JNK-interacting Proteins Research Articles

Manganese disrupts the maturation and degradation of axonal autophagosome leading to hippocampal synaptic toxicity in mice via the activation of LRRK2 on phosphorylation of Rab10

Manganese (Mn) overexposure induces hippocampal synaptotoxicity by the accumulation of dysfunctional synaptic vesicles (SVs). Leucine-rich repeat kinase 2 (LRRK2) kinase activity is involved in regulating axonal transport (autophagosomal maturation) and lysosomal function. Nevertheless, it remains unclear whether Mn-induced synaptotoxicity is associated with the LRRK2-mediated disruption of autophagosomal maturation in axonal transport and the impairment of lysosomes in hippocampal neurons. Here, we established models of manganism in C57BL/6 mice and hippocampal neuronal HT22 cells to verify the role of LRRK2-mediated Rab10 phosphorylation in the Mn-induced dysfunction of autophagy- lysosomal fusion. Our results proved that Mn-induced the disorder of axonal transport and that lysosome impairments were associated with the increased recruitment of phospho-Rab10 at the axon and lysosomes. Next, we established Lrrk2-KD and LRRK2 kinase- specific inhibitor (GNE-0877, GNE) pre-treated HT22 cells to inhibit Lrrk2 gene expression and kinase activity, respectively. In Mn-treated Lrrk2-KD or GNE-pretreated normal neurons, our results indicated that lysosomal pH and integrity and autophagic flow were restored, indicating by decreased levels of phospho-Rab10 on lysosomes and JNK-interacting proteins (JIP4). In addition, GNE pretreatment could provide protection against Mn-induced synaptotoxicity in vivo, which was evidenced by the partial recovery in synaptic plasticity and synaptic damage. Thus, the Mn-induced abnormal activation of LRRK2 affected lysosomes and the recruitment of phospho-Rab10 by JIP4, which disrupted autophagosomal maturation in proximal axons and resulted in the hippocampal synaptic toxicity of mice.

Axonal transport of autophagosomes is regulated by dynein activators JIP3/JIP4 and ARF/RAB GTPases.

Neuronal autophagosomes form and engulf cargos at presynaptic sites in the axon and are then transported to the soma to recycle their cargo. Autophagic vacuoles (AVs) mature en route via fusion with lysosomes to become degradatively competent organelles; transport is driven by the microtubule motor protein cytoplasmic dynein, with motor activity regulated by a sequential series of adaptors. Using lysate-based single-molecule motility assays and live-cell imaging in primary neurons, we show that JNK-interacting proteins 3 (JIP3) and 4 (JIP4) are activating adaptors for dynein that are regulated on autophagosomes and lysosomes by the small GTPases ARF6 and RAB10. GTP-bound ARF6 promotes formation of the JIP3/4-dynein-dynactin complex. Either knockdown or overexpression of RAB10 stalls transport, suggesting that this GTPase is also required to coordinate the opposing activities of bound dynein and kinesin motors. These findings highlight the complex coordination of motor regulation during organelle transport in neurons.

MAPK8IP2 is a potential prognostic biomarker and promote tumor progression in prostate cancer

BackgroundMAPK8IP2 is one of the JNK-interacting proteins (JIPs) family members, and is involved in the regulation of the JNK and P38 MAPK signaling pathways. MAPK8IP2 has been reported to be closely associated with several cancers. However, the biological function of MAPK8IP2 in prostate cancer (PCa) remains unclear.MethodsMAPK8IP2 expression in PCa and subgroups of PCa was analyzed by public databases. The prognostic role of MAPK8IP2 in prostate cancer was analyzed using the Cox regression method. The potential mechanism by which MAPK8IP2 affects PCa progression was investigated by utilizing public data, including genetic alteration, DNA methylation, m6A methylation, and immune infiltration data. We further performed in vitro assays to validate the effect of MAPK8IP2 on PCa cell proliferation, migration and invasion.ResultsMAPK8IP2 is highly expressed in PCa tissues. Overexpression of MAPK8IP2 is associated with adverse clinicopathological factors and a poor prognosis in PCa. Receiver operating curve analysis showed that MAPK8IP2 can distinguish PCa tissues from non-PCa tissues with a certain accuracy (AUC = 0.814). The MAPK8IP2 genetic alteration rate was 2.6% and MAPK8IP2 alterations correlated with a poor prognosis. We also found that CDK12 and TP53 mutations were associated with MAPK8IP2 expression. The DNA methylation level of MAPK8IP2 was higher in primary tumors than in normal tissues, and the high MAPK8IP2 DNA methylation group of PCa patients had poor survival. Enrichment analysis indicated that MAPK8IP2 was involved in the MAPK signaling pathway. In vitro, knockdown of MAPK8IP2 inhibited PCa cell proliferation, migration and invasion.ConclusionMAPK8IP2 is a potential target for PCa treatment and can serve as a novel biomarker for PCa diagnosis and prognosis evaluation.

