Biomimetic Orientated Total Synthesis of Neovibsane Natural Products and Comparison of Synthetic Neovibsanes on Neurite Outgrowth Promotion in PC12 Cells

Annette Chen

Unknown Date

Neovibsanin A and B are natural products which induced neurite outgrowth in PC12 cells. They belong in the neovibsane class under the rare vibsane natural product family, whose structures are characterized by polycyclic, polyoxygenated cores. Based on a proposed biosynthesis, the synthetic strategy towards neovibsanin A and B involved synthesizing a key enone intermediate. Initial investigation using this intermediate lead to the total synthesis of 2-O-methylneovibsanin H. Crucial to this concise synthesis was an acid-catalyzed, one-pot, four-step cascade reaction. Modifying the reaction condition leads to a different five-step cascade pathway, resulting in the total synthesis of 4,5-bis-epi-neovibsanin A and B. The synthetic trials and tribulations encountered on the road to these final compounds are explored. It is envisaged that other related neovibsane natural products may arise based on this synthetic sequence. 4,5-Bis-epi-neovibsanin A and B, as well as several other structural analogues collected during the synthesis, were biologically assayed using NGF-stimulated PC12 cells. All compounds induced a significant proportion of neurons to extend neurite processes compared to control cultures. The structure-activity relationship studies indicated that the tricyclic core, as well as the 3,3-dimethylacroyl enol ester side chain, may be responsible for promoting a biological response.

neovibsanin a

neovibsanin b

2-O-methylneovibsanin h

biological activity

neurite outgrowth

natural product

total synthesis

Biomimetic Orientated Total Synthesis of Neovibsane Natural Products and Comparison of Synthetic Neovibsanes on Neurite Outgrowth Promotion in PC12 Cells

Annette Chen

Unknown Date

Neovibsanin A and B are natural products which induced neurite outgrowth in PC12 cells. They belong in the neovibsane class under the rare vibsane natural product family, whose structures are characterized by polycyclic, polyoxygenated cores. Based on a proposed biosynthesis, the synthetic strategy towards neovibsanin A and B involved synthesizing a key enone intermediate. Initial investigation using this intermediate lead to the total synthesis of 2-O-methylneovibsanin H. Crucial to this concise synthesis was an acid-catalyzed, one-pot, four-step cascade reaction. Modifying the reaction condition leads to a different five-step cascade pathway, resulting in the total synthesis of 4,5-bis-epi-neovibsanin A and B. The synthetic trials and tribulations encountered on the road to these final compounds are explored. It is envisaged that other related neovibsane natural products may arise based on this synthetic sequence. 4,5-Bis-epi-neovibsanin A and B, as well as several other structural analogues collected during the synthesis, were biologically assayed using NGF-stimulated PC12 cells. All compounds induced a significant proportion of neurons to extend neurite processes compared to control cultures. The structure-activity relationship studies indicated that the tricyclic core, as well as the 3,3-dimethylacroyl enol ester side chain, may be responsible for promoting a biological response.

neovibsanin a

neovibsanin b

2-O-methylneovibsanin h

biological activity

neurite outgrowth

natural product

total synthesis

Biomimetic Orientated Total Synthesis of Neovibsane Natural Products and Comparison of Synthetic Neovibsanes on Neurite Outgrowth Promotion in PC12 Cells

Annette Chen

Unknown Date

Neovibsanin A and B are natural products which induced neurite outgrowth in PC12 cells. They belong in the neovibsane class under the rare vibsane natural product family, whose structures are characterized by polycyclic, polyoxygenated cores. Based on a proposed biosynthesis, the synthetic strategy towards neovibsanin A and B involved synthesizing a key enone intermediate. Initial investigation using this intermediate lead to the total synthesis of 2-O-methylneovibsanin H. Crucial to this concise synthesis was an acid-catalyzed, one-pot, four-step cascade reaction. Modifying the reaction condition leads to a different five-step cascade pathway, resulting in the total synthesis of 4,5-bis-epi-neovibsanin A and B. The synthetic trials and tribulations encountered on the road to these final compounds are explored. It is envisaged that other related neovibsane natural products may arise based on this synthetic sequence. 4,5-Bis-epi-neovibsanin A and B, as well as several other structural analogues collected during the synthesis, were biologically assayed using NGF-stimulated PC12 cells. All compounds induced a significant proportion of neurons to extend neurite processes compared to control cultures. The structure-activity relationship studies indicated that the tricyclic core, as well as the 3,3-dimethylacroyl enol ester side chain, may be responsible for promoting a biological response.

