Combinatorial actions of Tgfß and Activin ligands promote oligodendrocyte development and CNS myelination.

In the embryonic CNS, development of myelin-forming oligodendrocytes is limited by bone morphogenetic proteins, which constitute one arm of the transforming growth factor-ß (Tgfß) family and signal canonically via Smads 1/5/8. Tgfß ligands and Activins comprise the other arm and signal via Smads 2/3, but their roles in oligodendrocyte development are incompletely characterized. Here, we report that Tgfß ligands and activin B (ActB) act in concert in the mammalian spinal cord to promote oligodendrocyte generation and myelination. In mouse neural tube, newly specified oligodendrocyte progenitors (OLPs) are first exposed to Tgfß ligands in isolation, then later in combination with ActB during maturation. In primary OLP cultures, Tgfß1 and ActB differentially activate canonical Smad3 and non-canonical MAP kinase signaling. Both ligands enhance viability, and Tgfß1 promotes proliferation while ActB supports maturation. Importantly, co-treatment strongly activates both signaling pathways, producing an additive effect on viability and enhancing both proliferation and differentiation such that mature oligodendrocyte numbers are substantially increased. Co-treatment promotes myelination in OLP-neuron co-cultures, and maturing oligodendrocytes in spinal cord white matter display strong Smad3 and MAP kinase activation. In spinal cords of ActB-deficient Inhbb(-/-) embryos, apoptosis in the oligodendrocyte lineage is increased and OLP numbers transiently reduced, but numbers, maturation and myelination recover during the first postnatal week. Smad3(-/-) mice display a more severe phenotype, including diminished viability and proliferation, persistently reduced mature and immature cell numbers, and delayed myelination. Collectively, these findings suggest that, in mammalian spinal cord, Tgfß ligands and ActB together support oligodendrocyte development and myelin formation.

Proapoptotic and antiapoptotic actions of Stat1 versus Stat3 underlie neuroprotective and immunoregulatory functions of IL-11.

Current therapies for multiple sclerosis target inflammation but do not directly address oligodendrocyte protection or myelin repair. The gp130 family cytokines ciliary neurotrophic factor, leukemia inhibitory factor, and IL-11 have been identified as oligodendrocyte growth factors, and IL-11 is also strongly immunoregulatory, but their underlying mechanisms of action are incompletely characterized. In this study, we demonstrate that these effects of IL-11 are mediated via differential regulation of apoptosis in oligodendrocytes versus Ag-presenting dendritic cells (DCs), and are dependent on lineage-specific activity of the transcription factors Stat1 versus Stat3. Focal demyelinating lesions induced in cerebral cortices of IL-11Rα(-/-) mice using stereotactic microinjection of lysolecithin were larger than in controls, and remyelination was delayed. In IL-11Rα(-/-) mice, lesions displayed extensive oligodendrocyte loss and axonal transection, and increased infiltration by inflammatory cells including CD11c(+) DCs, CD3(+) lymphocytes, and CD11b(+) phagocytes. In oligodendrocyte progenitor cell (OPC) cultures, IL-11 restricted caspase 9 activation and apoptosis, and it increased myelination in OPC-neuron cocultures. Importantly, siRNA inhibition of Stat1 enhanced the antiapoptotic effects of IL-11 on OPCs, but IL-11 induced apoptosis in the presence of Stat3 silencing. In contrast, IL-11 augmented caspase activation and apoptosis in cultures of CD11c(+) DCs, but not in CD11b(+) or CD3(+) cells. Inhibition of Stat3 exacerbated the proapoptotic effects of IL-11 on DCs, whereas they were ablated in Stat1(-/-) cultures. Collectively, these findings reveal novel mechanisms underlying the actions of a neuroprotective and immunoregulatory member of the gp130 cytokine family, suggesting avenues to enhance oligodendrocyte viability and restrict CNS inflammation in multiple sclerosis.

TGFbeta1 induces Jagged1 expression in astrocytes via ALK5 and Smad3 and regulates the balance between oligodendrocyte progenitor proliferation and differentiation.

