Angela S. Archambault

STAT-3 Activation Is Required for Normal G-CSF-Dependent Proliferation and Granulocytic Differentiation

To investigate the role of signal transducer and activator of transcription (STAT) proteins in granulocyte colony-stimulating factor (G-CSF)-regulated biological responses, we generated transgenic mice with a targeted mutation of their G-CSF receptor (termed d715F) that abolishes G-CSF-dependent STAT-3 activation and attenuates STAT-5 activation. Homozygous mutant mice are severely neutropenic with an accumulation of immature myeloid precursors in their bone marrow. G-CSF-induced proliferation and granulocytic differentiation of hematopoietic progenitors is severely impaired. Expression of a constitutively active form of STAT-3 in d715F progenitors nearly completely rescued these defects. Conversely, expression of a dominant-negative form of STAT-3 in wild-type progenitors results in impaired G-CSF-induced proliferation and differentiation. These data suggest that STAT-3 activation by the G-CSFR is critical for the transduction of normal proliferative signals and contributes to differentiative signals.

Mycobacterium abscessus Glycopeptidolipids Mask Underlying Cell Wall Phosphatidyl-myo-Inositol Mannosides Blocking Induction of Human Macrophage TNF-α by Preventing Interaction with TLR2

Mycobacterium abscessus causes disease in patients with structural abnormalities of the lung, and it is an emerging pathogen in patients with cystic fibrosis. Colonization of the airways by nontuberculous mycobacteria is a harbinger of invasive lung disease. Colonization is facilitated by biofilm formation, with M. abscessus glycopeptidolipids playing an important role. M. abscessus can transition between a noninvasive, biofilm-forming, smooth colony phenotype that expresses glycopeptidolipid, and an invasive rough colony phenotype that expresses minimal amounts of glycopeptidolipid and is unable to form biofilms. The ability of this pathogen to transition between these phenotypes may have particular relevance to lung infection in cystic fibrosis patients since the altered pulmonary physiology of these patients makes them particularly susceptible to colonization by biofilm-forming bacteria. In this study we demonstrate that rough variants of M. abscessus stimulate the human macrophage innate immune response through TLR2, while smooth variants do not. Temperature-dependent loss or physical removal of glycopeptidolipid from the cell wall of one of the smooth variants leads to TLR2 stimulation. This response is stimulated in part through phosphatidyl-myo-inositol mannosides that are present in the cell wall of both rough and smooth variants. Mannose-binding lectins bind to rough variants, but lectin binding to an isogenic smooth variant is markedly reduced. This suggests that glycopeptidolipid in the outermost portion of the M. abscessus cell wall masks underlying cell wall lipids involved in stimulating the innate immune response, thereby facilitating colonization. Conversely spontaneous “unmasking” of cell wall lipids may promote airway inflammation.

Defining antigen-dependent stages of T cell migration from the blood to the central nervous system parenchyma

In experimental autoimmune encephalomyelitis (EAE), intravenous transfer of activated CD4+ myelin‐specific T cells is sufficient to induce disease. Transferred T cells access the CNS parenchyma by trafficking across the blood brain barrier (BBB) vascular endothelium into the perivascular space, and then across the glial limitans that is made up of astrocytes and microglia. Flow cytometry analysis of cells isolated from CNS tissue does not distinguish between T cell populations at the various stages of migration. In this study, we have used GK1.5 (anti‐CD4) treatment along with immunohistochemistry to distinguish between populations of T cells that are associated with the vasculature, T cells that have migrated into the perivascular space, and T cells in the parenchyma. We have also re‐evaluated antigen specificity requirements of T cells as they are recruited to the CNS parenchyma. Activated myelin‐specific T cells are restricted to the CNS vasculature for at least 24 h post transfer. MHC class II expression on the recipient is required for cells to traffic across the CNS vascular endothelium. Further, Con A‐stimulated or non‐CNS‐specific (ovalbumin‐specific) T cells fail to migrate into the perivascular space, and only enter the CNS parenchyma when co‐transferred with myelin‐specific T cells. Our results indicate that Th1 populations cannot accumulate in the perivascular (subarachnoid, Virchow‐Robbins) space without a CNS antigen‐specific signal.

The Lymphotoxin LTα1β2 Controls Postnatal and Adult Spleen Marginal Sinus Vascular Structure and Function

The lymphotoxin LTalpha(1)beta(2) supports the development and maintenance of several aspects of spleen structure, but its significance for marginal sinus (MS) vascular organization is unclear. We showed here that, in early postnatal lymphotoxin-deficient mice, the developing Flk-1+ white pulp vessels failed to organize or upregulate MAdCAM-1, leading to altered spatial rearrangement of both the white pulp endothelial cells and the smooth muscle actin-expressing cells. In vitro, MAdCAM-1 directed the reorganization of LTbeta receptor+ endothelial cells grown on Matrigel. LTalpha(1)beta(2) also regulated the maintenance of both MAdCAM-1 expression and mature MS structure in adult mice, contributing importantly to normal trafficking of CD11b+ cells in response to bacterial antigens. Together, our studies demonstrate that LTalpha(1)beta(2) and LTbeta receptor signals control proper development and maintenance of the mature MS structure and implicate MAdCAM-1 in the structuring of the MS endothelial cells that is important for the movement of immune cells within the spleen.

