Diana L. Wallace

Rapid Turnover of Effector-Memory CD4 T Cells in Healthy Humans

Memory T cells can be divided into central–memory (TCM) and effector–memory (TEM) cells, which differ in their functional properties. Although both subpopulations can persist long term, it is not known whether they are maintained by similar mechanisms. We used in vivo labeling with deuterated glucose to measure the turnover of CD4+ T cells in healthy humans. The CD45R0+CCR7− TEM subpopulation was shown to have a rapid proliferation rate of 4.7% per day compared with 1.5% per day for CD45R0+CCR7+ TCM cells; these values are equivalent to average intermitotic (doubling) times of 15 and 48 d, respectively. In contrast, the CD45RA+CCR7+ naive CD4+ T cell population was found to be much longer lived, being labeled at a rate of only 0.2% per day (corresponding to an intermitotic time of approximately 1 yr). These data indicate that human CD4+ TEM cells constitute a short-lived cell population that requires continuous replenishment in vivo.

A Deletion in the Gene Encoding the CD45 Antigen in a Patient with SCID

SCID is a heterogeneous group of hereditary diseases. Mutations in the common γ-chain (γc) of cytokine receptors, including those for IL-2, IL-4, IL-7, IL-9, and IL-15, are responsible for an X-linked form of the disease, while mutations of several other genes, including Janus-associated kinase-3, may cause autosomal recessive forms of SCID. We investigated the first SCID patient to be described with minimal cell surface expression of the leukocyte common (CD45) Ag. CD45 is an abundant transmembrane tyrosine phosphatase, expressed on all leukocytes, and is required for efficient lymphocyte signaling. CD45-deficient mice are severely immunodeficient and have very few peripheral T lymphocytes. We report here that a homozygous 6-bp deletion in the gene encoding CD45 (PTPRC, gene map locus 1q31–32), which results in a loss of glutamic acid 339 and tyrosine 340 in the first fibronectin type III module of the extracellular domain of CD45, is associated with failure of surface expression of CD45 and SCID. Molecular modeling suggests that tyrosine 340 is crucial for the structural integrity of CD45 protein. This is the second description of a clinically relevant CD45 mutation, provides direct evidence for the importance of CD45 in immune function in humans, and suggests that abnormalities in CD45 expression are a possible cause of SCID in humans.

In vivo kinetics of human natural killer cells: the effects of ageing and acute and chronic viral infection

Human natural killer (NK) cells form a circulating population in a state of dynamic homeostasis. We investigated NK cell homeostasis by labelling dividing cells in vivo using deuterium‐enriched glucose in young and elderly healthy subjects and patients with viral infection. Following a 24‐hr intravenous infusion of 6,6‐D2‐glucose, CD3– CD16+ NK cells sorted from peripheral blood mononuclear cells (PBMC) by fluorescence‐activated cell sorter (FACS) were analysed for DNA deuterium content by gas chromatography mass spectrometry to yield minimum estimates for proliferation rate (p). In healthy young adults (n = 5), deuterium enrichment was maximal ∼ 10 days after labelling, consistent with postmitotic maturation preceding circulation. The mean (± standard deviation) proliferation rate was 4·3 ± 2·4%/day (equivalent to a doubling time of 16 days) and the total production rate was 15 ± 7·6 × 106 cells/l/day. Labelled cells disappeared from the circulation at a similar rate [6·9 ± 4·0%/day; half‐life (T½) < 10 days]. Healthy elderly subjects (n = 8) had lower proliferation and production rates (P = 2·5 ± 1·0%/day and 7·3 ± 3·7 × 106 cells/l/day, respectively; P = 0·04). Similar rates were seen in patients chronically infected with human T‐cell lymphotropic virus type I (HTLV‐I) (P = 3·2 ± 1·9%/day). In acute infectious mononucleosis (n = 5), NK cell numbers were increased but kinetics were unaffected (P = 2·8 ± 1·0%/day) a mean of 12 days after symptom onset. Human NK cells have a turnover time in blood of about 2 weeks. Proliferation rates appear to fall with ageing, remain unperturbed by chronic HTLV‐I infection and normalize rapidly following acute Epstein–Barr virus infection.