neovibsanin a

neovibsanin b

2-O-methylneovibsanin h

biological activity

neurite outgrowth

natural product

total synthesis

Biomimetic Orientated Total Synthesis of Neovibsane Natural Products and Comparison of Synthetic Neovibsanes on Neurite Outgrowth Promotion in PC12 Cells

Annette Chen

Unknown Date

Neovibsanin A and B are natural products which induced neurite outgrowth in PC12 cells. They belong in the neovibsane class under the rare vibsane natural product family, whose structures are characterized by polycyclic, polyoxygenated cores. Based on a proposed biosynthesis, the synthetic strategy towards neovibsanin A and B involved synthesizing a key enone intermediate. Initial investigation using this intermediate lead to the total synthesis of 2-O-methylneovibsanin H. Crucial to this concise synthesis was an acid-catalyzed, one-pot, four-step cascade reaction. Modifying the reaction condition leads to a different five-step cascade pathway, resulting in the total synthesis of 4,5-bis-epi-neovibsanin A and B. The synthetic trials and tribulations encountered on the road to these final compounds are explored. It is envisaged that other related neovibsane natural products may arise based on this synthetic sequence. 4,5-Bis-epi-neovibsanin A and B, as well as several other structural analogues collected during the synthesis, were biologically assayed using NGF-stimulated PC12 cells. All compounds induced a significant proportion of neurons to extend neurite processes compared to control cultures. The structure-activity relationship studies indicated that the tricyclic core, as well as the 3,3-dimethylacroyl enol ester side chain, may be responsible for promoting a biological response.

neovibsanin a

neovibsanin b

2-O-methylneovibsanin h

biological activity

neurite outgrowth

natural product

total synthesis

Biomimetic Orientated Total Synthesis of Neovibsane Natural Products and Comparison of Synthetic Neovibsanes on Neurite Outgrowth Promotion in PC12 Cells

Annette Chen

Unknown Date

Neovibsanin A and B are natural products which induced neurite outgrowth in PC12 cells. They belong in the neovibsane class under the rare vibsane natural product family, whose structures are characterized by polycyclic, polyoxygenated cores. Based on a proposed biosynthesis, the synthetic strategy towards neovibsanin A and B involved synthesizing a key enone intermediate. Initial investigation using this intermediate lead to the total synthesis of 2-O-methylneovibsanin H. Crucial to this concise synthesis was an acid-catalyzed, one-pot, four-step cascade reaction. Modifying the reaction condition leads to a different five-step cascade pathway, resulting in the total synthesis of 4,5-bis-epi-neovibsanin A and B. The synthetic trials and tribulations encountered on the road to these final compounds are explored. It is envisaged that other related neovibsane natural products may arise based on this synthetic sequence. 4,5-Bis-epi-neovibsanin A and B, as well as several other structural analogues collected during the synthesis, were biologically assayed using NGF-stimulated PC12 cells. All compounds induced a significant proportion of neurons to extend neurite processes compared to control cultures. The structure-activity relationship studies indicated that the tricyclic core, as well as the 3,3-dimethylacroyl enol ester side chain, may be responsible for promoting a biological response.

neovibsanin a

neovibsanin b

2-O-methylneovibsanin h

biological activity

neurite outgrowth

natural product

total synthesis

Rôle de la protéine G protein-regulated inducer of neurite outgrowth 3 (GPRIN3), fortement exprimée dans le striatum, dans le contrôle moteur et les phénomènes de motivation

