Oswald Steward

Human Embryonic Stem Cell-Derived Oligodendrocyte Progenitor Cell Transplants Remyelinate and Restore Locomotion after Spinal Cord Injury

Demyelination contributes to loss of function after spinal cord injury, and thus a potential therapeutic strategy involves replacing myelin-forming cells. Here, we show that transplantation of human embryonic stem cell (hESC)-derived oligodendrocyte progenitor cells (OPCs) into adult rat spinal cord injuries enhances remyelination and promotes improvement of motor function. OPCs were injected 7 d or 10 months after injury. In both cases, transplanted cells survived, redistributed over short distances, and differentiated into oligodendrocytes. Animals that received OPCs 7 d after injury exhibited enhanced remyelination and substantially improved locomotor ability. In contrast, when OPCs were transplanted 10 months after injury, there was no enhanced remyelination or locomotor recovery. These studies document the feasibility of predifferentiating hESCs into functional OPCs and demonstrate their therapeutic potential at early time points after spinal cord injury.

A call for transparent reporting to optimize the predictive value of preclinical research

The US National Institute of Neurological Disorders and Stroke convened major stakeholders in June 2012 to discuss how to improve the methodological reporting of animal studies in grant applications and publications. The main workshop recommendation is that at a minimum studies should report on sample-size estimation, whether and how animals were randomized, whether investigators were blind to the treatment, and the handling of data. We recognize that achieving a meaningful improvement in the quality of reporting will require a concerted effort by investigators, reviewers, funding agencies and journal editors. Requiring better reporting of animal studies will raise awareness of the importance of rigorous study design to accelerate scientific progress.

PTEN deletion enhances the regenerative ability of adult corticospinal neurons

Despite the essential role of the corticospinal tract (CST) in controlling voluntary movements, successful regeneration of large numbers of injured CST axons beyond a spinal cord lesion has never been achieved. We found that PTEN/mTOR are critical for controlling the regenerative capacity of mouse corticospinal neurons. After development, the regrowth potential of CST axons was lost and this was accompanied by a downregulation of mTOR activity in corticospinal neurons. Axonal injury further diminished neuronal mTOR activity in these neurons. Forced upregulation of mTOR activity in corticospinal neurons by conditional deletion of Pten, a negative regulator of mTOR, enhanced compensatory sprouting of uninjured CST axons and enabled successful regeneration of a cohort of injured CST axons past a spinal cord lesion. Furthermore, these regenerating CST axons possessed the ability to reform synapses in spinal segments distal to the injury. Thus, modulating neuronal intrinsic PTEN/mTOR activity represents a potential therapeutic strategy for promoting axon regeneration and functional repair after adult spinal cord injury.

Selective targeting of newly synthesized Arc mRNA to active synapses requires NMDA receptor activation.

Newly synthesized Arc mRNA is selectively targeted to synapses that have experienced particular patterns of activity. Here, we demonstrate that the targeting requires NMDA receptor activation. Arc expression was induced by an electroconvulsive seizure, and the newly synthesized mRNA was then targeted to synaptic sites by activating the perforant path projections to the dentate gyrus. When micropipette electrodes containing NMDA receptor antagonists (MK801 or APV) were positioned in the dentate gyrus during the stimulation period, newly synthesized Arc mRNA was transported into dendrites but did not localize in the activated lamina; instead, the mRNA remained diffusely distributed. AMPA receptor antagonists (CNQX) blocked targeting of Arc mRNA in a small region, and mGluR antagonists (MCPG) did not affect localization. These results demonstrate that NMDA receptor activation is required for the targeting of Arc mRNA to active synapses.

Lack of Enhanced Spinal Regeneration in Nogo-Deficient Mice

The failure of regeneration of severed axons in the adult mammalian central nervous system is thought to be due partly to the presence of endogenous inhibitors of axon regeneration. The nogo gene encodes three proteins (Nogo-A, -B, and -C) that have been proposed to contribute to this inhibition. To determine whether deletion of nogo enhances regenerative ability, we generated two lines of mutant mice, one lacking Nogo-A and -B but not -C (Nogo-A/B mutant), and one deficient in all three isoforms (Nogo-A/B/C mutant). Although Nogo-A/B-deficient myelin has reduced inhibitory activity in a neurite outgrowth assay in vitro, tracing of corticospinal tract fibers after dorsal hemisection of the spinal cord did not reveal an obvious increase in regeneration or sprouting of these fibers in either mouse line, suggesting that elimination of Nogo alone is not sufficient to induce extensive axon regeneration.

Mitochondrial uncoupling protein-2 protects the immature brain from excitotoxic neuronal death.

