Rachel M. Sherrard

Transcranial pulsed magnetic field stimulation facilitates reorganization of abnormal neural circuits and corrects behavioral deficits without disrupting normal connectivity

Although the organization of neuronal circuitry is shaped by activity patterns, the capacity to modify and/or optimize the structure and function of whole projection pathways using external stimuli is poorly defined. We investigate whether neuronal activity induced by pulsed magnetic fields (PMFs) alters brain structure and function. We delivered low‐intensity PMFs to the posterior cranium of awake, unrestrained mice (wild‐type and ephrin‐A2A5 ‐/‐) that have disorganized retinocollicular circuitry and associated visuomotor deficits. Control groups of each genotype received sham stimulation. Following daily stimulation for 14 d, we measured biochemical, structural (anterograde tracing), and functional (electrophysiology and behavior) changes in the retinocollicular projection. PMFs induced BDNF, GABA, and nNOS expression in the superior colliculus and retina of wild‐type and ephrin‐A2A5‐/‐ mice. Furthermore, in ephrin‐A2A5‐/‐mice, PMFs corrected abnormal neuronal responses and selectively removed inaccurate ectopic axon terminals to improve structural and functional organization of their retinocollicular projection and restore normal visual tracking behavior. In contrast, PMFs did not alter the structure or function of the normal projection in wild‐type mice. Sham PMF stimulation had no effect on any mice. Thus, PMF‐induced biochemical changes are congruent with its capacity to facilitate beneficial reorganization of abnormal neural circuits without disrupting normal connectivity and function.—Rodger, J., Mo, C., Wilks, T., Dunlop, S. A., Sherrard, R. M. Transcranial pulsed magnetic field stimulation facilitates reorganization of abnormal neural circuits and corrects behavioral deficits without disrupting normal connectivity. FASEB J. 26, 1593‐1606 (2012). www.fasebj.org

Functional Topography and Integration of the Contralateral and Ipsilateral Retinocollicular Projections of Ephrin-A−/− Mice

Topographically ordered projections are established by molecular guidance cues and refined by neuronal activity. Retinal input to a primary visual center, the superior colliculus (SC), is bilateral with a dense contralateral projection and a sparse ipsilateral one. Both projections are topographically organized, but in opposing anterior–posterior orientations. This arrangement provides functionally coherent input to each colliculus from the binocular visual field, supporting visual function. When guidance cues involved in contralateral topography (ephrin-As) are absent, crossed retinal ganglion cell (RGC) axons form inappropriate terminations within the SC. However, the organization of the ipsilateral projection relative to the abnormal contralateral input remains unknown, as does the functional capacity of both projections. We show here that in ephrin-A−/− mice, the SC contains an expanded, diffuse ipsilateral projection. Electrophysiological recording demonstrated that topography of visually evoked responses recorded from the contralateral superior colliculus of ephrin-A−/− mice displayed similar functional disorder in all genotypes, contrasting with their different degrees of anatomical disorder. In contrast, ipsilateral responses were retinotopic in ephrin-A2−/− but disorganized in ephrin-A2/A5−/− mice. The lack of integration of binocular input resulted in specific visual deficits, which could be reversed by occlusion of one eye. The discrepancy between anatomical and functional topography in both the ipsilateral and contralateral projections implies suppression of inappropriately located terminals. Moreover, the misalignment of ipsilateral and contralateral visual information in ephrin-A2/A5−/− mice suggests a role for ephrin-As in integrating convergent visual inputs.

Low-Intensity Repetitive Transcranial Magnetic Stimulation Improves Abnormal Visual Cortical Circuit Topography and Upregulates BDNF in Mice