Notch1 receptor signaling regulates oligodendrocyte progenitor differentiation and myelin formation in development, and during remyelination in the adult CNS. In active multiple sclerosis lesions, Notch1 localizes to oligodendrocyte lineage cells, and its ligand Jagged1 is expressed by reactive astrocytes. Here, we examined induction of Jagged1 in human astrocytes, and its impact on oligodendrocyte differentiation. In human astrocyte cultures, the cytokine TGFbeta1 induced Jagged1 expression and blockade of the TGFbeta1 receptor kinase ALK5 abrogated Jagged1 induction. TGFbeta2 and beta3 had similar effects, but induction was not observed in response to the TGFbeta family member activin A or other cytokines. Downstream, TGFbeta1 activated Smad-dependent signaling, and Smad-independent pathways that included PI3 kinase, p38, and JNK MAP kinase, but only inhibition of the Smad-dependent pathway blocked Jagged1 expression. SiRNA inhibition of Smad3 downregulated induction of Jagged1, and this was potentiated by Smad2 siRNA. Purified oligodendrocyte progenitor cells (OPCs) nucleofected with Notch1 intracellular signaling domain displayed a shift towards proliferation at the expense of differentiation, demonstrating functional relevance of Notch1 signaling in OPCs. Furthermore, human OPCs plated onto Jagged1-expressing astrocytes exhibited restricted differentiation. Collectively, these data illustrate the mechanisms underlying Jagged1 induction in human astrocytes, and suggest that TGFbeta1-induced activation of Jagged1-Notch1 signaling may impact the size and differentiation of the OPC pool in the human CNS.

Notch1 signaling plays a role in regulating precursor differentiation during CNS remyelination.

In the developing CNS, Notch1 and its ligand, Jagged1, regulate oligodendrocyte differentiation and myelin formation, but their role in repair of demyelinating lesions in diseases such as multiple sclerosis remains unresolved. To address this question, we generated a mouse model in which we targeted Notch1 inactivation to oligodendrocyte progenitor cells (OPCs) using Olig1Cre and a floxed Notch1 allele, Notch1(12f). During CNS development, OPC differentiation was potentiated in Olig1Cre:Notch1(12f/12f) mice. Importantly, in adults, remyelination of demyelinating lesions was also accelerated, at the expense of proliferation within the progenitor population. Experiments in vitro confirmed that Notch1 signaling was permissive for OPC expansion but inhibited differentiation and myelin formation. These studies also revealed that astrocytes exposed to TGF-beta1 restricted OPC maturation via Jagged1-Notch1 signaling. These data suggest that Notch1 signaling is one of the mechanisms regulating OPC differentiation during CNS remyelination. Thus, Notch1 may represent a potential therapeutical avenue for lesion repair in demyelinating disease.

IL-11 regulates autoimmune demyelination.

Current therapies for the autoimmune demyelinating disease multiple sclerosis (MS) target inflammation, but do not directly address neuroprotection or lesion repair. Cytokines of the gp130 family regulate survival and differentiation of both neural and immune cells, and we recently identified expression of the family member IL-11 in active MS plaques. In this study, we show that IL-11 regulates the clinical course and neuropathology of experimental autoimmune encephalomyelitis, a demyelinating model that mimics many of the clinical and pathologic features of MS. Importantly, the effects of IL-11 are achieved via a combination of immunoregulation and direct neuroprotection. IL-11R-alpha-null (IL-11Ralpha(-/-)) mice displayed a significant increase in clinical severity and neuropathology of experimental autoimmune encephalomyelitis compared with wild-type littermates. Inflammation, demyelination, and oligodendrocyte and neuronal loss were all exacerbated in IL-11Ra(-/-) animals. Conversely, wild-type mice treated with IL-11 displayed milder clinical signs and neuropathology than vehicle-treated controls. In cocultures of murine myelin oligodendrocyte glycoprotein(35-55)-specific CD4+ T lymphocytes and CD11c+ APCs, IL-11 treatment resulted in a significant decrease in T cell-derived effector cytokine production. This effect was generated via modulation of CD11c+ APC-mediated lymphocyte activation, and was associated with a decrease in the size of the CD11c+ cell population. Conversely, IL-11 strongly reduced apoptosis and potentiated mitosis in primary cultures of mouse oligodendrocyte progenitors. Collectively, these data reveal that IL-11 regulates inflammatory demyelination via a unique combination of immunoregulation and neuroprotection. IL-11 signaling may represent a therapeutic avenue to restrict CNS inflammation and potentiate oligodendrocyte survival in autoimmune demyelinating disease.

VEGF-mediated disruption of endothelial CLN-5 promotes blood-brain barrier breakdown.

