Anna K. Stalder

Late-Onset Chronic Inflammatory Encephalopathy in Immune-Competent and Severe Combined Immune-Deficient (SCID) Mice with Astrocyte-Targeted Expression of Tumor Necrosis Factor

To examine the role of tumor necrosis factor (TNF)-alpha in the pathogenesis of degenerative disorders of the central nervous system (CNS), transgenic mice were developed in which expression of murine TNF-alpha was targeted to astrocytes using a glial fibrillary acidic protein (GFAP)-TNF-alpha fusion gene. In two independent GFAP-TNFalpha transgenic lines (termed GT-8 or GT-2) adult (>4 months of age) animals developed a progressive ataxia (GT-8) or total paralysis affecting the lower body (GT-2). Symptomatic mice had prominent meningoencephalitis (GT-8) or encephalomyelitis (GT-2) in which large numbers of B cells and CD4+ and CD8+ T cells accumulated at predominantly perivascular sites. The majority of these lymphocytes displayed a memory cell phenotype (CD44high, CD62Llow, CD25-) and expressed an early activation marker (CD69). Parenchymal lesions contained mostly CD45+ high, MHC class II+, and Mac-1+ cells of the macrophage microglial lineage with lower numbers of neutrophils and few CD4+ and CD8+ T cells. Cerebral expression of the cellular adhesion molecules ICAM-1, VCAM-1, and MAdCAM as well as a number of alpha- and beta-chemokines was induced or upregulated and preceded the development of inflammation, suggesting an important signaling role for these molecules in the CNS leukocyte migration. Degenerative changes in the CNS of the GFAP-TNFalpha mice paralleled the development of the inflammatory lesions and included primary and secondary demyelination and neurodegeneration. Disease exacerbation with more extensive inflammatory lesions that contained activated cells of the macrophage/microglial lineage occurred in GFAP-TNFalpha mice with severe combined immune deficiency. Thus, persistent astrocyte expression of murine TNF-alpha in the CNS induces a late-onset chronic inflammatory encephalopathy in which macrophage/microglial cells but not lymphocytes play a central role in mediating injury.

Astrocyte-Targeted Expression of IL-12 Induces Active Cellular Immune Responses in the Central Nervous System and Modulates Experimental Allergic Encephalomyelitis

The role of IL-12 in the evolution of immunoinflammatory responses at a localized tissue level was investigated. Transgenic mice were developed with expression of either both the IL-12 subunits (p35 and p40) or only the IL-12 p40 subunit genes targeted to astrocytes in the mouse CNS. Glial fibrillary acidic protein (GF)-IL-12 mice, bigenic for the p35 and p40 genes, developed neurologic disease which correlated with the levels and sites of transgene-encoded IL-12 expression. In these mice, the brain contained numerous perivascular and parenchymal inflammatory lesions consisting of predominantly CD4+ and CD8+ T cells as well as NK cells. The majority of the infiltrating T cells had an activated phenotype (CD44high, CD45Rblow, CD62Llow, CD69high, VLA-4 high, and CD25+). Functional activation of the cellular immune response was also evident with marked cerebral expression of the IFN-γ, TNF, and IL-1αβ genes. Concomitant with leukocyte infiltration, the CNS expression of immune accessory molecules was induced or up-regulated, including ICAM-1, VCAM-1, and MHC class II and B7-2. Glial fibrillary acidic protein-p40 mice with expression of IL-12 p40 alone remained asymptomatic, with no inflammation evident at any age studied. The effect of local CNS production of IL-12 in the development of experimental autoimmune encephalomyelitis was studied. After immunization with myelin oligodendrocyte glycoprotein-peptides, GF-IL-12 mice had an earlier onset and higher incidence but not more severe disease. We conclude that localized expression of IL-12 by astrocytes can 1) promote the spontaneous development of activated type 1 T cell and NK cellular immunity and cytokine responses in the CNS, and 2) promote more effective Ag-specific T cell dynamics but not activity in experimental autoimmune encephalomyelitis.

