Thymus transplantation for complete DiGeorge syndrome: European experience

Background: Thymus transplantation is a promising strategy for the treatment of athymic complete DiGeorge syndrome (cDGS). Methods: Twelve patients with cDGS were transplanted with allogeneic cultured thymus. Objective: To confirm and extend the results previously obtained in a single centre. Results: Two patients died of pre-existing viral infections without developing thymopoeisis and one late death occurred from autoimmune thrombocytopaenia. One infant suffered septic shock shortly after transplant resulting in graft loss and the need for a second transplant. Evidence of thymopoeisis developed from 5-6 months after transplantation in ten patients. The median (range) of circulating naïve CD4 counts (x10663 /L) were 44(11-440) and 200(5-310) at twelve and twenty-four months post-transplant and T-cell receptor excision circles were 2238 (320-8807) and 4184 (1582 -24596) per106 65 T-cells. Counts did not usually reach normal levels for age but patients were able to clear pre-existing and later acquired infections. At a median of 49 months (22-80), eight have ceased prophylactic antimicrobials and five immunoglobulin replacement. Histological confirmation of thymopoeisis was seen in seven of eleven patients undergoing biopsy of transplanted tissue including five showing full maturation through to the terminal stage of Hassall body formation. Autoimmune regulator (AIRE) expression was also demonstrated. Autoimmune complications were seen in 7/12 patients. In two, early transient autoimmune haemolysis settled after treatment and did not recur. The other five suffered ongoing autoimmune problems including: thyroiditis (3); haemolysis (1), thrombocytopaenia (4) and neutropenia (1). Conclusions: This study confirms the previous reports that thymus transplantation can reconstitute T cells in cDGS but with frequent autoimmune complications in survivors

Targeting the T cell receptor β-chain constant region for immunotherapy of T cell malignancies

Mature T cell cancers are typically aggressive, treatment resistant and associated with poor prognosis. Clinical application of immunotherapeutic approaches has been limited by a lack of target antigens that discriminate malignant from healthy (normal) T cells. Unlike B cell depletion, pan–T cell aplasia is prohibitively toxic. We report a new targeting strategy based on the mutually exclusive expression of T cell receptor β-chain constant domains 1 and 2 (TRBC1 and TRBC2). We identify an antibody with unique TRBC1 specificity and use it to demonstrate that normal and virus-specific T cell populations contain both TRBC1+ and TRBC2+ compartments, whereas malignancies are restricted to only one. As proof of concept for anti-TRBC immunotherapy, we developed anti-TRBC1 chimeric antigen receptor (CAR) T cells, which recognized and killed normal and malignant TRBC1+, but not TRBC2+, T cells in vitro and in a disseminated mouse model of leukemia. Unlike nonselective approaches targeting the entire T cell population, TRBC-targeted immunotherapy could eradicate a T cell malignancy while preserving sufficient normal T cells to maintain cellular immunity

IL-15 drives the specific migration of CD94+ and TCR-??+ intraepithelial lymphocytes in organ cultures of treated celiac patients

Objectives: Celiac disease (CD) is an under-diagnosed but extremely frequent disease, triggered by the ingestion of gliadin. The pathogenic mechanisms of CD are still poorly understood, but intraepithelial lymphocytes are considered to have a key role. We intended to define the subsets of T lymphocytes migrating upon gliadin challenge in organ cultures of treated celiac patients and establish the type of factor(s) driving such an infiltration.Methods: Duodenum biopsies from 10 treated celiacs and 7 controls were cultured in vitro with/without gliadin digest (1 mg/ml) or interleukin (IL)-15 (10 ng/ml). In 7 treated celiacs IL-7, IL-4, and IL-2 were similarly tested. Intraepithelial CD3, CD8, TCR-??, and CD94 were detected by immunohistochemistry and numbered per mm epithelium.Results: IL-15 but not IL-7, IL-4, or IL-2 induced intraepithelial increase of CD3+ and CD8+ cells in celiac and control intestine (p< 0.001 vs cultures with medium). IL-15 induced increases in the number of intraepithelial TCR-??+ and CD94+ cells only in celiacs (p< 0.001). IL-7 was also effective in increasing intraepithelial TCR-??+ (but not CD94+) cells in celiac biopsies (p< 0.001). Gliadin induced intraepithelial migration of CD3+, CD8+ (p< 0.001), and CD94+ (p< 0.05) cells in celiacs, but not in controls.Conclusions: The results we describe in this report indicate that IL-15 might have a key role in modulating and driving intraepithelial infiltration and ultimately in the pathogenesis of CD