Structural characterization of the RH1-LZI tandem of JIP3/4 highlights RH1 domains as a cytoskeletal motor-binding motif

JIP3 and JIP4 (JNK-interacting proteins 3 and 4) are adaptors for cargo recruitment by dynein/dynactin and kinesin1 motors. Both are dimers that are stabilised by two sections of leucine zipper coiled coils. The N-terminal Leucine Zipper I (LZI) belongs to a section that binds dynein-DLIC and kinesin1-KHC, whilst the medial Leucine Zipper II (LZII) binds dynactin-p150glued and kinesin1-KLC. Structural data is available for the LZII, but the LZI section is still uncharacterized. Here we characterize the N-terminal part of JIP3/4 which consists of an RH1 (RILP homology 1) domain followed by the LZI coiled coil using bioinformatical, biophysical and structural approaches. The RH1-LZI tandem of JIP3 associates as a high affinity homodimer exhibiting elongated alpha-helical fold. 3D homology modelling of the RH1-LZI tandem reveals that the kinesin1-KHC binding site mainly overlaps with the RH1 domain. A sequence comparison search indicates that only one other protein family has RH1 domains similar to those of JIP3/4, the RILP (Rab-interacting lysosomal protein) family which consists of adaptor proteins linking Rab GTPases to cytoskeletal motors. RILPL2 is recruited through its RH1 domain by the myosin 5a motor. Here, we showed that the RH1 domain of JIP3 also interacts with myosin 5 A in vitro, highlighting JIP3/4 as possible myosin 5a adaptors. Finally, we propose that JIP3/4 and RILP family members define a unique RH1/RH2-architecture adaptor superfamily linking cytoskeletal motors and Rab GTPases.

C-Jun N-Terminal Kinases (JNKs) in Myocardial and Cerebral Ischemia/Reperfusion Injury.

In this article, we review the literature regarding the role of c-Jun N-terminal kinases (JNKs) in cerebral and myocardial ischemia/reperfusion injury. Numerous studies demonstrate that JNK-mediated signaling pathways play an essential role in cerebral and myocardial ischemia/reperfusion injury. JNK-associated mechanisms are involved in preconditioning and post-conditioning of the heart and the brain. The literature and our own studies suggest that JNK inhibitors may exert cardioprotective and neuroprotective properties. The effects of modulating the JNK-depending pathways in the brain and the heart are reviewed. Cardioprotective and neuroprotective mechanisms of JNK inhibitors are discussed in detail including synthetic small molecule inhibitors (AS601245, SP600125, IQ-1S, and SR-3306), ion channel inhibitor GsMTx4, JNK-interacting proteins, inhibitors of mixed-lineage kinase (MLK) and MLK-interacting proteins, inhibitors of glutamate receptors, nitric oxide (NO) donors, and anesthetics. The role of JNKs in ischemia/reperfusion injury of the heart in diabetes mellitus is discussed in the context of comorbidities. According to reviewed literature, JNKs represent promising therapeutic targets for protection of the brain and the heart against ischemic stroke and myocardial infarction, respectively. However, different members of the JNK family exert diverse physiological properties which may not allow for systemic administration of non-specific JNK inhibitors for therapeutic purposes. Currently available candidate JNK inhibitors with high therapeutic potential are identified. The further search for selective JNK3 inhibitors remains an important task.

