LIM domains regulate protein kinase C activity: a novel molecular function.

Enigma homolog protein 1 (ENH1) acts as a scaffold that selectively associates protein kinases and transcription factors with cytoskeletal elements. ENH1 comprises an N-terminal PDZ domain and three C-terminal LIM domains. Through the LIM domains ENH1 interacts with the N-terminal region of protein kinase C ßI (PKCßI). Here, we show that when ENH1 is co-expressed, PKCßI is translocated from the cytoplasm to the plasma membrane in the absence of any other stimulation. Moreover expression of ENH1 markedly increases PKCßI activity in the absence of PKC activators. A similar activation of PKCßI was observed with co-expression of Cypher1 or Enigma, but not other LIM proteins. The region including the three LIM domains of ENH1 (residues 415-591) appears to be sufficient for this PKCßI activation. Finally, interaction with ENH1 also increases the activity of PKCα and PKCγ, whereas it reduces PKCζ activity. These findings provide strong evidence that ENH1 activates conventional PKCs by directly binding through its LIM domains. Thus, LIM domains have a novel molecular function: the regulation of PKC activities in a PKC isoform-specific manner.

A PKC epsilon-ENH-channel complex specifically modulates N-type Ca2+ channels.

Multiple protein kinase C (PKC) isozymes are present in neurons, where they regulate a variety of cellular functions. Due to the lack of specific PKC isozyme inhibitors, it remains unknown how PKC acts on its selective target(s) and achieves its specific actions. Here we show that a PKC binding protein, enigma homolog (ENH), interacts specifically with both PKCepsilon and N-type Ca2+ channels, forming a PKCepsilon-ENH-Ca2+ channel macromolecular complex. Coexpression of ENH facilitated modulation of N-type Ca2+ channel activity by PKC. Disruption of the complex reduced the potentiation of the channel activity by PKC in neurons. Thus, ENH, by interacting specifically with both PKCepsilon and the N-type Ca2+ channel, targets a specific PKC to its substrate to form a functional signaling complex, which is the molecular mechanism for the specificity and efficiency of PKC signaling.