B Cell Antigen Presentation Is Sufficient To Drive Neuroinflammation in an Animal Model of Multiple Sclerosis

B cells are increasingly regarded as integral to the pathogenesis of multiple sclerosis, in part as a result of the success of B cell–depletion therapy. Multiple B cell–dependent mechanisms contributing to inflammatory demyelination of the CNS have been explored using experimental autoimmune encephalomyelitis (EAE), a CD4 T cell–dependent animal model for multiple sclerosis. Although B cell Ag presentation was suggested to regulate CNS inflammation during EAE, direct evidence that B cells can independently support Ag-specific autoimmune responses by CD4 T cells in EAE is lacking. Using a newly developed murine model of in vivo conditional expression of MHC class II, we reported previously that encephalitogenic CD4 T cells are incapable of inducing EAE when B cells are the sole APC. In this study, we find that B cells cooperate with dendritic cells to enhance EAE severity resulting from myelin oligodendrocyte glycoprotein (MOG) immunization. Further, increasing the precursor frequency of MOG-specific B cells, but not the addition of soluble MOG-specific Ab, is sufficient to drive EAE in mice expressing MHCII by B cells alone. These data support a model in which expansion of Ag-specific B cells during CNS autoimmunity amplifies cognate interactions between B and CD4 T cells and have the capacity to independently drive neuroinflammation at later stages of disease.

Region-specific regulation of inflammation and pathogenesis in experimental autoimmune encephalomyelitis

Experimental autoimmune encephalomyelitis (EAE) is an animal model of multiple sclerosis and is characterized by an infiltrate of predominantly T cells and macrophages in the spinal cord and brain. In both the spinal cord and the cerebellum, Th1 cells direct inflammation to antigen-rich white matter tracts, and there is a TNFR1-dependent recruitment of CD11b(hi) cells in both regions. In the spinal cord, parenchymal invasion, demyelination and clinical symptoms are associated with TNFR1-dependant parenchymal induction (especially astrocytes) of VCAM-1 and CXCL2. None of these events occur in the cerebellum despite the fact that an inflammatory infiltrate accumulates in the perivascular space. Therefore regional specificity in astrocyte responses to inflammatory cytokines may regulate regional parenchymal infiltration and pathogenesis.

Cutting Edge: Conditional MHC Class II Expression Reveals a Limited Role for B Cell Antigen Presentation in Primary and Secondary CD4 T Cell Responses

The activation, differentiation, and subsequent effector functions of CD4 T cells depend on interactions with a multitude of MHC class II (MHCII)–expressing APCs. To evaluate the individual contribution of various APCs to CD4 T cell function, we have designed a new murine tool for selective in vivo expression of MHCII in subsets of APCs. Conditional expression of MHCII in B cells was achieved using a cre-loxP approach. After i.v. or s.c. priming, partial proliferation and activation of CD4 T cells was observed in mice expressing MHCII only by B cells. Restricting MHCII expression to B cells constrained secondary CD4 T cell responses in vivo, as demonstrated in a CD4 T cell–dependent model of autoimmunity, experimental autoimmune encephalomyelitis. These results highlight the limitations of B cell Ag presentation during initiation and propagation of CD4 T cell function in vivo using a novel system to study individual APCs by the conditional expression of MHCII.

IL-1–induced Bhlhe40 identifies pathogenic T helper cells in a model of autoimmune neuroinflammation

Lin et al. show that Bhlhe40 expression identifies encephalitogenic CD4+ T helper cells and define a pertussis toxin–IL-1–Bhlhe40 pathway active in experimental autoimmune encephalomyelitis, a mouse model of multiple sclerosis.

Apolipoprotein E mediation of neuro-inflammation in a murine model of multiple sclerosis

Apolipoprotein E (ApoE) functions as a ligand in receptor-mediated endocytosis of lipoprotein particles and has been demonstrated to play a role in antigen presentation. To explore the contribution of ApoE during autoimmune central nervous system (CNS) demyelination, we examined the clinical, cellular immune function, and pathologic consequences of experimental autoimmune encephalomyelitis (EAE) induction in ApoE knockout (ApoE(-/-)) mice. We observed reduced clinical severity of EAE in ApoE(-/-) mice in comparison to WT mice that was concomitant with an early reduction of dendritic cells (DCs) followed by a reduction of additional innate cells in the spinal cord at the peak of disease without any differences in axonal damage. While T cell priming was enhanced in ApoE(-/-) mice, reduced severity of EAE was also observed in ApoE(-/-) recipients of encephalitogenic wild type T cells. Expression of ApoE during EAE was elevated within the CNS of wild type mice, particularly by innate cells such as DCs. Overall, ApoE promotes clinical EAE, likely by mediation of inflammation localized within the CNS.

T-cell trafficking competence is required for CNS invasion

T-cell invasion of the CNS is critical for the induction of a variety of autoimmune mediated neuronal diseases. We utilized blood-brain barrier (BBB) mediated exclusion of anti-CD4 antibody to define populations of encephalitogenic T-cells recovered from mouse CNS preparations as either CNS invasive or non-invasive. This separation of cells allowed flow cytometric examination of the kinetics of encephalitogenic T-cell entry past the BBB. Further experiments examined the relative contribution of EAE inflammatory conditioning of the BBB to the kinetics of T-cell adherence and migration into the CNS. Inflammatory conditioning was found to have no effect on accumulation of T-cells at the vascular interface of the BBB, but was found to increase the entry of adoptively transferred T-cells into the CNS following their initial adherence to the BBB.