MLK3 as a regulator of disease progression in Non‐alcoholic steatohepatitis

Non-alcoholic steatohepatitis (NASH) is one of the most common chronic liver diseases worldwide (1). Despite the large number of studies published in the field, the molecular signals triggering the progression of NASH from simple steatosis to necroinflammation are still poorly understood. One of the most important and early features of progressive NASH is lipoapoptosis of hepatocytes that creates a proinflammatory and fibrogenic environment (2, 3). The activation of c-jun N-terminal kinase 1(JNK1) in both hepatocytes and macrophages has been described as a key event in NASH (4, 5), thus the signals governing its induction need to be better elucidated. The article published by Ibrahim et al. (6) has focused on the role of the mixed-lineage kinase 3 (MLK3) as an important proximal JNK activator that has a major role in progressive liver injury in diet-induced NASH. Several studies demonstrated that MLK3/JNK activation plays an essential role in saturated fatty acid-induced insulin resistance and hepatocyte lipotoxicity (7–9). Exposure to free fatty acid induced MLK3/JNK in mouse embryonic fibroblasts, and the MLK3-/- cells displayed increased insulin sensitivity (8); the same trend was found in the MLK3-/- mice on high-fat diet (8, 10). In hepatocytes, palmitate induced the recruitment of cdc42/Rac1 and the activation of MLK3/JNK, leading to downstream ER stress signalling (7). In a different study, the palmitate-induced M1 macrophage polarization was diminished in the MLK3-/- cells (10). All of these suggest that MLK3/JNK signalling plays an important role in the progression of NASH. MLKs are MAPK-kinase kinases (MKKKs) that activate JNK and p38 signalling cascades via the MAPK kinases (MKKs) by either forming a homodimer or associating with Rho GTPases (11–13). The selective activation of MKKs and the downstream induction of JNK1/2 or p38 by MLKs are mediated by the MAPK scaffold proteins such as JNK-interacting proteins (JIPs) (13, 14). How these JIPs direct selective activation of their targets is still under investigation. JIP3 was shown to bind to MLK3/MKK7 inducing JNK1 activation in neurons (14–16). It is however, not clear which JIPs are predominant in the liver and whether they selectively mediate JNK1 and 2 activation. c-Jun N-terminal kinase activation plays a key role in saturated fatty acid-induced hepatocyte apoptosis (5), both in humans and in animal models (17–19). In HSC, phosphorylated-JNK1 directly mediates transdifferentiation contributing to fibrosis (20). MLK3/JNK/P38 activation in LX-2 cells has been observed when cells were stimulated with a PPARβ/δ ligand, leading to cell proliferation (21). JNK1 and JNK2 have differential effects in NASH: JNK1 mediates steatohepatitis and lipotoxicity, whereas JNK2 activation is more protective (22, 23). It is not yet known whether MLK3 has differential effects on JNK1 or JNK2 in the liver, and if so, how the differential induction is mediated. This study is in agreement with previous findings demonstrating that the MLK3-/- mice developed less hepatic steatosis, decreased liver injury, inflammation and fibrosis. The diet used in this study mimics the fast food diet consumed by humans inducing insulin resistance, steatohepatitis and fibrosis (24). It has been recently reported that compared to the WT mice, the global MLK3-deficient mice on high-fat diet displayed significantly less weight gain, and reduced macrophage infiltration in the adipose tissue and also decreased systemic inflammation (10). Interestingly, these mice had increased energy expenditure that could have accounted for the slower weight gain. The improved inflammation in the liver could be explained by the decreased macrophage recruitment and JNK inactivation in the MLK3-/- mice (10). Using the MLK2/3 double knockout mice on the high-fat diet model, Davis and colleagues showed that the obesity-resistant phenotype of these animals was related to the upregulation of the sympatho-adrenal system, as using a selective antagonist to the β3-adrenergic receptor prevented the increase in body temperature and decreased the expression of the adrenergic target genes (25). Distinct from the studies described above, the authors in this study chose high-fat diet combined with high fructose consumption. The mice in this study gained similar amount of weight in both treatment arms, and this could be attributed to the high fructose intake. As fibrosis was diminished in the MLK3-/- mice, it is likely that MLK3 in stellate cells was involved in their transdifferentiation, which has been observed in lung fibroblasts by Lin et al. (26). Macrophage polarization could also be affected by MLK3 (10); and there is evidence showing that MLK3 interacts with TLR signalling by directly binding to Myd88 (27). The dominant cell type and mechanisms for the pro-inflammatory and fibrogenic activity of MLK3 in the liver would require further investigation, and could be addressed in the future by the generation of conditional knockout mice.

