Induction of ABCA1 Expression Is Correlated With Increased CREB Phosphorylation and Altered Cytokine Secretion

Zaid, Maryam

18 April 2011

ABCA1 is believed to affect macrophage inflammatory responses, but the mechanism by which ABCA1 may impact cytokine secretion in macrophages has yet to be fully defined. We observed that the induction of ABCA1 expression in three different cell lines, namely BHK, RAW 264.7 macrophages, and primary bone marrow derived macrophages (BMDMs), results in a significant increase in phosphorylated CREB, a known protein kinase A (PKA) substrate. In RAW macrophages, induction of ABCA1 expression by the LXR-agonist T0901317 is correlated with a decrease in LPS-stimulated secretion of proinflammatory cytokines IL-6 and TNF-α. Additionally, the secretion of anti-inflammatory cytokine IL-10 was increased upon ABCA1 induction. A similar trend was observed in BMDMS: ABCA1-expressing BMDMs released less TNF-α and more IL-10 compared to ABCA1-knockout BMDMs. We speculated that the inflammation modulating effects of ABCA1 in macrophages could be a result of PKA activation. Indeed, we found that the LXR-induced ABCA1 phenotype can be mimicked by cAMP in macrophages. 8-bromo-cAMP, a PKA activator, dose-dependently suppressed inflammatory cytokine secretion while promoting IL-10 release in the absence of ABCA1 expression. Finally, we found that the T0901317-induced ABCA1 expression is correlated with higher expression levels of MKP-1, a downstream target of PKA known to suppress inflammatory responses. Together, our results suggest that ABCA1 expression may activate PKA and CREB and that such activation may contribute to the inflammatory modulating effects of ABCA1.

ABCA1

atherosclerosis

LXR-agonist

CREB

MKP-1

PKA

inflammation

Induction of ABCA1 Expression Is Correlated With Increased CREB Phosphorylation and Altered Cytokine Secretion

Zaid, Maryam

18 April 2011

ABCA1 is believed to affect macrophage inflammatory responses, but the mechanism by which ABCA1 may impact cytokine secretion in macrophages has yet to be fully defined. We observed that the induction of ABCA1 expression in three different cell lines, namely BHK, RAW 264.7 macrophages, and primary bone marrow derived macrophages (BMDMs), results in a significant increase in phosphorylated CREB, a known protein kinase A (PKA) substrate. In RAW macrophages, induction of ABCA1 expression by the LXR-agonist T0901317 is correlated with a decrease in LPS-stimulated secretion of proinflammatory cytokines IL-6 and TNF-α. Additionally, the secretion of anti-inflammatory cytokine IL-10 was increased upon ABCA1 induction. A similar trend was observed in BMDMS: ABCA1-expressing BMDMs released less TNF-α and more IL-10 compared to ABCA1-knockout BMDMs. We speculated that the inflammation modulating effects of ABCA1 in macrophages could be a result of PKA activation. Indeed, we found that the LXR-induced ABCA1 phenotype can be mimicked by cAMP in macrophages. 8-bromo-cAMP, a PKA activator, dose-dependently suppressed inflammatory cytokine secretion while promoting IL-10 release in the absence of ABCA1 expression. Finally, we found that the T0901317-induced ABCA1 expression is correlated with higher expression levels of MKP-1, a downstream target of PKA known to suppress inflammatory responses. Together, our results suggest that ABCA1 expression may activate PKA and CREB and that such activation may contribute to the inflammatory modulating effects of ABCA1.