Repetitive transcranial magnetic stimulation (rTMS) is increasingly used as a treatment for neurological and psychiatric disorders. Although the induced field is focused on a target region during rTMS, adjacent areas also receive stimulation at a lower intensity and the contribution of this perifocal stimulation to network-wide effects is poorly defined. Here, we examined low-intensity rTMS (LI-rTMS)-induced changes on a model neural network using the visual systems of normal (C57Bl/6J wild-type, n = 22) and ephrin-A2A5−/− (n = 22) mice, the latter possessing visuotopic anomalies. Mice were treated with LI-rTMS or sham (handling control) daily for 14 d, then fluorojade and fluororuby were injected into visual cortex. The distribution of dorsal LGN (dLGN) neurons and corticotectal terminal zones (TZs) was mapped and disorder defined by comparing their actual location with that predicted by injection sites. In the afferent geniculocortical projection, LI-rTMS decreased the abnormally high dispersion of retrogradely labeled neurons in the dLGN of ephrin-A2A5−/− mice, indicating geniculocortical map refinement. In the corticotectal efferents, LI-rTMS improved topography of the most abnormal TZs in ephrin-A2A5−/− mice without altering topographically normal TZs. To investigate a possible molecular mechanism for LI-rTMS-induced structural plasticity, we measured brain derived neurotrophic factor (BDNF) in the visual cortex and superior colliculus after single and multiple stimulations. BDNF was upregulated after a single stimulation for all groups, but only sustained in the superior colliculus of ephrin-A2A5−/− mice. Our results show that LI-rTMS upregulates BDNF, promoting a plastic environment conducive to beneficial reorganization of abnormal cortical circuits, information that has important implications for clinical rTMS.

Differential expression of TrkB isoforms switches climbing fiber-Purkinje cell synaptogenesis to selective synapse elimination

Correct neural function depends on precisely organized connectivity, which is refined from broader projections through synaptic/collateral elimination. In the rat, olivocerebellar topography is refined by regression of multiple climbing fiber (CF) innervation of Purkinje cells (PC) during the first two postnatal weeks. The molecules that initiate this regression are not fully understood. We assessed the role of cerebellar neurotrophins by examining tropomycin receptor kinase (Trk) receptor expression in the inferior olive and cerebellum between postnatal days (P)3‐7, when CF‐PC innervation changes from synapse formation to selective synapse elimination, and in a denervation‐reinnervation model when synaptogenesis is delayed. Trks A, B, and C are expressed in olivary neurons; although TrkA was not transported to the cerebellum and TrkC was unchanged during innervation and reinnervation, suggesting that neither receptor is involved in CF‐PC synaptogenesis. In contrast, both total and truncated TrkB (TrkB.T) increased in the olive and cerebellum from P4, whereas full‐length and activated phosphorylated TrkB (phospho‐TrkB) decreased from P4‐5. This reveals less TrkB signaling at the onset of CF regression. This expression pattern was reproduced during CF‐PC reinnervation: in the denervated hemicerebellum phospho‐TrkB decreased as CF terminals degenerated, then increased in parallel with the delayed neosynaptogenesis as new CFs reinnervated the denervated hemicerebellum. In the absence of this signaling, CF reinnervation did not develop. Our data reveal that olivocerebellar TrkB activity parallels CF‐PC synaptic formation and stabilization and is required for neosynaptogenesis. Furthermore, TrkB.T expression rises to reduce TrkB signaling and permit synapse elimination.

Post-lesion transcommissural growth of olivary climbing fibres creates functional synaptic microzones

In the adult mammalian central nervous system, reinnervation and recovery from trauma is limited. During development, however, postlesion plasticity may generate alternate paths, providing models to investigate reinnervating axon–target interactions. After unilateral transection of the neonatal rat olivocerebellar path, axons from the ipsilateral inferior olive grow into the denervated hemicerebellum and develop climbing fibre (CF)‐like arbors on Purkinje cells (PCs). However, the synaptic function and extent of PC reinnervation remain unknown. In adult rats pedunculotomized on postnatal day 3 the morphological and electrophysiological properties of reinnervating olivocerebellar axons were studied, using axonal reconstruction and patch‐clamp PC recording of CF‐induced synaptic currents. Reinnervated PCs displayed normal CF currents, and the frequency of PC reinnervation decreased with increasing laterality. Reinnervating CF arbors were predominantly normal but 6% branched within the molecular layer forming smaller secondary arbors. CFs arose from transcommissural olivary axons, which branched extensively near their target PCs to produce on average 36 CFs, which is six times more than normal. Axons terminating in the hemisphere developed more CFs than those terminating in the vermis. However, the precise parasagittal microzone organization was preserved. Transcommissural axons also branched, although to a lesser extent, to the deep cerebellar nuclei and terminated in a distribution indicative of the olivo‐cortico‐nuclear circuit. These results show that reinnervating olivocerebellar axons are highly plastic in the cerebellum, compensating anatomically and functionally for early postnatal denervation, and that this reparation obeys precise topographic constraints although axonal plasticity is modified by target (PC or deep nuclear neurons) interactions.

