Dimerization of cGMP-dependent protein kinase 1alpha and the myosin-binding subunit of myosin phosphatase: role of leucine zipper domains

Nitric oxide (NO) and nitrovasodilators induce vascular smooth muscle cell relaxation in part by cGMP-dependent protein kinase (cGK)-mediated activation of myosin phosphatase, which dephosphorylates myosin light chains. We recently found that cGMP-dependent protein kinase 1alpha binds directly to the myosin-binding subunit (MBS) of myosin phosphatase via the leucine/isoleucine zipper of cGK. We have now studied the role of the leucine zipper domain of MBS in dimerization with cGK and the leucine/isoleucine zipper and leucine zipper domains of both proteins in homodimerization. Mutagenesis of the MBS leucine zipper domain disrupts cGKIalpha-MBS dimerization. Mutagenesis of the MBS leucine zipper eliminates MBS homodimerization, while similar disruption of the cGKIalpha leucine/isoleucine zipper does not prevent formation of cGK dimers. The MBS leucine zipper domain is phosphorylated by cGK, but this does not have any apparent effect on heterodimer formation between the two proteins. MBS LZ mutants that are unable to bind cGK were poor substrates for cGK. These data support the theory that the MBS leucine zipper domain is necessary and sufficient to mediate both MBS homodimerization and binding of the protein to cGK. In contrast, the leucine/isoleucine zipper of cGK is required for binding to MBS, but not for cGK homodimerization. These data support that the MBS and cGK leucine zipper domains mediate the interaction between these two proteins. The contribution of these domains to both homodimerization and their specific interaction with each other suggest that additional regulatory mechanisms involving these domains may exist.     

Dissociation and unfolding of GCN4 leucine zipper in the presence of sodium dodecyl sulfate.

The dissociation and unfolding behavior of the GCN4 leucine zipper has been studied using SDS titration. Circular dichroism (CD) spectra showed that the alpha-helix content of the leucine zipper (20 microM) decreased during the sodium dodecyl sulfate (SDS) titration. However, the alpha-helix content of the leucine zipper still remained significant in the presence of 1 mM SDS, with little change detected when the SDS concentration further increased to 2 mM. The dimer dissociation of the leucine zipper is also a co-operative process during SDS titration; with no dimer remaining when SDS concentration reached 1 mM, as shown by electrophoresis and the the theta(222)/theta(208) ratio. Our results indicate that SDS efficiently induces leucine zipper dimer dissociation with the monomers still partially folded. The experimental results provide important evidence for the previous model that partial helix formation precedes dimerization in coiled coil folding.     

Leucine zipper-mediated homodimerization of the p21-activated kinase-interacting factor, beta Pix. Implication for a role in cytoskeletal reorganization

Pix, a p21-activated kinase-interacting exchange factor, is known to be involved in the regulation of Cdc42/Rac GTPases. The 85-kDa betaPix-a protein contains an Src homology 3 domain, the tandem Dbl homology and Pleckstrin homology domains, a proline-rich region, and a GIT1-binding domain. In addition to those domains, betaPix-a also contains a putative leucine zipper domain at the C-terminal end. In this study, we demonstrate that the previously identified putative leucine zipper domain mediates the formation of betaPix-a homodimers. Using in vitro and in vivo methodologies, we show that deletion of the leucine zipper domain is sufficient to abolish betaPix-a homodimerization. In NIH3T3 fibroblast cells, expression of wild type betaPix-a induces the formation of membrane ruffles. However, cells expressing the leucine zipper domain deletion mutant could not form membrane ruffle structures. Moreover, platelet-derived growth factor-mediated cytoskeletal changes were completely blocked by the leucine zipper domain deletion mutant. The results suggest that the leucine zipper domain enables betaPix-a to homodimerize, and homodimerization is essential for betaPix-a signaling functions leading to the cytoskeletal reorganization.     

