Programmed ageing: decline of stem cell renewal, immunosenescence, and Alzheimer's disease

ABSTRACT The characteristic maximum lifespan varies enormously across animal species from a few hours to hundreds of years. This argues that maximum lifespan, and the ageing process that itself dictates lifespan, are to a large extent genetically determined. Although controversial, this is supported...

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Veröffentlicht in:	Biological reviews of the Cambridge Philosophical Society 2023-08, Vol.98 (4), p.1424-1458
Hauptverfasser:	Lathe, Richard, St. Clair, David
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Sprache:	eng
Schlagworte:	Age Aged ageing Aging Alzheimer Disease - genetics Alzheimer's disease Animal species Animals antimicrobial Antimicrobial peptides Bone marrow Brain Cell proliferation Cell Self Renewal Circadian rhythms clock DNA methylation FGF Fibroblast growth factors Gene expression Genomic analysis Geriatrics Germfree Growth factors Health risks hippocampus Hormones Humans hypothalamus Immune system immunity Immunosenescence Immunosenescence - physiology infection Infections Insulin KLOTHO Klotho protein Life span Mammals Mice Microorganisms Neurodegenerative diseases Parabiosis progeria Senescence stem cell Stem cells Steroid hormones
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description	ABSTRACT The characteristic maximum lifespan varies enormously across animal species from a few hours to hundreds of years. This argues that maximum lifespan, and the ageing process that itself dictates lifespan, are to a large extent genetically determined. Although controversial, this is supported by firm evidence that semelparous species display evolutionarily programmed ageing in response to reproductive and environmental cues. Parabiosis experiments reveal that ageing is orchestrated systemically through the circulation, accompanied by programmed changes in hormone levels across a lifetime. This implies that, like the circadian and circannual clocks, there is a master ‘clock of age’ (circavital clock) located in the limbic brain of mammals that modulates systemic changes in growth factor and hormone secretion over the lifespan, as well as systemic alterations in gene expression as revealed by genomic methylation analysis. Studies on accelerated ageing in mice, as well as human longevity genes, converge on evolutionarily conserved fibroblast growth factors (FGFs) and their receptors, including KLOTHO, as well as insulin‐like growth factors (IGFs) and steroid hormones, as key players mediating the systemic effects of ageing. Age‐related changes in these and multiple other factors are inferred to cause a progressive decline in tissue maintenance through failure of stem cell replenishment. This most severely affects the immune system, which requires constant renewal from bone marrow stem cells. Age‐related immune decline increases risk of infection whereas lifespan can be extended in germfree animals. This and other evidence suggests that infection is the major cause of death in higher organisms. Immune decline is also associated with age‐related diseases. Taking the example of Alzheimer's disease (AD), we assess the evidence that AD is caused by immunosenescence and infection. The signature protein of AD brain, Aβ, is now known to be an antimicrobial peptide, and Aβ deposits in AD brain may be a response to infection rather than a cause of disease. Because some cognitively normal elderly individuals show extensive neuropathology, we argue that the location of the pathology is crucial – specifically, lesions to limbic brain are likely to accentuate immunosenescence, and could thus underlie a vicious cycle of accelerated immune decline and microbial proliferation that culminates in AD. This general model may extend to other age‐related diseases, and we pro
doi_str_mv	10.1111/brv.12959
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Studies on accelerated ageing in mice, as well as human longevity genes, converge on evolutionarily conserved fibroblast growth factors (FGFs) and their receptors, including KLOTHO, as well as insulin‐like growth factors (IGFs) and steroid hormones, as key players mediating the systemic effects of ageing. Age‐related changes in these and multiple other factors are inferred to cause a progressive decline in tissue maintenance through failure of stem cell replenishment. This most severely affects the immune system, which requires constant renewal from bone marrow stem cells. Age‐related immune decline increases risk of infection whereas lifespan can be extended in germfree animals. This and other evidence suggests that infection is the major cause of death in higher organisms. Immune decline is also associated with age‐related diseases. Taking the example of Alzheimer's disease (AD), we assess the evidence that AD is caused by immunosenescence and infection. The signature protein of AD brain, Aβ, is now known to be an antimicrobial peptide, and Aβ deposits in AD brain may be a response to infection rather than a cause of disease. Because some cognitively normal elderly individuals show extensive neuropathology, we argue that the location of the pathology is crucial – specifically, lesions to limbic brain are likely to accentuate immunosenescence, and could thus underlie a vicious cycle of accelerated immune decline and microbial proliferation that culminates in AD. 