Karadurmus, Deniz

28 February 2018

Le striatum est composé principalement de neurones épineux de taille moyenne, subdivisés en neurones striatopallidaux et striatonigraux en fonction de leurs projections et de leur expression en récepteurs et neuropeptides. Ces deux populations neuronales sont respectivement à l’origine des voies indirecte (ou inhibitrice) et directe (ou activatrice) des noyaux de la base, présentant des effets opposés à la fois au niveau moteur et motivationnel. Ces deux voies sont également différemment affectées dans différentes pathologies des noyaux de la base, telles que les maladies de Huntington et de Parkinson et les addictions. Les mécanismes moléculaires et cellulaires de régulation des neurones STP et STN ne sont cependant pas encore pleinement compris. Dès lors, l’identification et l’étude de la fonction de gènes spécifiques de l’une ou l’autre de ces sous-populations pourraient constituer une étape importante vers une meilleure compréhension de leur fonctionnement. Dans cette optique, notre laboratoire a précédemment réalisé une étude comparative des profils d’expression de chacune des sous-populations striatales par microarray. Parmi les gènes potentiellement inégalement exprimés dans les neurones STP et STN, nous avons identifié GPRIN3, un membre de la famille G Protein-Regulated Inducer of Neurite outgrowth (GPRIN), comme étant une cible intéressante. Cette famille, bien qu’encore très peu caractérisée, interagit en effet avec les sous-unités Gαi/o des protéines G et joue par conséquent un rôle régulateur sur la fonction et la voie de signalisation de certains GPCRs, tels que le récepteur μ opioïde. De plus, contrairement aux autres membres de la famille GPRIN, nos résultats de microarray suggèrent également un niveau d’expression élevé de GPRIN3 dans les neurones striataux chez l’adulte. Etant donné le rôle crucial des GPCRs au niveau du striatum et plus particulièrement dans le comportement différentiel des neurones STP et STN, GPRIN3 pourrait dès lors constituer un élément important dans le fonctionnement des neurones striataux. Ce travail s'est par conséquent axé sur l’élucidation du rôle de GPRIN3 dans les fonctions striatales. Dans ce but, nous avons dans un premier temps établi le profil d'expression de GPRIN3 chez la souris, au niveau du cerveau adulte et lors de l'embryogénèse. Ceci nous a permis de confirmer, chez l'adulte, l'expression majoritairement striatale de GPRIN3, et l'expression préférentielle dans les neurones STP. Nous avons également généré différents vecteurs d'expression de la protéine GPRIN3 et établi sa localisation subcellulaire en lignée HEK293T. La génération et la caractérisation d'un modèle d'invalidation constitutive ainsi que d'un modèle de répression par interférence ARN ont par la suite mis en évidence une implication, directe ou indirecte, de GPRIN3 dans la régulation fine de la signalisation du D2R. En effet, nous avons montré une modification des comportements liés à la motivation et à la réponse à la cocaïne ainsi qu’une altération de l’état de phosphorylation de DARPP32 et de la réponse à l’halopéridol dans le modèle d’invalidation constitutive. De plus, la réponse au quinpirole est également modifiée dans les deux modèles testés. Pris dans leur ensemble, ces résultats suggèrent dès lors une altération de la voie de signalisation du D2R en l’absence de GPRIN3 fonctionnel. En outre, les neurones STP dépourvus de GPRIN3 fonctionnel présentent des modifications de leur morphologie et de leurs propriétés électrophysiologiques. En conclusion, ce travail de thèse a permis d’apporter les premières pistes quant à la fonction de GPRIN3, une protéine totalement méconnue, dans le striatum, de par la création de modèles d’invalidation constitutive et de répression Cre-dépendante de cette protéine. Divers outils moléculaires ont également été générés et pourront être utilisés dans la suite de la caractérisation des fonctions de GPRIN3. / Doctorat en Sciences biomédicales et pharmaceutiques (Médecine) / info:eu-repo/semantics/nonPublished

Sciences bio-médicales et agricoles

contrôle moteur

motivation

striatum

Der Einfluss von humanem Wildtyp-Alpha-Synuclein und seinen Mutationen A30P und A53T auf das Neuritenwachstum primärer dopaminerger Mittelhirnneurone der Ratte / α-Synuclein-wildtype and its mutants A30P and A53T affect neurite outgrowth in rat primary dopaminergic midbrain neurons

Haack, Jessica Franziska

20 January 2021

No description available.

