Lori Lebson

Trafficking CD11b-Positive Blood Cells Deliver Therapeutic Genes to the Brain of Amyloid-Depositing Transgenic Mice

A major question for gene therapy in brain concerns methods to administer therapeutic genes in a uniform manner over major portions of the brain. A second question in neuroimmunology concerns the extent to which monocytes migrate to the CNS in degenerative disorders. Here we show that CD11b+ cells (largely monocytes) isolated from the bone marrow of GFP (green fluorescent protein)-expressing donors spontaneously home to compacted amyloid plaques in the brain. Injections of these cells as a single pulse show a rapid clearance from circulation (90 min half-life) and tissue residence half-lives of ∼3 d. The uptake into brain was minimal in nontransgenic mice. In transgenic mice containing amyloid deposits, uptake was dramatically increased and associated with a corresponding decrease in monocyte uptake into peripheral organs compared to nontransgenic littermates. Twice weekly infusions of the CD11b+ bone marrow cells transfected with a genetically engineered form of the protease neprilysin completely arrest amyloid deposition in an aggressively depositing transgenic model. Exploiting the natural homing properties of peripherally derived blood cells to deliver therapeutic genes has the advantages of access to the entire CNS, expression largely restricted to sites of injury, low risk of immune reactivity, and fading of expression if adverse reactions are encountered. These observations support the feasibility of testing autologous monocytes for application of therapeutic genes in human CNS disease. Moreover, these data support the results from bone marrow grafts that circulating CD11b+ cells can enter the CNS without requiring the use of lethal irradiation.

Aging Analysis Reveals Slowed Tau Turnover and Enhanced Stress Response in a Mouse Model of Tauopathy

We have extensively analyzed the biochemical and histochemical profiles of the tau protein from the rTg4510 transgenic mouse model in which the animals uniquely develop forebrain tau pathologies similar to those found in human tauopathies. Levels of several soluble phosphorylated tau species were highest at 1 month relative to later time points, suggesting that certain tau hyperphosphorylation events were insufficient to drive tangle formation in young mice. Despite a robust, pre-tangle-like accumulation of phospho-tau in 1-month-old mice, this material was cleared by 3 months, indicating that the young mouse brain either fails to facilitate tau insolubility or possesses an enhanced ability to clear tau relative to the adult. We also found that while heat shock protein expression increased with normal aging, this process was accelerated in rTg4510 mice. Moreover, by exploiting an exon 10 (-) specific antibody, we demonstrated that endogenous mouse tau turnover was slowed in response to human tau over-expression, and that this endogenous tau adopted disease-related properties. These data suggest that a younger brain fails to develop lasting tau pathology despite elevated levels of phosphorylated tau, perhaps because of reduced expression of stress-related proteins. Moreover, we show that the active production of small amounts of abnormal tau protein facilitates dysfunction and accumulation of otherwise normal tau, a significant implication for the pathogenesis of patients with Alzheimers disease.

Aging enhances classical activation but mitigates alternative activation in the central nervous system

The roles of microglia and macrophages during neuroinflammation and neurodegenerative diseases remain controversial. To date, at least 2 activations states have been suggested, consisting of a classical response (M1) and the alternative response (M2). Identifying selective biomarkers of microglia that representative their functional activation states may help elucidate disease course and enable a better understanding of repair mechanisms. Two cocktails containing either tumor necrosis factor (TNF)-α, interleukin (IL)-12, and IL-1β (referred to as CKT-1) or IL-13 and IL-4 (referred to CKT-2) were injections into the hippocampus of mice aged 6, 12, or 24 months. Microarray analysis was performed on hippocampal tissue 3 days postinjection. Gene transcripts were compared between CKT-1 versus CKT-2 stimulator cocktails. Several selective transcripts expressed for the CKT-1 included CXCL13, haptoglobin, MARCO, and calgranulin B, whereas a smaller subset of genes was selectively induced by the CKT-2 and consisted of FIZZ1, IGF-1, and EAR 11. Importantly, selective transcripts were induced at all ages by CKT-1, whereas selective gene transcripts induced by CKT-2 decreased with age suggesting an age-related reduction in the IL-4/ IL-13 signaling pathway.