Integrated regulation of motor-driven organelle transport by scaffolding proteins.

Intracellular trafficking pathways, including endocytosis, autophagy, and secretion, rely on directed organelle transport driven by the opposing microtubule motor proteins kinesin and dynein. Precise spatial and temporal targeting of vesicles and organelles requires the integrated regulation of these opposing motors, which are often bound simultaneously to the same cargo. Recent progress demonstrates that organelle-associated scaffolding proteins, including Milton/TRAKs (trafficking kinesin-binding protein), JIP1, JIP3 (JNK-interacting proteins), huntingtin, and Hook1, interact with molecular motors to coordinate activity and sustain unidirectional transport. Scaffolding proteins also bind to upstream regulatory proteins, including kinases and GTPases, to modulate transport in the cell. This integration of regulatory control with motor activity allows for cargo-specific changes in the transport or targeting of organelles in response to cues from the complex cellular environment.

Phosphorylation of the M3/6 dual-specificity phosphatase enhances the activation of JNK by arsenite

Specific outcomes upon activation of the c-Jun N-terminal kinase (JNK) pathway critically depend on the intensity and duration of signal transmission. Dual-specificity phosphatases (DUSPs) play a very important role in these events by modulating the extent of JNK phosphorylation and activation and thus regulating cellular responses to stress. M3/6 (DUSP8) is one of the dual-specificity protein phosphatases with distinct specificity towards JNK. It has been shown that M3/6 itself is phosphorylated by JNK upon stimulation with arsenite, but the role of this phosphorylation has not been investigated. In this study, we mapped JNK-induced phosphorylation sites on M3/6 using mass spectrometry. Phosphorylated residues Ser 515, Thr 518 and Ser 520 were identified and site-directed mutagenesis was employed to investigate their role. Upon arsenite stimulation, M3/6 mutated at these sites exhibited decreased phosphorylation compared to the wild-type protein. No difference was observed in terms of the enzyme's in vitro phosphatase activity, its substrate specificity towards JNK isoforms, its interactions with JNK and the scaffold family of JNK-interacting proteins (JIPs), its stability or its subcellular localization. Interestingly, expression of M3/6 phosphorylation mutants delayed the time-course of JNK phosphorylation and activation by arsenite. We propose that phosphorylation of the M3/6 phosphatase by JNK in response to stress stimuli results in attenuation of phosphatase activity and acceleration of JNK activation.

Decoupling of Activation and Effector Binding Underlies ARF6 Priming of Fast Endocytic Recycling

The small GTP-binding protein ADP-ribosylation factor 6 (ARF6) controls the endocytic recycling pathway of several plasma membrane receptors. We analyzed the localization and GDP/GTP cycle of GFP-tagged ARF6 by total internal reflection fluorescent microscopy. We found that ARF6-GFP associates with clathrin-coated pits (CCPs) at the plasma membrane in a GTP-dependent manner in a mechanism requiring the adaptor protein complex AP-2. In CCP, GTP-ARF6 mediates the recruitment of the ARF-binding domain of downstream effectors including JNK-interacting proteins 3 and 4 (JIP3 and JIP4) after the burst recruitment of the clathrin uncoating component auxilin. ARF6 does not contribute to receptor-mediated clathrin-dependent endocytosis. In contrast, we found that interaction of ARF6 and JIPs on endocytic vesicles is required for trafficking of the transferrin receptor in the fast, microtubule-dependent endocytic recycling pathway. Our findings unravel a novel mechanism of separation of ARF6 activation and effector function, ensuring that fast recycling may be determined at the level of receptor incorporation into CCPs.

