Tumor necrosis factor promotes human T-cell development in nonobese diabetic/severe combined immunodeficient mice.

A major problem after clinical hematopoietic stem cell transplantations is poor T-cell reconstitution. Studying the mechanisms underlying this concern is hampered, because experimental transplantation of human stem and progenitor cells into nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice usually results in low T-lymphocyte reconstitution. Because tumor necrosis factor alpha (TNFalpha) has been proposed to play a role in T-lineage commitment and differentiation in vitro, we investigated its potential to augment human T-cell development in vivo. Administration of TNF to irradiated NOD/SCID mice before transplantation of human mononuclear cells from either cord blood or adult G-CSF-mobilized peripheral blood (MPBL) led 2-3 weeks after transplantation to the emergence of human immature CD4(+)CD8(+) double-positive T-cells in the bone marrow (BM), spleen, and thymus, and in this organ, the human cells also express CD1a marker. One to 2 weeks later, single-positive CD4(+) and CD8(+) cells expressing heterogenous T-cell receptor alpha beta were detected in all three organs. These cells were also capable of migrating through the blood circulation. Interestingly, human T-cell development in these mice was associated with a significant reduction in immature lymphoid human CD19(+) B cells and natural killer progenitors in the murine BM. The human T cells were mostly derived from the transplanted immature CD34(+) cells. This study demonstrates the potential of TNF to rapidly augment human T lymphopoiesis in vivo and also provides clinically relevant evidence for this process with adult MPBL progenitors.

Age related microsatellite instability in T cells from healthy individuals.

Many immune functions decline with age and may jeopardize the elderly, as illustrated, for example by the significantly higher mortality rate from influenza in old age. Although innate and humoral immunity are affected by aging, it is the T cell compartment, which manifests most alterations. The mechanisms behind these alterations are still unclear, and several explanations have been offered including thymic involution and Telomere attrition leading to cell senescence. Age related accumulation of mutations has been documented and could serve as an additional mechanism of T cell dysfunction. One effective repair mechanism capable of rectifying errors in DNA replications is the mismatch repair (MMR) system. We previously reported a comparative examination of individual DNA samples from blood cells obtained at 10 year intervals from young and old subjects. We showed significantly higher rates of microsatellite instability (MSI), an indicator of MMR dysfunction in older subjects, compared to young. In the present study we confirm this result, using direct automated sequencing and in addition, we demonstrate that as CD8 lymphocytes from aged individuals, undergo repeated population doublings (PDs) in culture, they develop MSI. CD4 clones that also undergo repeated PDs in culture develop significant MSI as well. Elucidation of this previously unexplored facet of lymphocyte dynamics in relation to aging may help identify novel mechanisms of immunosenescence and pathways that could serve as targets for interventions to restore immune function.

T cells and aging, January 2002 update.

Age-related changes in the immune system may contribute to morbidity and mortality due to decreased resistance to infection and, possibly, certain cancers in the aged. Many studies mostly performed in mice, rats and man but also including monkeys and dogs have established that age-associated immune decline is characterized by decreases in both humoral and cellular responses. The former may be largely a result of the latter, because observed changes both in the B cell germline-encoded repertoire and the age-associated decrease in somatic hypermutation of the B cell antigen receptors are now known to be critically affected by helper T cell aging. As antigen presenting cell (APC) function appears to be well-maintained in the elderly, this review will focus on the T cell. Factors contributing to T cell immunosenescence may include a) altered production of T cell progenitors (stem cell defects, stromal cell defects), b) decreased levels of newly-generated mature T cells (thymic involution), c) aging of resting immune cells, d) disrupted activation pathways in immune cells (stimulation via the T cell receptor for antigen, costimulation, apoptosis control), e) replicative senescence of clonally expanding cells. This review aims to consider the current state of knowledge on the scientific basis for and potential clinical relevance of those factors in immunosenescence in humans. Experiments in other species will be touched upon with the proviso that there are clearly differences between them, especially between humans and rodents, but exactly what those differences are is not completely clear. Given its potential importance and the increasing proportion of elderly people the world over, coupled with the realisation that whereas mortality is decreasing, morbidity may not be decreasing in parallel (1), a better understanding of the causes and impact of immunosenescence may offer the possibility of identifying where prevention or delay of onset, as well as therapeutic intervention, might be beneficial. Amelioration of the effects of dysregulated immune responses in the elderly by replacement therapy, supplementation therapy or other approaches may result in an enhancement of their quality of life, and significant reductions in the cost of medical care in old age.

Hematopoietic cells and replicative senescence.

Replicative senescence describes the finite cell replicative capacity in response to chronic proliferative stimulation. A key element in this process is the shortening of the telomeres, which to a major extent is caused by the lack of expression of telomerase. Whereas this situation has been well documented for a variety of somatic cell types, the question of whether stem cells "senesce" in the course of enforced chronic sequential divisions is as yet unresolved. This article examines several distinct features of hematopoietic cells (HC) in light of their similarity to certain aspects of memory T cells. It appears that although the capacity of HC for replication is not exhausted under normal physiological conditions in vivo, under certain experimental conditions and in specific in clinical situations HC do show signs of telomere shortening. This limited potential should be taken into account both with respect to aging in vivo, and also in terms of attempts to expand these cells ex vivo for therapeutic use.