Function and regulation of the scaffold protein IB1/JIP-1 in the uro-genital tract.

RESUME Ce mémoire de thèse traite de l'étude de la « scaffold »protéine ou protéine «échafaud», « Islet-Brain1/ JNK Interacting Protein 1 » (IB1/JIP-1) dans la vessie et la prostate, deux organes importants de l'appareil uro-genital. Cette protéine, mise en évidence dans notre laboratoire à la fin des année 90, a été reconnue pour réguler la voie de signalisation des « Mitogen-Activated Protein Kinases » (MAPKs), et en particulier de la MAPK appelée c-Jun N-terminal Kinase (JNK). Le réseau de voie de signalisation permet aux cellules de percevoir les changements dans le milieu extracellulaire et de permettre une réponse appropriée à ces différents stimuli. La connaissance des voies de signalisation a permis de mettre en évidence leur rôle crucial tant dans l'homéostase des tissus sains que dans des processus pathologiques comme l'oncogenèse. Parmi une vingtaine de voie de signalisation, la voie de signalisation des «MAPKinases » est une des plus importantes et a été montrée pour participer à diverses fonctions cellulaires telles que la différentiation, la motilité, la division et la mort cellulaire. La voie de signalisation des « MAPKinases » est typiquement constituée d'un module de trois kinases qui s'activent séquentiellement par phosphorylation. On note la présence d'une MAPK, d'un activateur de MAPK et d'un activateur de l'activateur de MAPK. Une fois la MAPK activée, elle permettra la régulation de différentes cibles dont certain facteur de transcription. Chez les mammifères, il existe 3 grands groupes de MAPKs : the extracellular signal-regulated kinase 1 and 2 (ERK 1/2) cascade, qui régule préférentiellement la croissance et la différentiation cellulaire, ainsi que les cascades JNK et p38 qui régulent préférentiellement la réponse à différents stress cellulaires telle que l'inflammation ou l'apoptose. JNK est activé par différents stress cellulaire telle que les cytokines inflammatoires. JNK est également requis au cours du développement embryonnaire et contribue à la mort (apoptose) ou à la prolifération cellulaire. Plusieurs études ont mis en évidence le rôle de JNK durant le processus tumoral, sans que son rôle soit clairement identifié. JNK pourrait avoir des fonctions différentes durant l'initiation puis de la progression tumorale. Chez les mammifères, les voies de signalisation intracellulaires forment un réseau complexe et elles interagissent entre elles, ce qui permet aux cellules une réponse adéquate aux multitudes de stimuli existants dans les organismes pluricellulaires. Parmi plusieurs mécanismes de régulation, les protéines dites « scaffold » ou «échafaud » jouent un rôle crucial dans l'homéostase de la voie de signalisation des «MAPKinase ». L'introduction revoit brièvement ces différents aspects, de la voie de signalisation des «MAPKinase et des connaissance sur IB1/JIP-1. Les premières études effectuées sur IB1/JIP-1 ont montré une expression relativement spécifique de cette protéine dans certains types de neurones ainsi que dans la cellule beta-sécrétrice d'insuline. IB1/JIP-1 régule la voie de signalisation JNK par interaction avec les différents composants du module, modifiant ainsi le spectre de substrats activés par JNK. La fonction précise de IB1/JIP-1 n'était pas encore élucidée, mais plusieurs travaux mettaient en lumière un rôle dans la régulation, et la sous-location cellulaire des composants de la voie de signalisation JNK, ainsi que dans la survie cellulaire à certain stress. Cette expression relativement spécifique est intrigante car elle suggère que sa présence serait nécessaire à une régulation spécifique de la MAPKinase JNK ou à certaines autres fonctions cellulaires également spécifiques de certains tissus. Le premier but de ce travail a consisté à mettre en évidence l'expression de IB1/JIP-1 dans l'appareil uro-génital et plus particulièrement dans la vessie et la prostate. Nos résultats ont montré que IB1/JIP-1 est spécifiquement exprimé au niveau de l'urothélium vésical, mais pas dans le muscle lisse. Il en est de même au niveau de la prostate où IB1/JIP-1 est exprimé spécifiquement au niveau de l'épithélium sécrétoire et absent au niveau du stroma fibro-musculaire. La vessie et la prostate sont des organes ou l'activité JNK pourrait être crucial tant dans l' homeostase tissulaire que dans le développement de pathologies bénignes ou malignes. La vessie et la prostate sont le siège fréquent de tumeur. La base pour le développement du cancer est complexe et implique plusieurs anomalies génétiques. Ce processus complexe lié au développement tumoral est encore loin d`être complètement élucidé, raison pour laquelle il est crucial de poursuivre l'étude des différents gènes pouvant être impliqué dans ces processus ou pouvant être utilisé comme outil thérapeutique. Dans l'urothelium de la vessie, la fonction de la MAPK JNK n'a été que très peu étudiée. Il existe quelques études, in vitro, suggérant une implication possible de cette voie de signalisation dans des processus telle que le développement ou la progression tumorale. Le chapitre 1 décrit une étude in vivo dans la vessie un modèle de stress mécanique, connu pour activer les MAPKinase. La dilatation vésicale, due à une obstruction urétrale, a mis en évidence une diminution de l'expression de IB1/JIP-1 ainsi qu'une activation de la MAPKinase JNK. Dans ce modèle, la régulation de IB1/JIP-1, par l'intermédiaire d'un vecteur viral, a permis de démontrer que IB1/JIP-1 régulait l'activité de JNK dans ce tissu. Pour poursuivre l'étude de cette fonction d' IB1/JIP-1 dans l'urothélium, nous avons investigué l'activité JNK dans des souris génétiquement modifiées et porteuse d'une délétion de 1 des 2 allèles du gène codant pour IB1/JIP-1, avec un contenu en IB1/JIP-1 diminué de moitié. L'activation de JNK est également augmentée dans l'urothelium