Your search keyword '"ZHIGANG HE"' showing total 6 results

1. Effects of PTEN and Nogo Codeletion on Corticospinal Axon Sprouting and Regeneration in Mice.

Author

Geoffroy, Cédric G., Lorenzana, Ariana O., Kwan, Jeffrey P., Lin, Kyle, Ghassemi, Omeed, Ma, Andrew, Nuo Xu, Creger, Daniel, Kai Liu, Zhigang He, and Binhai Zheng

Subjects

PTEN protein genetics, NERVOUS system regeneration, THERAPEUTICS, SPINAL cord injuries, NEURAL development, CENTRAL nervous system stimulants, PYRAMIDAL tract, AXONS, LABORATORY mice

Abstract

Axons in the adult CNS have poor ability to grow after injury, impeding functional recovery in patients of spinal cord injury. This has been attributed to both a developmental decline in neuron-intrinsic growth ability and the presence of extrinsic growth inhibitors. We previously showed that genetic deletion of Nogo, an extrinsic inhibitor, promoted axonal sprouting from uninjured corticospinal tract (CST) neurons but not regeneration from injured CST neurons, whereas genetic deletion of PTEN, an intrinsic inhibitor, promoted both CST sprouting and regeneration. Here we test the hypothesis that combining an elevation of neuron-intrinsic growth ability and a reduction of extrinsic growth inhibition by genetic codeletion of PTEN and Nogo may further improve injury-induced axonal growth. In an apparent paradox, additionally deleting Nogo further enhanced CST regeneration but not sprouting in PTEN-deleted mice. Enhanced CST regeneration and sprouting in PTEN and PTEN/Nogo-deleted mice were associated with no or only temporary improvement in functional recovery. Our data illustrate that neuron-intrinsic and -extrinsic factors regulate axon regeneration and sprouting in complex ways and provide proof-of-principle evidence that targeting both can further improve regeneration. Neuron-intrinsic growth ability is an important determinant of neuronal responsiveness to changes in extrinsic growth inhibition, such that an elevated intrinsic growth state is a prerequisite for reducing extrinsic inhibition to take effect on CST regeneration. Meanwhile, additional strategies are required to unleash the full potential for functional recovery with enhanced axon regeneration and/or sprouting. [ABSTRACT FROM AUTHOR]

Published

2015

2. Characterization of Long Descending Premotor Propriospinal Neurons in the Spinal Cord.

Author

Yingchun Ni, Homaira Nawabi, Xuefeng Liu, Liu Yang, Kazunari Miyamichi, Andrea Tedeschi, Bengang Xu, Wall, Nicholas R., Callaway, Edward M., and Zhigang He

Subjects

PREMOTOR cortex, SPINAL cord, NEURAL circuitry, RABIES virus, MOTOR neurons, AXONS, MICE

Abstract

The motor function of the spinal cord requires the computation of the local neuronal circuits within the same segments as well as the long-range coordination of different spinal levels. Implicated players in this process are the propriospinal neurons (PPNs) that project their axons across different levels of the spinal cord. However, their cellular, molecular, and functional properties remain unknown. Here we use a recombinant rabies virus-based method to label a specific type of long-projecting premotor PPNs in the mouse upper spinal cord that are monosynaptically connected to the motor neurons in the lumbar spinal cord. With a whole spinal cord imaging method, we find that these neurons are distributed along the entire length of the upper spinal cord with more in the lower thoracic levels. Among them, a subset of thoracic PPNs receive substantial numbers of sensory inputs, suggesting a function in coordinating the activity of trunk and hindlimb muscles. Although many PPNs in the cervical and thoracic spinal cord receive the synaptic inputs from corticospinal tract or serotonergic axons, limited bouton numbers suggested that these supraspinal inputs might not be major regulators of the PPNs in intact animals. Molecularly, these PPNs appear to be distinct from other known premotor interneurons, but some are derived from Chx10 + lineages. This study provides an anatomical basis for further exploring different functions of PPNs. [ABSTRACT FROM AUTHOR]