ABCA1

atherosclerosis

LXR-agonist

CREB

MKP-1

PKA

inflammation

Unconventional forms of synaptic plasticity in the hippocampus and the striatum

Liu, Zhi

11 1900

Synaptic transmission occurs as a result of either a spontaneous release of presynaptic vesicles or a batch release of presynaptic vesicles driven by action potentials. The physiological consequence of synaptic transmission driven by different patterns and frequencies of presynaptic stimulation has been extensively investigated. However, the physiological nature, mechanism as well as relevance of prolonged presynaptic stimulation have been poorly characterized. In this dissertation, I present three projects in which prolonged stimulation of synaptic transmission in different forms and different brain regions was studied for its effect on synaptic transmission, mechanisms and physiological relevance. In the first project, prolonged electrical stimulation (100 sec) at high frequency induced a deep synaptic depression in acute hippocampal slices, followed by a recovery of synaptic transmission after ~15 min. The deep synaptic depression was attributed to a complete depletion of presynaptic vesicle pools. In the second project, attempts were made to characterize the mechanism of nuclear activation of gene transcription induced by prolonged electrical stimulation (100 sec). Our results demonstrated that reduced inactivation of non-L-type calcium channels failed to provide calcium required for gene transcription, leaving the activation of gene transcription a selective function for L-type calcium channels. In the third project, we sought to study the physiological relevance of enhanced miniature events of inhibitory synapses induced by prolonged chemical stimulation. We showed that prolonged application (2 min) of nicotine to the striatal slice enhanced the frequency of miniature inhibitory currents that was accompanied with a reduction in the amplitude of evoked response. This reduction in the amplitude of evoked responses was ascribed to a compromised action potential invasion of presynaptic terminals possibly due to inactivation of sodium channels resulting from nicotine-induced depolarization. To summarize, prolonged stimulation of presynaptic vesicle release imposes significant influence upon neuron-to-neuron communication, with distinct mechanisms in different brain regions.

Hippocampus

Striatum

CREB

Synaptic transmission

Voltage-gated calcium channel

Unconventional forms of synaptic plasticity in the hippocampus and the striatum

Liu, Zhi

11 1900

Synaptic transmission occurs as a result of either a spontaneous release of presynaptic vesicles or a batch release of presynaptic vesicles driven by action potentials. The physiological consequence of synaptic transmission driven by different patterns and frequencies of presynaptic stimulation has been extensively investigated. However, the physiological nature, mechanism as well as relevance of prolonged presynaptic stimulation have been poorly characterized. In this dissertation, I present three projects in which prolonged stimulation of synaptic transmission in different forms and different brain regions was studied for its effect on synaptic transmission, mechanisms and physiological relevance. In the first project, prolonged electrical stimulation (100 sec) at high frequency induced a deep synaptic depression in acute hippocampal slices, followed by a recovery of synaptic transmission after ~15 min. The deep synaptic depression was attributed to a complete depletion of presynaptic vesicle pools. In the second project, attempts were made to characterize the mechanism of nuclear activation of gene transcription induced by prolonged electrical stimulation (100 sec). Our results demonstrated that reduced inactivation of non-L-type calcium channels failed to provide calcium required for gene transcription, leaving the activation of gene transcription a selective function for L-type calcium channels. In the third project, we sought to study the physiological relevance of enhanced miniature events of inhibitory synapses induced by prolonged chemical stimulation. We showed that prolonged application (2 min) of nicotine to the striatal slice enhanced the frequency of miniature inhibitory currents that was accompanied with a reduction in the amplitude of evoked response. This reduction in the amplitude of evoked responses was ascribed to a compromised action potential invasion of presynaptic terminals possibly due to inactivation of sodium channels resulting from nicotine-induced depolarization. To summarize, prolonged stimulation of presynaptic vesicle release imposes significant influence upon neuron-to-neuron communication, with distinct mechanisms in different brain regions.