au repos de ces souris, ce qui confirme la fonction régulatrice de JNK par IB1/JIP-1. Ces résultats ont permis de mettre en évidence un rôle critique de celle-ci dans l'homéostase de I`urothelium et suggère une nouvelle cible pour réguler la voie de signalisation dans ce tissu. En outre, la modulation des niveaux d'expression d'IB1/JIP-1 dans la vessie, in vivo, par l'intermédiaire de vecteurs viraux s'est révélée réalisable et indique un moyen élégant pour développer une thérapie génique dans cet organe. Un autre élément de ce travail de thèse, révélée au chapitre 2, a été d'étudier la régulation dans la vessie de rat de la communication intercellulaire de type « GAP ». Les cellules adjacentes partagent des ions, messagers secondaires et des petits métabolites par l'intermédiaire de canaux intercellulaire qui forment les jonctions de type « GAP ». Ce type de communications intercellulaire permet une activité cellulaire coordonnée, une caractéristique importante pour l'homéostase des organismes multicellulaire. Ce type de communication intercellulaire est formé de 2 demi-canaux appelés connexons. Chaque connexon est formé de six protéines appelées connexins (Cx). Il existe environ vingt connexines différentes nommées par leur poids moléculaire respectif. Les jonctions de type canaux "GAP" permettent aux cellules de communiquer avec les cellules voisines au quelles elles sont mécaniquement ou électriquement couplées. La vessie peut être particulièrement dépendante de la communication intercellulaire par les canaux « Gap » qui permettrait de coordonner la réponse de la musculature ainsi que de l'urothélium à l'augmentation de la pression transmurale du à l'accumulation d'urine, situation fréquemment observée dans le cadre de l'hyperplasie bénigne de la prostate. Dans la vessie de rat, la connexine26 est exprimée uniquement dans l'urothelium. La Cx26, a été montrée pour être un possible « tumor suppressor gene » dans le cancer de vessie. Une augmentation de la Cx26 ainsi que du couplage des cellules urothéliales a été démontré dans notre modèle de stress mécanique sur la vessie de rat et est dépendante de 2 éléments de réponses connues pour interagir avec AP-1. La régulation de IB1/JIP-1 a permis de montrer que celle-ci régulait l'activité JNK, ainsi que l'activité du facteur de transcription AP-1, composé de c-Jun lui-même cible de JNK. Cette réduction de l'activité de AP-1 est associée à une diminution de l'expression du transcipt de la Cx26. En résumé, la Cx26 pourrait être régulée par le complexe AP-1 lui-même dépendant du contenu en IB1/JIP-1. Dans le chapitre 3, l'étude de IB1/J1P-1 s'est portée sur la prostate. Cet organe, siège fréquent de pathologie telle que le cancer ou l'hyperplasie bénigne de la prostate, exprime IB1/JIP-1 au niveau de son épithélium sécrétoire. Cette expression est maintenue dans une lignée cellulaire humaine largement étudiée est reconnue comme un modèle adéquat de cellules tumorales de type androgène-sensible. IB1/JIP-1 a été investigué dans un modèle in vitro d'apoptose en réponse à un agent appelé N-(4-hydroxyphenyl)retinamide (4-HPR) qui induit une activation de la MAPK JNK ainsi que également un diminution du contenu en IB1/JIP-1. La surexpression de IB1/JIP-1 en utilisant à nouveau des virus comme vecteur a démontré que IB1/JIP-1 était capable de réguler l'activité de JNK ainsi que les taux d'apoptose. Dans le cancer de la prostate, certains travaux ont montré que la différentiation neuroendocrine des cellules tumorales est associée à la progression tumorale et à la perte de sensibilité aux androgènes. Ce travail a permis de dévoiler l'augmentation d'expression de IB1/JIP-1 dans un modèle de neurodifferentiation des cellules d'une lignée prostatique humaine (LNCaP). Les mécanismes qui permettent une expression spécifique de IB1/JIP-1 ont été partiellement investiguée dans notre laboratoire. Son promoteur humain contient un « Neuron Restricive Silencer Element » (NRSE) connu pour se lier a répresseur transcriptionel appelé « RE-1 Silencer Transcription Factor » ou « Neuron Restrictive Silencer Factor » (REST/NRSF). NRSF/REST est capable de réprimer l'expression de gènes neuronaux en dehors du système neuronal. Il prend part à la différentiation terminale des gènes neuronaux. Dans le chapitre 3, on observe que l'activité de REST/NRSF est diminuée dans les cellules LNCaP qui se transdifferencient de manière neuroendocrine, et que REST/NRSF est capable de moduler l'expression de ces gènes cibles dans ce type cellulaire. Ces travaux laissent suggérer que NRSF/REST participe à l'acquisition du phénotype neuroendocrinien et pourrait être une cible pour réguler ce phénomène. En conclusion, ce travail de thèse présente l'expression de IB1/JIP-1 dans 2 organes de l'appareil uro-génital ; la vessie et la prostate. La fonction de IB1/JIP-1 a été étudiée in vivo dans la vessie de rat, ce qui a mis en évidence sa fonction régulatrice de l'activité de la MAPKinase JNK, et de l'activité du facteur de transcription AP-1 ; ainsi que sa possible implication régulatrice de gène cible tel que la Connexin 26 (Cx26). AP-1 et la Cx26 pourraient jouer un rôle dans le processus oncologique, tant dans le control de l'invasion cellulaire ou le control de la croissance cellulaire. Dans la prostate, IB1/JIP-1 régule également l'activité JNK; crucial dans la transmission de certains stimulis pro-apoptotiques. Dans un modèle de transdifférenciation neuroendocrinienne, phénotype possiblement lié au caractère agressif du cancer de la prostate, l'expression de IB1/JIP-1 est augmenté, suggérant soit un rôle possible dans le développement du phénotype neuronal ou une implication dans une fonction anti-apoptotique. Ce travail a donc permis d'élargir nos connaissances sur la régulation et le control de la voie de signalisation des MAPKinases par IB1/JIP-1, qui pourrait avoir encore d'autres fonctions dans ces tissus.

