SUMMARY There are numerous hallmarks of aging in mammals, but no unifying cause has been identified. In budding yeast, aging is associated with a loss of epigenetic information that occurs in response to genome instability, particularly DNA double-strand breaks (DSBs). Mammals also undergo predictable epigenetic changes with age, including alterations to DNA methylation patterns that serve as epigenetic “age” clocks, but what drives these changes is not known. Using a transgenic mouse system called “ICE” (for inducible c hanges to the e pigenome), we show that a tissue’s response to non-mutagenic DSBs reorganizes the epigenome and accelerates physiological, cognitive, and molecular changes normally seen in older mice, including advancement of the epigenetic clock. These findings implicate DSB-induced epigenetic drift as a conserved cause of aging from yeast to mammals. One Sentence Summary DNA breaks induce epigenomic changes that accelerate the aging clock in mammals
The goal of this study was to map mouse quantitative trait loci (QTL) that influence the development of murine age-related cataract and synechia, by using a genetically heterogeneous mouse population bred by a four-way cross.The test population consisted initially of 510 mice bred as the progeny of (BALB/cJ x C57BL/6J)F1 females and (C3H/HeJ x DBA/2J)F1 males. Each mouse was examined by slit lamp at 18 and 24 months of age and scored for degree of lens opacity on a 0 to 4+ scale, and the presence or absence of additional anterior chamber disease was noted. The presence of synechia was confirmed by histology. Each mouse was genotyped at 96 maternal and 92 paternal loci, and the significance of association between genotype and eye lesions was tested by permutation analysis.Significant QTL with effects on lens opacity at 24 months were detected on mouse chromosomes 4, 11, and 12. The effects were additive, and severe cataracts were seen in 80% of the mice with all three high-risk alleles, but in only 28% of the mice with all three low-risk alleles. The risk of synechia was associated with paternal chromosome 1 and on both the maternal and paternally inherited chromosome 4. Mice with all three high-risk alleles had a 68% risk of synechia, compared with a 0% incidence in mice with all three counteralleles.A four-way cross population of mice can be used to map polymorphic loci that influence cataract severity and synechia prevalence in late life. The results provide a first step toward identification of the individual genes involved and may help to guide the search for homologous human genes.
Selective lodgement or homing of transplanted hemopoietic stem cells in the recipient's bone marrow (BM) is a critical step in the establishment of long-term hemopoiesis after BM transplantation. However, despite its biologic and clinical significance, little is understood about the process of homing. In the present study, we have concentrated on the initial stages of homing and explored the functional role in vivo of some of the adhesion pathways previously found to mediate in vitro adhesion of hemopoietic cells to cultured BM stroma. We have found that homing of murine hemopoietic progenitors of the BM of lethally irradiated recipients at 3 h after transplant was significantly reduced after pretreatment of the donor cells with an antibody to the integrin very late antigen 4 (VLA4). This inhibition of marrow homing was accompanied by an increase in hemopoietic progenitors circulating in the blood and an increased uptake of these progenitors by the spleen. Similar results were obtained by treatment of the recipients with an antibody to vascular cell adhesion molecule 1 (VCAM-1), a ligand for VLA4. Furthermore, we showed that administration of the same antibodies (anti-VLA4 or anti-VCAM-1) to normal animals causes mobilization of hemopoietic progenitors into blood. These data suggest that hemopoietic cell lodgement in the BM is a regulatable process and can be influenced by VLA4/VCAM-1 adhesion pathway. Although additional molecular pathways are not excluded and may be likely, our data establish VCAM-1 as a BM endothelial addressin, analogous to the role that mucosal addressin cell adhesion molecule (MAdCAM) plays in lymphocyte homing. Whether splenic uptake of hemopoietic progenitors is passive or controlled through different mechanisms remains to be clarified. In addition, we provide experimental evidence that homing and mobilization are related phenomena involving, at least partly, similar molecular pathways.