Measurement and modeling of human T cell kinetics

The ability to measure, describe and interpret T cell kinetics is pivotal in understanding normal lymphocyte homeostasis and diseases that affect T cell numbers. Following in vivo labeling of dividing cells with 6,6‐D2‐glucose in eight healthy volunteers, peripheral blood T cells were sorted by CD4, CD8 and CD45 phenotype. Enrichment of deuterium in DNA was measured by gas chromatography‐mass spectrometry. A novel model of T cell kinetics, allowing for heterogeneity within T cell pools, was used to analyze data on acquisition and loss of label and calculate proliferation and disappearance rates for each subpopulation. Proliferation rates for CD45RO+CD8+ cells and CD45RO+CD4+ cells were 5.1% and 2.7% /day, respectively (equivalent doubling times: 14 and 26 days). CD45RA+CD8+ lymphocytes and CD45RA+CD4+ lymphocytes had slower proliferation rates, 0.5% and 0.6% / day, respectively (doubling time about 4 months). Disappearance rates of labeled cells were similar for all cell types (7%–12% / day) and exceeded corresponding proliferation rates. This disparity may be understood conceptually in terms of either phenotypic heterogeneity (rapid versus slow turnover pools), or history (recently divided cells are more likely to die). The new kinetic model fits the data closely and avoids the need to postulate a large external source of lymphocytes to maintain equilibrium.

Direct Measurement of T Cell Subset Kinetics In Vivo in Elderly Men and Women

The age-associated decline in immunocompetence is paralleled by changes in the proportions of PBL subpopulations. In turn, the size and composition of the peripheral lymphocyte pool is determined by input from the thymus and bone marrow and by the balance of proliferation and death in each lymphocyte subpopulation. We compared the kinetics of lymphocyte subtypes in young (seven of eight CMV seronegative) and healthy elderly human subjects (six of seven CMV seropositive), using deuterated glucose DNA labeling in vivo to measure rates of T cell proliferation and disappearance. For CD45RO+ cells of both CD4+ and CD8+ subtypes and for CD4+CD45RA+ cells the kinetics of proliferation and disappearance were remarkably similar between elderly and young subjects. In the young, the kinetics of CD8+CD45RA+ cells with a naive phenotype resembled those of CD4+CD45RA+ cells. However, CD8+CD45RA+ T cells from the elderly exhibited a predominantly primed phenotype, and for this subset, although the proliferation rate was similar to that of other CD45RA+ cells, the disappearance rate of labeled cells was greatly decreased compared with that of all other T cell subsets. Our data provide a direct demonstration that there are no substantial changes in in vivo kinetics for most T cell populations in healthy elderly compared with young subjects. However, primed CD8+CD45RA+ cells show unusual kinetic properties, indicating the persistence of these cells in the blood and dissociation of proliferation from disappearance.

In vivo T lymphocyte dynamics in humans and the impact of human T-lymphotropic virus 1 infection

Human T-lymphotropic virus type 1 (HTLV-1) is a persistent CD4+ T-lymphotropic retrovirus. Most HTLV-1-infected individuals remain asymptomatic, but a proportion develop adult T cell leukemia or inflammatory disease. It is not fully understood how HTLV-1 persists despite a strong immune response or what determines the risk of HTLV-1-associated diseases. Until recently, it has been difficult to quantify lymphocyte kinetics in humans in vivo. Here, we used deuterated glucose labeling to quantify in vivo lymphocyte dynamics in HTLV-1-infected individuals. We then used these results to address four questions. (i) What is the impact of HTLV-1 infection on lymphocyte dynamics? (ii) How does HTLV-1 persist? (iii) What is the extent of HTLV-1 expression in vivo? (iv) What features of lymphocyte kinetics are associated with HTLV-1-associated myelopathy/tropical spastic paraparesis? We found that CD4+CD45RO+ and CD8+CD45RO+ T lymphocyte proliferation was elevated in HTLV-1-infected subjects compared with controls, with an extra 1012 lymphocytes produced per year in an HTLV-1-infected subject. The in vivo proliferation rate of CD4+CD45RO+ cells also correlated with ex vivo viral expression. Finally, the inflammatory disease HTLV-1-associated myelopathy/tropical spastic paraparesis was associated with significantly increased CD4+CD45RO+ cell proliferation. We suggest that there is persistent viral gene expression in vivo, which is necessary for the maintenance of the proviral load and determines HTLV-1-associated myelopathy/tropical spastic paraparesis risk.