Transgenic expression of TNF by astrocytes increases mechanical allodynia in a mouse neuropathy model.

It has been hypothesized that increased expression of proinflammatory cytokines mediate a variety of central nervous system disorders such as multiple sclerosis, Alzheimers disease, cerebral ischemia, spinal cord injury, HIV encephalopathy and chronic pain. In order to further examine the central role of TNF in neuropathic pain, transgenic mice were used in which expression of murine TNF was targeted to astrocytes using a glial fibrillary acidic protein (GFAP)–TNF fusion gene. Spinal nerve (L5) transection was performed in either the GFAP–TNF transgenic or wild type mice. Mechanical allodynia was significantly enhanced in the GFAP–TNF transgenic mice compared with the wild type mice. These data support a central role of glial expression of TNF in the generation of neuropathic pain.

Barrier disruption increases gene expression of cytokines and the 55 kD TNF receptor in murine skin

Abstract The signalling mechanisms that regulate epidermal permeability barrier homeostasis arc not known. Previous Northern blot analysis showed that both acute and chronic barrier disruption increase mRNA levels of several cytokines in murine epidermis. To further characterize the epidermal response to barrier abrogation, we used more sensitive, multi‐probe RNasc protection assays to measure the mRNA levels of additional cytokines. as well as cytokine receptors in acute and chronic models of barrier disruption. Normal mouse epidermis expressed interleukin (IL)‐lα, interferon‐γ (IFN‐γ). tumor necrosis factor‐α (TNF‐α) and IL‐6 mRNAs. Following tape‐stripping, only the mRNA levels for TNF‐α, IL‐lα, IL‐lβ and IL‐6 increased at 2.5 and 7 h, and returned toward normal levels by IX h. No mRNAs encoding TNF‐β. IL‐2, IL‐3. IL‐4 or IL‐5, were detected in the epidermis either under basal conditions or after tape‐stripping. Similarly, in a chronic model, essential fatty acid deficiency, epidermal levels of TNF‐α, IL‐lα, IL‐lβ and IL‐6 mRNAs, but not IFN‐γ mRNA. were elevated over controls; and again, mRNAs for the remaining probed cytokines were not detected. In contrast, in the dermis. only IL‐Iβ mRNA levels increased 2.5 h after tape‐stripping, and remained elevated at I8 h. mRNAs encoding the IL‐1 (p60), IFN‐γ ami IL‐6 receptors were present in epidermis, but their levels remained unchanged following either acute or chronic barrier disruption. In contrast, epidermal TNF (p55) receptor mRNA levels were increased by 87% (P<0.01) at 2.5 h, returned to control levels at 7 h and were increased by 68% (p<0.03) at 18 h after tape‐stripping. The increase at 2 h was confirmed by Northern blot analysis and was not prevented by latex occlusion performed immediately after tape‐stripping. mRNAs for the IL‐I (p80) receptor and TNF (p75) receptor were not detected in epidermis. Low levels of TNF (p55) receptor mRNA were present in the dermis. and they remained unchanged after tape‐stripping. The presence of specific receptor mRNAs in the epidermis and dermis suggests that these tissues are capable of responding in an autocrine and/or paracrine fashion to the cognate cytokines. These results suggest that epidermal cytokines produced after barrier disruption may initiate a cytokine cascade which could regulate cytokine and cytokine receptor production and/or inflammatory responses.

Regulation of matrix metalloproteinases and their inhibitor genes in lipopolysaccharide-induced endotoxemia in mice.