Kv1.3 Deletion Biases T Cells toward an Immunoregulatory Phenotype and Renders Mice Resistant to Autoimmune Encephalomyelitis

Increasing evidence suggests ion channels have critical functions in the differentiation and plasticity of T cells. Kv1.3, a voltage-gated K+ channel, is a functional marker and a pharmacological target for activated effector memory T cells. Selective Kv1.3 blockers have been shown to inhibit proliferation and cytokine production by human and rat effector memory T cells. We used Kv1.3 knockout (KO) mice to investigate the mechanism by which Kv1.3 blockade affects CD4+ T cell differentiation during an inflammatory immune-mediated disease. Kv1.3 KO animals displayed significantly lower incidence and severity of myelin oligodendrocyte glycoprotein (MOG) peptide-induced experimental autoimmune encephalomyelitis. Kv1.3 was the only KV channel expressed in MOG 35–55-specific CD4+ T cell blasts, and no KV current was present in MOG-specific CD4+ T cell-blasts from Kv1.3 KO mice. Fewer CD4+ T cells migrated to the CNS in Kv1.3 KO mice following disease induction, and Ag-specific proliferation of CD4+ T cells from these mice was impaired with a corresponding cell-cycle delay. Kv1.3 was required for optimal expression of IFN-γ and IL-17, whereas its absence led to increased IL-10 production. Dendritic cells from Kv1.3 KO mice fully activated wild-type CD4+ T cells, indicating a T cell-intrinsic defect in Kv1.3 KO mice. The loss of Kv1.3 led to a suppressive phenotype, which may contribute to the mechanism by which deletion of Kv1.3 produces an immunotherapeutic effect. Skewing of CD4+ T cell differentiation toward Ag-specific regulatory T cells by pharmacological blockade or genetic suppression of Kv1.3 might be beneficial for therapy of immune-mediated diseases such as multiple sclerosis.

Cutting Edge: The Transcription Factor Kruppel-Like Factor 4 Regulates the Differentiation of Th17 Cells Independently of RORγt

Th17 cells play a significant role in inflammatory and autoimmune responses. Although a number of molecular pathways that contribute to the lineage differentiation of T cells have been discovered, the mechanisms by which lineage commitment occurs are not fully understood. Transcription factors play a key role in driving T cells toward specific lineages. We have identified a role for the transcription factor Kruppel-like factor (KLF) 4 in the development of IL-17–producing CD4+ T cells. KLF4 was required for the production of IL-17, and further, chromatin immunoprecipation analysis demonstrated binding of KLF4 to the IL-17 promoter, indicating a direct effect on the regulation of IL-17. Further, KLF4-deficient T cells upregulated expression of retinoic acid-related orphan receptor γt similar to wild-type during the polarization process toward Th17, suggesting that these two transcription factors are regulated independently.

Induction of the glucocorticoid-induced leucine zipper gene limits the efficacy of dendritic cell vaccines

Dendritic cell (DC) vaccines have shown great promise in generating antitumor immune responses but have generally fallen short of producing durable cures. Determining mechanisms by which these vaccines fail will provide one strategy toward improving their success. Several manipulations of DCs have improved their migration and longevity, but the immune inhibitory environment surrounding tumors provides a powerful suppressive influence. To determine the mechanisms by which DCs at the site of the tumor convert to a suppressive phenotype, we evaluated pathways in DCs that become expressed at the tumor site. Our results revealed that tumors lead to induction of the glucocorticoid-induced leucine zipper (GILZ) gene in DCs, and that this gene is critical for the development of tumor-induced tolerance of both DCs and T cells. Previous data suggested that GILZ is a pivotal gene in the balance between activation and tolerance of DCs. Our new data show that GILZ is highly upregulated in DCs in the tumor microenvironment in vivo and that blockade of this gene in DC vaccines significantly improves long-term survival. These results suggest that GILZ may be an ideal candidate gene to target for novel immune-based tumor therapies.

