Your search keyword '"Susan van Erp"' showing total 6 results

1. PI 3-kinase delta enhances axonal PIP3 to support axon regeneration in the adult CNS

Author

Charles ffrench-Constant, Craig S Pearson, Amanda C. Barber, Keith R Martin, Bart Nieuwenhuis, Tasneem Z Khatib, Patrice D. Smith, Rachel S Evans, Lianne A Hulshof, Joachim Fuchs, Richard Eva, Klaus Okkenhaug, Raquel D. Conceição, Sarita S Deshpande, Britta J. Eickholt, Andrew Osborne, Joshua Cave, James W. Fawcett, Barbara Haenzi, Susan van Erp, Amy R. MacQueen, Netherlands Institute for Neuroscience (NIN), Okkenhaug, Klaus [0000-0002-9432-4051], Martin, Keith [0000-0002-9347-3661], Fawcett, James [0000-0002-7990-4568], Eva, Richard [0000-0003-0305-0452], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Adult, Central Nervous System, Medicine (General), animal structures, Central nervous system, CNS axon regeneration, p110 delta, P110α, QH426-470, optic nerve, 03 medical and health sciences, Mice, Phosphatidylinositol 3-Kinases, 0302 clinical medicine, R5-920, medicine, Genetics, Animals, Humans, Axon, PI3K/AKT/mTOR pathway, Neurons, Phosphoinositide 3-kinase, biology, Regeneration (biology), phosphoinositide 3-kinase, axon transport, phosphoinositide 3‐kinase, Axons, Nerve Regeneration, Rats, 030104 developmental biology, medicine.anatomical_structure, nervous system, Peripheral nervous system, embryonic structures, Optic nerve, biology.protein, Molecular Medicine, Neuroscience, 030217 neurology & neurosurgery

Abstract

Peripheral nervous system (PNS) neurons support axon regeneration into adulthood, whereas central nervous system (CNS) neurons lose regenerative ability after development. To better understand this decline whilst aiming to improve regeneration, we focused on phosphoinositide 3‐kinase (PI3K) and its product phosphatidylinositol (3,4,5)‐trisphosphate (PIP3). We demonstrate that adult PNS neurons utilise two catalytic subunits of PI3K for axon regeneration: p110α and p110δ. However, in the CNS, axonal PIP3 decreases with development at the time when axon transport declines and regenerative competence is lost. Overexpressing p110α in CNS neurons had no effect; however, expression of p110δ restored axonal PIP3 and increased regenerative axon transport. p110δ expression enhanced CNS regeneration in both rat and human neurons and in transgenic mice, functioning in the same way as the hyperactivating H1047R mutation of p110α. Furthermore, viral delivery of p110δ promoted robust regeneration after optic nerve injury. These findings establish a deficit of axonal PIP3 as a key reason for intrinsic regeneration failure and demonstrate that native p110δ facilitates axon regeneration by functioning in a hyperactive fashion.

Published

2020

2. PI 3-kinase delta enhances axonal PIP

Author

Bart, Nieuwenhuis, Amanda C, Barber, Rachel S, Evans, Craig S, Pearson, Joachim, Fuchs, Amy R, MacQueen, Susan, van Erp, Barbara, Haenzi, Lianne A, Hulshof, Andrew, Osborne, Raquel, Conceicao, Tasneem Z, Khatib, Sarita S, Deshpande, Joshua, Cave, Charles, Ffrench-Constant, Patrice D, Smith, Klaus, Okkenhaug, Britta J, Eickholt, Keith R, Martin, James W, Fawcett, and Richard, Eva

Subjects

Adult, Central Nervous System, Neurons, CNS axon regeneration, p110 delta, Articles, axon transport, Regenerative Medicine, Axons, Article, optic nerve, phosphoinositide 3‐kinase, Nerve Regeneration, Rats, Mice, Phosphatidylinositol 3-Kinases, nervous system, Animals, Humans, Neuroscience

Abstract

Peripheral nervous system (PNS) neurons support axon regeneration into adulthood, whereas central nervous system (CNS) neurons lose regenerative ability after development. To better understand this decline whilst aiming to improve regeneration, we focused on phosphoinositide 3‐kinase (PI3K) and its product phosphatidylinositol (3,4,5)‐trisphosphate (PIP 3). We demonstrate that adult PNS neurons utilise two catalytic subunits of PI3K for axon regeneration: p110α and p110δ. However, in the CNS, axonal PIP 3 decreases with development at the time when axon transport declines and regenerative competence is lost. Overexpressing p110α in CNS neurons had no effect; however, expression of p110δ restored axonal PIP 3 and increased regenerative axon transport. p110δ expression enhanced CNS regeneration in both rat and human neurons and in transgenic mice, functioning in the same way as the hyperactivating H1047R mutation of p110α. Furthermore, viral delivery of p110δ promoted robust regeneration after optic nerve injury. These findings establish a deficit of axonal PIP 3 as a key reason for intrinsic regeneration failure and demonstrate that native p110δ facilitates axon regeneration by functioning in a hyperactive fashion., CNS axons lose the ability to regenerate with maturity, whilst PNS axons do not. This study shows that PIP3 levels decline in CNS neurons at the time when regenerative ability is lost. CNS overexpression of one isoform of PI3K, p110δ, enhances axonal PIP3, axon transport, and regenerative ability.