An imbalance between matrix metalloproteinases (MMPs) and inhibitors of MMPs (TIMPs) may contribute to tissue destruction that is found in various inflammatory disorders. To determine in an in vivo experimental setting whether the inflammatory reaction in the course of lipopolysaccharide (LPS)-induced endotoxemia causes an altered balance in the MMP/TIMP system, we analyzed the expression of a number of MMP and TIMP genes as well as MMP enzymatic activity in the liver, kidney, spleen, and brain at various time points after systemic injection of different doses of LPS in mice. Injection of sublethal doses of LPS led to an organ- and time-specific pattern of up-regulation of several MMP genes and the TIMP-1 gene in the liver, spleen, and kidney, whereas in the brain only TIMP-1 was induced. Injection of a lethal dose of LPS caused similar but more prolonged expression of these MMP genes as well as the induction of additional MMP genes in all organs. In LPS-treated mice in situ hybridization revealed collagenase 3 gene induction in cells resembling macrophages whereas TIMP-1 RNA was detected predominantly in parenchymal cells. Finally, gelatin zymography revealed increased gelatinolytic activity in all organs after LPS treatment. These observations highlight a dramatic shift in favor of increased expression of the MMP genes over the TIMP genes during LPS-induced endotoxemia, and suggest that MMPs may contribute to the development of organ damage in endotoxemia.

Transgenic Models to Study the Actions of Cytokines in the Central Nervous System

To better understand the actions of cytokines in the mammalian central nervous system (CNS), we have developed transgenic mice in which the expression of various cytokines including interleukin (IL)-3, IL-6, IL-12, interferon-α or tumor necrosis factor-α was targeted to astrocytes under the transcriptional control of the glial fibrillary acidic protein (GFAP) promoter. Transgenic lines displaying low astrocyte expression of the respective cytokine were developed and characterized. The findings indicate that expression of these different cytokines in the intact CNS produces divergent inflammatory responses which are associated with the development of wide-ranging and progressive molecular, cellular and functional CNS impairments. These transgenic mice provide a powerful tool which we are now exploiting further to define novel mechanisms that might underlie the individual cytokine-driven neuroinflammatory responses. To date the results clearly show there are distinct model-associated patterns of cerebral expression of key molecules involved in the inflammatory response including the cellular adhesion molecules, chemokines, major histocompatibility complex molecules and the matrix metalloproteinases. In conclusion, these GFAP-cytokine transgenic mice highlight the potent and diverse array of actions mediated by cytokines when expressed in the CNS and provide a valuable resource to further our knowledge of the mechanisms by which cytokines exert their effects.

RNAse protection assays for the simultaneous and semiquantitative analysis of multiple murine matrix metalloproteinase (MMP) and MMP inhibitor mRNAs.

Matrix metalloproteinases (MMPs) are a family of proteinases that play a major role in the metabolic degradation of extracellular matrix proteins. In order to examine the expression pattern of different MMP or MMP-inhibitor genes two RNase protection assays (RPAs) were developed that allow the simultaneous and semiquantitative assessment of their respective mRNAs. Probes for the detection of MMPs stromelysin 1, 2 and 3, matrilysin, metalloelastase, gelatinase A and B, collagenase and membrane type MMP (MT1-MMP) were included in the first RPA probe set, while probes for tissue inhibitor of matrix metalloproteinase (TIMP) 1, 2, 3 and alpha 2-macroglobulin (alpha 2-M) were included in the second probe set (inhibitor of matrix metalloproteinase-IMP set). Titration experiments revealed that this method allows the detection of MMP and inhibitor mRNAs present in at least 0.03 microgram of spleen poly(A)+ RNA. Both RPA sets were further evaluated by analyzing the expression of MMP and IMP genes in brain, kidney, spleen and liver in a murine model for endotoxemia after intraperitoneal LPS injection. Control animals showed an organ-specific constitutive expression of one or more MMPs and a high expression of TIMPs. Following LPS injection, an organ-specific upregulation or induction of MMP and TIMP RNA species was found. This change was most pronounced in the spleen, while liver, kidney and brain showed minor or no changes in MMP expression. An IMP upregulation was detected in all organs. These RPA probe sets provide a valuable tool for the simultaneous assessment of MMP and IMP gene expression under physiological and pathological conditions.

