Susan L. Semple-Rowland

Cytokine mRNA Profiles in Contused Spinal Cord and Axotomized Facial Nucleus Suggest a Beneficial Role for Inflammation and Gliosis

We have studied temporal mRNA expression patterns for interleukin-1beta (IL-1beta), tumor necrosis factor-alpha (TNF-alpha), interleukin-6 (IL-6), macrophage colony stimulating factor (M-CSF), and transforming growth factor-beta1 (TGF-beta1) in two rat injury paradigms with very different cellular inflammatory reactions: contussion of the spinal cord and axotomy of the facial nerve. Our comparative analyses using semiquantitative reverse transcription polymerase chain reaction (RT-PCR) show an early and robust upregulation of IL-1beta, TNF-alpha, IL-6, and M-CSF mRNAs in spinal cord after contusion injury. Peak expression of these mRNAs was transient and returned to control levels by 24 h postinjury. In contrast, expression of IL-1beta and TNF-alpha mRNAs in the axotomized facial nucleus was minimal and delayed, and levels of M-CSF mRNA remained unaltered. Similar to injured spinal cord, the axotomized nucleus showed a dramatic and early upregulation of IL-6 mRNA, but unlike spinal cord, IL-6 mRNA levels subsided only gradually. Both injury paradigms showed gradually increasing levels of TGF-beta1 mRNA which were maximal at 7 days postinjury. RT-PCR analyses were also performed on isolated blood-borne mononuclear cells and neutrophils. The results showed that these cells contain high levels of IL-1beta and M-CSF mRNAs, moderate levels of TGF-beta and TNF-alpha mRNAs, and minimal levels of IL-6 mRNA. The RT-PCR analyses together with histological observations indicate that expression of the proinflammatory cytokines IL-1beta, TNF-alpha, and IL-6 is short-lived and self-limited after contusion injury, and that it occurs primarily within endogenous glial cells. Transient expression of these molecules likely triggers secondary events which may be beneficial to wound repair and regeneration.

Hippocampal polymorph neurons are the cells of origin for ipsilateral association and commissural afferents to the dentate gyrus

Neurons in the polymorph layer of the hippocampal dentate hilus were found to be the cells of origin for ipsilateral association and commissural projections to the dentate gyrus. Both afferent systems terminate in the proximal one-third of the stratum moleculare. The polymorph layer is the primary target for noradrenergic, serotonergic and cholinergic input to the hippocampal dentate region. It is hypothesized that one or all of these afferent groups affect hippocampal function through synaptic modification of the defined polymorph afferent system.

Comparative evaluation of cytokine profiles and reactive gliosis supports a critical role for interleukin-6 in neuron-glia signaling during regeneration.

Using reverse transcription polymerase chain reaction (RT‐PCR), we have studied the temporal expression of interleukin‐1β (IL‐1β), interleukin‐6 (IL‐6), transforming growth factor‐β 1 (TGF‐β 1), and tumor necrosis factor‐α (TNF‐α) mRNAs in three axotomy paradigms with distinct functional outcomes. Axotomy of adult rat facial motoneurons results in neuronal regeneration, axotomy of neonatal facial motoneurons results in neuronal apoptosis, and axotomy of rubrospinal neurons results in neuronal atrophy. Our RT‐PCR findings show that a significant and sustained upregulation of IL‐6 mRNA is associated uniquely with the regeneration of adult facial motoneurons. Histochemical studies using IL‐6 immunohistochemistry show intense IL‐6 immunoreactivity in axotomized adult facial motoneurons. Assessment of reactive glial changes with astroglial and microglial markers reveals that the reactive gliosis following adult facial nerve axotomy is more intense than that observed in either of the other two paradigms. Exposure of cultured microglial cells to IL‐6 stimulates microglial proliferation in a dose‐dependent manner. Cultured microglia also show expression of IL‐6 receptor mRNA, as determined by RT‐PCR. Our findings support the idea that reactive gliosis is required for neuron regeneration to occur, and more specifically, they suggest that neuron‐derived IL‐6 serves as a signalling molecule that induces microglial proliferation during motoneuron regeneration. J. Neurosci. Res. 61:10–20, 2000.

Lentiviral expression of retinal guanylate cyclase-1 (RetGC1) restores vision in an avian model of childhood blindness.