Association between innate response to gliadin and activation of pathogenic T cells in coeliac disease

Background: the adaptive immune system is central to the development of coeliac disease. Adaptive immune responses are, however, controlled by a preceding activation of the innate immune system. We investigated whether gliadin, a protein present in wheat flour, could activate an innate as well as an adaptive immune response in patients with coeliac disease.Methods: duodenal biopsy samples from 42 patients with untreated coeliac disease, 37 treated patients, and 18 controls, were cultured in vitro for 3 h or 24 h, in the presence of either immunodominant gliadin epitopes (p?-2 and p?-9) or a non-immunodominant peptide (p31–43) known to induce small intestine damage in coeliac disease. We also incubated biopsy samples from nine untreated and six treated patients with a non-immunodominant peptide for 3 h, before incubation with immunodominant gliadin epitopes. Different combinations of interleukin-15 or signal transduction inhibitors were added to selected incubations.Findings: only the non-immunodominant peptide induced rapid expression of interleukin-15, cd83, cyclo-oxygenase (COX)-2, and CD25 by CD3– cells (p=O005 vs medium alone) and enterocyte apoptosis (p<0·0001). Only the non-immunodominant peptide induced p38 MAP kinase activation in CD3– cells. Pre-incubation with the non-immunodominant peptide enabled immunodominant epitopes to induce T-cell activation (p=0·001) and enterocyte apoptosis. Inhibition of interleukin-15 or of p38 MAP kinase controlled such activity.Interpretation: a gliadin fragment can activate the innate immune system, affecting the in situ T-cell recognition of dominant gliadin epitopes. Although our findings emphasise the key role of gliadin-specific T cells, they suggest a complex pathogenic situation, and show that inhibition of interleukin-15 or p38 MAP kinase might have the potential to control coeliac disease

Apixaban interacts with haemoglobin: effects on its plasma levels

The direct oral anticoagulant apixaban (APX), a strong factor Xa inhibitor, binds also to plasma proteins, especially albumin, and minimally to α 1 -acid glycoprotein. Although APX can cross the red cell membrane, due to its chemical structure, and could bind to haemoglobin (Hb), no investigation was performed on this possible phenomenon that could affect the APX plasma concentration and thus its pharmacokinetics and pharmacodynamics. We addressed this issue by (1) measuring the levels of APX and haematological/biochemical parameters in 90 patients on APX therapy; (2) assessing the effect of APX on oxygen saturation curves of Hb; (3) testing the direct APX binding to Hb by fluorescence spectroscopy and a zinc-induced precipitation of Hb coupled to a reversed-phase high-performance liquid chromatography (HPLC)-based method; and (4) simulating in silico by molecular docking the APX interaction with human Hb. In a multivariable analysis, Hb was the only independent variable significantly and inversely associated in 90 patients with APX peak plasma level, at variance with patients treated with rivaroxaban (n = 86) and dabigatran (n = 34) therapy. APX causes a progressive left-shift of the oxygen dissociation curve of purified Hb solution, with a K d ?300 μM. Fluorescence- and HPLC-based assays concordantly showed that APX binds to Hb with a K d 350 μM. Finally, docking simulations showed that APX can fit into in the central cavity of Hb. These findings support the hypothesis that APX does bind to Hb, which, due to its millimolar concentration in blood, can act as 'buffer' for the drug and consequently affect its free plasma level