Hippocampus

Striatum

CREB

Synaptic transmission

Voltage-gated calcium channel

LIMK1 Regulation of Long-term Memory and Synaptic Plasticity

Todorovski, Zarko

16 December 2013

The LIM-Kinase family of proteins (LIMK) plays an important role in actin dynamics through its regulation of ADF/cofilin. A subtype of LIMK, LIMK1, is mostly expressed in neuronal tissues with high levels in the mature synapse. Previous studies from the Zhen Ping Jia laboratory have shown that LIMK1-/- mice exhibit abnormal spine morphology as well as altered hippocampal synaptic plasticity. LIMK1 has been shown to interact with CREB during neuronal development (Yang et al., 2004). We propose that LIMK1 is able to phosphorylate CREB in response to a synaptic activity. We hypothesize that if LIMK1 activates CREB in mature neurons, then LIMK1 knockout mice will have decreased L-LTP and deficits in long-term memory. My results show that LIMK1 and CREB exist in a complex and are bound to each other in mature neurons. LIMK1-/- mice exhibit deficits in the late phase of long-term potentiation and specific deficits in long-term memory while short-term memory remains unaltered. Pharmacological activation of CREB attenuates the observed deficits in synaptic plasticity and long-term memory. These results show a potentially novel mechanism of CREB activation in response to synaptic activity. Moreover, using peptides to manipulate actin dynamics in LIMK1 lacking animals only has effects on early LTP and is not able to rescue the late phase LTP deficits found in LIMK1 -/- mice. These results indicate a specific role of LIMK1 long-term memory and synaptic plasticity through regulation of CREB and not through regulation of the actin cytoskeleton.

synaptic plasticity

learning and memory

LTP

LIMK1

CREB

0317

LIMK1 Regulation of Long-term Memory and Synaptic Plasticity

Todorovski, Zarko

16 December 2013

The LIM-Kinase family of proteins (LIMK) plays an important role in actin dynamics through its regulation of ADF/cofilin. A subtype of LIMK, LIMK1, is mostly expressed in neuronal tissues with high levels in the mature synapse. Previous studies from the Zhen Ping Jia laboratory have shown that LIMK1-/- mice exhibit abnormal spine morphology as well as altered hippocampal synaptic plasticity. LIMK1 has been shown to interact with CREB during neuronal development (Yang et al., 2004). We propose that LIMK1 is able to phosphorylate CREB in response to a synaptic activity. We hypothesize that if LIMK1 activates CREB in mature neurons, then LIMK1 knockout mice will have decreased L-LTP and deficits in long-term memory. My results show that LIMK1 and CREB exist in a complex and are bound to each other in mature neurons. LIMK1-/- mice exhibit deficits in the late phase of long-term potentiation and specific deficits in long-term memory while short-term memory remains unaltered. Pharmacological activation of CREB attenuates the observed deficits in synaptic plasticity and long-term memory. These results show a potentially novel mechanism of CREB activation in response to synaptic activity. Moreover, using peptides to manipulate actin dynamics in LIMK1 lacking animals only has effects on early LTP and is not able to rescue the late phase LTP deficits found in LIMK1 -/- mice. These results indicate a specific role of LIMK1 long-term memory and synaptic plasticity through regulation of CREB and not through regulation of the actin cytoskeleton.

synaptic plasticity

learning and memory

LTP

LIMK1

CREB

0317

Induction of ABCA1 Expression Is Correlated With Increased CREB Phosphorylation and Altered Cytokine Secretion

Zaid, Maryam

18 April 2011

ABCA1 is believed to affect macrophage inflammatory responses, but the mechanism by which ABCA1 may impact cytokine secretion in macrophages has yet to be fully defined. We observed that the induction of ABCA1 expression in three different cell lines, namely BHK, RAW 264.7 macrophages, and primary bone marrow derived macrophages (BMDMs), results in a significant increase in phosphorylated CREB, a known protein kinase A (PKA) substrate. In RAW macrophages, induction of ABCA1 expression by the LXR-agonist T0901317 is correlated with a decrease in LPS-stimulated secretion of proinflammatory cytokines IL-6 and TNF-α. Additionally, the secretion of anti-inflammatory cytokine IL-10 was increased upon ABCA1 induction. A similar trend was observed in BMDMS: ABCA1-expressing BMDMs released less TNF-α and more IL-10 compared to ABCA1-knockout BMDMs. We speculated that the inflammation modulating effects of ABCA1 in macrophages could be a result of PKA activation. Indeed, we found that the LXR-induced ABCA1 phenotype can be mimicked by cAMP in macrophages. 8-bromo-cAMP, a PKA activator, dose-dependently suppressed inflammatory cytokine secretion while promoting IL-10 release in the absence of ABCA1 expression. Finally, we found that the T0901317-induced ABCA1 expression is correlated with higher expression levels of MKP-1, a downstream target of PKA known to suppress inflammatory responses. Together, our results suggest that ABCA1 expression may activate PKA and CREB and that such activation may contribute to the inflammatory modulating effects of ABCA1.