Published

2014

3. Short Hairpin RNA against PTEN Enhances Regenerative Growth of Corticospinal Tract Axons after Spinal Cord Injury.

Author

Zukor, Katherine, Belin, Stephane, Chen Wang, Keelan, Nadia, Xuhua Wang, and Zhigang He

Subjects

RNA, PTEN protein genetics, NEURAL circuitry, PYRAMIDAL tract, SPINAL cord injuries, AXONS, FIBROBLASTS, MACROPHAGES

Abstract

Developing approaches to promote the regeneration of descending supraspinal axons represents an ideal strategy for rebuilding neuronal circuits to improve functional recovery after spinal cord injury (SCI). Our previous studies demonstrated that genetic deletion of phosphatase and tensin homolog (PTEN) in mouse corticospinal neurons reactivates their regenerative capacity, resulting in significant regeneration of corticospinal tract (CST) axons after SCI. However, it is unknown whether nongenetic methods of suppressingPTENhave similar effects and how regenerating axons interact with the extrinsic environment. Herein, we show that suppressing PTEN expression with short-hairpin RNA (shRNA) promotes the regeneration of injured CST axons, and these axons form anatomical synapses in appropriate areas of the cord caudal to the lesion. Importantly, this model of increased CST regrowth enables the analysis of extrinsic regulators of CST regeneration in vivo.We find that regenerating axons avoid dense clusters of fibroblasts and macrophages in the lesion, suggesting that these cell types might be key inhibitors of axon regeneration. Furthermore, most regenerating axons cross the lesion in association with astrocytes, indicating that these cells might be important for providing a permissive bridge for axon regeneration. Lineage analysis reveals that these bridge-forming astrocytes are not derived from ependymal stem cells within the spinal cord, suggesting that they are more likely derived from a subset of mature astrocytes. Overall, this study reveals insights into the critical extrinsic and intrinsic regulators of axon regeneration and establishes shRNA as a viable means to manipulate these regulators and translate findings into other mammalian models. [ABSTRACT FROM AUTHOR]

Published

2013

4. The Nogo-66 Receptor NgR1 Is Required Only for the Acute Growth Cone-Collapsing But Not the Chronic Growth-Inhibitory Actions of Myelin Inhibitors.

Author

Chivatakarn, Onanong, Kaneko, Shinjiro, Zhigang He, Tessier-Lavigne, Marc, and Giger, Roman J.

Subjects

GLYCOPROTEINS, MYELIN proteins, RNA, LIGANDS (Biochemistry), NEURONS, AXONS

Abstract

Neuronal Nogo-66 receptor 1 (NgR1) has been proposed to function as an obligatory coreceptor for the myelin-derived ligands Nogo-A, oligodendrocyte myelin glycoprotein (OMgp), and myelin-associated glycoprotein (MAG) to mediate neurite outgrowth inhibition by these ligands. To examine the contribution of neuronal NgR1 to outgrowth inhibition, we used two different strategies, genetic ablation of NgR1 through the germline and transient short hairpin RNA interference (shRNAi)-mediated knock-down. To monitor growth inhibition, two different paradigms were used, chronic presentation of substrate-bound inhibitor to measure neurite extension and acute application of soluble inhibitor to assay growth cone collapse. We find that regardless of the NgR1 genotype, membrane-bound MAG strongly inhibits neurite outgrowth of primary cerebellar, sensory, and cortical neurons. Similarly, substrate-bound OMgp strongly inhibits neurite outgrowth of NgR1 wild-type and mutant sensory neurons. Consistent with these results, shRNAi-mediated knock-down of neuronal NgR1 does not result in a substantial release of L-MAG (large MAG) inhibition. When applied acutely, however, MAG-Fc and OMgp-Fc induce a modest degree of growth cone collapse that is significantly attenuated in NgR1-null neurons compared with wild-type controls. Based on our findings and previous studies with Nogo-66, we propose that neuronal NgR1 has a circumscribed role in regulating cytoskeletal dynamics after acute exposure to soluble MAG, OMgp, or Nogo-66, but is not required for these ligands to mediate their growth-inhibitory properties in chronic outgrowth experiments. Our results thus provide unexpected evidence that the growth conecollapsing activities and substrate growth-inhibitory activities of inhibitory ligands can be dissociated. We also conclude that chronic axon growth inhibition by myelin is mediated by NgR1-independent mechanisms. [ABSTRACT FROM AUTHOR]

