Caloric restriction: conservation of cellular replicative capacity in vitro accompanies life-span extension in mice.

We have tested whether life-long caloric restriction (CR) slows or delays the age-related loss of cellular replicative potential that occurs during normal aging in ad libitum (AL) fed mice. Both mean and maximum life spans of the restricted animals (60% of AL intake) were significantly extended 30-40% by CR treatment. Proliferative potential, measured by determining the fraction of cells capable of forming large clones in vitro, was compared in five cell types from six tissue sites from two strains of mice (Male (C57BL/6 x DBA/2)F1("B6D2F1") and female (C57BL/6 x C3H)F1("B6C3F1")). This included four nonhematopoietic organ sites: fibroblast cells from ear skin, tail skin, and subdermal connective tissue and epithelial cells from the medullary part of the kidney and two cell types, myofibroblasts and endothelial-like cells, from spleen and bone marrow. The proliferative potential of cells from AL mice decreased progressively with age in all tissues sites of both mouse strains. CR delayed or decreased the loss of proliferative potential in all situations, but the timing of this was tissue specific. For cells from the four nonhematopoietic tissues sites from female B6C3F1 female mice, CR delayed the onset of proliferative loss, such that the fraction of large clones was significantly greater for the CR 18- to 24-month-old mice than in AL controls at three of four sites (as determined by the fraction of large clones after 1 week of clonal growth). The proliferative loss in CR tissues then accelerated from 24 to 30 months, so that both CR and AL mice had similar fractions of large clones after 30 months of age. CR was also seen to delay loss of proliferative potential in cells from skin and kidney of B6D2F1 male mice at 23-24 months of age when cloned for 2 weeks. For fibroblast and endothelial-like cells from bone marrow and spleen stromal sites from both strains of mice, CR also significantly decreased loss of proliferative potential; furthermore, in these tissues the proliferative advantages remained or increased from 24 to over 30 months of age. In companion studies (N.S. Wolf et al., 1995. Exp. Cell. Res. 217, 000-000), CR was seen to decrease age-related losses in the maximal rates of cell replication in vivo in a panel of tissues from B6D2F1 male mice.(ABSTRACT TRUNCATED AT 400 WORDS)

Caloric restriction: conservation of in vivo cellular replicative capacity accompanies life-span extension in mice.

In male mice of a long-lived hybrid strain (B6D2F1), long-term 40% caloric restriction (CR) extended both mean and maximum life spans by 36 and 20%, respectively, over that of ad libitum fed (AL) controls. Measurements of entry into S-phase were made in vivo of six different cell types in five different organs using 2-week exposures to BrdU. The labeling index (L.I.) in all organs studied was lower in young CR mice than in young AL fed mice. In most cases, the L.I. in AL mice fell to the levels of that in the CR mice by 13 months of age, and the two groups then remained so through old age. However, when the L.I. was measured in old CR mice which had been placed on the AL diet for a period of 4 weeks (this was termed refeeding (RF), it was found to be above that of similar age AL or CR mice and almost at the level of young AL mice. This was still true, but to a lesser degree, in a repeat study using an 8-week period of RF. In a separate but parallel in vitro study (companion paper, this volume), the superiority of CR over AL for retention of cellular replication capacity was confirmed by clone size distribution measurements made in several cell types in mice of several age groups. These results indicate that: (1) the rate of cell replication in AL diet mice diminishes greatly by early middle age in all organ sites studied and then plateaus or declines much more slowly; (2) CR broadly preserves in vivo cellular replicative capacity but often requires the energy levels provided by a switch to AL feeding to demonstrate this late in life; (3) accordingly, the replicative deficit in AL fed mice appears to be cumulative and is significant only in old age. The mechanism(s) involved is yet to be discovered but may be related to, or even the same as, that which extends life spans in CR animals. Correspondingly, and with corroborative data from our in vitro companion study, (W. R. Pendergrass et al., 1995. Exp. Cell. Res. 217, 309-316), we suggest that cell populations sustain an accrual of biochemical damage or physiological alterations which increasingly limit their replicative capacity as the animal ages, and that CR reduces the accrual of this damage.

Dissecting the hematopoietic microenvironment. IX. Further characterization of murine bone marrow stromal cells.

