Abstract
ICln is a multifunctional protein involved in regulatory mechanisms as different as membrane ion transport and RNA splicing. The protein is water-soluble, and during regulatory volume decrease after cell swelling, it is able to migrate from the cytosol to the cell membrane. Purified, water-soluble ICln is able to insert into lipid bilayers to form ion channels. Here, we show that ICln<sub>159</sub>, a truncated ICln mutant, which is also able to form ion channels in lipid bilayers, belongs to the pleckstrin homology (PH) domain superfold family of proteins. The ICln PH domain shows unusual properties as it lacks the electrostatic surface polarization seen in classical PH domains. However, similar to many classical PH domain-containing proteins, ICln interacts with protein kinase C, and in addition, interacts with cAMP-dependent protein kinase and cGMP-dependent protein kinase type II but not cGMP-dependent protein kinase type Iβ. A major phosphorylation site for all three kinases is Ser-45 within the ICln PH domain. Furthermore, ICln<sub>159</sub> interacts with LSm4, a protein involved in splicing and mRNA degradation, suggesting that the ICln<sub>159</sub> PH domain may serve as a protein-protein interaction platform.
Highlights
ICln is a multifunctional protein involved in regulatory mechanisms as different as membrane ion transport and RNA splicing
ICln is a multifunctional protein involved in several different regulatory modules within the living cell
The ability of ICln to interact with more than one regulatory module suggests that the water-soluble form of ICln acts as a connector hub [3] for different regulatory mechanisms
Summary
ICln is a multifunctional protein involved in regulatory mechanisms as different as membrane ion transport and RNA splicing. We show that ICln159, a truncated ICln mutant, which is able to form ion channels in lipid bilayers, belongs to the pleckstrin homology (PH) domain superfold family of proteins. ICln159 interacts with LSm4, a protein involved in splicing and mRNA degradation, suggesting that the ICln159 PH domain may serve as a protein-protein interaction platform. ICln is a small (Ϸ25 kDa), multifunctional protein involved in regulatory mechanisms as different as cell volume regulation and RNA splicing [1, 2]. Proteins involved in more than one regulatory mechanisms were recently defined as “connector hubs” [3] and play a pivotal role in cell function. No vital embryos can be obtained in either animal system [2, 4], which suggests a key role of ICln in cell homeostasis
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