Developmental Changes in Bone Marrow Thymocyte Progenitors and Thy1 + Cells in Aging (original) (raw)
Related papers
A mathematical model of the effect of aging on bone marrow cells colonizing the thymus
Mechanisms of Ageing and Development, 1993
The process of T cell generation in the thymus involves complex cell-cell interactions between the various types of thymic stromal cells, thymocyte progenitors, thymocytes at different stages of differentiation and external factors. We applied the tool of mathematical modelling to analyze hypotheses and direct experiments concerning mechanisms underlying the observed developmental inferiority of bone-marrow thymocyte progenitors from old mice. Previous experimental data showed that lower cell numbers were obtained from old bone marrow-derived thymocyte progenitors, compared to young bone marrow-derived progenitors, when colonizing simultaneously the same fetal thymus. In this study, simulations based on the mathematical model indicate that the developmental inferiority of old bone marrow-derived progenitors cannot be explained by a change in a single parameter, such as the observed differences in progenitor frequency, an increase in cell cycle duration, a reduction in the fraction of proliferating cells in old age, and/or an increase in the rate of cell death. We have performed experimental measurements of the fractions of cycling cells. No significant difference was found between these fractions in young and old bone marrow-derived thymocytes. The difference in developmental patterns of young and old bone marrow-derived thymocytes may be due to a combination of more than one mechanism, possibly including interactions between competing thymocytes of old and young bone marrow origin.
Thymic Control of Proliferation of T Cell Precursors in Bone Marrow
Proceedings of The National Academy of Sciences, 1979
The activity of.T lymphocyte precursors (pre-T cells) in the bone marrow of mice was measured by the concanavalin A response synergy assay. Pre-T cell levels were low in marrow of neonatally thymectomized mice and could be restored to control values by treatment in vivo with an extract of mouse thymus. Levels of activity were also low in aging mice and again could be restored by thymic extract treatment. The most profound fall with ang was in the proliferating pre-T cell compartment as detected bytritiated thymidine suicide; and this compartment was restored by thymic extract treatment. Irradiation to the thymus, with the bone marrow shielded, caused a fall in resting pre-T cells in the bone marrow and a concomitant rise in proliferating cells. These results are consistent with a model of control of pre-T cell maturation in which the thymus senses the number of developing iymphocytes within
Characterization of thymus-seeding precursor cells from mouse bone marrow
The nature of the cells that seed the thymus of an irradiated recipient after intravenous (IV) transfer of bone marrow (BM) cells was investigated using 2 approaches. First, direct entry of a small number of donor BM cells into the thymus was tracked using a Ly-5 marker. Second, secondary IV transfer of the seeded thymus cells into a secondary recipient was used as an assay for precursor activity. A range of cell types was found to enter the recipient thymus initially, including Blineage cells and myeloid cells, but T precursors were undetectable by flow cy-tometry over the first few days. Although all cells initially entering the thymus proliferated, no sustained thymus reconstitution was seen until day 4, when recognizable T-lineage precursors began to appear. The secondary transfer assays revealed the presence of lymphoid precursors in the recipient thymus, including T, NKT, NK, and B precursor activity, with a notable early burst of B-lineage generative capacity. There was no evidence of sustained myeloid precursor or multipotent stem cell activity, even though these were seen if BM cells were injected di-rectly into the recipient thymus rather than introduced into the bloodstream. It is concluded that even though many cell types may initially enter an irradiated thymus, the thymus acts as a sieve, allowing lymphoid precursors, but not multipotent stem cells, to seed the environmental niches that permit selected precursor cell development and thymus reconstitution. (Blood. 2001;98:696-704)
Indirect demonstration of the lifetime function of human thymus
Clinical and Experimental Immunology, 1998
The aim of this study was to test the hypothesis that human thymus maintains its function as the site of early T cell development throughout life, but to a progressively diminishing extent. Mononuclear cell suspensions prepared from the samples of 39 human thymuses were analysed for the total number of cells per gram of thymus tissue, percentage of single marker-positive CD2, CD4 and CD8 cells, percentages of double-positive CD4 CD8 and CD2 CD8 cells, double-negative CD4 CD8 cells, absolute numbers of these cells per gram of tissue, and extent of the in vitro proliferation upon stimulation with concanavalin A (Con A), phytohaemagglutinin (PHA) and pokeweed mitogen (PWM) mitogens. The main outcome measures were flow cytometric data on thymus lymphoid cell composition (according to CD classification), expressed as percentages and numbers of cells per gram of thymus tissue. The total number of mononuclear cells expressed per gram of thymus tissue exponentially decreased with age. The slope of none of the analysed cell subpopulations differed from the slope of the line constructed for age-related decline of the total number of mononuclear cells (¹0·024 on a semilogarithmic scale). The thymuses of all ages contained all analysed cell subpopulations in approximately the same proportions: percentages of these cell subpopulations did not change with age, except for all CD4 þ (P ¼ 0·017) and double-positive CD4 þ CD8 þ (P ¼ 0·016) cells, which tended to decrease with age. The extent of proliferation of thymus cells upon stimulation with T and B cell mitogens was unrelated to age. We conclude that the thymus retains its function as the site of differentiation of T lymphocytes throughout life. With respect to the number of involved lymphoid cells, the function exponentially decreases with age.