We have previously shown the adherent nontransformed, nonimmortalized murine bone marrow stromal cell (BMSC) population to consist of phagocytic macrophage and endothelial-like cells and nonphagocytic fibroblasts. Both colonial and near confluent growth of each cell type was obtained following magnetic bead separation, subsequent passaging, and sustained culture with fetal bovine serum and cytokines. Monoclonal antibody staining of antigenic determinants was used to characterize the phenotype of the stromal cell population in primary platings of murine colony-forming unit fibroblast and long-term bone marrow cultures. The antibodies MECA-99, MECA-32, and MJ7-18, raised against murine vascular endothelial antigenic determinants, and von Willebrand's factor all stained selectively for the rounded endothelial-like cells. Endothelial-like cells as well as macrophages expressed the myeloid surface antigens F4/80, 7/4, and Mac-1 under our culture conditions. The cytoskeleton of the stromal fibroblasts in culture was shown to express smooth muscle-specific actin isoforms, as evidenced by positive staining of stress fibers for alpha smooth muscle-1, CGA-7 (alpha/gamma isoforms), and HHF-35 (recognizes all muscle-specific actins). Under culture conditions, stromal fibroblasts were also found to be positive for a polyclonal smooth muscle myosin. It was found that these fibroblasts stained for collagens type I, III, and IV in our cultures. Although collagen type IV is considered a by-product of endothelial cells, endothelial-like cells in our cultures did not stain for any of the collagen types. We propose a classification listing for murine BMSCs as macrophages, endothelial-like cells, and fibroblasts that display smooth muscle-like characteristics in culture.

An age-related reduction in the replicative capacity of two murine hematopoietic stroma cell types.

Two stromal cell types, myofibroblasts and endothelial-like cells, that were identifiable by structural and antigenic specificities, were obtained from murine bone marrow and spleen of young, middle-aged, and old mice of two strains and sexes and grown in liquid culture for 9 or 10 days. As expected, there were more total nucleated cells per organ in the old mice (with larger organs) than in the young mice. However, the concentration of stromal colony forming cells was greater in the young mice, resulting in the number of colony forming cells per organ not being significantly different in most comparisons. The in vitro replicative capacity of the two stromal cell types from both organs in all age groups was determined by clone size distribution assays. In all instances the number of cell doublings achieved was statistically significantly greater in the stromal cell clones from young mice than those from old mice. The cell doubling capacity of the middle-aged mice fell between that of the young and the old mice and in most instances that difference was also statistically significant. It was concluded that these in vitro findings constituted a biomarker of aging in these tissues and that this was significant in relation to previous in vivo and in vitro work by these authors and by others reporting the inferiority of aged bone marrow and spleen stroma to regenerate and to support hematopoiesis.

A method to establish pure fibroblast and endothelial cell colony cultures from murine bone marrow.

Studies on the effect of the microenvironment on hematopoiesis would benefit from the availability of pure populations of nontransformed cells of each of the stromal cell types. The adherent murine bone marrow stromal cell population in this study consisted of fibroblasts, endothelial cells, and macrophages. Fibroblasts were segregated from the phagocytic endothelial cells and macrophages by allowing the phagocytic cells to ingest magnetic beads, with subsequent exposure to a magnetic field, effecting cell separation. Pure colony cultures of fibroblasts and endothelial cells were formed by varying the bead-to-cell ratio and incubation period of the cells. For complete purification of the fibroblasts, subsequent passaging was also necessary. Near confluent growth of each type was obtained with subsequent passages and sustained culture. The cytokine granulocyte-macrophage colony-stimulating factor (GM-CSF) was used to enhance endothelial cell growth. We were not able to obtain pure populations of bone marrow macrophages in near confluent culture. The three cell types were identified by cellular morphology, acid and alkaline phosphatase staining, binding with the lectins Ulex europaeus and Bandeiraea simplicifolia, and the capacity to stain for the factor VIII-related antigen (von Willebrand's Factor).

Allogeneic fetal liver transplantation in acute leukemia.

Three patients with acute leukemia in first complete remission were transplanted with fetal liver cells from May 1983 to June 1984. A conditioning regimen of cyclophosphamide (60-80 mg/kg) and TBI 600-700 rads (a dose rate of 5-7r per minute) was taken. The hemopoietic and immunological recovery was rapid and complete in every patient. There was proof of chimerism in case 1 as demonstrated by the existance of the XX karyotype of donor fetus in 68.7% and 75% of marrow metaphases, in 25% of peripheral blood metaphases, by the appearance of new HLA-antigens and RBC blood type antigens of donor origin. The serum alpha-fetoprotein level increased and maintained for 40 days in case 2, but definite evidence of engraftment was not observed. The allogeneic marker, the donor's HLA-antigens and RBC isoenzyme, were detected in case 3.