Analysis of cytokine production is a tool to functionally characterise T cells. In this study, spontaneous and polyclonal activation induced cytokine production in T cells were assessed by flow cytometry in patients with B-CLL. Patients with progressive disease had a significantly increased number of T cells spontaneously producing IL-2, IL-4 and GM-CSF as compared to healthy donors and patients with non-progressive CLL, which was not the case for TNF-alpha and IFN-gamma producing T cells. However, no difference in the frequency of T cells producing these cytokines was seen comparing patients with non-progressive disease to control donors. Polyclonal activation of B-CLL T cells in vitro induced an increased proportion of T cells producing these five cytokines in patients as well as in control donors, indicating that T cells in CLL patients might have a relatively well preserved functional capacity. However, the increase in GM-CSF, TNF-alpha and IL-4 producing T cells was more marked in CLL patients than in controls. Furthermore, following activation, a higher frequency of cytokine-producing T cells was noted in patients with progressive disease as compared to those with non-progressive disease. The augmented number of cytokine-producing T cells in CLL may indicate an up-regulated capability of T cells to secrete cytokines, especially in patients with progressive CLL. The increased production of the T cell derived cytokines GM-CSF, TNF-alpha, IL-4 and IL-2 is interesting, as these cytokines have previously been shown to support growth of B-CLL leukaemic cells in vitro and as T cells might specifically recognise the autologous leukaemic B cells in vivo. The findings may suggest a role for T cells in the pathogenesis of B-CLL.
Summary. This study analysed a naturally occurring specific cellular immunity against tumour cells in chronic lymphocytic leukaemia (CLL) patients. Five out of eight patients had blood T lymphocytes able to recognize spontaneously and specifically the autologous tumour B cells (proliferation assay). In these five patients, detection of cytokines by realtime reverse transcription polymerase chain reaction (RT-PCR) revealed that granulocyte±macrophage colony-stimulating factor (GM-CSF) was the most abundant cytokine gene expressed by the T cells that recognized the autologous tumour B cells. Other activated cytokine genes were ginterferon (IFN), interleukin (IL)-2 and tumour necrosis factor (TNF)-a, but not IL-4. This profile suggests a type 1 anti-B-CLL T-cell response. CD80 and CD54 were relatively downregulated on the native tumour B cells compared with control normal B cells. Upregulation of CD80 on the leukaemic cells was mandatory for the induction of such a specific T-cell response. CD80 and CD54 monoclonal antibodies inhibited the specific T-cell DNA synthesis proliferation. The proliferative T-cell response was either MHC class I or class II restricted (inhibition by monoclonal antibodies). The specific cytokine gene expression could be found in isolated CD4, as well as CD8, T-cell subsets. This study demonstrated the presence of a potential natural specific CD4, as well as a CD8 type 1 T-cell immunity against the leukaemic CLL tumour B cells in CLL. A further detailed analysis of the spontaneous anti-CLL T-cell immunity is warranted that may facilitate the development of effective anti-tumour vaccines in CLL.
Peripheral or tonsil lymphocyte populations of EBV-seropositive donors give rise to EBV-carrying LCLs upon in vitro explantation. Such lines can arise either by a 2-step mechanism, namely release of virus from some of the explanted cells followed by infection of previously uninfected B cells, or by direct outgrowth of virus-harboring B cells (Rickinson et al., 1974; Dalens et al., 1975; Hinuma and Katsuki 1978; Katsuki et al., 1979). We observed that cells responsible for both the 2-step mechanism and for direct outgrowth are found in the purified B-cell compartment. Virus release was more frequent than direct outgrowth. The majority of virus-releasing cells were found in the low-density fraction that contains large, activated B blasts. Cells that were capable of spontaneous outgrowth in the presence of the viral inhibitor PFA and of virus-neutralizing antibody gave rise to cell lines that carried the sex chromosome marker of the original donor, rather than that of admixed cord blood lymphocyte of the opposite sex. Such cells were found in both the low- and the high-density fractions. The majority of the EBV-carrying B cells in vivo are thus low-density blasts. Rare small B cells of high density harboring EBV were capable of spontaneous outgrowth. This may be indicative of a host control mechanism that is removed upon cultivation in vitro.
Cigarette smoke contains toxic and carcinogenic substances that contribute to the development of cancer and various diseases. Genetic variation might be important, because not all smokers develop smoking-related disease. The current study addressed the possible interactions among selected single nucleotide polymorphisms (SNPs) in genes related to systemic inflammation, smoking status, the levels of circulating immune response cells and plasma biomarkers of systemic inflammation. Sixty-four healthy blood donors were recruited, 31 of whom were current smokers and 33 were never-users of tobacco products, references. Compared to references, the smokers showed significantly increased levels of circulating total white blood cells, lymphocytes, monocytes, neutrophils, basophils and C-reactive protein (CRP). Smokers also more frequently exhibited circulating cell phenotypes that are associated with an immunocompromised state: CD8 cells in the lymphocyte group, CD13 CD11 , CD13 CD14 , CD13 CD56 cells in the monocyte group and CD13 CD11 , CD13 CD56 cells in the neutrophil group. We observed an interaction among SNPs, smoking status and some of the studied biomarkers. The average plasma CRP level was significantly higher among the smokers, with the highest level found among those with the CRP rs1800947 CC genotype. Additionally, an increased CD8 GZB cells in the CD8 group were found among smokers with the GZB rs8192917 AA genotype. Thus, smoking appears to be associated with systemic inflammation and increased levels of circulating immunosuppressive cells. The extent of these effects was associated with SNPs among the smokers. This observation may contribute to a better understanding of the genetic susceptibility of smoking-related disease and the variations observed in clinical outcomes.
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