Background Leber congenital amaurosis (LCA) is a genetically heterogeneous group of retinal diseases that cause congenital blindness in infants and children. Mutations in the GUCY2D gene that encodes retinal guanylate cyclase–1 (retGC1) were the first to be linked to this disease group (LCA type 1 [LCA1]) and account for 10%–20% of LCA cases. These mutations disrupt synthesis of cGMP in photoreceptor cells, a key second messenger required for function of these cells. The GUCY1*B chicken, which carries a null mutation in the retGC1 gene, is blind at hatching and serves as an animal model for the study of LCA1 pathology and potential treatments in humans. Methods and Findings A lentivirus-based gene transfer vector carrying the GUCY2D gene was developed and injected into early-stage GUCY1*B embryos to determine if photoreceptor function and sight could be restored to these animals. Like human LCA1, the avian disease shows early-onset blindness, but there is a window of opportunity for intervention. In both diseases there is a period of photoreceptor cell dysfunction that precedes retinal degeneration. Of seven treated animals, six exhibited sight as evidenced by robust optokinetic and volitional visual behaviors. Electroretinographic responses, absent in untreated animals, were partially restored in treated animals. Morphological analyses indicated there was slowing of the retinal degeneration. Conclusions Blindness associated with loss of function of retGC1 in the GUCY1*B avian model of LCA1 can be reversed using viral vector-mediated gene transfer. Furthermore, this reversal can be achieved by restoring function to a relatively low percentage of retinal photoreceptors. These results represent a first step toward development of gene therapies for one of the more common forms of childhood blindness.

Viral Vector–mediated Delivery of Estrogen Receptor-α to the Hippocampus Improves Spatial Learning in Estrogen Receptor-α Knockout Mice

Estrogen, which influences both classical genomic and rapid membrane-associated signaling cascades, has been implicated in the regulation of hippocampal function, including spatial learning. Gene mutation studies suggest that estrogen effects are mediated by estrogen receptor-alpha (ER-alpha); however, because gonadal steroids influence the organization of the hippocampus during development, it has been difficult to distinguish developmental effects from those specific to adults. In this study we show that lentiviral delivery of the gene encoding ER-alpha to the hippocampus of adult ER-alpha-knockout (ER-alphaKO) mice restores hippocampal responsiveness to estrogen and rescues spatial learning. We propose that constitutive estrogen receptor activity is important for maintaining hippocampus-dependent memory function in adults.Estrogen, which influences both classical genomic and rapid membrane-associated signaling cascades, has been implicated in the regulation of hippocampal function, including spatial learning. Gene mutation studies suggest that estrogen effects are mediated by estrogen receptor-α (ER-α); however, because gonadal steroids influence the organization of the hippocampus during development, it has been difficult to distinguish developmental effects from those specific to adults. In this study we show that lentiviral delivery of the gene encoding ER-α to the hippocampus of adult ER-α-knockout (ER-αKO) mice restores hippocampal responsiveness to estrogen and rescues spatial learning. We propose that constitutive estrogen receptor activity is important for maintaining hippocampus-dependent memory function in adults.

Arborization of dendrites by developing neocortical neurons is dependent on primary cilia and type 3 adenylyl cyclase.

The formation of primary cilia is a highly choreographed process that can be disrupted in developing neurons by overexpressing neuromodulatory G-protein-coupled receptors GPCRs or by blocking intraflagellar transport. Here, we examined the effects of overexpressing the ciliary GPCRs, 5HT6 and SSTR3, on cilia structure and the differentiation of neocortical neurons. Neuronal overexpression of 5HT6 and SSTR3 was achieved by electroporating mouse embryo cortex in utero with vectors encoding these receptors. We found that overexpression of ciliary GPCRs in cortical neurons, especially 5HT6, induced the formation of long (>30 μm) and often forked cilia. These changes were associated with increased levels of intraflagellar transport proteins and accelerated ciliogenesis in neonatal neocortex, the induction of which required Kif3a, an anterograde motor critical for cilia protein trafficking and growth. GPCR overexpression also altered the complement of signaling molecules within the cilia. We found that SSTR3 and type III adenylyl cyclase (ACIII), proteins normally enriched in neuronal cilia, were rarely detected in 5HT6-elongated cilia. Intriguingly, the changes in cilia structure were accompanied by changes in neuronal morphology. Specifically, disruption of normal ciliogenesis in developing neocortical neurons, either by overexpressing cilia GPCRs or a dominant-negative form of Kif3a, significantly impaired dendrite outgrowth. Remarkably, coexpression of ACIII with 5HT6 restored ACIII to cilia, normalized cilia structure, and restored dendrite outgrowth, effects that were not observed in neurons coexpressing ACIII and dominant-negative form of Kif3a. Collectively, our data suggest the formation of neuronal dendrites in developing neocortex requires structurally normal cilia enriched with ACIII.

