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Immunosenescence

Author: Prof. Dr. med. Peter Altmeyer

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Last updated on: 01.04.2022

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Synonym(s)

Immunosensitivity

Definition
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The term "immunosenescence" (lat. from immunis "free, 'pure" and senescere = "to grow old") describes the slow aging of the immune system in the course of life. Immunosenescence is thus on the one hand a "physiological" side effect of chronological aging. It affects both the innate and the acquired immune system (Gruver Al et al. 2007). On the other hand, it leads to a limitation of the functionality of the humoral immune response (Pera A et al. 2015) and is one of the causes for an increased susceptibility to infections in older people as well as for the increase in tumours (Pawelec G 2017) - and autoimmune diseases.

General information
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The large number of infectious or inflammatory events ("multiple hits") in the course of life cause inflammatory stress ("inflammatory/pathogenic burden"). This contributes significantly to the increase in inflammatory parameters and further to the increase in diseases with pro-inflammatory pathogenesis such as atherosclerosis, arthritis, Alzheimer's disease and others (Chalan P et al. 2015). Immunosenescence is thus partly responsible for the increase in morbidity and mortality in old age (inflammatory ageing; inflammation).

Clinical picture
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The following changes characterize the (physiological) changes of the immune system in advanced age:

Involution of the thymus: This begins with sexual maturity and is completed between the ages of 40 and 50. After this time, the maturation of T-lymphocytes is no longer possible; as a result, the immune system is dependent on the pool of T-lymphocytes formed up to this point. However, the thymus shows residual activity throughout life, recognizable by CD31-labeled lymphocytes. Only CD4-naive lymphocytes that have freshly left the thymus carry the CD31 marker on their surface (thymic reserve).

Age-related leukopenia: In adolescence, the organism has a high proportion of naive -T lymphocytes, a low proportion of memory cells and hardly any effector cells. In old age, the effector cells dominate.

Involution of lymph nodes (age-related decrease in germinal centers, lipomatous atrophy) (Luscieti P et al. 1980); decrease in the number of B cells. Antibody production decreases (Listì F et al 2006). Individual B-cell clones proliferate and produce AK specificity (incidence of monoclonal gammopathies of unclear significance = MGUS increases; it is 20-25% in 70-year-olds); autoantibodies (and autoimmune diseases) increase.

Reduction in the lifespan of activated neutrophil granulocytes (decreased apoptosis protection).

Increase in the number of cytotoxic NK cells; their cell function decreases. Increase in regulatory T cells (Treg). Inhibition of Th1 immune response (immune brake).

Macrophages: Reduced chemotaxis and phagocytosis - Inhibited response to growth factors - Reduced nitrite oxide/H2O2 production.

Increase in inflammatory cytokines (inflammaging); decrease in release of interleukin-2 and interleukin-4

Fever and leukocytosis are less frequentand less pronounced ("the older, the colder"). Cause: Altered production of cytokine spectrum -decreased temperature control of hypothalamic receptors.

Increase of tumor and autoimmune diseases; general increase of morbidity and mortality in old age (see also inflammatory aging).

Increased susceptibility to infections, often with oligosymptomatic and severe, even septic courses (Martín S et al 2017):

  • Lung: pneumonia (aspiration pneumonia: anaerobes! early tachypnea as the only symptom); urinary tract infections (often nonspecific symptoms); tuberculosis (reactivation).
  • Intestine: gastric anacidity, increased enteritis rate (C. difficile colitis); diverticulitis; appendicitis
  • Heart: endocarditis (nonspecific symptoms such as weakness, weight loss, thrombosis, joint pain, preexisting heart murmurs)
  • CNS: herpes zoster; meningitis/meningoencephalitis -listeria-: confusion, clouding of consciousness, absence of fever/meningismus).
  • Urinary tract: decreased diuresis, increased risk of urinary tract infections.

Immunosenescence further leads to attenuation of vaccine response (Gruver Al et al 2007). As a result, antibody formation is attenuated after vaccination. This has led to the development of new, more immunogenic vaccines. This is achieved, for example, in influenza vaccination by adding an adjuvant (e.g. MF59) or else by increasing the antigen content fourfold. In order to minimize the clinically relevant negative effects of immune senescence during vaccination, the concept of lifelong vaccination seems to be recommendable.

Literature
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  1. Chalan P et al (2015) Rheumatoid Arthritis, Immunosenescence and the Hallmarks of Aging. Curr Aging Sci 8:131-146.
  2. Giunta F et al (2008) Inflammaging as a prodrome to Alzheimer's disease. In: Journal of neuroinflammation. Volume 5 S 51
  3. Gruver Al et al (2007) Immunosenescence of ageing. J Pathol 211: 144-156.
  4. Harrison DE et al (1997) Relative to adult marrow, fetal liver repopulates almost five times more effectively long-term than short-term. Exp Hematol 25:293-297.
  5. Lamberts SW et al. (1997) The endocrinology of aging. Science 278:419-424.
  6. Larbi A et al (2008) Aging of the immune system as a prognostic factor for human longevity. Physiology (Bethesda) 23: 64-74.
  7. Liang Y et al. (2005) Effects of aging on the homing and engraftment of murine hematopoietic stem and progenitor cells. Blood 106:1479-1487.
  8. Listì F et al. (2006) A study of serum immunoglobulin levels in elderly persons that provides new insights into B cell immunosenescence. Ann N Y Acad Sci 1089:487-495.
  9. Luscieti P et al (1980) Human lymph node morphology as a function of age and site. J Clin Pathol 33:454-461.
  10. Martín S et al (2017) Sepsis and Immunosenescence in the Elderly Patient: A Review. Front Med (Lausanne) 4:20.
  11. Mauch P et al (1982) Decline in bone marrow proliferative capacity as a function of age. Blood. 60: 245–252.
  12. Pawelec G (2017) Immunosenescence and cancer.biogerontology 18:717-721. https://www.ncbi.nlm.nih.gov/pubmed/28220304
  13. Pera A et al (2015) Immunosenescence: Implications for response to infection and vaccination in older people. Maturity 82:50-55.
  14. Rebel VI et al (1996) The repopulation potential of fetal liver hematopoietic stem cells in mice exceeds that of their liver adult bone marrow counterparts. Blood 87:3500-3507.
  15. Sergio G (2008): Exploring the complex relations between inflammation and aging (inflamm-aging): anti-inflamm-aging remodelling of inflamm- aging, from robustness to frailty. Inflammation Research 57: 558-563.
  16. Wang CQ et al (1995) Effect of age on marrow macrophage number and function. Aging (Milan) 7:379-384.
  17. Yuan R et al. (2005) Genetic regulation of hematopoietic stem cell exhaustion during development and growth. Exp Hematol 33: 243-250.

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Last updated on: 01.04.2022