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This argues that maximum lifespan, and the ageing process that itself dictates lifespan, are to a large extent genetically determined. Although controversial, this is supported by firm evidence that semelparous species display evolutionarily programmed ageing in response to reproductive and environmental cues. Parabiosis experiments reveal that ageing is orchestrated systemically through the circulation, accompanied by programmed changes in hormone levels across a lifetime. This implies that, like the circadian and circannual clocks, there is a master ‘clock of age’ (circavital clock) located in the limbic brain of mammals that modulates systemic changes in growth factor and hormone secretion over the lifespan, as well as systemic alterations in gene expression as revealed by genomic methylation analysis. Studies on accelerated ageing in mice, as well as human longevity genes, converge on evolutionarily conserved fibroblast growth factors (FGFs) and their receptors, including KLOTHO, as well as insulin‐like growth factors (IGFs) and steroid hormones, as key players mediating the systemic effects of ageing. Age‐related changes in these and multiple other factors are inferred to cause a progressive decline in tissue maintenance through failure of stem cell replenishment. This most severely affects the immune system, which requires constant renewal from bone marrow stem cells. Age‐related immune decline increases risk of infection whereas lifespan can be extended in germfree animals. This and other evidence suggests that infection is the major cause of death in higher organisms. Immune decline is also associated with age‐related diseases. Taking the example of Alzheimer's disease (AD), we assess the evidence that AD is caused by immunosenescence and infection. The signature protein of AD brain, Aβ, is now known to be an antimicrobial peptide, and Aβ deposits in AD brain may be a response to infection rather than a cause of disease. Because some cognitively normal elderly individuals show extensive neuropathology, we argue that the location of the pathology is crucial – specifically, lesions to limbic brain are likely to accentuate immunosenescence, and could thus underlie a vicious cycle of accelerated immune decline and microbial proliferation that culminates in AD. 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St. Clair, David</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c3889-67cd937ccb3651f0620b15c0d8e7b6fe323b29b398c8c0360bbf203e0a56e1ac3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2023</creationdate><topic>Age</topic><topic>Aged</topic><topic>ageing</topic><topic>Aging</topic><topic>Alzheimer Disease - genetics</topic><topic>Alzheimer's disease</topic><topic>Animal species</topic><topic>Animals</topic><topic>antimicrobial</topic><topic>Antimicrobial peptides</topic><topic>Bone marrow</topic><topic>Brain</topic><topic>Cell proliferation</topic><topic>Cell Self Renewal</topic><topic>Circadian rhythms</topic><topic>clock</topic><topic>DNA methylation</topic><topic>FGF</topic><topic>Fibroblast growth factors</topic><topic>Gene expression</topic><topic>Genomic analysis</topic><topic>Geriatrics</topic><topic>Germfree</topic><topic>Growth factors</topic><topic>Health risks</topic><topic>hippocampus</topic><topic>Hormones</topic><topic>Humans</topic><topic>hypothalamus</topic><topic>Immune system</topic><topic>immunity</topic><topic>Immunosenescence</topic><topic>Immunosenescence - physiology</topic><topic>infection</topic><topic>Infections</topic><topic>Insulin</topic><topic>KLOTHO</topic><topic>Klotho protein</topic><topic>Life span</topic><topic>Mammals</topic><topic>Mice</topic><topic>Microorganisms</topic><topic>Neurodegenerative diseases</topic><topic>Parabiosis</topic><topic>progeria</topic><topic>Senescence</topic><topic>stem cell</topic><topic>Stem cells</topic><topic>Steroid hormones</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Lathe, Richard</creatorcontrib><creatorcontrib>St. Clair, David</creatorcontrib><collection>Wiley-Blackwell