Published

2019

3. Selective rab11 transport and the intrinsic regenerative ability of CNS axons

Author

Susan van Erp, Charles ffrench-Constant, Brian Yh Lam, Veselina Petrova, Matteo Donegà, Richard Eva, Giles Sh Yeo, Jessica C. F. Kwok, Hiroaki Koseki, James W. Fawcett, van Erp, Susan [0000-0003-0883-2795], Eva, Richard [0000-0003-0305-0452], Fawcett, James W [0000-0002-7990-4568], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, QH301-705.5, Endosome, Science, Cellular differentiation, medicine.medical_treatment, Biology, small GTPases, General Biochemistry, Genetics and Molecular Biology, neuroscience, Rats, Sprague-Dawley, 03 medical and health sciences, trafficking, medicine, Journal Article, Animals, Regeneration, rat, human, Biology (General), Axon, Growth cone, General Immunology and Microbiology, General Neuroscience, Cytoplasmic Vesicles, axon regeneration, Biological Transport, Cell Differentiation, General Medicine, Anatomy, Axon growth, Axons, Cell biology, axotomy, Somatodendritic compartment, 030104 developmental biology, medicine.anatomical_structure, nervous system, endosomes, rab GTP-Binding Proteins, Axoplasmic transport, Medicine, Axotomy, axonal transport, Research Article

Abstract

Neurons lose intrinsic axon regenerative ability with maturation, but the mechanism remains unclear. Using an in-vitro laser axotomy model, we show a progressive decline in the ability of cut CNS axons to form a new growth cone and then elongate. Failure of regeneration was associated with increased retraction after axotomy. Transportation into axons becomes selective with maturation; we hypothesized that selective exclusion of molecules needed for growth may contribute to regeneration decline. With neuronal maturity rab11 vesicles (which carry many molecules involved in axon growth) became selectively targeted to the somatodendritic compartment and excluded from axons by predominant retrograde transport However, on overexpression rab11 was mistrafficked into proximal axons, and these axons showed less retraction and enhanced regeneration after axotomy. These results suggest that the decline of intrinsic axon regenerative ability is associated with selective exclusion of key molecules, and that manipulation of transport can enhance regeneration., eLife digest The nerves in the brain and spinal cord can be damaged by trauma, stroke and other conditions. Damage to these nerve fibres can destroy the connections they form with each other, which may lead to paralysis, loss of sensation and loss of body control. If we could stimulate the regeneration and reconnection of the damaged nerve fibres then neurological function could be restored. However, although embryonic nerve fibres can regenerate when they are transplanted into the adult central nervous system, this regenerative ability appears to be lost as the nerve fibres mature. To investigate when and why nerve fibres lose the ability to regenerate, Koseki et al. first developed a tissue culture assay in which individual nerve fibres were cut with a laser and imaged for several hours to track their regeneration (or failure to regenerate). The results demonstrate that nerve fibres from the central nervous system progressively lose the ability to grow and regenerate as they mature. To investigate why mature nerve fibres cannot regenerate, Koseki et al. measured whether nerve fibres can transport some of the molecules needed for growth and regeneration to sites of damage. This showed that the compartments in which some key growth molecules are transported become excluded from mature nerve fibres. These compartments are marked by a protein called rab11, and Koseki et al. found that forcing rab11 back into mature nerve fibres restored their ability to regenerate. There is still a lot of work needed before these findings can lead to a new regeneration treatment for patients, but it is a crucial step forwards. Furthermore, the assay developed by Koseki et al. could be used to develop and test such treatments.

Published

2018

4. Pitx3 potentiates Nurr1 in dopamine neuron terminal differentiation through release of SMRT-mediated repression

Author

Annemarie J. A. van der Linden, Susan van Erp, J. Peter H. Burbach, Frank M. J. Jacobs, Lars von Oerthel, and Marten P. Smidt

Subjects

Dopamine, Cellular differentiation, Substantia nigra, Biology, Models, Biological, Histone Deacetylases, Mice, Nuclear Receptor Subfamily 4, Group A, Member 2, medicine, Animals, Nuclear Receptor Co-Repressor 2, PTB-Associated Splicing Factor, Promoter Regions, Genetic, Molecular Biology, Transcription factor, Psychological repression, Nuclear receptor co-repressor 2, Homeodomain Proteins, Neurons, Genome, Dopaminergic, Gene Expression Regulation, Developmental, RNA-Binding Proteins, Cell Differentiation, Embryo, Mammalian, eye diseases, Cell biology, DNA-Binding Proteins, Repressor Proteins, medicine.anatomical_structure, Nuclear receptor, Cancer research, Neuron, Protein Binding, Transcription Factors, Developmental Biology

