David N. Ernst

T Cell differentiation and cytokine expression in late life

Elderly humans are at significant risk with regard to the incidence and severity of many infectious diseases and cancers. Current theory holds that these late-life vulnerabilities arise, in part, through age-related changes in immune function, particularly in the T lymphocyte lineage. Herein, we discuss how such factors as thymic involution and ongoing T cell differentiation in the peripheral tissues contribute to progressive and irreversible shifts in the state of differentiation of the mature T cell pool. We propose that, by late life, these processes yield a T cell compartment with a suboptimal balance of naive and memory T cell subsets, each with altered, subset-specific programs for cytokine gene expression. As such, the T cell compartment in late life may be more prone to immune deficiency or cytokine-mediated dysregulation in response to new or previously encountered pathogens.

T Cell Differentiation and Functional Maturation in Aging Mice

Advancing age is accompanied by changes in immune potential, frequently characterized as declines in the capacity to mount effective cell-mediated or humoral immune responses (reviewed in 1–3). Age-related functional changes can be identified earliest in the T cell compartment, therefore understanding the impact of advancing age on T cell activity may provide the key to understanding immune senescence. The expression of effector function by T cells requires their activation to cell cycle entry. The sequence of events involved in T cell activation are affected by the aging process and result in the altered T cell reactivity demonstrated in the aged.

Age-related changes in mature CD4+ T cells: cell cycle analysis.

T cell proliferative responses decrease with age, but the mechanisms responsible are unknown. We examined the impact of age on memory and naive CD4(+) T cell entry and progression through the cell cycle using acridine orange to identify cell cycle stage. For both subsets, fewer stimulated cells from old donors were able to enter and progress through the first cell cycle, with an increased number of cells arrested in G(0) and fewer cells in post G(0) phases. The number of dead cells as assessed by sub-G(0) DNA was also significantly greater in the old group. CD4(+) T cells from old mice also exhibited a significant reduction in clonal history as assessed by CFSE staining. This was associated with a significant decline in cyclin D2 mRNA and protein. We propose that decreases in cyclin D2 are at least partially responsible for the proliferative decline found in aged CD4(+) T cells.

Expression of membrane activation antigens on murine B lymphocytes stimulated with lipopolysaccharide

The expression of two membrane glycoproteins, RL388 antigen and transferrin receptor (TfR), was examined on murine B cells stimulated with lipopolysaccharide (LPS) in vitro. Immunofluorescent staining with monoclonal antibodies and flow cytofluorometric analysis were used to monitor the expression of these markers as a function of the time in culture, the state of membrane Ia antigen expression, the position in cell cycle, and the degree of B-cell differentiation. Freshly explanted splenic B cells expressed low levels of RL388 antigen and TfR. Following LPS stimulation, increased expression of RL388 antigen was detectable by 8 to 12 hr of culture, a time span characterized by increased Ia antigen expression, blast transformation, and G0 to G1 phase transition. The increased expression of TfR was apparent later and correlated with entry into late G1 phase and the onset of S phase. LPS-stimulated cell cultures treated with actinomycin D (G0/G1 block) exhibited increased expression of Ia antigen, but neither RL388 antigen nor TfR, whereas hydroxyurea treatment (G1/S block) allowed expression of all three markers. These results indicate that hyperexpression of RL388 antigen and TfR occurs during G1 phase and that these events are subsequent to Ia antigen hyperexpression. Finally, B cells in late G1 through M phase of the cell cycle simultaneously express high levels of RL388 antigen and TfR. These findings suggest that the expression patterns of RL388 antigen and TfR might be useful parameters for defining compartments of the murine B-cell cycle.

Effects of tolerance induction on early cell cycle progression by Th1 clones

Human gamma-globulin (HGG)-specific mouse Th1 clones exposed to tolerogenic signals provided by HGG-pulsed paraformaldehyde-fixed splenocytes (HGG-FAPC) were analyzed for antigen-induced progression through the early phases of the cell cycle. Exposure of Th1 clones to HGG-FAPC in primary cultures inhibits the ability of the clones to synthesize DNA in response to HGG and normal APC in secondary cultures. The Th1 clones in these secondary cultures were found to be blocked in G1a phase as evidenced by cell cycle analysis and by reduced numbers of cells expressing high levels of IL-2R and TfR. This cell cycle blockade of Th1 cells was not observed if the secondary cultures were stimulated with IL-2-containing Con A CM instead of antigen. These data suggest that in our system the inhibition in antigen-induced cell cycle progression associated with Th1 tolerance induction occurs at the G1a/G1b phase transition.

Ability of tolerized Th1 and Th2 clones to stimulate B cell activation and cell cycle progression

Tolerant and nontolerant murine Th1 and Th2 clones, specific for human gamma-globulin (HGG), were compared for their ability to promote cell cycle entry and progression by B cells in vitro. When stimulated with HGG, nontolerant Th1 and Th2 clones induced similar increases in B cell membrane MHC class II levels--a phenomenon associated with early B cell activation. Nontolerant Th1 and Th2 clones also induced B cell DNA synthesis, an event associated with subsequent G1 phase traversal, although Th2 cells were more efficient than Th1 cells in stimulating this activity. Exposure of Th clones to tolerogen in the form of HGG-pulsed chemically fixed APC inhibited the ability of Th1 clones, but not Th2 clones to promote polyclonal B cell DNA synthesis in HGG-stimulated secondary cultures. However, Th1 clones exposed to tolerogen did not lose their ability to increase the expression of MHC class II molecules on B cells in these cultures. These results indicate that tolerance induction does not inhibit the ability of Th1 clones promote B cell cycle progression. In contrast, exposure of Th2 cells to tolerogen does not inhibit significantly the ability of these cells to stimulate B cell cycle entry or progression.