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  • Title: Identification of a novel di-leucine motif mediating K(+)/Cl(-) cotransporter KCC2 constitutive endocytosis.
    Author: Zhao B, Wong AY, Murshid A, Bowie D, Presley JF, Bedford FK.
    Journal: Cell Signal; 2008 Oct; 20(10):1769-79. PubMed ID: 18625303.
    Abstract:
    The neuron-specific potassium-chloride cotransporter 2 (KCC2) plays a crucial role, by controlling chloride extrusion, in the development and maintenance of inhibitory neurotransmission. Although it is now well established that activity-dependent mechanisms can down regulate KCC2 gene expression, the role of post-translational mechanisms in controlling KCC2 expression, specifically at the cell-surface, are poorly understood. We therefore set out to identify the mechanisms and motifs regulating KCC2 endocytosis, one important pathway that may control KCC2 membrane expression. Using a fluorescence-based assay, we show KCC2 when expressed in HEK293 cells is constitutively internalized via a dynamin- and clathrin-dependent pathway. Consistent with this, we demonstrate KCC2 from adult mouse brain associates in vivo with the clathrin-binding adaptor protein-2 (AP-2) complex. Using an endocytosis reporter system, we identify the presence of an autonomous endocytosis motif in the carboxyl cytoplasmic terminus of KCC2. By site-directed mutagenesis we define this novel KCC2 endocytic motif as a non-canonical di-leucine motif, (657)LLXXEE(662). Finally by mutating this motif in the context of full-length KCC2 we demonstrate that this novel KCC2 endocytic motif is essential for the constitutive internalization of KCC2 and for binding to the AP-2 complex. Subsequent sequence analysis reveals this motif is highly conserved between the closely related K(+)/Cl(-) family members that mediate chloride efflux, but absent from the more distant related cotransporters controlling chloride influx. In conclusion, our results indicate constitutive internalization of KCC2 is clathrin-mediated and dependent on the binding of AP-2 to this novel endocytic motif. Furthermore, that this process appears to be an evolutionarily conserved mechanism amongst functionally homologous cotransporters.
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