Regulation of stress-associated scaffold proteins JIP1 and JIP3 on the c-Jun NH2-terminal kinase in ischemia–reperfusion

Ischemia-reperfusion (IR)-induced cell apoptosis involves the activation of c-Jun NH2-terminal kinase (JNK). The activation of JNK requires the presence of scaffold proteins called JNK-interacting proteins (JIP), which bind several members of a signaling cascade for proper signaling specificity. In this study, the expression of scaffold proteins JIP1 and JIP3 and their roles in the regulation of JNK activity were investigated in simulated IR in a cell model (H9c2). JIP1 protein expression was significantly decreased, whereas JIP3 protein expression was increased in IR H9c2 cells. Adenovirus-induced overexpression of JIP1 reduced IR-induced JNK activity and apoptosis. Conversely, overexpression of JIP3 increased JNK activity and apoptosis following IR. Depletion of endogenous JIP1 by siRNA treatment increased the IR-induced JNK activity, whereas siRNA-mediated depletion of endogenous JIP3 inhibited JNK activity. These results suggest that JIP1 and JIP3 play important roles in the activation of JNK during simulated IR challenge in H9c2 cells.

Computational Prediction and Experimental Verification of New MAP Kinase Docking Sites and Substrates Including Gli Transcription Factors

In order to fully understand protein kinase networks, new methods are needed to identify regulators and substrates of kinases, especially for weakly expressed proteins. Here we have developed a hybrid computational search algorithm that combines machine learning and expert knowledge to identify kinase docking sites, and used this algorithm to search the human genome for novel MAP kinase substrates and regulators focused on the JNK family of MAP kinases. Predictions were tested by peptide array followed by rigorous biochemical verification with in vitro binding and kinase assays on wild-type and mutant proteins. Using this procedure, we found new ‘D-site’ class docking sites in previously known JNK substrates (hnRNP-K, PPM1J/PP2Czeta), as well as new JNK-interacting proteins (MLL4, NEIL1). Finally, we identified new D-site-dependent MAPK substrates, including the hedgehog-regulated transcription factors Gli1 and Gli3, suggesting that a direct connection between MAP kinase and hedgehog signaling may occur at the level of these key regulators. These results demonstrate that a genome-wide search for MAP kinase docking sites can be used to find new docking sites and substrates.

Signal Transduction Cross Talk Mediated by Jun N-Terminal Kinase-Interacting Protein and Insulin Receptor Substrate Scaffold Protein Complexes

Scaffold proteins have been established as important mediators of signal transduction specificity. The insulin receptor substrate (IRS) proteins represent a critical group of scaffold proteins that are required for signal transduction by the insulin receptor, including the activation of phosphatidylinositol 3 kinase. The c-Jun NH(2)-terminal kinase (JNK)-interacting proteins (JIPs) represent a different group of scaffold molecules that are implicated in the regulation of the JNK. These two signaling pathways are functionally linked because JNK can phosphorylate IRS1 on the negative regulatory site Ser-307. Here we demonstrate the physical association of these signaling pathways using a proteomic approach that identified insulin-regulated complexes of JIPs together with IRS scaffold proteins. Studies using mice with JIP scaffold protein defects confirm that the JIP1 and JIP2 proteins are required for normal glucose homeostasis. Together, these observations demonstrate that JIP proteins can influence insulin-stimulated signal transduction mediated by IRS proteins.

The structural basis of Arf effector specificity: the crystal structure of ARF6 in a complex with JIP4

The JNK-interacting proteins, JIP3 and JIP4, are specific effectors of the small GTP-binding protein ARF6. The interaction of ARF6-GTP with the second leucine zipper (LZII) domains of JIP3/JIP4 regulates the binding of JIPs to kinesin-1 and dynactin. Here, we report the crystal structure of ARF6-GTP bound to the JIP4-LZII at 1.9 A resolution. The complex is a heterotetramer with dyad symmetry arranged in an ARF6-(JIP4)(2)-ARF6 configuration. Comparison of the ARF6-JIP4 interface with the equivalent region of ARF1 shows the structural basis of JIP4's specificity for ARF6. Using site-directed mutagenesis and surface plasmon resonance, we further show that non-conserved residues at the switch region borders are the key structural determinants of JIP4 specificity. A structure-derived model of the association of the ARF6-JIP3/JIP4 complex with membranes shows that the JIP4-LZII coiled-coil should lie along the membrane to prevent steric hindrances, resulting in only one ARF6 molecule bound. Such a heterotrimeric complex gives insights to better understand the ARF6-mediated motor switch regulatory function.