The scaffold protein IB1/JIP-1 is a critical mediator of cytokine-induced apoptosis in pancreatic beta cells.

In insulin-secreting cells, cytokines activate the c-Jun N-terminal kinase (JNK), which contributes to a cell signaling towards apoptosis. The JNK activation requires the presence of the murine scaffold protein JNK-interacting protein 1 (JIP-1) or human Islet-brain 1(IB1), which organizes MLK3, MKK7 and JNK for proper signaling specificity. Here, we used adenovirus-mediated gene transfer to modulate IB1/JIP-1 cellular content in order to investigate the contribution of IB1/JIP-1 to beta-cell survival. Exposure of the insulin-producing cell line INS-1 or isolated rat pancreatic islets to cytokines (interferon-gamma, tumor necrosis factor-alpha and interleukin-1beta) induced a marked reduction of IB1/JIP-1 content and a concomitant increase in JNK activity and apoptosis rate. This JNK-induced pro-apoptotic program was prevented in INS-1 cells by overproducing IB1/JIP-1 and this effect was associated with inhibition of caspase-3 cleavage. Conversely, reducing IB1/JIP-1 content in INS-1 cells and isolated pancreatic islets induced a robust increase in basal and cytokine-stimulated apoptosis. In heterozygous mice carrying a selective disruption of the IB1/JIP-1 gene, the reduction in IB1/JIP-1 content in happloinsufficient isolated pancreatic islets was associated with an increased JNK activity and basal apoptosis. These data demonstrate that modulation of the IB1-JIP-1 content in beta cells is a crucial regulator of JNK signaling pathway and of cytokine-induced apoptosis.

