DN-CUL4A or DN-CUL4B can enhance CLC-1 protein trafficking to cell membrane by biotinylation technique. We also proved that the mutation related to myotonia congenita, A531V, has more significant effect to DN-RING domain E3 ligase comparing to wild type CLC-1. These results are consistent with the mutant type were more significant than wild-type. In addition, in order to understand how ubiquitin is covalently linked to CLC-1 protein via specific residues, can use different sites of lysine to form different types of ubiquitin chain, co-expressed CLC-1 WT and A531V proteins with various ubiquitin constructs harboring different lysine mutations. In this result, we find that ubiquitin covalently linked to CLC-1 by using K48 residues, which would be recognized by proteasome.