Signal Transduction in Human T Lymphocytes

T-cell activation leads to proliferation and ultimately to the generation of effector cells which mediate helper, suppressor and cytotoxic T-cell functions. These processes take many hours and involve complex celland factor-mediated interactions such that analysis of these late proliferative and functional events can provide only limited information about the initial Ugand-receptor interactions.

Fibroblasts prevent apoptosis of IL-2-deprived T cells without inducing proliferation: a selective effect on Bcl-xL expression

The apoptosis of human cytokine‐deprived activated T cells can be prevented by a soluble mediator secreted by fibroblasts, epithelial and endothelial cells, and this rescue occurs with fibroblasts from different species. Fractionation of WI38 fibroblast‐conditioned medium indicated that the survival‐promoting agent(s) were >30 000 MW. The continuous presence of the survival factor was required for prevention of apoptosis, which did not involve the induction of proliferation. Nevertheless, the co‐cultured T cells remained in a primed state. The expression of the apoptosis‐inducing proteins Bax and CD95 (Fas/Apo‐1) was either unchanged or slightly increased in fibroblast‐rescued T cells, suggesting that constraints on survival still existed after co‐culture. A fundamental observation in the present study was that although Bcl‐2 was reduced, the levels of Bcl‐xL was maintained in cytokine‐deprived T cells by fibroblast co‐culture. This suggests that fibroblasts and/or other stromal cells may promote activated T‐cell survival by a selective effect on Bcl‐xL expression, which is consistent with histological examination of activated T cells within lymphoid tissue in vivo. The rescued T cells could be re‐activated by CD3 antibody, but only in the presence of CD28 co‐stimulation, which induced both Bcl‐2 and Bcl‐xL expression and also proliferation. Thus, survival signals from stromal cells in tissue microenvironments may enable activated T‐cell persistence in a primed but quiescent state, and our data suggest that the regulation of Bcl‐xL expression may be central in this process. The further characterization of this process is essential to clarify how signals from stromal cells can influence the resolution and/or chronicity of immune responses in different tissues in vivo.

Regulation of alternative splicing of CD45 by antagonistic effects of SR protein splicing factors.

CD45 is a transmembrane glycoprotein possessing tyrosine phosphatase activity, which is involved in cell signaling. CD45 is expressed on the surface of most leukocytes and can be alternatively spliced by the inclusion or skipping of three variable exons (4, 5, and 6 or A, B, and C) to produce up to eight isoforms. In T cells, the splicing pattern of CD45 isoforms changes after activation; naive cells express high m.w. isoforms of CD45 which predominantly express exon A (CD45RA), whereas activated cells lose expression of exon A to form low m.w. isoforms of CD45 including CD45RO. Little is known about the specific factors controlling the switch in CD45 splicing which occurs on activation. In this study, we examined the influence of the SR family of splicing factors, which, like CD45, are expressed in tissue-specific patterns and have been shown to modulate the alternative splicing of a variety of transcripts. We show that specific SR proteins have antagonistic effects on CD45 splicing, leading either to exon inclusion or skipping. Furthermore, we were able to demonstrate specific changes in the SR protein expression pattern during T cell activation.

Prolonged exposure of naive CD8(+) T cells to interleukin-7 or interleukin-15 stimulates proliferation without differentiation or loss of telomere length

Interleukin (IL)‐7 and IL‐15 are cytokines implicated in homeostatic control of the peripheral CD8 T‐cell pool. We compared the effects of IL‐7 and IL‐15 on survival and proliferation of purified human CD8+ T‐cell subsets. Low concentrations of either cytokine reduced the spontaneous apoptosis of all subsets, and enhancement of survival corresponded to the extent of Bcl‐2 up‐regulation. Surprisingly, although minimal proliferation of naïve CD8+ T cells was observed during the first week of culture with cytokines, a marked expansion of these cells occurred at later time points, particularly in response to IL‐15. This occurred largely without phenotypic change or acquisition of effector function, indicating a dissociation of differentiation from proliferation. Notably, progression of naïve CD8+ T cells through several cell divisions resulted in up‐regulation of telomerase and the maintenance of telomere length. These data show that IL‐7 and IL‐15 induce cell proliferation and rescue from apoptosis in a concentration, time and subset‐dependent manner, and have implications for the homeostatic expansion of the naïve CD8+ T‐cell pool.