The scaffold protein IB1/JIP-1 controls the activation of JNK in rat stressed urothelium.

The c-Jun N-terminal kinase (JNK) is critical for cell survival, differentiation, apoptosis and tumorigenesis. This signalling pathway requires the presence of the scaffold protein Islet-Brain1/c-Jun N-terminal kinase interacting protein-1 (IB1/JIP-1). Immunolabeling and in situ hybridisation of bladder sections showed that IB1/JIP-1 is expressed in urothelial cells. The functional role of IB1/JIP-1 in the urothelium was therefore studied in vivo in a model of complete rat bladder outlet obstruction. This parietal stress, which is due to urine retention, reduced the content of IB1/JIP-1 in urothelial cells and consequently induced a drastic increase in JNK activity and AP-1 binding activity. Using a viral gene transfer approach, the stress-induced activation of JNK was prevented by overexpressing IB1/JIP-1. Conversely, the JNK activity was increased in urothelial cells where the IB1/JIP-1 content was experimentally reduced using an antisense RNA strategy. Furthermore, JNK activation was found to be increased in non-stressed urothelial cells of heterozygous mice carrying a selective disruption of the IB1/JIP-1 gene. These data established that mechanical stress in urothelial cells in vivo induces a robust JNK activation as a consequence of regulated expression of the scaffold protein IB1/JIP-1. This result highlights a critical role for that scaffold protein in the homeostasis of the urothelium and unravels a new potential target to regulate the JNK pathway in this tissue.

Crystallization and preliminary crystallographic characterization of an SH3 domain from the IB1 scaffold protein.

IB1 is a mammalian scaffold protein that interacts with components of the c-Jun N-terminal kinase (JNK) signal-transduction pathway mainly via its protein-protein interaction domains. Crystallization of the key Src homology 3 (SH3) domain of IB1 has been achieved. Crystallization experiments with unmodified protein and deliberately oxidized protein have led to different crystal forms. X-ray data have been collected to 3.0 A resolution from a crystal form with rectangular prism morphology. These crystals are orthorhombic (P2(1)2(1)2(1)), with unit-cell parameters a = 45.9, b = 57.0, c = 145.5 A. These are the first crystallographic data on a scaffold molecule such as IB1 to be reported.

Connexin26 is regulated in rat urothelium by the scaffold protein IB1/JIP-1.

Proper function of the wall of bladder requires gap junctional communication for coordinating the responses of smooth muscle (SMC) and urothelial cells exposed to urine pressure. In the rat bladder, Cx43 is expressed by SMC and urothelial cells, whereas Cx26 expression is restricted to the epithelium. We used a model of bladder outlet obstruction, in which a ligature is placed around the urethra to increase voiding pressure. Increased fluid pressure was associated with increased Cx43 and Cx26 mRNA expression and with the activation of a signaling cascade including the transcription factor c-Jun, which is a component of the AP-1 complex. The signaling pathway of the c-Jun NH2 terminal kinase (JNK) requires the presence of the scaffold protein Islet-Brain1/c-Jun amino-terminal kinase Interacting Protein-1 (IB1/JIP-1). Under stress conditions resulting from urine retention, we have found a reduced content of IB1/JIP-1 in urothelial cells, which in turn induced a drastic increase of JNK and AP-1 binding activities. The stress-induced activation of JNK was prevented by overexpressing IB1/JIP-1, using a viral gene transfer approach, a condition which also resulted in a decrease in Cx26 mRNA. The data show that: 1) mechanical stress of urothelial cells activates in vivo JNK, as a consequence of a regulated expression of IB1/JIP-1 and 2) that urothelial Cx26 may be directly regulated by the AP-1 complex.

