Whether hematopoietic stem cells (HSCs) change with aging has been controversial. Previously, we showed that the HSC compartment in young mice consists of distinct subsets, each with predetermined self-renewal and differentiation behavior. Three classes of HSCs can be distinguished based on their differentiation programs: lymphoid biased, balanced, and myeloid biased. We now show that aging causes a marked shift in the representation of these HSC subsets. A clonal analysis of repopulating HSCs demonstrates that lymphoid-biased HSCs are lost and long-lived myeloid-biased HSCs accumulate in the aged. Myeloid-biased HSCs from young and aged sources behave similarly in all aspects tested. This indicates that aging does not change individual HSCs. Rather, aging changes the clonal composition of the HSC compartment. We show further that genetic factors contribute to the age-related changes of the HSC subsets. In comparison with B6 mice, aged D2 mice show a more pronounced shift toward myeloidbiased HSCs with a corresponding reduction in the number of both T-and B-cell precursors. This suggests that low levels of lymphocytes in the blood can be a marker for HSC aging. The loss of lymphoid-biased HSCs may contribute to the impaired immune response to infectious diseases and cancers in the aged.
IntroductionTraditionally, tissue stem cells were thought to be immortal and exempt from aging. Like all stem cells, hematopoietic stem cells (HSCs) self-renew, and serial transplantation studies show that populations of HSCs can live much longer than the donor from which they were originally isolated. 1 HSCs express telomerase, necessary for chromosome stability during cell division. 2 Together, these observations supported the idea of an immortal HSC. However, there is increasing evidence that HSCs isolated from aged donors are different from HSCs that are obtained from young donors. 3,4 For example, aged HSCs may have a reduced ability to home to the bone marrow (BM), 5,6 have an altered cell surface phenotype, 5,7 may cycle more rapidly, 5 produce more myeloid cells, [5][6][7][8] and have a different gene expression program than their young counterparts. 9,10 HSCs from aged environments may have slightly less self-renewal capacity than their younger counterparts. 11 An accumulation of DNA damage in HSCs has been invoked to explain an age-related decline in HSCs. 12,13 It should be emphasized that most of these age-related changes are controversial, and contradictory data have been published for almost every aspect of the behavior of aged HSCs. One of the reasons for these inconsistencies might be that most of the information about aged HSCs comes from comparisons of populations of HSCs from aged and young sources. However, it is clear by now that the HSC compartment consists of distinct subsets of HSCs. [14][15][16] We showed that HSCs in these subsets are very different from each other, each possessing distinct selfrenewal capacities, differentiation abilities, life span, and repopulation kinetics. [14][15][16] Our work was...