ARF6 Interacts with JIP4 to Control a Motor Switch Mechanism Regulating Endosome Traffic in Cytokinesis

Recent work has highlighted the importance of the recycling of endocytic membranes to the intercellular bridge for completion of cytokinesis in animal cells. ADP-ribosylation factor 6 (ARF6), which localizes to the plasma membrane and endosomal compartments, regulates endocytic recycling to the bridge during cytokinesis and is required for abscission. Here, we report that the JNK-interacting proteins JIP3 and JIP4, two highly related scaffolding proteins for JNK signaling modules, also acting as binding partners of kinesin-1 and dynactin complex, can function as downstream effectors of ARF6. In vitro, binding of GTP-ARF6 to the second leucine zipper domain of JIP3 and JIP4 interferes with JIPs' association with kinesin-1, whereas it favors JIPs' interaction with the dynactin complex. With protein silencing by small interfering RNA and dominant inhibition approaches, we show that ARF6, JIP4, kinesin-1, and the dynactin complex control the trafficking of recycling endosomes in and out of the intercellular bridge and are necessary for abscission. Our findings reveal a novel function for ARF6 as a regulatory switch for motor proteins of opposing direction that controls trafficking of endocytic vesicles within the intercellular bridge in a mechanism required for abscission.

JNK1 phosphorylation of SCG10 determines microtubule dynamics and axodendritic length

c-Jun NH2-terminal kinases (JNKs) are essential during brain development, when they regulate morphogenic changes involving cell movement and migration. In the adult, JNK determines neuronal cytoarchitecture. To help uncover the molecular effectors for JNKs in these events, we affinity purified JNK-interacting proteins from brain. This revealed that the stathmin family microtubule-destabilizing proteins SCG10, SCLIP, RB3, and RB3′ interact tightly with JNK. Furthermore, SCG10 is also phosphorylated by JNK in vivo on sites that regulate its microtubule depolymerizing activity, serines 62 and 73. SCG10-S73 phosphorylation is significantly decreased in JNK1−/− cortex, indicating that JNK1 phosphorylates SCG10 in developing forebrain. JNK phosphorylation of SCG10 determines axodendritic length in cerebrocortical cultures, and JNK site–phosphorylated SCG10 colocalizes with active JNK in embryonic brain regions undergoing neurite elongation and migration. We demonstrate that inhibition of cytoplasmic JNK and expression of SCG10-62A/73A both inhibited fluorescent tubulin recovery after photobleaching. These data suggest that JNK1 is responsible for regulation of SCG10 depolymerizing activity and neurite elongation during brain development.

Interaction of N-Terminal Acetyltransferase with the Cytoplasmic Domain of -Amyloid Precursor Protein and Its Effect on A Secretion

The processing of beta-amyloid precursor protein (APP) generates the amyloid beta-protein (A beta) and contributes to the development of Alzheimer's disease (AD). Elucidating the regulation of APP processing will, therefore, contribute to the understanding of AD. Many APP-binding proteins, such as FE65, X11s, and JNK-interacting proteins (JIPs), bind the motif 681-GYENPTY-687 within the cytoplasmic domain of APP. Here we found that the human homologue of yeast amino-terminal acetyltransferase ARD1 (hARD1) interacts with a novel motif, 658-HGVVEVD-664, in the cytoplasmic domain of APP695. hARD1 expressed its acetyltransferase activity in association with a human subunit homologous to another yeast amino-acetyltransferase, hNAT1. Co-expression of hARD1 and hNAT1 in cells suppressed A beta40 secretion and the suppression correlated with their enzyme activity. These observations suggest that the association of APP with hARD1 and hNAT1 and/or their N-acetyltransferase activity contributes to the regulation of A beta generation.

Islet-Brain (IB)/JNK-Interacting Proteins (JIPs): Future Targets for the Treatment of Neurodegenerative Diseases?