ABCA1

atherosclerosis

LXR-agonist

CREB

MKP-1

PKA

inflammation

The Essential Role of the Crtc2-CREB Pathway in β Cell Function and Survival

Eberhard, Chandra

23 January 2013

Immunosuppressants that target the serine/threonine phosphatase calcineurin are commonly administered following organ transplantation. Their chronic use is associated with reduced insulin secretion and new onset diabetes in a subset of patients, suggestive of pancreatic β cell dysfunction. Calcineurin plays a critical role in the activation of CREB, a key transcription factor required for β cell function and survival. CREB activity in the islet is activated by glucose and cAMP, in large part due to activation of Crtc2, a critical coactivator for CREB. Previous studies have demonstrated that Crtc2 activation is dependent on dephosphorylation regulated by calcineurin. In this study, we sought to evaluate the impact of calcineurin-inhibiting immunosuppressants on Crtc2-CREB activation in the primary β cell. In addition, we further characterized the role and regulation of Crtc2 in the β cell. We demonstrate that Crtc2 is required for glucose dependent up-regulation of CREB target genes. The phosphatase calcineurin and kinase regulation by LKB1 contribute to the phosphorylation status of Crtc2 in the β cell. CsA and FK506 block glucose-dependent dephosphorylation and nuclear translocation of Crtc2. Overexpression of a constitutively active mutant of Crtc2 that cannot be phosphorylated at Ser171 and Ser275 enables CREB activity under conditions of calcineurin inhibition. Furthermore, β cells lacking Crtc2 display impaired glucose-stimulated insulin secretion and cell survival. Together, these results demonstrate that phosphorylation of Crtc2 plays a critical role in regulating CREB activity and contributes to β cell dysfunction and death caused by chronic immunosuppression.