Accelerated axon loss in MOG35-55 experimental autoimmune encephalomyelitis (EAE) in myelin-associated glycoprotein-deficient (MAGKO) mice

Myelin-associated glycoprotein (MAG) expressed by oligodendrocytes promotes the stability of axons but also impedes neural repair by inhibiting axon extension through lesioned white matter. We previously reported exacerbated axon losses in MAGKO as compared to wild type mice, 30days into experimental autoimmune encephalitis (EAE). Here, we report the time course of axon losses in EAE and show this occurs as early as 7days post-immunization, confirming MAG is protective against immune-mediated axon transection events. MAGKO mice also exhibit increased microglial activation prior to EAE, which is not seen in B4galnt1KO mice that also have axon loss, suggesting that the microglial activation may be a consequence of the loss of MAG inhibitory influence, and not a simple result of axonal degeneration.

Chronological Age Impacts Immunotherapy and Monocyte Uptake Independent of Amyloid Load

One vexing issue in biomedical research is the failure of many therapies to translate from success in animal models to effective treatment of human disease. One significant difference between the animal models and the human disease is the age of the subject. Cancer, stroke and Alzheimer’s occur mainly in humans beyond the 75% mean survival age, while most mouse models use juvenile or young adult animals. Here we compare two mouse models of amyloid deposition, the Tg2576 APP model and the more aggressive APP+PS1 model in which a mutant presenilin1 gene is overexpressed with Tg2576. Middle-aged APP+PS1 mice and aged APP mice have similar degrees of amyloid pathology with a few differences that may partially explain some of the differences between the two age cohorts. The first study evaluated production of microhemorrhage by a monoclonal anti-Aβ antibody. We found that in spite of greater amyloid clearance in middle-aged APP+PS1 mice than aged APP mice, the microhemorrhage only developed in old animals. This argues that preclinical studies of immunotherapy in young or middle-aged mice may not predict this potential liability in clinical trials. A second study evaluated the infiltration of systemically injected GFP labeled monocytes into the CNS. Here we find that infiltration is greater in aged mice than middle-aged mice, in spite of greater total Aß staining in the middle–aged animals. We conclude that preclinical studies should be conducted in aged animal models as well as young mice to better prepare for unintended consequences in the human trial.

P3-363: Time course of monocyte infiltration into brain and organs in amyloid-depositing APP+PS1 and nontransgenic mice

important pathology in Alzheimer’s disease. It is well known that A induces neuronal cell death through several pathogenic mechanisms. Although the role of glycogen synthase kinase (GSK)-3 in the neurotoxicity of A has been highlighted, there has been no report evaluating the effect of direct GSK-3 inhibition on A -induced neurotoxicity. In this study, the relationship between GSK-3 activity and A -induced neurotoxicity was explored. Methods: To investigate the role of GSK-3 in A -induced neurotoxicity, neurons were treated with amyloid betaprotein (1-42) (A 42) oligomers with or without the addition of a GSK-3 inhibitor for 72 h. An MTT (3-[4,5-dimethylthiazol-2-yl]-2,5diphenyltetrazolium bromide) assay, trypan blue staining, and DAPI staining all showed that A 42 treatment alone resulted in decreased neuronal cell viability in a concentration-dependent manner. Results: A 42 treatment significantly increased the activity of GSK-3 and cell death signals such as phosphorylated Tau (pThr231), cytosolic cytochrome c, and activated caspase-3. A 42 treatment also resulted in decreased survival signals, including that of heat shock transcription factor-1. Treatment with a GSK-3 inhibitor prevented A -induced cell death. Conclusions: These results suggest that the neurotoxic effect of A 42 is mediated by GSK-3 activation and that inhibition of GSK-3 can reduce A 42-induced neurotoxicity.