BDNF increases homotypic olivocerebellar reinnervation and associated fine motor and cognitive skill

Recovery of complex neural function after injury to the adult CNS is limited by minimal spontaneous axonal regeneration and/or sprouting from remaining pathways. In contrast, the developing CNS displays spontaneous reorganization following lesion, in which uninjured axons can develop new projections to appropriate target neurons and provide partial recovery of complex behaviours. Similar pathways can be induced in the mature CNS, providing models to optimize post-injury recovery of complex neural functions. After unilateral transection of a developing olivocerebellar path (pedunculotomy), remaining inferior olivary axons topographically reinnervate the denervated hemicerebellum and compensate functional deficits. Brain-derived neurotrophic factor (BDNF) partly recreates such reinnervation in the mature cerebellum. However the function of this incomplete reinnervation and any unwanted behavioural effects of BDNF remain unknown. We measured olivocerebellar reinnervation and tested rotarod and navigation skills in Wistar rats treated with BDNF/vehicle and pedunculotomized on day 3 (Px3; with reinnervation) or 11 (Px11; without spontaneous reinnervation). BDNF treatment did not affect motor or spatial behaviour in normal (control) animals. Px11-BDNF animals equalled controls on the rotarod, outperforming Px11-vehicle animals. Moreover, Px3-BDNF and Px11-BDNF animals achieved spatial learning and memory tasks as well as controls, with Px11-BDNF animals showing better spatial orientation than Px11-vehicle counterparts. BDNF slightly increased olivocerebellar reinnervation in Px3 animals and induced sparse (22% Purkinje cells) yet widespread reinnervation in Px11 animals. As reinnervation correlated with spatial function, these data imply that after injury even a small amount of reinnervation that is homotypic to correct target neurons compensates deficits in appropriate complex motor and spatial skills. As there was no effect in control animals, BDNF effectively induces this axon collateralisation without interfering with normal neuronal circuits.

Brain-derived neurotrophic factor induces post-lesion transcommissural growth of olivary axons that develop normal climbing fibers on mature Purkinje cells

In the adult mammalian central nervous system, reinnervation and recovery from trauma is limited. During development, however, post-lesion plasticity may generate alternate paths providing models to investigate factors that promote reinnervation to appropriate targets. Following unilateral transection of the neonatal rat olivocerebellar pathway, axons from the remaining inferior olive reinnervate the denervated hemicerebellum and develop climbing fiber arbors on Purkinje cells. However, the capacity to recreate this accurate target reinnervation in a mature system remains unknown. In rats lesioned on day 15 (P15) or 30 and treated with intracerebellar injection of brain-derived neurotrophic factor (BDNF) or vehicle 24 h later, the morphology and organisation of transcommissural olivocerebellar reinnervation was examined using neuronal tracing and immunohistochemistry. In all animals BDNF, but not vehicle, induced transcommissural olivocerebellar axonal growth into the denervated hemicerebellum. The distribution of reinnervating climbing fibers was not confined to the injection sites but extended throughout the denervated hemivermis and, less densely, up to 3.5 mm into the hemisphere. Transcommissural olivocerebellar axons were organised into parasagittal microzones that were almost symmetrical to those in the right hemicerebellum. Reinnervating climbing fiber arbors were predominantly normal, but in the P30-lesioned group 10% were either branched within the molecular layer forming a smaller secondary arbor or were less branched, and in the P15 lesion group the reinnervating arbors extended their terminals almost to the pial surface and were larger than control arbors (P < 0.02). These results show that BDNF can induce transcommissural olivocerebellar reinnervation, which resembles developmental neuroplasticity to promote appropriate target reinnervation in a mature environment.

Climbing fiber development: do neurotrophins have a part to play?

The climbing fiber input to the cerebellum is crucial for its normal function but those factors which control the development of this precisely organized pathway are not fully elucidated. The neurotrophins are a family of peptides, which have many roles during development of the nervous system, including the cerebellum. Since the cerebellum and inferior olive express neurotrophins and their receptors, we propose that neurotrophins are involved in the regulation of climbing fiber development. Here we review the temporo-spatial expression of neurotrophins and their receptors at key ages during climbing fiber development and then examine evidence linking neurotrophins to climbing fiber development, including some of the intracellular pathways involved. During prenatal development the expression of neurotrophins in the hindbrain coupled with their function in neurogenesis and migration, is consistent with a role of NT3 in inferior olivary genesis. Subsequently, cerebellar expression of two neurotrophins, NT3 and NT4, is concurrent with olivary receptor expression and the time of olivary axonal outgrowth and this continues postnatally during early climbing fiber synaptogenesis on Purkinje cells. The expression-pattern of neurotrophins changes with age, with falling NGF, NT3 and NT4 but increasing granule cell BDNF. Importantly, olivary expression of neurotrophin receptors, and therefore climbing fiber responsiveness to neurotrophins, falls specifically during maturation of the climbing fiber-Purkinje cell synapse. The function of BDNF is less certain, but experimental studies indicate that it has a role in climbing fiber innervation of Purkinje cells, particularly synaptogenesis and synaptic plasticity. Its importance is highlighted by the overlap of BDNF signalling with several cellular pathways, which regulate climbing fiber maturation. From the data presented, we propose not only that neurotrophins are involved in climbing fiber development, but also that several act in a specific temporal order.