Breakdown of the blood-brain barrier (BBB) is an early and significant event in CNS inflammation. Astrocyte-derived VEGF-A has been implicated in this response, but the underlying mechanisms remain unresolved. Here, we identify the endothelial transmembrane tight junction proteins claudin-5 (CLN-5) and occludin (OCLN) as targets of VEGF-A action. Down-regulation of CLN-5 and OCLN accompanied up-regulation of VEGF-A and correlated with BBB breakdown in experimental autoimmune encephalomyelitis, an animal model of CNS inflammatory disease. In cultures of brain microvascular endothelial cells, VEGF-A specifically down-regulated CLN-5 and OCLN protein and mRNA. In mouse cerebral cortex, microinjection of VEGF-A disrupted CLN-5 and OCLN and induced loss of barrier function. Importantly, functional studies revealed that expression of recombinant CLN-5 protected brain microvascular endothelial cell cultures from a VEGF-induced increase in paracellular permeability, whereas recombinant OCLN expressed under the same promoter was not protective. Previous studies have shown CLN-5 to be a key determinant of trans-endothelial resistance at the BBB. Our findings suggest that its down-regulation by VEGF-A constitutes a significant mechanism in BBB breakdown.

Characterizing antibody specificity to different protein morphologies by AFM.

Protein misfolding and aggregation can lead to several neurodegenerative diseases including Alzheimer's Disease (AD), Parkinson's Disease (PD) and Huntington's Disease (HD). While the respective proteins involved in each disease differ in their pathological effects and amino acid sequences, the aggregated forms all share a common cross beta-sheet conformation. Substantial controversy exists over the roles of the different aggregate morphologies in disease onset and progression, and analytical tools such as morphology specific antibodies are needed to distinguish between the different protein morphologies in situ. Here we utilize atomic force microscopy (AFM) to characterize the binding of three single chain antibody fragments (scFvs) to different morphologies of alpha-synuclein (alphaS). From the topographic images generated using the AFM, we were able to show that one scFv bound all morphologies of alphaS, a second bound only oligomeric alphaS, and a third bound only fibrillar alphaS by comparing the height distribution of the different alphaS morphologies with and without addition of the different scFvs. These results demonstrate the versatility of the AFM-based technique as an easy tool to characterize specific antigen-antibody binding and the potential applications of scFvs as promising immunodiagnostics for protein misfolding diseases.

Anti-oligomeric Abeta single-chain variable domain antibody blocks Abeta-induced toxicity against human neuroblastoma cells.

The Amyloid-beta (Abeta) peptide is a major component of the amyloid plaques associated with Alzheimer's disease (AD). Recent studies suggest that the most toxic forms of Abeta are small, soluble oligomeric aggregates. Here, we report the isolation and characterization of a single-chain variable domain (scFv) antibody isolated against oligomeric Abeta using a protocol developed in our laboratory that combines phage display technology and atomic force microscopy (AFM). Starting with a randomized, single framework phage display library, after three rounds of selection against oligomeric Abeta, we identified an scFv that bound oligomeric Abeta specifically, but not monomeric or fibrillar forms. The anti-oligomeric scFv inhibits Abeta aggregation and toxicity, and reduces the toxicity of preformed oligomeric Abeta towards human neuroblastoma cells. When used to probe samples of human brain tissue, the scFv reacted with AD tissue but not a healthy control or Parkinson's disease brain samples. The anti-oligomeric Abeta scFv therefore has potential therapeutic and diagnostic applications in specifically targeting or identifying the toxic morphologies of Abeta in AD brains.

Anti-oligomeric single chain variable domain antibody differentially affects huntingtin and alpha-synuclein aggregates.

Huntington's and Parkinson's diseases are both neurodegenerative disorders caused at least in part by misfolding and aggregation of huntingtin (htt) and alpha-synuclein, respectively. Here we use a single chain antibody fragment (scFv) isolated against oligomeric alpha-synuclein to probe similarities and differences between the aggregation and toxic mechanisms of htt and alpha-synuclein. When incubated with htt, the scFv both blocks formation of and promotes dissociation of fibrillar aggregates, but stabilizes formation of cytotoxic oligomeric aggregates. Previous studies with monomeric alpha-synuclein showed the scFv prevented fibrillar aggregation, but blocked toxicity of oligomeric aggregates. These divergent effects suggest the toxic mechanisms of oligomeric aggregates differ among amyloidogenic protein species.

Single chain Fv antibodies against the 25-35 Abeta fragment inhibit aggregation and toxicity of Abeta42.