Diabetes

Insulin

Creb

Crtc2

Calcineurin

Phosphorylation

beta cell

Ο ρόλος του μεταγραφικού παράγοντα CREB σε καρκινικά κύτταρα του δέρματος

Πυριόχου, Διονυσία

08 January 2013

Σήμερα ο καρκίνος του δέρματος αποτελεί την πιο κοινή μορφή καρκίνου. Κάθε χρόνο στις ΗΠΑ πάνω απο ένα εκατομμύριο άνθρωποι προσβάλλονται απο κάποια μορφή καρκίνου του δέρματος. Οι τρεις κύριες κατηγορίες δερματικών καρκίνων είναι το Βασικοκυτταρικό καρκίνωμα (BCC), το Ακανθοκυτταρικό καρκίνωμα (SCC) και το Μελάνωμα, με τις δύο πρώτες να αποτελούν πιο ήπιες μορφές καρκίνου με σαφώς καλύτερη πρόγνωση σε σχέση με το μελάνωμα. Ο στόχος αυτής της εργασία είναι να διερευνήσει το ρόλος του μεταγράφικου παράγοντα CREB σε καρκινικά κύτταρα του δέρματος. Ο CREB ρυθμίζει την έκφραση γονιδίων που εμπλέκονται στην επιβίωση, τον πολλαπλασιασμό και το μεταβολισμό της γλουκόζης καθώς και γονίδια που σχετίζονται με τον καρκίνο. ‘Εχει αποδειχθεί οτι ο CREB υπερεκφράζεται ή βρίσκεται στην ενεργή φωσφωριλιωμένη του μορφή σχεδόν σε όλους τους τύπους καρκίνου. Στον καρκίνο του δέρματος υπάρχει ενεργοποίηση και υπερέκφραση του CREB κατά την εξέλιξη προς κακοήθη φαινότυπο. Ξέρουμε επίσης οτι η μεταστατική ικανότητα του μελανώματος σχετίζεται με τη δραστηριότητα και υπερέκφραση του CREB. Παρόλα αυτά η έρευνα σχετικά με τον ρόλο του CREB στον καρκίνο του δέρματος βρίσκεται ακόμα σε πρώιμο στάδιο. Ο στόχος αυτής της ερευνητικής εργασίας είναι να διερευνήσει τον ρόλο του CREB στον καρκίνο του δέρματος και πιο συγκεκριμένα στοχεύουμε να μελετήσουμε την έκφραση του pCREB και του CREB σε δείγματα ασθενών, να εξακριβώσουμε ποιά είναι τα γονίδια-στόχοι του CREB κατά την ογκογένεση και μετάσταση, καθώς και τον αριθμό των αντιτύπων του σε καρκινικές κυτταρικές σειρές και να δημιουργήσουμε stable mutant CREB κυτταρικές σειρές. Τέλος, να μελετήσουμε την επίδραση της αποσιώπησης του CREB σε καρκινικές σειρές με siRNA πειράματα. Αρχικά, πραγματοποιήθηκε μια σειρά απο πειράματα ανοσοïστοχημείας σε Knock out έμβρυα προκειμένου να εντοπίσουμε αντισώματα-δείκτες του πολλαπλασιασμού. Στην συνέχεια μελετήσαμε την παρουσία της ενεργής μορφής του CREB με tissue array σε πλακάκια που έφεραν ιστό από διάφορους τύπους καρκίνου του δέρματος. Επιπλέον, μελετήθηκε η βιωσιμότητα των κυττάρων της καρκινικής σειράς Α 375 ανθρώπινου μελανώματος μετά από την επίδραση της αποσιώπησης της έκφρασης του CREB μέσω siRNA μορίων (CREB siRNA knock down). Τέλος, μελετήθηκε η βιωσιμότητα κυττάρων ανθρώπινου μελανώματος (Α375) που εκφράζουν σταθερά μια dominant negative μορφή του CREB (CREB-M1) και μια σταθερά ενεργοποιημένη μορφή (CREB-FY) σε σχέση με τα κύτταρα ελέγχου που είχαν σταθερά διαμολυνθεί με GFP. / --

Καρκίνος του δέρματος

616.994 071

Skin cancer

CREB

Unconventional forms of synaptic plasticity in the hippocampus and the striatum

Liu, Zhi

11 1900

Synaptic transmission occurs as a result of either a spontaneous release of presynaptic vesicles or a batch release of presynaptic vesicles driven by action potentials. The physiological consequence of synaptic transmission driven by different patterns and frequencies of presynaptic stimulation has been extensively investigated. However, the physiological nature, mechanism as well as relevance of prolonged presynaptic stimulation have been poorly characterized. In this dissertation, I present three projects in which prolonged stimulation of synaptic transmission in different forms and different brain regions was studied for its effect on synaptic transmission, mechanisms and physiological relevance. In the first project, prolonged electrical stimulation (100 sec) at high frequency induced a deep synaptic depression in acute hippocampal slices, followed by a recovery of synaptic transmission after ~15 min. The deep synaptic depression was attributed to a complete depletion of presynaptic vesicle pools. In the second project, attempts were made to characterize the mechanism of nuclear activation of gene transcription induced by prolonged electrical stimulation (100 sec). Our results demonstrated that reduced inactivation of non-L-type calcium channels failed to provide calcium required for gene transcription, leaving the activation of gene transcription a selective function for L-type calcium channels. In the third project, we sought to study the physiological relevance of enhanced miniature events of inhibitory synapses induced by prolonged chemical stimulation. We showed that prolonged application (2 min) of nicotine to the striatal slice enhanced the frequency of miniature inhibitory currents that was accompanied with a reduction in the amplitude of evoked response. This reduction in the amplitude of evoked responses was ascribed to a compromised action potential invasion of presynaptic terminals possibly due to inactivation of sodium channels resulting from nicotine-induced depolarization. To summarize, prolonged stimulation of presynaptic vesicle release imposes significant influence upon neuron-to-neuron communication, with distinct mechanisms in different brain regions. / Medicine, Faculty of / Graduate

Hippocampus

Striatum

CREB

Synaptic transmission

Voltage-gated calcium channel