Microtubule-associated protein 1B, a growth-associated and phosphorylated scaffold protein.

Microtubule-associated protein 1B, MAP1B, is one of the major growth associated and cytoskeletal proteins in neuronal and glial cells. It is present as a full length protein or may be fragmented into a heavy chain and a light chain. It is essential to stabilize microtubules during the elongation of dendrites and neurites and is involved in the dynamics of morphological structures such as microtubules, microfilaments and growth cones. MAP1B function is modulated by phosphorylation and influences microtubule stability, microfilaments and growth cone motility. Considering its large size, several interactions with a variety of other proteins have been reported and there is increasing evidence that MAP1B plays a crucial role in the stability of the cytoskeleton and may have other cellular functions. Here we review molecular and functional aspects of this protein, evoke its role as a scaffold protein and have a look at several pathologies where the protein may be involved.

Increased vulnerability to kainic acid-induced epileptic seizures in mice underexpressing the scaffold protein Islet-Brain 1/JIP-1.

Islet-Brain 1, also known as JNK-interacting protein-1 (IB1/JIP-1) is a scaffold protein mainly involved in the regulation of the pro-apoptotic signalling cascade mediated by c-Jun-N-terminal kinase (JNK). IB1/JIP-1 organizes JNK and upstream kinases in a complex that facilitates JNK activation. However, overexpression of IB1/JIP-1 in neurons in vitro has been reported to result in inhibition of JNK activation and protection against cellular stress and apoptosis. The occurrence and the functional significance of stress-induced modulations of IB1/JIP-1 levels in vivo are not known. We investigated the regulation of IB1/JIP-1 in mouse hippocampus after systemic administration of kainic acid (KA), in wild-type mice as well as in mice hemizygous for the gene MAPK8IP1, encoding for IB1/JIP-1. We show here that IB1/JIP-1 is upregulated transiently in the hippocampus of normal mice, reaching a peak 8 h after seizure induction. Heterozygous mutant mice underexpressing IB1/JIP-1 showed a higher vulnerability to the epileptogenic properties of KA, whereas hippocampal IB1/JIP-1 levels remained unchanged after seizure induction. Subsequently, an increasing activation of JNK in the 8 h following seizure induction was observed in IB1/JIP-1 haploinsufficient mice, which also underwent more severe excitotoxic lesions in hippocampal CA3, as assessed histologically 3 days after KA administration. Taken together, these data indicate that IB1/JIP-1 in hippocampus participates in the regulation of the neuronal response to excitotoxic stress in a level-dependent fashion.

The scaffold protein KSR1, a novel therapeutic target for the treatment of Merlin-deficient tumors

Merlin has broad tumor-suppressor functions as its mutations have been identified in multiple benign tumors and malignant cancers. In all schwannomas, the majority of meningiomas and 1/3 of ependymomas Merlin loss is causative. In neurofibromatosis type 2, a dominantly inherited tumor disease because of the loss of Merlin, patients suffer from multiple nervous system tumors and die on average around age 40. Chemotherapy is not effective and tumor localization and multiplicity make surgery and radiosurgery challenging and morbidity is often considerable. Thus, a new therapeutic approach is needed for these tumors. Using a primary human in vitro model for Merlin-deficient tumors, we report that the Ras/Raf/mitogen-activated protein, extracellular signal-regulated kinase kinase (MEK)/extracellular signal-regulated kinase (ERK) scaffold, kinase suppressor of Ras 1 (KSR1), has a vital role in promoting schwannomas development. We show that KSR1 overexpression is involved in many pathological phenotypes caused by Merlin loss, namely multipolar morphology, enhanced cell-matrix adhesion, focal adhesion and, most importantly, increased proliferation and survival. Our data demonstrate that KSR1 has a wider role than MEK1/2 in the development of schwannomas because adhesion is more dependent on KSR1 than MEK1/2. Immunoprecipitation analysis reveals that KSR1 is a novel binding partner of Merlin, which suppresses KSR1's function by inhibiting the binding between KSR1 and c-Raf. Our proteomic analysis also demonstrates that KSR1 interacts with several Merlin downstream effectors, including E3 ubiquitin ligase CRL4DCAF1. Further functional studies suggests that KSR1 and DCAF1 may co-operate to regulate schwannomas formation. Taken together, these findings suggest that KSR1 serves as a potential therapeutic target for Merlin-deficient tumors.

