Leu 7+(HNK-l+) Cells

In the present study, combined methods (indirect immunofluorescence with monoclonal antibodies, Percoll density fractionation, FACS analysis, and the cytotoxicity test) were used for further characterization of peripheral blood Leu 7+ cells (human NK and K cells). The Leu 7+ cell content was found to be relatively higher in the low-density cell fraction in which cells of large granular lymphocyte morphology predominated. However, Leu 7+ cells were also present in intermediate and high-density fractions. Low-density Leu 7+ cells were characterized by both Leu 2 (T suppressor/cytotoxic) and OKM1 (myelomonocytic) markers, whereas among high-density Leu 7+ cells the Leu 2 phenotype strictly predominated. Depletion of OKT3+ cells from the non-adherent cell population caused a decrease of cells with T helper and T suppressor phenotypes but did not have this effect on Leu 7+ and OKM1+ cells. After depletion of Leu 7+ cells from the OKT3- population the content of both T suppressor and OKM1+ cells decreased. Both the present results and previous reports enable us to conclude that two main Leu 7+ cell subpopulations are present in blood, namely Leu 7+Leu 2+/Leu 4+ and Leu 7+/OKM1+ cells. The presence of small and large Leu 7+ cells was also shown by FACS analysis.     

Leu 7+(HNK-l+) Cells

In the present immunohistochemical studies, Leu 7+ (HNK-1+, human natural killer and killer) cells were found to occupy preferentially germinal centres of follicles in lymph nodes and tonsils. Leu 7+ cells were also present in germinal-like zones of spleen follicles and in mantle zones of hyperplastic thymus follicles and varied in localization in lymph nodes involved in different types of follicular centre cell-derived malignant lymphomas. Most of the Leu 7+ cells in the follicles expressed the Leu 3 (helper/inducer) marker. Double staining studies of tonsil sheep erythrocyte-rosetting and peripheral blood mononuclear cell suspensions showed that two main, mutually complementary, subpopulations of Leu 7+ cells could be distinguished in both cases, namely Leu 7+/Leu 4+ (subdivided into Leu 2+ (suppressor/cytotoxic) and Leu 3+) and Leu 7+/Leu 4-, including mostly cells with OKM 1 (myelomonocytic) characteristics. Thus, in the tonsil cell suspension the cells with Leu 7+ Leu 3+/OKM 1- immunophenotype strongly predominated, whereas among peripheral blood mononuclear cells Leu 7+Leu 2+/OKM 1- and Leu 7+/OKM 1+ immunophenotypes were mostly observed.     

Small conductance Ca2+-activated K+ channels and calmodulin

Small conductance Ca²⁺-activated K⁺ channels (SK channels) contribute to the long lasting afterhyperpolarization (AHP) that follows an action potential in many central neurones. The biophysical and pharmacological attributes of cloned SK channels strongly suggest that one or more of them underlie the medium component of the AHP that regulates interspike interval and plays an important role in setting tonic firing frequency. The cloned SK channels comprise a distinct subfamily of K⁺ channels. Heterologously expressed SK channels recapitulate the biophysical and pharmacological hallmarks of native SK channels, being gated solely by intracellular Ca²⁺ ions with no voltage dependence to their gating, small unitary conductance values and sensitivity to the bee venom peptide toxin, apamin. Molecular, biochemical and electrophysiological studies have revealed that Ca²⁺ gating in SK channels is due to heteromeric assembly of the SK α pore-forming subunits with calmodulin (CaM). Ca²⁺ binding to the N-terminal E–F hands of CaM is responsible for SK channel gating. Crystallographic studies suggest that SK channels gate as a dimer-of-dimers, and that the physical gate of SK channels resides at or near the selectivity filter of the channels. In addition, Ca²⁺-independent interactions between the SK channel α subunits and CaM are necessary for proper membrane trafficking.     

CD8+ T Cells Induce Medullary Thymic Epithelium and CD4+CD8+CD25+ TCRβ− Thymocytes in SCID Mice

During T-cell development the transition in the thymus of CD4-CD8- double negative (DN) progenitor T cells into CD4+CD8+ double positive (DP) cells is dependent on the expression of a T-cell receptor (TCR)-beta-chain protein. In this study purified peripheral CD4+ and CD8+ T lymphocytes from the C.B-17 strain of mice were adoptively transferred into syngeneic, neonatal SCID mice, where donor cells resided at constant numbers in thymus from 2 weeks until 10 weeks post cell transfer. In the recipient thymus the CD8+ donor cells outnumbered the CD4+ cells by a factor of three to five and both subsets contained a large fraction of activated cells. During the late phase of treatment, CD8+ T cells induced high numbers of DP thymocytes in the SCID mice, a process accompanied by the maturation of medullary epithelial cells. Such thymic development in the SCID mouse was inhibited by coresiding CD4+ donor T cells. These results indicate a regulatory role by mature peripheral T cells on medullary epithelial growth and thymocyte development in the treated SCID mice.     

The lifestyle of naturally occurring CD4+CD25+Foxp3+ regulatory T cells

Summary: Numerous studies over the past 10 years have demonstrated the importance of naturally occurring CD4⁺CD25⁺Foxp3⁺ regulatory T cells (nTregs) in immune regulation. We analyzed the mechanism of action of nTregs in a well‐characterized model of autoimmune gastritis and demonstrated that nTregs act at an early stage of disease progression to inhibit the differentiation of naïve T cells to pathogenic T‐helper 1 effectors. The effects of nTregs in this model are not antigen‐specific but are mediated by activation of the nTregs by ubiquitous self‐peptide major histocompatibility complex class II complexes together with cytokines released by activated effector cells. Studies in vitro confirmed that some nTregs exist in an activated state in vivo and can be activated to exert non‐specific suppressor effector function by stimulation with interleukin‐2 in the absence of engagement of their T‐cell receptor. Natural Tregs can differentiate in vitro to exhibit potent granzyme B‐dependent, partially perforin‐independent cytotoxic cells that are capable of specifically killing antigen‐presenting B cells. Natural Treg‐mediated killing of antigen‐presenting cells may represent one pathway by which they can induce long‐lasting suppression of autoimmune disease.