Islet-Brain (IB) proteins [also called JNK-interacting proteins (JIPs)] are scaffold proteins that are mainly expressed in the pancreatic islets and in the brain. Functionally, the IB family is composed of IB1, IB2, IB3, and IB4 each with distinct splice variants. The IB family of proteins regulates several mitogen-activated protein kinase (MAPK) pathways by tethering their components and modifying the spectrum of substrates targeted by the MAPKs. The expression of these proteins is developmentally regulated, indicating that they play important functions during brain formation. While it is currently unclear what the precise physiological functions of the IB proteins are, there are indications that they participate in subcellular targeting of signalling proteins and modulate cell survival. Synthetic derivatives of these proteins can efficiently counteract apoptotic signalling in cells and tissues and represent therefore promising protective agents against traumatic insults, including stroke and hypoxia. This review will focus on the molecular functions of the IB proteins and their potential implications in the development of several human pathologies.

Differential Roles of JIP Scaffold Proteins in the Modulation of Amyloid Precursor Protein Metabolism

We previously found that the JNK-interacting proteins JIP1b and JIP2 associate with the cytoplasmic domain of the Alzheimer's amyloid precursor protein (APP) (Taru, H., Iijima, K., Hase, M., Kirino, Y., Yagi, Y., and Suzuki, T. (2002) J. Biol. Chem. 277, 20070-20078). This interaction involves the carboxyl-terminal phosphotyrosine interaction (PI) domain of JIP1b or JIP2 and the GYENPTY motif in the APP cytoplasmic domain. The expression of JIP1b stabilizes immature APP and suppresses the production of a secreted large extracellular amino-terminal domain of APP, the generation of a cleaved intracellular carboxyl-terminal fragment of APP, and the secretion of beta-amyloid 40 and 42. Deletion of the PI domain or alteration of PI amino acid residues prevents JIP1b from interacting with APP and affecting its metabolism, but deletion of the JNK-binding domain of JIP1b has no effect. JIP2, a weaker APP-binding protein, does not influence the processing of APP, although it is known that both JIP1b and JIP2 equally regulate the JNK signaling cascade. The present results suggest that JIP1b can directly modulate APP metabolism by interacting with the APP cytoplasmic domain, independent of its regulation of the JNK signaling cascade.

Mixed lineage kinase-dependent JNK activation is governed by interactions of scaffold protein JIP with MAPK module components.

It has been proposed that JNK-interacting proteins (JIP) facilitate mixed lineage kinase-dependent signal transduction to JNK by aggregating the three components of a JNK module. A new model for the assembly and regulation of these modules is proposed based on several observations. First, artificially induced dimerization of dual leucine zipper-bearing kinase (DLK) confirmed that DLK dimerization is sufficient to induce DLK activation. Secondly, under basal conditions, DLK associated with JIP is held in a monomeric, unphosphorylated and catalytically inactive state. Thirdly, JNK recruitment to JIP coincided with significantly decreased affinity of JIP and DLK. JNK promoted the dimerization, phosphorylation and activation of JIP-associated DLK. Similarly, treatment of cells with okadaic acid inhibited DLK association with JIP and resulted in DLK dimerization in the presence of JIP. In summary, JIP maintains DLK in a monomeric, unphosphorylated, inactive state. Upon stimulation, JNK-JIP binding affinity increases while JIP-DLK interaction affinity is attenuated. Dissociation of DLK from JIP results in subsequent DLK dimerization, autophosphorylation and module activation. Evidence is provided that this model holds for other MLK-dependent JNK modules.

Cargo of Kinesin Identified as Jip Scaffolding Proteins and Associated Signaling Molecules

The cargo that the molecular motor kinesin moves along microtubules has been elusive. We searched for binding partners of the COOH terminus of kinesin light chain, which contains tetratricopeptide repeat (TPR) motifs. Three proteins were found, the c-jun NH(2)-terminal kinase (JNK)-interacting proteins (JIPs) JIP-1, JIP-2, and JIP-3, which are scaffolding proteins for the JNK signaling pathway. Concentration of JIPs in nerve terminals requires kinesin, as evident from the analysis of JIP COOH-terminal mutants and dominant negative kinesin constructs. Coprecipitation experiments suggest that kinesin carries the JIP scaffolds preloaded with cytoplasmic (dual leucine zipper-bearing kinase) and transmembrane signaling molecules (the Reelin receptor, ApoER2). These results demonstrate a direct interaction between conventional kinesin and a cargo, indicate that motor proteins are linked to their membranous cargo via scaffolding proteins, and support a role for motor proteins in spatial regulation of signal transduction pathways.