Published

2007

5. Counteracting the Nogo Receptor Enhances Optic Nerve Regeneration If Retinal Ganglion Cells Are in an Active Growth State.

Author

Fischer, Dietmar, Zhigang He, and Benowitz, Larry I.

Subjects

*RETINAL ganglion cells, *NEURONS, *AXONS, *MACROPHAGES, *GLYCOPROTEINS

Abstract

Mature retinal ganglion cells (RGCs), like other CNS neurons, cannot regrow injured axons into a myelin-rich environment. If stimulated by macrophage-derived factors, however, RGCs can regenerate their axons for considerable distances through the distal optic nerve. Using this "sensitized background," we investigated the effects of either increasing the expression or suppressing the activity of the Nogo receptor (NgR). NgR mediates the growth-inhibiting effects of three myelin proteins, Nogo, OMgp (oligodendrocyte-myelin glycoprotein), and MAG (myelin-associated glycoprotein). Transfecting growth-sensitized RGCs with adeno-associated viruses expressing a dominant-negative form of NgR (NgRDN) increased axon regeneration several-fold; however, when the growth program of RGCs was not activated, NgRDN expression had no beneficial effects. Overexpression of wild-type NgR blocked almost all regeneration from growth-sensitized RGCs and caused axons proximal to the lesion site to retract. We conclude that gene therapy is an effective approach to enhancing axon regeneration in the CNS and that inactivation of NgR functioning greatly enhances axon regeneration provided the intrinsic growth program of neurons is activated. [ABSTRACT FROM AUTHOR]

Published

2004

6. Protecting Axonal Degeneration by Increasing Nicotinamide Adenine Dinucleotide Levels in Experimental Autoimmune Encephalomyelitis Models.

Author

Kaneko, Shinjiro, Jin Wang, Kaneko, Marie, Yiu, Glenn, Hurrell, Joanna M., Chitnis, Tanuja, Khoury, Samia J., and Zhigang He

Subjects

MORPHOLOGY, CENTRAL nervous system, MULTIPLE sclerosis, ANIMAL models in research, AXONS, NICOTINAMIDE, BIOSYNTHESIS

Abstract

Axonal damage is a major morphological alteration in the CNS of patients with multiple sclerosis (MS) and its animal model, experimental autoimmune encephalomyelitis (EAE). However, the underlying mechanism for the axonal damage associated with MS/EAE and its contribution to the clinical symptoms remain unclear. The expression of a fusion protein, named "Wallerian degeneration slow" (Wlds), can protect axons from degeneration, likely through a β-nicotinamide adenine dinucleotide (NAD)-dependent mechanism. In this study, we find that, when induced with EAE, Wlds mice showed a modest attenuation of behavioral deficits and axon loss, suggesting that EAE-associated axon damage may occur by a mechanism similar to Wallerian degeneration. Furthermore, nicotinamide (NAm), an NAD biosynthesis precursor, profoundly prevents the degeneration of demyelinated axons and improves the behavioral deficits in EAE models. Finally, we demonstrate that delayedNAmtreatment is also beneficial to EAE models, pointing to the therapeutic potential of NAm as a protective agent for EAE and perhaps MS patients. [ABSTRACT FROM AUTHOR]

Published

2006