Open Access Titles</collection><collection>Wiley Free Content</collection><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Animal Behavior Abstracts</collection><collection>Ecology Abstracts</collection><collection>Entomology Abstracts (Full archive)</collection><collection>Environmental Sciences and Pollution Management</collection><collection>MEDLINE - Academic</collection><jtitle>Biological reviews of the Cambridge Philosophical Society</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Lathe, Richard</au><au>St. Clair, David</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Programmed ageing: decline of stem cell renewal, immunosenescence, and Alzheimer's disease</atitle><jtitle>Biological reviews of the Cambridge Philosophical Society</jtitle><addtitle>Biol Rev Camb Philos Soc</addtitle><date>2023-08</date><risdate>2023</risdate><volume>98</volume><issue>4</issue><spage>1424</spage><epage>1458</epage><pages>1424-1458</pages><issn>1464-7931</issn><issn>1469-185X</issn><eissn>1469-185X</eissn><abstract>ABSTRACT The characteristic maximum lifespan varies enormously across animal species from a few hours to hundreds of years. This argues that maximum lifespan, and the ageing process that itself dictates lifespan, are to a large extent genetically determined. Although controversial, this is supported by firm evidence that semelparous species display evolutionarily programmed ageing in response to reproductive and environmental cues. Parabiosis experiments reveal that ageing is orchestrated systemically through the circulation, accompanied by programmed changes in hormone levels across a lifetime. This implies that, like the circadian and circannual clocks, there is a master ‘clock of age’ (circavital clock) located in the limbic brain of mammals that modulates systemic changes in growth factor and hormone secretion over the lifespan, as well as systemic alterations in gene expression as revealed by genomic methylation analysis. Studies on accelerated ageing in mice, as well as human longevity genes, converge on evolutionarily conserved fibroblast growth factors (FGFs) and their receptors, including KLOTHO, as well as insulin‐like growth factors (IGFs) and steroid hormones, as key players mediating the systemic effects of ageing. Age‐related changes in these and multiple other factors are inferred to cause a progressive decline in tissue maintenance through failure of stem cell replenishment. This most severely affects the immune system, which requires constant renewal from bone marrow stem cells. Age‐related immune decline increases risk of infection whereas lifespan can be extended in germfree animals. This and other evidence suggests that infection is the major cause of death in higher organisms. Immune decline is also associated with age‐related diseases. Taking the example of Alzheimer's disease (AD), we assess the evidence that AD is caused by immunosenescence and infection. The signature protein of AD brain, Aβ, is now known to be an antimicrobial peptide, and Aβ deposits in AD brain may be a response to infection rather than a cause of disease. Because some cognitively normal elderly individuals show extensive neuropathology, we argue that the location of the pathology is crucial – specifically, lesions to limbic brain are likely to accentuate immunosenescence, and could thus underlie a vicious cycle of accelerated immune decline and microbial proliferation that culminates in AD. This general model may extend to other age‐related diseases, and we propose a general paradigm of organismal senescence in which declining stem cell proliferation leads to programmed immunosenescence and mortality.</abstract><cop>Oxford, UK</cop><pub>Blackwell Publishing Ltd</pub><pmid>37068798</pmid><doi>10.1111/brv.12959</doi><tpages>35</tpages><orcidid>https://orcid.org/0000-0001-9698-9834</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Age Aged ageing Aging Alzheimer Disease - genetics Alzheimer's disease Animal species Animals antimicrobial Antimicrobial peptides Bone marrow Brain Cell proliferation Cell Self Renewal Circadian rhythms clock DNA methylation FGF Fibroblast growth factors Gene expression Genomic analysis Geriatrics Germfree Growth factors Health risks hippocampus Hormones Humans hypothalamus Immune system immunity Immunosenescence Immunosenescence - physiology infection Infections Insulin KLOTHO Klotho protein Life span Mammals Mice Microorganisms Neurodegenerative diseases Parabiosis progeria Senescence stem cell Stem cells Steroid hormones
title	Programmed ageing: decline of stem cell renewal, immunosenescence, and Alzheimer's disease
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