Excitotoxic cell death is the fundamental process responsible for many human neurodegenerative disorders, yet the basic mechanisms involved are not fully understood. Here, we exploited the fact that the immature brain is remarkably resistant to seizure‐induced excitotoxic cell death and examined the underlying protective mechanisms. We found that, unlike in the adult, seizures do not increase the formation of reactive oxygen species or result in mitochondrial dysfunction in neonatal brain, because of high levels of the mitochondrial uncoupling protein (UCP2). UCP2 expression and function were basally increased in neonatal brain by the fat‐rich diet of maternal milk, and substituting a low‐fat diet reduced UCP2, restored mitochondrial coupling, and permitted seizure‐induced neuronal injury. Thus, modulation of UCP2 expression and function by dietary fat protects neonatal neurons from excitotoxicity by preventing mitochondrial dysfunction. This mechanism offers novel neuroprotective strategies for individuals, greater than 1% of the worlds population, who are affected by seizures. Ann Neurol 2003

A cellular mechanism for targeting newly synthesized mRNAs to synaptic sites on dendrites

Long-lasting forms of activity-dependent synaptic plasticity involve molecular modifications that require gene expression. Here, we describe a cellular mechanism that mediates the targeting newly synthesized gene transcripts to individual synapses where they are locally translated. The features of this mechanism have been revealed through studies of the intracellular transport and synaptic targeting of the mRNA for a recently identified immediate early gene called activity-regulated cytoskeleton-associated protein Arc. Arc is strongly induced by patterns of synaptic activity that also induce long-term potentiation, and Arc mRNA is then rapidly delivered into dendrites after episodes of neuronal activation. The newly synthesized Arc mRNA localizes selectively at synapses that recently have been activated, and the encoded protein is assembled into the synaptic junctional complex. The dynamics of trafficking of Arc mRNA reveal key features of the mechanism through which synaptic activity can both induce gene expression and target particular mRNA transcripts to the active synapses.

False resurrections: Distinguishing regenerated from spared axons in the injured central nervous system

Several recent studies report that axon regeneration can be induced in the mature mammalian nervous system by novel treatments or genetic manipulations. In assessing these reports, it is important to be mindful of the history of regeneration research, which is littered with the corpses of studies that reported regeneration that later proved incorrect. One important reason is the “spared axon conundrum,” in which axons that survive a lesion are mistakenly identified as having regenerated. Here, we illustrate the problem and propose criteria that may be used to identify regenerated vs. spared axons, focusing on the injured spinal cord. J. Comp. Neurol. 459:1–8, 2003.

Growth of a new fiber projection in the brain of adult rats: Re-innervation of the dentate gyrus by the contralateral entorhinal cortex following ipsilateral entorhinal lesions

SummaryAblation of the entorhinal cortex of the rat removes the major synaptic input to the granule cells of the ipsilateral dentate gyrus. Following unilateral entorhinal lesions in adult rats, we have examined the efferent projections of the remaining contralateral entorhinal cortex to determine if these might sprout to re-innervate the deafferented dentate gyrus. Autoradiographical tracing of the fiber projections of the remaining contralateral entorhinal cortex 60 days following lesions indicates that new fibers sprout and grow for several hundred microns into the denervated regions, to terminate on portions of the granule cell dendrites which would normally receive ipsilateral entorhinal afferents.These re-innervating fibers form electrophysiologically functional synaptic connections with the denervated dentate granule cells. In the normal animal, unilateral stimulation of the entorhinal cortex does not result in short latency activation of the contralateral dentate gyrus whereas following ipsilateral entorhinal lesions, re-innervation by contralateral entorhinal afferents is reflected electrophysiologically by the appearance of a new short latency evoked potential to contralateral entorhinal stimulation. By field potential analysis, we demonstrate that this new short latency evoked potential is a reflection of mono-synaptic activation of the denervated dentate granule cells by the re-innervating contralateral entorhinal fibers.In addition, the time course of contralateral entorhinal re-innervation is determined electrophysiologically. The new short latency response to contralateral entorhinal stimulation appears as early as 9 days post-lesion, matures functionally between 9 and 15 days, and after 15 days, remains apparently undiminished for as long as 200 days. This implies that the new synapses formed in response to a deafferenting lesion are formed rapidly and remain permanently capable of activating the dentate granule cells which had been deprived of ipsilateral entorhinal input.

Concepts and Methods for the Study of Axonal Regeneration in the CNS

Progress in the field of axonal regeneration research has been like the process of axonal growth itself: there is steady progress toward reaching the target, but there are episodes of mistargeting, misguidance along false routes, and connections that must later be withdrawn. This primer will address issues in the study of axonal growth after central nervous system injury in an attempt to provide guidance toward the goal of progress in the field. We address definitions of axonal growth, sprouting and regeneration after injury, and the research tools to assess growth.