Mature Purkinje Cells Require the Retinoic Acid-Related Orphan Receptor-α (RORα) to Maintain Climbing Fiber Mono-Innervation and Other Adult Characteristics

Neuronal maturation during development is a multistep process regulated by transcription factors. The transcription factor RORα (retinoic acid-related orphan receptor α) is necessary for early Purkinje cell (PC) maturation but is also expressed throughout adulthood. To identify the role of RORα in mature PCs, we used Cre-lox mouse genetic tools in vivo that delete it specifically from PCs between postnatal days 10–21. Up to 14 d of age, differences between mutant and control PCs were not detectable: both were mono-innervated by climbing fibers (CFs) extending along their well-developed dendrites with spiny branchlets. By week 4, mutant mice were ataxic, some PCs had died, and remaining PC soma and dendrites were atrophic, with almost complete disappearance of spiny branchlets. The innervation pattern of surviving RORα-deleted PCs was abnormal with several immature characteristics. Notably, multiple functional CF innervation was reestablished on these mature PCs, simultaneously with the relocation of CF contacts to the PC soma and their stem dendrite. This morphological modification of CF contacts could be induced even later, using lentivirus-mediated depletion of rora from adult PCs. These data show that the late postnatal expression of RORα cell-autonomously regulates the maintenance of PC dendritic complexity, and the CF innervation status of the PC (dendritic vs somatic contacts, and mono-innervation vs multi-innervation). Thus, the differentiation state of adult neurons is under the control of transcription factors; and in their absence, adult neurons lose their mature characteristics and acquire some characteristics of an earlier developmental stage.

Investigation of sex differences in the expression of RORA and its transcriptional targets in the brain as a potential contributor to the sex bias in autism

BackgroundAutism spectrum disorder (ASD) is a neurodevelopmental condition characterized by significant impairment in reciprocal social interactions and communication coupled with stereotyped, repetitive behaviors and restricted interests. Although genomic and functional studies are beginning to reveal some of the genetic complexity and underlying pathobiology of ASD, the consistently reported male bias of ASD remains an enigma. We have recently proposed that retinoic acid-related orphan receptor alpha (RORA), which is reduced in the brain and lymphoblastoid cell lines of multiple cohorts of individuals with ASD and oppositely regulated by male and female hormones, might contribute to the sex bias in autism by differentially regulating target genes, including CYP19A1 (aromatase), in a sex-dependent manner that can also lead to elevated testosterone levels, a proposed risk factor for autism.MethodsIn this study, we examine sex differences in RORA and aromatase protein levels in cortical tissues of unaffected and affected males and females by re-analyzing pre-existing confocal immunofluorescence data from our laboratory. We further investigated the expression of RORA and its correlation with several of its validated transcriptional targets in the orbital frontal cortex and cerebellum as a function of development using RNAseq data from the BrainSpan Atlas of the Developing Human Brain. In a pilot study, we also analyzed the expression of Rora and the same transcriptional targets in the cortex and cerebellum of adult wild-type male and female C57BL/6 mice.ResultsOur findings suggest that Rora/RORA and several of its transcriptional targets may exhibit sexually dimorphic expression in certain regions of the brain of both mice and humans. Interestingly, the correlation coefficients between Rora expression and that of its targets are much higher in the cortex of male mice relative to that of female mice. A strong positive correlation between the levels of RORA and aromatase proteins is also seen in the cortex of control human males and females as well as ASD males, but not ASD females.ConclusionsBased on these studies, we suggest that disruption of Rora/RORA expression may have a greater impact on males, since sex differences in the correlation of RORA and target gene expression indicate that RORA-deficient males may experience greater dysregulation of genes relevant to ASD in certain brain regions during development.