Alzheimer's disease (AD) is characterized by the deposition of amyloid-beta (Abeta) protein in the brain. Immunization studies have demonstrated that anti-Abeta antibodies reduce Abeta deposition and improve clinical symptoms seen in AD. However, conventional antibody-based therapies risk an inflammatory response that can result in meningoencephalitis and cerebral hemorrhage. Here we report on the development of human-based single chain variable domain antibody fragments (scFvs) directed against the Abeta 25-35 region as potential therapeutics for AD that do not risk an inflammatory response. The 25-35 region of Abeta represents a promising therapeutic target since it promotes aggregation and is highly toxic. Two scFvs with differing affinities for Abeta were studied, and both inhibited aggregation of Abeta42 as determined by thioflavin T binding assay and atomic force microscopy analysis and blocked Abeta-induced toxicity toward human neuroblastoma SH-SY5Y cells as determined by MTT and LDH release assays. These results provide additional evidence that scFvs against Abeta provide an attractive alternative to more conventional antibody-based therapeutics for controlling aggregation and toxicity of Abeta.

Single chain variable fragments against beta-amyloid (Abeta) can inhibit Abeta aggregation and prevent abeta-induced neurotoxicity.

Beta-amyloid (Abeta) is a major pathological determinant of Alzheimer's disease (AD). Both active and passive immunization studies have shown that antibodies against Abeta are effective in decreasing cerebral Abeta levels, reducing Abeta accumulation, and attenuating cognitive deficits in animal models of AD. However, the therapeutic potential of these antibodies in human AD patients is limited because of adverse inflammatory reactions and cerebral hemorrhaging associated with the treatments. Here we show that single chain variable fragments (scFv's) represent an attractive alternative to more conventional antibody-based therapeutics to reduce Abeta toxicity. The binding affinities and binding epitopes of two different scFv's to Abeta were characterized using a surface plasmon resonance (SPR) biosensor. An scFv binding the 17-28 region of Abeta effectively inhibited in vitro aggregation of Abeta as determined by thioflavin T (ThT) fluorescence staining and atomic force microscopy (AFM) analysis, while an scFv binding the carboxyl-terminal region of Abeta (residues 29-40) did not inhibit aggregation. The scFv to the 17-28 region when co-incubated with Abeta not only decreased aggregation but also eliminated any toxic effects of aggregated Abeta on the human neuroblastoma cell line, SH-SY5Y. The ability of scFv's to inhibit both aggregation and cytotoxicity of Abeta indicates that scFv's have potential therapeutic value for treating AD.

B and T cells in the brains of autoimmune mice.

Systemic lupus erythematosus (SLE) is an autoimmune disorder that can involve the central nervous system (CNS). Recently, we reported the presence of autoantibodies bound to the brain tissue of murine models of lupus; MRL/lpr and BXSB. We postulated that the source of these autoantibodies was in part due to in situ production, caused by the entry of B and T cells. Frozen brain sections of MRL/lpr and BXSB at 1 and 4 months of age were stained for CD3 (T cells) and CD19 (B cells) markers using an immunofluorescent antibody binding assay. Confocal fluorescence microscopy showed both CD3(+) and CD19(+) cells at 4 months of age only in MRL/lpr mice. There were no lymphocytes seen in the other autoimmune model, BXSB. Results suggest a difference in the mechanisms by which autoantibodies access the brain in these two autoimmune models of lupus.

Increased ICAM-1 and VCAM-1 expression in the brains of autoimmune mice.

Pathogenic mechanisms of central nervous system (CNS) involvement in systemic lupus erythematosus (SLE) remain unknown. We recently reported the presence of autoantibodies in the brain tissue ex vivo of autoimmune MRL/lpr mice. We postulated that at least some of these autoantibodies are produced in situ because of B-cell entry into the brain. The blood-brain barrier (BBB) blocks the entry of most large molecules and cells into the brain. In certain CNS pathologies, however, immune cells gain entry due to elevated expression of adhesion molecules. This study looked at adhesion molecule expression, ICAM-1 and VCAM-1, in the brains of MRL/lpr mice. Using immunofluorescent antibody binding assays and confocal laser imaging, we show that expression of ICAM-1 and VCAM-1 is elevated in MRL/lpr mice brains at 4 months of age as compared to age-matched controls. These results suggest a possible mechanism for leukocyte entry into the brains of autoimmune mice that in turn suggest immune-mediated pathology in CNS-lupus.