610

α-Synuclein

Neuritenwachstum

Mittelhirnneurone

α-Synuclein

neurite outgrowth

midbrain neurons

Essential Role of ERK Activation in Neurite Outgrowth Induced by α-Lipoic Acid

Wang, Xiaohui, Wang, Zhuyao, Yao, Yuzhen, Li, Jingjin, Zhang, Xiaojin, Li, Chuanfu, Cheng, Yunlin, Ding, Guoxian, Liu, Li, Ding, Zhengnian

01 May 2011

Background: Neurite outgrowth is an important aspect of neuronal plasticity and regeneration after neuronal injury. Alpha-lipoic acid (LA) has been used as a therapeutic approach for a variety of neural disorders. We recently reported that LA prevents local anesthetics-induced neurite loss. In this study, we hypothesized that LA administration promotes neurite outgrowth. Methods: To test our hypothesis, we treated mouse neuroblastoma N2a cells and primary neurons with LA. Neurite outgrowth was evaluated by examination of morphological changes and by immunocytochemistry for α-tubulin-3. ROS production was examined, as were the phosphorylation levels of ERK and Akt. In separate experiments, we determined the effects of the inhibition of ERK or PI3K/Akt as well as ROS production on LA-induced neurite outgrowth. Results: LA promoted significantly neurite outgrowth in a time- and concentration-dependent manner. LA stimulation significantly increased the phosphorylation levels of both Akt and ERK and transiently induced ROS production. PI3K/Akt inhibition did not affect LA-induced neurite outgrowth. However, the inhibition of ERK activation completely abolished LA-induced neurite outgrowth. Importantly, the prevention of ROS production by antioxidants attenuated LA-stimulated ERK activation and completely abolished LA-promoted neurite outgrowth. Conclusion: Our data suggest that LA stimulates neurite outgrowth through the activation of ERK signaling, an effect mediated through a ROS-dependent mechanism. This article is part of a Special Issue entitled: 11th European Symposium on Calcium.

alpha-lipoic acid

MEK/ERK signaling pathway

neurite outgrowth

reactive oxygen species

Surgery

MEK/ERKs Signaling Is Essential for Lithium-Induced Neurite Outgrowth in N2a Cells

Wang, Zhuyao, Wang, Juan, Li, Jingjin, Wang, Xiaohui, Yao, Yuzhen, Zhang, Xiaojin, Li, Chuanfu, Cheng, Yunlin, Ding, Guoxian, Liu, Li, Ding, Zhengnian

01 June 2011

Lithium, a drug used for the treatment of bipolar disorder, has been shown to affect different aspects of neuronal development such as neuritogenesis, neurogenesis and survival. The underlying mechanism responsible for lithium's influence on neuronal development, however, still remains to be elucidated. In the present study, we demonstrate that lithium increases the phosphorylation of extracellular-signal regulated kinases (ERKs) and protein kinase B (Akt) and promotes neurite outgrowth in mouse N2a neuroblastoma cells (N2a). The inactivation of mitogen-activated protein kinase kinase (MEK)/ERKs signaling with a MEK inhibitor inhibits neurite outgrowth, but it enhances Akt activation in lithium-treated N2a cells. Furthermore, the inactivation of phosphoinositide-3-kinase (PI3K)/Akt signaling with a PI3K inhibitor increases both lithium-induced ERKs activation and lithium-induced neurite outgrowth. Taken together, our study suggests that lithium-induced neurite outgrowth in N2a cells is regulated by cross-talk between the MEK/ERKs and PI3K/Akt pathways and requires the activation of the MEK/ERKs signaling.

cross-talk

lithium

MEK/ERKs pathway

neurite outgrowth

PI3K/Akt pathway

Surgery

MOLECULAR MECHANISM OF L1CAM FUNCTION: AXON GROWTH AND GUIDANCE

Cheng, Ling

07 April 2004

No description available.

Biology, Neuroscience

L1

NEURITE

RANBPM

NEURITE OUTGROWTH

OUTGROWTH

L1CD

ADHESION MOLECULE