David E. Harrison scite author profile

Marrow stem cell lines from old donors and those from young controls gave equally rapid rates of colony growth on spleens of irradiated mice. Old and young stem cell lines competed equally well with chromosomally marked marrow stem cells from a young donor in producing cell types that are stimulated by bleeding; old cells competed 70% as well as young in producing cell types stimulated by phytohemagglutinin (PHA) in vitro. After a single serial transplantation, the rates of colony growth declined 1.5- to 2.5-fold, and the ability to compete declined 2- to 4-fold for bleeding-stimulated and 4- to 10-fold for PHA-stimulated cells. Thus, immediate stem cell proliferative capacities decline much more after one serial transplantation than after a lifetime of normal function.

show abstract

The mouse as a model for understanding chronic diseases of aging: the histopathologic basis of aging in inbred mice

Sundberg

Berndt

Sundberg

et al. 2011

Pathobiology of Aging & Age-related Diseases

102

View full text Add to dashboard Cite

Inbred mice provide a unique tool to study aging populations because of the genetic homogeneity within an inbred strain, their short life span, and the tools for analysis which are available. A large-scale longitudinal and cross-sectional aging study was conducted on 30 inbred strains to determine, using histopathology, the type and diversity of diseases mice develop as they age. These data provide tools that when linked with modern in silico genetic mapping tools, can begin to unravel the complex genetics of many of the common chronic diseases associated with aging in humans and other mammals. In addition, novel disease models were discovered in some strains, such as rhabdomyosarcoma in old A/J mice, to diseases affecting many but not all strains including pseudoxanthoma elasticum, pulmonary adenoma, alopecia areata, and many others. This extensive data set is now available online and provides a useful tool to help better understand strain-specific background diseases that can complicate interpretation of genetically engineered mice and other manipulatable mouse studies that utilize these strains.

show abstract

Changes in the expression of splicing factor transcripts and variations in alternative splicing are associated with lifespan in mice and humans

Lee¹,

Pilling

Emond³

et al. 2016

Aging Cell

View full text Add to dashboard Cite

SummaryDysregulation of splicing factor expression and altered alternative splicing are associated with aging in humans and other species, and also with replicative senescence in cultured cells. Here, we assess whether expression changes of key splicing regulator genes and consequent effects on alternative splicing are also associated with strain longevity in old and young mice, across 6 different mouse strains with varying lifespan (A/J, NOD.B10Sn‐H2b/J, PWD.Phj, 129S1/SvlmJ, C57BL/6J and WSB/EiJ). Splicing factor expression and changes to alternative splicing were associated with strain lifespan in spleen and to a lesser extent in muscle. These changes mainly involved hnRNP splicing inhibitor transcripts with most changes more marked in spleens of young animals from long‐lived strains. Changes in spleen isoform expression were suggestive of reduced cellular senescence and retained cellular proliferative capacity in long‐lived strains. Changes in muscle isoform expression were consistent with reduced pro‐inflammatory signalling in longer‐lived strains. Two splicing regulators, HNRNPA1 and HNRNPA2B1, were also associated with parental longevity in humans, in the InCHIANTI aging study. Splicing factors may represent a driver, mediator or early marker of lifespan in mouse, as expression differences were present in the young animals of long‐lived strains. Changes to alternative splicing patterns of key senescence genes in spleen and key remodelling genes in muscle suggest that correct regulation of alternative splicing may enhance lifespan in mice. Expression of some splicing factors in humans was also associated with parental longevity, suggesting that splicing regulation may also influence lifespan in humans.

show abstract

Competitive repopulation: a new assay for long-term stem cell functional capacity

Harrison¹

1980

View full text Add to dashboard Cite

A new assay for the long-term functional capacity of hemopoietic stem cells is reported. Stem cell function in each donor of a particular genotype is assayed by mixing its marrow cells with a constant number of marrow cells from a donor with distinguishable hemoglobin and measuring the relative ability of each donor to populate stem-cell- depleted recipients. For example, cells from many different B6 donors may be assayed by mixing them with a constant number of WBB6F1 cells from a single pool and injecting them into irradiated WBB6F1 recipients. As the ratio of B6 to WBB6F1 marrow cells increases from 0:1 to 3:1 the percentage of B6 hemoglobin increases in a linear fashion. This is also found with WB and WBB6F1 or CBA and B6CBAF1 mixtures. Correlation coefficients between the percentage of hemoglobin of one donor type and the ratio of cells in the mixture of that type ranged from 0.78 to 0.98 in single experiments, and were 0.68 and 0.75 using data pooled from several experiments.

show abstract

Long-term erythropoietic repopulating ability of old, young, and fetal stem cells.

Harrison¹

1983

119

View full text Add to dashboard Cite

It is possible that erythropoietic stem cells do not age. This would mean that stem cells from old donors can function as well as those from young or fetal donors. The competitive repopulation assay has been used to test long-term stem cell function by directly comparing how well competing stem cells repopulate a recipient and produce differentiated cell types. C57BL/6J (B6) mice were used as donors, while recipients and competitors were WBB6F1 hybrids with genetically distinguishable hemoglobin. Lethally irradiated young WBB6F1 recipients were given a mixture of 2.5 X 10(6) cells from B6 old marrow, young marrow, or fetal liver donors; each recipient also received a standard dose of 1 X 10(6) marrow cells from a pool of young WBB6F1 competitors. Surprisingly, the old marrow cells competed the best in repopulating the recipients. This pattern was maintained even after recovery from sublethal irradiation, a treatment that severely stresses stem cells. This stress was demonstrated when sublethal irradiation caused a 20-fold decline in repopulating ability measured using hemoglobin markers, and a 3- to 7-fold decline using chromosome markers. Stem cells from old marrow competed better than young or fetal cells in similar experiments using immunologically crippled recipients or using unirradiated W/Wv recipients that are immunologically intact. In both types of recipients, the advantage of old marrow cells again persisted after recovery from sublethal irradiation. Other genotypes were tested, and marrow cells from old B6CBAF1 donors competed better than those from young donors of that genotype. However, marrow cells from young CBA donors completed better than those from old CBA donors. These results support the hypothesis that stem cells do not age, and suggest that regulatory changes with age promote rapid stem cell repopulation in B6 and B6CBAF1 mice, but inhibit it in CBA mice.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

hi@scite.ai

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

David E. Harrison

Loss of proliferative capacity in immunohemopoietic stem cells caused by serial transplantation rather than aging.

The mouse as a model for understanding chronic diseases of aging: the histopathologic basis of aging in inbred mice

Changes in the expression of splicing factor transcripts and variations in alternative splicing are associated with lifespan in mice and humans

Competitive repopulation: a new assay for long-term stem cell functional capacity

Long-term erythropoietic repopulating ability of old, young, and fetal stem cells.

Contact Info

Product

Resources

About