An engineered leucine zipper a position mutant with an unusual three-state unfolding pathway

The leucine zipper is a dimeric coiled-coil structural motif consisting of four to six heptad repeats, designated (abcdefg)(n). In the GCN4 leucine zipper, a position 16 in the third heptad is occupied by an Asn residue whereas the other a positions are Val residues. Recently, we have constructed variants of the GCN4 leucine zipper in which the a position Val residues were replaced by Ile. The folding and unfolding of the wild-type GCN4 leucine zipper and the Val to Ile variant both adhere to a simple two-state mechanism. In this study, another variant of the GCN4 leucine zipper was constructed by moving the single Asn residue from a position 16 to a position 9. This switch causes the thermal unfolding of the GCN4 leucine zipper to become three state. The unfolding pathway of this variant was determined by thermal denaturation, limited proteinase K digestion, and sedimentation equilibrium analysis. Our data are consistent with a model in which the variant first unfolds from its N terminus and changes the oligomerization specificity from a native dimer to a partially unfolded intermediate containing a mixture of dimers and trimers and then completely unfolds to unstructured monomers.     

Homodimerization via a leucine zipper motif is required for enzymatic activity of quiescent cell proline dipeptidase

Quiescent cell proline dipeptidase (QPP) is an intracellular serine protease that is also secreted upon cellular activation. This enzyme cleaves N-terminal Xaa-Pro dipeptides from proteins, an unusual substrate specificity shared with dipeptidyl peptidase IV (CD26/DPPIV). QPP is a 58-kDa protein that elutes as a 120-130-kDa species from gel filtration, indicating that it forms a homodimer. We analyzed this dimerization with in vivo co-immunoprecipitation assays. The amino acid sequence of QPP revealed a putative leucine zipper motif, and mutational analyses indicated that this leucine zipper is required for homodimerization. The leucine zipper mutants showed a complete lack of enzymatic activity, suggesting that homodimerization is important for QPP function. On the other hand, an enzyme active site mutant retained its ability to homodimerize. These data are the first to demonstrate a role for a leucine zipper motif in a proteolytic enzyme and suggest that leucine zipper motifs play a role in mediating dimerization of a diverse array of proteins.     

Leucine zipper-mediated homodimerization of the adaptor protein c-Cbl. A role in c-Cbl's tyrosine phosphorylation and its association with epidermal growth factor receptor.

The 120-kDa proto-oncogenic protein c-Cbl is a multidomain adaptor protein that is phosphorylated in response to the stimulation of a broad range of cell surface receptors and participates in the assembly of signaling complexes that are formed as a result of the activation of various signal transduction pathways. Several structural features of c-Cbl, including the phosphotyrosine-binding domain, proline-rich domain, and motifs containing phosphotyrosine and phosphoserine residues, mediate the association of c-Cbl with other components of these complexes. In addition to those domains that have been demonstrated to play a role in the binding of c-Cbl to other signaling molecules, c-Cbl also contains a RING finger motif and a putative leucine zipper. In this study, we demonstrate that the previously identified putative leucine zipper mediates the formation of Cbl homodimers. Using the yeast two-hybrid system, we show that deletion of the leucine zipper domain is sufficient to abolish Cbl homodimerization, while Cbl mutants carrying extensive N-terminal truncations retain the ability to dimerize with the full-length Cbl. The requirement of the leucine zipper for the homodimerization of Cbl was confirmed by in vitro binding assays, using deletion variants of the C-terminal half of Cbl with and without the leucine zipper domain, and in cells using Myc and green fluorescent protein (GFP) N-terminal-tagged Cbl variants. In cells, the deletion of the leucine zipper caused a decrease in both the tyrosine phosphorylation of Cbl and its association with the epidermal growth factor receptor following stimulation with epidermal growth factor, thus demonstrating a role for the leucine zipper in c-Cbl's signaling functions. Thus, the leucine zipper domain enables c-Cbl to homodimerize, and homodimerization influences Cbl's signaling function, modulating the activity of Cbl itself and/or affecting Cbl's associations with other signaling proteins in the cell.     