Effects of Castration on Thymocyte Development in Two Different Models of Thymic Involution
The Journal of Immunology, 2005
Age-associated thymic involution is accompanied by decreased thymic output. This adversely affects general immune competence and T cell recovery following cytoreductive treatments such as chemotherapy. A causal link between increasing sex steroids and age-related thymic atrophy is well established. Although castration has been demonstrated to regenerate the atrophied thymus, little is known about how this is initiated or the kinetics of thymocyte regeneration. The present study shows that although castration impacts globally across thymocyte development in middle-aged mice, the regenerative effects are initiated in the immature triple-negative compartment and early T lineage progenitors (ETP). Specifically, there was a reduction in number of ETP with age, which was restored following castration. There was, however, no change in ETP reconstitution potential in ETP at this age or following castration. Furthermore, in a chemotherapy-induced model of thymic involution, we demonstrate castration enhances intrathymic proliferation and promotes differentiation through the triple-negative program. Clinically, reversible sex steroid ablation is achieved hormonally, and thus presents a means of ameliorating immune inadequacies, for example, following chemotherapy for bone marrow transplantation. By improving our understanding of the kinetics of thymic recovery, this study will allow more appropriate timing of therapy to achieve maximal reconstitution, especially in the elderly.
European Journal of Immunology, 1998
Age-associated thymic involution results in a diminished capacity to regenerate T cell populations, although the magnitude of this effect is unknown. In this report, thymic function was studied in aged vs. young adult mice after lethal irradiation and administration of T celldepleted bone marrow (BM) from young mice. Abnormalities observed in aged thymi (reduced thymocyte numbers, histologic abnormalities) were not reversed by administration of young BM via bone marrow transplantation (BMT), but agend thymi displayed a normal thymocyte subset distribution and appropriately deleted Mls-reactive T cells after BMT. Aged BMT recipients regenerated significantly reduced numbers of splenic T cells compared to young recipients and showed increased peripheral expansion of thymic emigrants since a higher proportion of BM-derived T cells expressed a memory phenotype in aged vs. young BMT recipients. Because peripheral expansion of thymic emigrants could substantially increase the number of thymic progeny present in the spleen, we sought to measure thymic T cell regenerative capacity after BMT in a setting devoid of peripheral expansion. To do this, TCR-transgenic (Tg + ) T cell-depleted BM was administered to aged and young recipients lacking antigen specific for the Tg + TCR. Aged recipients regenerated approximately 50 % of the TCR Tg + cells regenerated in young BMT recipients, providing evidence that even very aged thymi retain the capacity to regenerate significant numbers of mature T cell progeny. Therefore, thymic function is reduced with aged but it is not lost, suggesting that therapeutic approaches to enhance thymic function may be successful even in very aged hosts.