Metallothioneins are upregulated in symptomatic mice with astrocyte-targeted expression of tumor necrosis factor-α

Transgenic mice expressing TNF-alpha under the regulatory control of the GFAP gene promoter (GFAP-TNFalpha mice) exhibit a unique, late-onset chronic-progressive neurological disorder with meningoencephalomyelitis, neurodegeneration, and demyelination with paralysis. Here we show that the metallothionein-I + II (MT-I + II) isoforms were dramatically upregulated in the brain of symptomatic but not presymptomatic GFAP-TNFalpha mice despite TNF-alpha expression being present in both cases. In situ hybridization analysis for MT-I RNA and radioimmunoassay results for MT-I + II protein revealed that the induction was observed in the cerebellum but not in other brain areas. Increased MT-I RNA levels occurred in the Purkinje and granular neuronal layers of the cerebellum but also in the molecular layer. Reactive astrocytes, activated rod-like microglia, and macrophages, but not the infiltrating lymphocytes, were identified as the cellular sources of the MT-I + II proteins. In situ hybridization for MT-III RNA revealed a modest increase in the white matter of the cerebellum, which was confirmed by immunocytochemistry. MT-III immunoreactivity was present in cells which were mainly round or amoeboid monocytes/macrophages. The pattern of expression of the different MT isoforms in the GFAP-TNFalpha mice differed substantially from that described previously in GFAP-IL6 mice, demonstrating unique effects associated with the expression of each cytokine. The results suggest that the MT expression in the CNS reflects the inflammatory response and associated damage rather than a direct role of the TNF-alpha in their regulation and support a major role of these proteins during CNS injury.

Distribution of tumor necrosis factor receptor messenger RNA in normal and herpes simplex virus infected trigeminal ganglia in the mouse

PURPOSE to investigate the distribution of p55 and p75 tumor necrosis factor (TNF) receptor mRNA in normal murine trigeminal ganglia, and in murine trigeminal ganglia acutely infected with McKrae strain herpes simplex virus (HSV). METHODS in situ hybridization with antisense 35S-labeled riboprobes for mRNA encoding both the p55 and p75 TNF receptor (TNFR) subtypes was used in normal and HSV-infected murine trigeminal ganglia. Sense riboprobes were used as controls. RESULTS in situ hybridization with both p55 and p75 riboprobes produced a strong autoradiographic signal over many, but not all, trigeminal sensory neurons. Signal for mRNA encoding both TNFR subtypes was also present over the arachnoid layers surrounding trigeminal ganglia. Acute ocular HSV infection was accompanied by an intense leukocytic infiltrate into the ophthalmic portion of the trigeminal ganglia, and, in this setting, increased p55 and p75 mRNA signal was closely related to the location and number of infiltrating white blood cells. The distribution and number of trigeminal sensory neurons expressing mRNA for the two TNFR subtypes did not appear to change following infection. Signal over control sections hybridized with sense p55 and p75 TNFR cRNA probes was comparable to background. CONCLUSIONS the observed distribution of p55 and p75 TNFR mRNA over trigeminal sensory neurons and over the arachnoid layers surrounding trigeminal ganglia supports suggestions that TNF has a direct effect on neurons, either as a neuromodulator or neurotrophic factor, and that TNF may play a central role in blood-brain barrier regulation. Increased signal for TNFR mRNA in acutely infected trigeminal ganglia appears to reflect infiltration by receptor-bearing white blood cells.

Transgenic Mice Expressing Cytokines in the CNS as Model Systems for the Study of Inflammatory Neurodegenerative and Demyelinating Disorders

Cytokines are a diverse group of small molecular weight, soluble factors that were originally discovered as products of activated immune cells and which play a central role in immune regulation.1,2 However, it is now clear that these multifunctional factors are produced by and act on not only immune cells but virtually all cell types examined. Like hormones, cytokines exert their actions by binding to specific receptors on the surface of cells activating intracellular signaling pathways that result in the modulation of gene transcription. Unlike hormones which are largely endocrine regulators, cytokines tend to act in a more localized milieu influencing the function of immediately neighboring cells (termed paracrine regulation) or the producer cells themselves (termed autocrine regulation). In vivo, cytokines exert their actions within the context of a highly complex and yet tightly regulated network in which the cellular response evoked represents the sum of the overlapping, synergistic and antagonistic actions of multiple cytokines.