Identification of structural and functional domains in mixed lineage kinase dual leucine zipper-bearing kinase required for complex formation and stress-activated protein kinase activation

Accumulating evidence suggests that mitogen-activated protein kinase signaling pathways form modular signaling complexes. Because the mixed lineage kinase dual leucine zipper-bearing kinase (DLK) is a large modular protein, structure-function analysis was undertaken to examine the role of DLK domains in macromolecular complex formation. DLK mutants were used to demonstrate that a DLK leucine zipper-leucine zipper interaction is necessary for DLK dimerization and to show that DLK dimerization mediated by the leucine zipper domain is prerequisite for DLK activity and subsequent activation of stress-activated protein kinase (SAPK). Heterologous mixed lineage kinase family members can be co-immunoprecipitated. However, the DLK leucine zipper domain interacted specifically only with the DLK leucine zipper domain; in contrast, DLK NH(2)-terminal region was sufficient to co-immunoprecipitate leucine zipper kinase and DLK. DLK has been shown to associate with the putative scaffold protein JIP1. This association occurred through the DLK NH(2)-terminal region and occurred independently of DLK catalytic activity. Although the DLK NH(2)-terminal region associated directly with JIP-1, this region did not interact directly with either DLK or leucine zipper kinase. Therefore, DLK may interact with heterologous mixed lineage kinase proteins via intermediary proteins. The NH(2)-terminal region of overexpressed DLK was required for activation of SAPK. These results provide evidence that protein complex formation is required for signal transduction from DLK to SAPK.     

Methionine-containing zipper peptides

Using circular dichroism, we have examined the effect of single and multiple methionine mutations on the dimerization function of a previously reported engineered leucine zipper peptide. Our results show that the methionine-containing zipper peptides self-associate to form coiled coils that are less stable than that of the reference leucine zipper. The circular dichroism data also indicate that leucine at position d is more tolerant of methionine substitution than isoleucine at position a.     

Structure-based design of a leucine zipper protein with new DNA contacting region

We have employed a structure-based design to construct a small folding domain from the F-actin bundling protein villin that contains the amino acids necessary for the DNA binding of the basic leucine zipper protein GCN4 and have compared its DNA binding with GCN4. The monomeric motif folds into a stable domain and binds DNA in a rigid-body mechanism, while its affinity is not higher than that of the basic region peptide. The addition of the leucine zipper region to the folded domain restored its sequence-specific DNA binding comparable to that of GCN4. Unlike the monomeric folded domain, its leucine zipper derivative undergoes a conformational change upon DNA binding. CD spectral and thermodynamic studies indicate that the DNA-contacting region is folded in the presence or absence of DNA and suggest that the junction between the DNA-contacting and the leucine zipper regions transits to a helix in the presence of DNA. These results demonstrate that the structural transition outside the direct-contacting region, which adjusts the precise location of the DNA-contacting region, plays a critical role in the specific complex formation of basic leucine zipper proteins.     

A Leucine Zipper Motif Essential for Gating of Hyperpolarization-activated Channels

Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels are pacemakers in cardiac myocytes and neurons. Although their membrane topology closely resembles that of voltage-gated K⁺ channels, the mechanism of their unique gating behavior in response to hyperpolarization is still poorly understood. We have identified a highly conserved leucine zipper motif in the S5 segment of HCN family members. In order to study the role of this motif for channel function, the leucine residues of the zipper were individually mutated to alanine, arginine, or glutamine residues. Leucine zipper mutants traffic to the plasma membrane, but the channels lose their sensitivity to open upon hyperpolarization. Thus, our data indicate that the leucine zipper is an important molecular determinant for hyperpolarization-activated channel gating. Residues of the leucine zipper interact with the adjacent S6 segment of the channel. This interaction is essential for voltage-dependent gating of the channel. The lower part of the leucine zipper, at the intracellular mouth of the channel, is important for stabilizing the closed state. Mutations at these sites increase current amplitudes or result in channels with deficient closing and increased min-P_o. Our data are further supported by homology models of the open and closed state of the HCN2 channel pore. Thus, we conclude that the leucine zipper of HCN channels is a major determinant for hyperpolarization-activated channel gating.     