Lymphocyte Maturation in the Human Thymus
Scandinavian Journal of Immunology, 1983
The combination ot centrifugal elutriation as an efficient and reproducible method to separate thymocytes by size, micromethods to assess purine interconversion enzymes, and assessment of purine (deoxy)nucleoside inhibition of mitogen responses enabled us to study purine metabolism at the intrathymic level. Out of six fractions, four (nos, 3-6), containing mediumand large-sized lymphocytes, showed a proliferative response after stimulation with phytohaemagglutinin (PHA), In fractions 1-6 the number of cells with an immature immunological phenotype gradually decreased, and cells with the phenotype of mature cells gradually increased. The enzyme activity ratio of adenosine deaminase to purine nucleoside phosphorylase gradually decreased from 21 in fraction 1 to 7 in the last fraction (blood T-cell value, 0,7), We conclude that this enzyme activity ratio is a useful marker for intrathymic T-cell matiiration stages. In PHA-responsive cell fractions (3-6), the sensitivity to inhibition of the PHA response by (deoxy)adenosine and deoxyguanosine was inversely related to the enzyme activity ratio of ecto-5'-nucleotidase to deoxycytidine kinase. These findings are compatible with the hypothesis that intracellular concentrations of phosphorylated (deoxy)nucleosides are related to this inhibition. We conclude that the differences in purine metabolism among the various (mitogen-responsive) human thymocyte fractions are related to lymphoid cell function. Since the number of cells contributing to the enzyme activities and the number of cells contributing to the proliferative response (about 15% of unseparated cells) differ considerably, it is not possible to evaluate enzyme activities in unseparated thymocytes in terms of relationships between purine metabolism and lymphocyte function,
Cellular Immunology, 1973
Velocity sedimentation of thymus cell suspensions prepared from Wistar rats of different ages has been used to separate cells mainly on the basis of size. Large cells, many in division, sediment faster than the major population of small thymocytes and can be separated from them on this basis. In vitro responsiveness to mitogens has been found to be associated with the minor populations of larger cells, particularly the medium-large cells (230-270 pms). The mitogen-responsive populations also contain cells which show a high autonomous DNA synthesis. The size distribution of thymus cells in neonatal animals is more varied than in adults and there is frequently a higher proportion of large cells. The mitogen-responsive cells were again found among the fast sedimenting large cells and the highest responses were seen with the very largest cells (approximately 450 pms). The cells in both adult and neonatal animals which have the capacity to respond to mitogens in vitro are probably larger in size than the normal peripheral recirculating thoracic duct cells. The major population of normal small thymocytes showed a much lower spontaneous uptake of sH-thgmidine and did not respond to mitogens.
Experimental Gerontology, 2000
We previously demonstrated that the rat thymus undergoes a progressive remodelling long before the appearance of typical signs of involution . Age-dependent remodelling of rat thymus. Morphological and cytofluorimetric analysis from birth up to one year of age. Eur. J. Cell. Biol. 76,[156][157][158][159][160][161][162][163][164][165][166]. To focus better on the complex remodelling that occurs in the rat immune system during the first year of life, we analysed the phenotype profile of thymocytes, and T lymphocytes from mesenteric lymph nodes and peripheral blood of the same animals by flow cytometry. Two experimental sets were performed simultaneously using the same animal strain, but starting and ending the study at different ages (15 days up to 300 days in the first experimental set, and 90 days up to 360 days of life in the second). In the rat these ages appear to be crucial not only for developmental, maturative and early involutional processes of the thymus, but also of the entire immune system. The main findings were the following: (1) in the thymus, CD8 Ϫ CD4 Ϫ cells increased, CD5 ϩ ab TCR Ϫ and CD8 ϩ CD4 ϩ thymocytes decreased, while the most mature cell subset appeared well preserved with ageing; (2) in the lymph nodes, T helper and T cytotoxic lymphocytes decreased in the most aged animals. Memory/activated CD4 ϩ CD45RC Ϫ T cells decreased, while naive/resting M. Capri et al. / Experimental Gerontology 35 (2000) 613-625 613 Experimental Gerontology 35 (2000) 613-625 www.elsevier.nl/locate/expgero 0531-5565/00/$ -see front matter ᭧ (M. Capri).