Role of Estrogen Receptor α and β in Preserving Hippocampal Function during Aging

The expression of the ERα and ERβ estrogen receptors in the hippocampus may be important in the etiology of age-related cognitive decline. To examine the role of ERα and ERβ in regulating transcription and learning, ovariectomized wild-type (WT) and ERα and ERβ knockout (KO) mice were used. Hippocampal gene transcription in young ERαKO mice was similar to WT mice 6 h after a single estradiol treatment. In middle-age ERαKO mice, hormone deprivation was associated with a decrease in the expression of select genes associated with the blood–brain barrier; cyclic estradiol treatment increased transcription of these select genes and improved learning in these mice. In contrast to ERαKO mice, ERβKO mice exhibited a basal hippocampal gene profile similar to WT mice treated with estradiol and, in the absence of estradiol treatment, young and middle-age ERβKO mice exhibited preserved learning on the water maze. The preserved memory performance of middle-age ERβKO mice could be reversed by lentiviral delivery of ERβ to the hippocampus. These results suggest that one function of ERβ is to regulate ERα-mediated transcription in the hippocampus. This model is supported by our observations that knockout of ERβ under conditions of low estradiol allowed ERα-mediated transcription. As estradiol levels increased in the absence of ERα, we observed that other mechanisms, likely including ERβ, regulated transcription and maintained hippocampal-dependent memory. Thus, our results indicate that ERα and ERβ interact with hormone levels to regulate transcription involved in maintaining hippocampal function during aging.

Cytokine transcripts expressed by microglia in vitro are not expressed by ameboid microglia of the developing rat central nervous system.

Because of morphological similarities between ameboid microglia in the developing central nervous system (CNS), brain macrophages in the injured CNS, and cultured microglia in vitro, it is thought that these cell types are functionally equivalent. To investigate the validity of this assumption, we have compared mRNA levels of interleukin‐1α and ‐1β (IL‐1α and IL‐1β), tumor necrosis factor‐α and ‐β (TNF‐α and TNF‐β), transforming growth factor‐β1 (TGF‐β1), and macrophage colony‐stimulating factor (M‐CSF) in the postnatal day 4 (P4) supraventricular corpus callosum (SVCC) with those in unstimulated cultured microglia. Control tissues included spleen, cortex, hippocampus, and cerebellum. Our analyses have shown that while IL‐1α, IL‐1β, TNF‐α, TNF‐β, and TGF‐β1 transcripts are abundantly expressed by cultured microglia, they are very low to virtually undetectable in the SVCC. These data strongly suggest that ameboid microglia, which are concentrated in the SVCC, are unlikely to be a significant source of these cytokines. Our study, which shows clear differences in the functional status of cultured microglia vs. ameboid microglia in vivo, stresses the importance of using caution when interpreting in vitro findings in terms of the in vivo functions of microglia. GLIA 25:304–309, 1999.

Circadian regulation of iodopsin and clock is altered in the retinal degeneration chicken retina

We are interested in determining if the visual phototransduction cascade plays a role in light entrainment of photoreceptor circadian oscillators. In this study, we compared mRNA levels of iodopsin and the chicken homolog of Clock (cClock) in the retinas of normal and rd (retinal degeneration) chickens that lack functional rod and cone phototransduction cascades. Iodopsin is a circadian-regulated, photoreceptor-specific gene expressed in chicken retina, and Clock is a transcription factor that has been shown to play a role in the circadian clock mechanism in mouse and Drosophila. The results of our analyses show that cClock and iodopsin transcript levels undergo daily oscillations in retinas of normal animals housed under 12 h light:12 h dark (12L:12D) conditions, and that these oscillations are maintained in the absence of light. Levels of these transcripts in the retinas of rd/rd chickens housed under cyclic light conditions did not change significantly over the course of a 12L:12D cycle; however, there was evidence that the photoreceptor oscillators were entrained in these animals. Comparisons of our normal and rd/rd data suggest that there are at least two light entrainment pathways that impinge on the oscillators found in photoreceptor cells, one of which is effectively disabled by the GC1 null mutation carried by the rd chicken.

Reduction of Dicer Impairs Schwann Cell Differentiation and Myelination

The process of Schwann cell myelination requires precisely coordinated gene expression. At the onset of myelination, there is an increase in the expression of differentiation‐promoting transcription factors that regulate key Schwann cell genes. Further control of myelin gene expression occurs at the posttranscriptional level and, in part, is mediated by RNA binding proteins and micro‐RNAs (miRNAs). miRNAs are small, endogenously derived RNA molecules that repress gene expression by specifically binding to their mRNA targets. In the experiments described here, we tested whether miRNAs were essential in controlling myelination by reducing the levels of Dicer, an essential endoribonuclease in miRNA biogenesis. We decreased the expression of Dicer by about 60% within Schwann cells using a lentiviral vector expressing an shRNA against Dicer. The reduced levels of Dicer led to a decrease in the steady‐state expression of selected miRNAs and of the transcription factors Oct6 and Egr2/Krox20, both of which are critical for Schwann cells differentiation and myelination. In contrast, the levels of c‐jun and Sox2 were up‐regulated by the reduction in Dicer and were associated with an increase in Schwann cell proliferation. In dorsal root ganglion cocultures, Schwann cells transduced with Dicer shRNA synthesized less myelin, which was accompanied by significant reductions in the levels of myelin basic protein and protein zero. These findings support a critical role for Dicer and miRNAs in Schwann cell differentiation and myelination.