Janneke Heimweg

Preeclampsia is associated with lower percentages of regulatory T cells in maternal blood.

Objective: Immunological mechanisms are involved in the pathophysiology of preeclampsia. During pregnancy there is an increase in regulatory T (Treg) cells, which has an important role in regulating tolerance to the immunologically distinct fetus. We hypothesised that percentages of Treg cells are decreased in preeclamptic patients. Methods: Peripheral blood was obtained from 26 healthy pregnant controls and 18 preeclamptic patients. Treg cells were measured using flow-cytometry. Results: Women with pregnancies complicated by preeclampsia had significantly lower percentages of CD4+FOXP3+ Treg cells. Conclusion: We conclude that a deficiency of regulatory T cells may play a role in the pathophysiology of preeclampsia.

Cryopreservation does not alter the frequency of regulatory T cells in peripheral blood mononuclear cells

Sir,With great interest we read therecentarticle intheJournalof Immunological Methods by Elkord (2009), in which theauthor reports a reduction of human regulatory T (Treg) cellnumbers in peripheral blood mononuclear cells (PBMCs) aftercryopreservation. Treg cellswereidentified by flow cytometricmeasurementofCD25

Low-dose acarbose does not delay digestion of starch but reduces its bioavailability

Aims  Slowly digestible starch is associated with beneficial health effects. The glucose‐lowering drug acarbose has the potential to retard starch digestion since it inhibits α‐amylase and α‐glucosidases. We tested the hypothesis that a low dose of acarbose delays the rate of digestion of rapidly digestible starch without reducing its bioavailability and thereby increasing resistant starch flux into the colon.

Influence of a subsequent meal on the oro-cecal transit time of a solid test meal

Background  Oro‐cecal transit time (OCTT) is determined for clinical diagnostics of intestinal complaints and research purposes. Ingestion of a subsequent meal during the test period shortens the OCTT of a liquid test meal (glucose solution), as previously reported. This study was conducted to determine whether the same phenomenon occurs after ingestion of a solid test meal.

Flow cytometric analysis of cytokine expression in short-term allergen-stimulated T cells mirrors the phenotype of proliferating T cells in long-term cultures

BACKGROUND Allergen-specific T(H) cells play an important role in IgE-mediated disorders as allergies. Since this T(H) cell-population only accounts for a small percentage of T(H) cells, they are difficult to phenotype without prior selection or expansion. METHODS Grass-pollen-specific T(H) cell profiles were evaluated in 5 allergic and 4 non-allergic individuals using three different approaches: CD154 expression on ex vivo grass-pollen-activated PBMCs (i); CFSE-dilution in grass-pollen-restimulated PBMCs (ii) and T cell lines enriched for allergen-specific T cells (iii). RESULTS Relatively low numbers of allergen-specific T(H) cells were detected using CD154 expression, limiting the power to detect phenotypic differences between allergic and non-allergic individuals. In contrast, higher frequencies of proliferating T(H) cells were detected by loss-of-CFSE intensity in PBMCs and TCLs after grass-pollen-stimulation, resulting in the detection of significantly more IL-4 producing T(H) cells in allergic vs non-allergic individuals. In addition, higher numbers of IFNγ producing T(H) cells were detected in long-term cultures compared to the CD154 expressing T(H) cells. CONCLUSION To detect allergen-specific T(H) cells for a common allergen as grass-pollen, expansion is not absolutely necessary, although within 8-day grass-pollen cultures, higher numbers of proliferating T(H) cells resulted in increased statistical power to detect phenotypic differences. However, this approach also detects more bystander activated T(H) cells. TCLs resulted in comparable percentages of cytokine expressing T cells as 8-day cultures. Therefore enrichment can be necessary for detection of T(H) cells specific for a single allergen or allergen-derived peptides, but is dispensable for the detection and phenotyping of allergen-specific T(H) cells using crude extracts.

Viral mimic poly-(I:C) attenuates airway epithelial T-cell suppressive capacity: implications for asthma.

In allergen-sensitised asthmatic individuals, allergen-specific type-2 T-helper cells proliferate and secrete type-2 cytokines (e.g. interleukin (IL)-4, -5 and -13), driving the airway inflammatory response that gives rise to the clinical symptoms of asthma. Both early-life sensitisation to aeroallergens and lower respiratory viral infections are important environmental risk factors for developing asthma. Additionally, respiratory viral infections are the most common trigger for asthma exacerbations. Of interest, many asthma susceptibility genes are expressed in the airway epithelium [1], which forms the first continuous line of defence against inhaled environmental insults, including viruses and aeroallergens. Impaired immune regulation and failure to maintain tolerance to allergens is thought to contribute to allergic sensitisation. Asthma epithelium may be deficient in its innate immune defence against viral infections, resulting in increased viral replication upon rhinovirus infection compared to nonasthma-derived epithelial cultures [2]. Furthermore, there is evidence for loss of the mucosal immune barrier in asthma, with disruption of epithelial integrity [1, 3]. This may lead not only to increased permeability, but also to the release of pro-inflammatory mediators, specifically of cytokines that drive type-2 responses [3, 4]. We recently observed that the ability of allergens to disrupt epithelial barrier function is related to the development of type-2-mediated inflammation in asthma [5, 6]. Furthermore, we demonstrated that healthy murine lung epithelium is a potent inhibitor of T-cell proliferation and that this inhibition is lost upon viral infection [7]. It is unknown if this immune regulatory effect is displayed by human epithelium and is dysregulated in asthma. We hypothesise that changes in this regulatory effect translate into aberrant regulation of T-cell responses in asthma. We studied the epithelial regulation of T-cell proliferation and cytokine responses upon epithelial stimulation with a viral mimic, using co-culture of human T-cells and primary bronchial epithelial cells (PBECs) from healthy controls and asthma patients. Airway epithelial regulation of T-cell activity may be impaired during virus-induced exacerbations in asthma http://ow.ly/b9KB303KVul