1. Introduction and end of life pathologies Norman Wolf and Steven Austad 2. Animal size, metabolic rate, and survival, among and within species Steven Austad 3. Hormonal Influences on Aging and Lifespan Adam Spong and Andrzej Bartke 4. Exploring mechanisms of aging retardation by caloric restriction: studies in model organisms and mammals. Rozalyn Anderson, Ricki Colman & Richard Weindruch 5. Cell Replication Rates In Vivo and In Vitro and Wound Healing as Affected by Animal Age, Diet, and Species. Norman Wolf 6. The Comparative Biology of Sirtuin Function in Longevity Daniel L. Smith, Jr., and Jeffrey S. Smith 7. The Role of TOR signaling in Aging. Matt Kaeberlein and Lara S. Shamieh 8. Mitochondria, Oxidative Damage and Longevity: What Can Comparative Biology Teach Us? Yun Shi, Rochelle Buffenstein and Holly Van Remmen 9. Comparative genomics of aging. Jan Vijg, Ana Maria Garcia, Brent Calder and Martijn Dolle 10. Changes in lysosomes and their autophagic function in aging. The comparative biology of lysosomal function. Samantha J. Orenstein and Ana Maria Cuervo 11. Telomeres and telomerase. Inter-species comparisons of genetic, mechanistic and functional aging changes. N.M.V. Gomes, J.W. Shay, W.E. Wright, 12. Cardiac Aging. Dao-Fu Dai, Robert J. Wessells, Rolf Bodmer, Peter S. Rabinovitch 13. Comparative Skeletal Muscle Aging. David J. Marcinek, Jonathan Wanagat, Jason J. Villarin 14. Aging of the Nervous System. Catherine A. Wolkow, Sige Zou and Mark P. Mattson 15. Aging of the Immune System across Different Species. Janko Nikolich-Zugich and Luka Cicin-Sain
To determine the differences between species in the retention of lens fiber cell nuclei and nuclear fragments in the aging lens cortex and the relationship of nuclear retention to lens opacity. For this purpose old human, monkey, dog, and rat lenses were compared to those of three strains of mouse. We also investigated possible mechanisms leading to nuclear retention.Fixed specimens of the species referred to above were obtained from immediate on site sacrifice of mice and rats, or from recently fixed lenses of other species, dogs, monkeys, and humans, obtained from collaborators. The retention of undegraded nuclei and nuclear fragments was graded 1-4 from histologic observation. All species lenses were examined microscopically in fixed sections stained with hematoxylin and eosin (H&E) or 4',6-diamidino-2-phenylindole (DAPI). Slit lamp observations were made only on the mice and rats before sacrifice and lens fixation. Values of 0 to 4 (clear lens to cataract) were given to degree of opacity. MRNA content in young versus old C57BL/6 mouse lenses was determined by quantitative PCR (qPCR) for DNase II-like acid DNase (DLAD) and other proteins. DLAD protein was determined by immunofluorescence of fixed eye sections.In old C57BL/6 and DBA mice and, to a lesser degree, in old CBA mice and old Brown Norway (BN) rats lenses were seen to contain a greatly expanded pool of unresolved whole nuclei or fragments of nuclei in differentiating lens fiber cells. This generally correlated with increased slit lamp opacities in these mice. Most old dog lenses also had an increase in retained cortical nuclei, as did a few old humans. However, a second rat strain, BNF1, in which opacity was quite high had no increase in retained nuclei with age nor did any of the old monkeys, indicating that retained nuclei could not be a cause of opacity in these animals. The nuclei and nuclear fragments were located at all levels in the outer cortex extending inward from the lens equator and were observable by the DAPI. These nuclei and nuclear fragments were seen from 12 months onward in all C57BL/6 and DBA/2 mice and to a lesser degree in the CBA, increasing in number and in space occupancy with increasing age. Preliminary results suggest that retention of nuclei in the C57BL/6 mouse is correlated with an age-related loss of DLAD from old lenses.A very marked apparently light refractive condition caused by retained cortical nuclei and nuclear fragments is present in the lens cortices, increasing with age in the three strains of mice examined and in one of two strains of rats (BN). This condition was also seen in some old dogs and a few old humans. It may be caused by an age-related loss of DLAD, which is essential for nuclear DNA degradation in the lens. However, this condition does not develop in old BNF1 rats, or old monkeys and is only seen sporadically in humans. Thus, it can not be a universal cause for age related lens opacity or cataract presence, although it develops concurrently with opacity in mice. This phenomenon should be considered when using the old mouse as a model for human age-related cataract.
Abstract Spleen colonies produced by sublethally irradiated mouse bone marrow cells were compared to those produced by unirradiated marrow cells in lethally irradiated mice. Sublethally irradiated marrow cells gave rise to many fewer spleen colonies. At seven days of colony age, the ratio of erythroid colonies to granuloid colonies was lower (< 1) than for colonies formed by unirradiated marrow (2 to 3 or more). Delay of harvest of colonies to day 10 or 12 resulted in 6 to 11 fold increase in the ratio of erythroid to granuloid colonies due largely to the belated appearance of erythroid colonies.