CNK1 scaffold protein and its role in the regulations of NF-KB signalling

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Compartmentalization of the MAPK scaffold protein KSR1 modulates synaptic plasticity in hippocampal neurons

ERK1/2 is required for certain forms of synaptic plasticity, including the long-term potentiation of synaptic strength. However, the molecular mechanisms regulating synaptically localized ERK1/2 signaling are poorly understood. Here, we show that the MAPK scaffold protein kinase suppressor of Ras 1 (KSR1) is directly phosphorylated by the downstream kinase ERK1/2. Quantitative Western blot analysis further demonstrates that expression of mutated, feedback-deficient KSR1 promotes sustained ERK1/2 activation in HEK293 cells in response to EGF stimulation, compared to a more transient activation in control cells expressing wild-type KSR1. Immunocytochemistry and confocal imaging of primary hippocampal neurons from newborn C57BL6 mice further show that feedback phosphorylation of KSR1 significantly reduces its localization to dendritic spines. This effect can be reversed by tetrodotoxin (1 μM) or PD184352 (2 μM) treatment, further suggesting that neuronal activity and phosphorylation by ERK1/2 lead to KSR1 removal from the postsynaptic compartment. Consequently, electrophysiological recordings in hippocampal neurons expressing wild-type or feedback-deficient KSR1 demonstrate that KSR1 feedback phosphorylation restricts the potentiation of excitatory postsynaptic currents. Our findings, therefore, suggest that feedback phosphorylation of the scaffold protein KSR1 prevents excessive ERK1/2 signaling in the postsynaptic compartment and thus contributes to maintaining physiological levels of synaptic excitability. © FASEB.

Islet-brain1/C-Jun N-terminal kinase interacting protein-1 (IB1/JIP-1) promoter variant is associated with Alzheimer's disease.

Islet-brain1 (IB1) or c-Jun NH2 terminal kinase interacting protein-1 (JIP-1), the product of the MAPK8IP1 gene, functions as a neuronal scaffold protein to allow signalling specificity. IB1/JIP-1 interacts with many cellular components including the reelin receptor ApoER2, the low-density lipoprotein receptor-related protein (LRP), kinesin and the Alzheimer's amyloid precursor protein. Coexpression of IB1/JIP-1 with other components of the c-Jun NH2 terminal-kinase (JNK) pathway activates the JNK activity; conversely, selective disruption of IB1/JIP-1 in mice reduces the stress-induced apoptosis of neuronal cells. We therefore hypothesized that IB1/JIP-1 is a risk factor for Alzheimer's disease (AD). By immunocytochemistry, we first colocalized the presence of IB1/JIP-1 with JNK and phosphorylated tau in neurofibrillary tangles. We next identified a -499A>G polymorphism in the 5' regulatory region of the MAPK8IP1 gene. In two separate French populations the -499A>G polymorphism of MAPK8IP1 was not associated with an increased risk to AD. However, when stratified on the +766C>T polymorphism of exon 3 of the LRP gene, the IB1/JIP-1 polymorphism was strongly associated with AD in subjects bearing the CC genotype in the LRP gene. The functional consequences of the -499A>G polymorphism of MAPK8IP1 was investigated in vitro. In neuronal cells, the G allele increased transcriptional activity and was associated with an enhanced binding activity. Taken together, these data indicate that the increased transcriptional activity in the presence of the G allele of MAPK8IP1 is a risk factor to the onset of in patients bearing the CC genotype of the LRP gene.

Thyrotropin-releasing hormone-stimulated thyrotropin expression involves islet-brain-1/c-Jun N-terminal kinase interacting protein-1.

Islet-brain-1 (IB1)/c-Jun N-terminal kinase interacting protein 1 (JIP-1) is a scaffold protein that is expressed at high levels in neurons and the endocrine pancreas. IB1/JIP-1 interacts with the c-Jun N-terminal kinase and mediates the specific physiological stimuli (such as cytokines). However, the potential role of the protein in the pituitary has not been evaluated. Herein, we examined expression of the gene encoding IB1/JIP-1 and its translated product in the anterior pituitary gland and a pituitary cell line, GH3. We then examined the potential role of IB1/JIP-1 in controlling TSH-beta gene expression. Exposure of GH3 cells to TRH stimulated the expression of IB1/JIP-1 protein levels, mRNA, and transcription of the promoter. The increase of IB1/JIP-1 content by transient transfection study of a vector encoding IB1/JIP-1 or by the stimulation of TRH stimulates TSH-beta promoter activity. This effect is not found in the presence of a mutated nonfunctional (IB1S59N) IB1/JIP-1 protein. Together, these facts point to a central role of the IB1/JIP-1 protein in the control of TRH-mediated TSH-beta stimulation.