Abstract

In recent years, the meso-diencephalic dopaminergic (mdDA) neurons have been extensively studied for their association with Parkinson's disease. Thus far, specification of the dopaminergic phenotype of mdDA neurons is largely attributed to the orphan nuclear receptor Nurr1. In this study, we provide evidence for extensive interplay between Nurr1 and the homeobox transcription factor Pitx3 in vivo. Both Nurr1 and Pitx3 interact with the co-repressor PSF and occupy the promoters of Nurr1 target genes in concert. Moreover, in vivo expression analysis reveals that Nurr1 alone is not sufficient to drive the dopaminergic phenotype in mdDA neurons but requires Pitx3 for full activation of target gene expression. In the absence of Pitx3, Nurr1 is kept in a repressed state through interaction with the co-repressor SMRT. Highly resembling the effect of ligand activation of nuclear receptors, recruitment of Pitx3 modulates the Nurr1 transcriptional complex by decreasing the interaction with SMRT, which acts through HDACs to keep promoters in a repressed deacetylated state. Indeed, interference with HDAC-mediated repression in Pitx3-/- embryos efficiently reactivates the expression of Nurr1 target genes, bypassing the necessity for Pitx3. These data position Pitx3 as an essential potentiator of Nurr1 in specifying the dopaminergic phenotype, providing novel insights into mechanisms underlying development of mdDA neurons in vivo, and the programming of stem cells as a future cell replacement therapy for Parkinson's disease.

Published

2009

5. A role for Bicaudal-D2 in radial cerebellar granule cell migration

Author

R. Jeroen Pasterkamp, Nanda Keijzer, Max A. Schlager, Casper C. Hoogenraad, Robert van den Berg, Phebe S. Wulf, Anna Akhmanova, Susan van Erp, Chris I. De Zeeuw, Esther de Graaff, Dick Jaarsma, Sub Cell Biology, Celbiologie, Neurosciences, Cell biology, and Netherlands Institute for Neuroscience (NIN)

Subjects

Cerebellum, Time Factors, Microtubule-associated protein, Knockout, Dynein, Blotting, Western, General Physics and Astronomy, Mice, Transgenic, Biology, Inbred C57BL, Transgenic, General Biochemistry, Genetics and Molecular Biology, Mice, Cell Movement, medicine, Animals, Humans, Cerebral Cortex, Mice, Knockout, Neurons, Microscopy, Multidisciplinary, Microscopy, Confocal, Blotting, Brain, Cell migration, General Chemistry, Granule cell, BICD2, Cell biology, Rats, Mice, Inbred C57BL, medicine.anatomical_structure, nervous system, Confocal, Astrocytes, Neuroglia, Western, Microtubule-Associated Proteins, Astrocyte

Abstract

Bicaudal-D (BICD) belongs to an evolutionary conserved family of dynein adaptor proteins. It was first described in Drosophila as an essential factor in fly oogenesis and embryogenesis. Missense mutations in a human BICD homologue, BICD2, have been linked to a dominant mild early onset form of spinal muscular atrophy. Here we further examine the in vivo function of BICD2 in Bicd2 knockout mice. BICD2-deficient mice develop disrupted laminar organization of cerebral cortex and the cerebellum, pointing to impaired radial neuronal migration. Using astrocyte and granule cell specific inactivation of BICD2, we show that the cerebellar migration defect is entirely dependent upon BICD2 expression in Bergmann glia cells. Proteomics analysis reveals that Bicd2 mutant mice have an altered composition of extracellular matrix proteins produced by glia cells. These findings demonstrate an essential non-cell-autonomous role of BICD2 in neuronal cell migration, which might be connected to cargo trafficking pathways in glia cells.

Published

2014

6. Semaphorin signaling: molecular switches at the midline

Author

R. Jeroen Pasterkamp, Alwin A.H.A. Derijck, and Susan van Erp

Subjects

Molecular switch, Ventral midline, animal structures, Growth Cones, Context (language use), Cell Biology, Anatomy, Semaphorins, Biology, Axons, Mice, Semaphorin, Spinal Cord, biology.protein, Animals, sense organs, Signal transduction, Sonic hedgehog, Growth cone, Neuroscience, Floor plate, Signal Transduction

Abstract

To establish axonal connections growth cones must navigate multiple intermediate targets before reaching their final target. During this journey growth cones are guided by extracellular repulsive and attractive signals. Although initially identified as repulsive molecules, members of the semaphorin family include both attractants and repellents. How a navigating growth cone responds to a specific semaphorin is not absolute but instead depends on the biological context in which this cue is encountered. Here we review recent breakthroughs in our understanding of the extrinsic signals and molecular processes that control growth cone responses to class 3 semaphorins (Sema3s) at a well-characterized intermediate target, the spinal cord midline.

Published

2010