Reversion of anergy signatures in clonal CD21low B cells of mixed cryoglobulinemia after clearance of HCV viremia.

Hepatitis C virus (HCV) causes mixed cryoglobulinemia (MC) by driving clonal expansion of IgM+CD27+ B cells. These cells display both the features of anergy induced by continual engagement of the B cell receptor (BCR), such as high expression of phosphorylated extracellular signal regulated kinase (pERK) and reduced lifespan, and of virus-specific exhaustion such as CD21low phenotype and defective response to ligation of BCR and Toll-like receptor 9 (TLR9). Usually MC regresses after eradication of HCV with interferon, whose immunomodulatory activity might contribute to this effect. We investigated phenotypic and functional changes in clonal B cells of MC patients with sustained virologic responses to direct-acting antivirals (DAA), which lack immunomodulatory properties. We found that high pERK expression and accelerated apoptosis revert within 4 weeks after beginning therapy, whereas clonal B cells unresponsive to TLR9 stimulation persist for at least 24 weeks although they may partially rescue normal CD21 expression. Thus, similar to mouse models, features of anergy in MC B cells rapidly revert after disengagement from HCV, whereas virus-specific exhaustion imparts a durable inhibitory imprint on cell function. Treatment of HCV+ MC with DAA provides a valuable tool for untangling the molecular mechanisms of anergy and exhaustion in human B cells

Lung MRI as a Possible Alternative to CT Scan for Patients With Primary Immune Deficiencies and Increased Radiosensitivity

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Imaging of bronchial pathology in antibody deficiency: Data from the European Chest CT Group

Studies of chest computed tomography (CT) in patients with primary antibody deficiency syndromes (ADS) suggest a broad range of bronchial pathology. However, there are as yet no multicentre studies to assess the variety of bronchial pathology in this patient group. One of the underlying reasons is the lack of a consensus methodology, a prerequisite to jointly document chest CT findings. We aimed to establish an international platform for the evaluation of bronchial pathology as assessed by chest CT and to describe the range of bronchial pathologies in patients with antibody deficiency. Ffteen immunodeficiency centres from 9 countries evaluated chest CT scans of patients with ADS using a predefined list of potential findings including an extent score for bronchiectasis. Data of 282 patients with ADS were collected. Patients with common variable immunodeficiency disorders (CVID) comprised the largest subgroup (232 patients, 82.3%). Eighty percent of CVID patients had radiological evidence of bronchial pathology including bronchiectasis in 61%, bronchial wall thickening in 44% and mucus plugging in 29%. Bronchiectasis was detected in 44% of CVID patients aged less than 20 years. Cough was a better predictor for bronchiectasis than spirometry values. Delay of diagnosis as well as duration of disease correlated positively with presence of bronchiectasis. The use of consensus diagnostic criteria and a pre-defined list of bronchial pathologies allows for comparison of chest CT data in multicentre studies. Our data suggest a high prevalence of bronchial pathology in CVID due to late diagnosis or duration of disease

Modulatory Effects of Antibody Replacement Therapy to Innate and Adaptive Immune Cells

Intravenous immunoglobulin administered at replacement dosages modulates innate and adaptive immune cells in primary antibody deficiencies (PAD) in a different manner to what observed when high dosages are used or when their effect is analyzed byin vitroexperimental conditions. The effects seem to be beneficial on innate cells in that dendritic cells maturate, pro-inflammatory monocytes decrease, and neutrophil function is preserved. The effects are less clear on adaptive immune cells. IVIg induced a transient increase of Treg and a long-term increase of CD4 cells. More complex and less understood is the interplay of IVIg with defective B cells of PAD patients. The paucity of data underlies the need of more studies on patients with PAD before drawing conclusions on thein vivomechanisms of action of IVIg based onin vitroinvestigations

Immunomodulatory effects of intravenous immunoglobulin - assembling a jigsaw puzzle

Intravenous immunoglobulin (IVIG) is widely used for the treatment of autoimmune and inflammatory disorders because of its immunomodulatory effects. The interaction of IVIG with the immune system has been extensively investigated over the past 30 years but, since IVIG modifies responses of many immune cells, a unifying model is far from reach. Here we survey the in vitro studies on the effects on IVIG on macrophages, B cells, T regulatory cells, dendritic cells and soluble factors, as well as the in vivo studies in murine disease models and the preliminary in vivo findings in humans

Intravenous immunoglobulin replacement therapy in common variable immunodeficiency induces B cell depletion through differentiation into apoptosis-prone CD21low B cells

ntravenous immunoglobulin (IVIG), besides its use as replacement therapy in patients with antibody defi- ciencies, is broadly used as an immunomodulatory agent for the treatment of autoimmune and inflammatory disorders. The mechanisms of action of IVIG include Fc receptor blockade, inhibition of cytokines and growth factors, modulation of macrophages and dendritic cells, enhancement of regulatory T cells, and modulation of B cells through the FccRIIB receptor and CD22. Recent studies suggest that in vitro exposure of human B cells to IVIG determines functional changes reminiscent of anergy and that IVIG treatment of patients with common variable immunodeficiency (CVID) induces in B cells ERK activation, a feature of anergy. Here, we show that IVIG therapy drives the B cells of patients with CVID to down-regulate CD21 expression and to assume the peculiar phenotype of the anergic-like, apoptosis-prone CD21low B cells that are spontaneously expanded in a subset of CVID and in some other immunological disorders. The CD21low B cells newly generated after IVIG infusion undergo spontaneous apoptosis upon in vitro culture. Furthermore, IVIG infusion is rapidly followed by a significant, although discrete, decrease in the number of circulating B cells, but not of T cells or of natural killer cells. These findings suggest that IVIG therapy may constrain antibody responses by inducing B cell depletion through differentiation into CD21low B cells that undergo accelerated apoptosis