Nuclear scaffold proteins are differently sensitive to stabilizing treatment by heat or Cu++.

The distribution of three nuclear scaffold proteins (of which one is a component of a particular class of nuclear bodies) has been studied in intact K562 human erythroleukemia cells, isolated nuclei, and nuclear scaffolds. Nuclear scaffolds were obtained by extraction with the ionic detergent lithium diidosalicylate (LIS), using nuclei prepared in the absence of divalent cations (metal-depleted nuclei) and stabilized either by a brief heat exposure (20 min at 37C or 42C) or by Cu++ ions at 0C. Proteins were visualized by in situ immunocytochemistry and confocal microscopy. Only a 160-kD nuclear scaffold protein was unaffected by all the stabilization procedures performed on isolated nuclei. However, LIS extraction and scaffold preparation procedures markedly modified the distribution of the polypeptide seen in intact cells, unless stabilization had been performed by Cu++. In isolated nuclei, only Cu++ treatment preserved the original distribution of the two other antigens (M(r), 125 and 126 kD), whereas in heat-stabilized nuclei we detected dramatic changes. In nuclear scaffolds reacted with antibodies to 125 and 126-kD proteins, the fluorescent pattern was always disarranged regardless of the stabilization procedure. These results, obtained with nuclei prepared in the absence of Mg+2 ions, indicate that heat treatment per se can induce changes in the distribution of nuclear proteins, at variance with previous suggestions. Nevertheless, each of the proteins we have studied behaves in a different way, possibly because of its specific association with the nuclear scaffold.

Islet-brain1/JNK-interacting protein-1 is required for early embryogenesis in mice.

Islet-brain1/JNK-interacting protein-1 (IB1/JIP-1) is a scaffold protein that organizes the JNK, MKK7, and MLK1 to allow signaling specificity. Targeted disruption of the gene MAPK8IP1 encoding IB1/JIP-1 in mice led to embryonic death prior to blastocyst implantation. In culture, no IB1/JIP-1(-/-) embryos were identified indicating that accelerated cell death occurred during the first cell cycles. IB1/JIP-1 expression was detected in unfertilized oocytes, in spermatozoa, and in different stages of embryo development. Thus, despite the maternal and paternal transmission of the IB1/JIP-1 protein, early transcription of the MAPK8IP1 gene is required for the survival of the fertilized oocytes.

cDNA cloning and mapping of a novel islet-brain/JNK-interacting protein.

IB1/JIP-1 is a scaffold protein that regulates the c-Jun NH(2)-terminal kinase (JNK) signaling pathway, which is activated by environmental stresses and/or by treatment with proinflammatory cytokines including IL-1beta and TNF-alpha. The JNKs play an essential role in many biological processes, including the maturation and differentiation of immune cells and the apoptosis of cell targets of the immune system. IB1 is expressed predominantly in brain and pancreatic beta-cells where it protects cells from proapoptotic programs. Recently, a mutation in the amino-terminus of IB1 was associated with diabetes. A novel isoform, IB2, was cloned and characterized. Overall, both IB1 and IB2 proteins share a very similar organization, with a JNK-binding domain, a Src homology 3 domain, a phosphotyrosine-interacting domain, and polyacidic and polyproline stretches located at similar positions. The IB2 gene (HGMW-approved symbol MAPK8IP2) maps to human chromosome 22q13 and contains 10 coding exons. Northern and RT-PCR analyses indicate that IB2 is expressed in brain and in pancreatic cells, including insulin-secreting cells. IB2 interacts with both JNK and the JNK-kinase MKK7. In addition, ectopic expression of the JNK-binding domain of IB2 decreases IL-1beta-induced pancreatic beta-cell death. These data establish IB2 as a novel scaffold protein that regulates the JNK signaling pathway in brain and pancreatic beta-cells and indicate that IB2 represents a novel candidate gene for diabetes.