Analysis of CYS3 regulator function in Neurospora crassa by modification of leucine zipper dimerization specificity.

The CYS3 positive regulator is a basic region-leucine zipper (bZIP) DNA-binding protein that is essential for the expression of sulfur-controlled structural genes in Neurospora crassa. An approach of modifying the dimerization specificity of the CYS3 leucine zipper was used to determine whether the in vivo regulatory function of CYS3 requires the formation of homodimeric or heterodimeric complexes. Two altered versions of CYS3 with coiled coil elecrostatic interactions favorable to heterodimerization showed restoration of wild-type CYS3 function only when simultaneously expressed in a delta cys-3 strain. In addition, constructs having the CYS3 leucine zipper swapped for that of the oncoprotein Jun or the CYS3 leucine zipper extended by a heptad repeat showed wild-type CYS3 function when transformed into a delta cys-3 strain. Gel mobility shift and immunoprecipitation assays were used to confirm the modified CYS3 proteins dimerization and DNA binding properties. The studies, which precluded wild-type CYS3 dimerization, indicate that in vivo CYS3 is fully functional as a homodimer since no interaction was required with other leucine zipper proteins to activate sulfur regulatory and structural gene expression. The results demonstrate the utility of leucine zipper modification to study the in vivo function of bZIP proteins.     

Methionine-containing zipper peptides

Summary Using circular dichroism, we have examined the effect of single and multiple methionine mutations on the dimerization function of a previously reported engineered leucine zipper peptide. Our results show that the methionine-containing zipper peptides self-associate to form coiled coils that are less stable than that of the reference leucine zipper. The circular dichroism data also indicate that leucine at positiond is more tolerant of methionine substitution than isoleucine at positiona.     

A leucine zipper-based peptide hybrid delivers functional Nanog protein inside the cell nucleus

We synthesized a pair of compounds containing leucine zipper peptides to deliver protein cargo into cells. One is a cell-penetrating peptide (CPP) with Lz(E), a leucine zipper peptide containing negatively charged amino acids, and the other is a Nanog protein with Lz(K), a leucine zipper peptide containing positively charged amino acids. When cells were treated with these equimolar mixtures, Nanog-Lz(K) hybridized with Lz(E)-CPP was successfully delivered into the cells. Furthermore, Nanog-Lz(K) exerted its proper function after nuclear transport.     

Activity of the human centrosomal kinase, Nek2, depends on an unusual leucine zipper dimerization motif.

Nek2 is a human cell cycle-regulated kinase that is structurally related to the mitotic regulator, NIMA, of Aspergillus nidulans. Localization studies have shown that Nek2 is a core component of the centrosome, the microtubule organizing center of the cell, and functional approaches suggest a possible role for Nek2 in centrosome separation at the G2/M transition. Here, we have investigated the importance of an unusual leucine zipper coiled-coil motif present in the C-terminal noncatalytic domain of the Nek2 kinase. Glycerol gradient centrifugation indicated that endogenous Nek2 is present in HeLa cells as a salt-resistant 6 S complex, the predicted size of a Nek2 homodimer. Recombinant Nek2 overexpressed in insect cells also formed a 6 S complex, whereas a Nek2 mutant specifically lacking the leucine zipper motif was monomeric. Using yeast two-hybrid interaction analyses and coprecipitation assays, we found that Nek2 can indeed form homodimers both in vivo and in vitro and that this dimerization specifically required the leucine zipper motif. Moreover, deletion of the leucine zipper prevented a trans-autophosphorylation reaction on the C-terminal domain of Nek2 and strongly reduced Nek2 kinase activity on exogenous substrates. Finally, we emphasize that the Nek2 leucine zipper described here differs from classical leucine zippers in that it exhibits a radically different arrangement of hydrophobic and charged amino acids. Thus, this study reveals not only an important mechanism for the regulation of the Nek2 kinase but, furthermore, highlights an unusual organization of a leucine zipper dimerization motif.