Hostname: page-component-76fb5796d-45l2p Total loading time: 0 Render date: 2024-04-27T11:24:33.678Z Has data issue: false hasContentIssue false
  • English
  • Français

Nutrition and immunity in the elderly

Published online by Cambridge University Press:  28 February 2007

Bruno Lesourd  and
Lynda Mazari
Bruno Lesourd*
Affiliation:
Unité de Médecine Nutritionnelle Gériatrique, Hôpital Charles Foix, 7 Avenue de la République, 94200 Ivry sur Seine, France
Lynda Mazari
Affiliation:
Unité de Médecine Nutritionnelle Gériatrique, Hôpital Charles Foix, 7 Avenue de la République, 94200 Ivry sur Seine, France
*
*Corresponding Author: Professor D. Demeyer, fax +32 9 264 9099, email Daniel.Demeyer@mug.ac.uk
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Immune function declines with age, leading to increased infection and cancer rates in aged individuals. In fact, recent progress in the study of immune ageing has introduced the idea that rather than a general decline in the functions of the immune system with age, immune ageing is mainly characterized by a progressive appearance of immune dysregulation throughout life. Changes appear earlier in life for cell-mediated immunity than for humoral immunity. Thus, agerelated modifications in cell-mediated immunity, i.e. changes in naive: memory T-cells, mature: immature T-cells, T-helper 1: T-helper 2 cells are more important in the elderly than changes in humoral immunity, i.e. CD5: CD5+ cells or length of antibody responses. Such evolution of the immune system has been linked to declining thymus function and to accumulative antigenic influence over the lifespan. In contrast, innate immunity (macrophage functions) is preserved or even increased during the ageing process. This finding shows that the ‘primitive’ immune system is less affected by the ageing process than the sophisticated specific immune system. The present review focuses on innate and cell-mediated immune changes with ageing. It provides evidence that primary changes (intrinsic modifications in the immune system) and secondary changes (resulting from environmental influences during the lifespan) exert different influences on the immune system. Primary changes, occurring in healthy individuals, seem less important nowadays than they were considered to be previously. For example, interleukin 2 secretion in some very healthy aged individuals is comparable with that in younger adults. Primary immune changes may not explain the increased incidence and severity of infections observed in the elderly population. Secondary immunological changes are far more frequent and are certainly responsible for most of the immune modifications observed in the elderly population. Environmental factors leading to secondary immune dysfunctions include not only antigenic influence, which is a reflection of diseases experienced over the lifespan, but also many other factors such as drug intake, physical activity and diet; factors for which important changes occur in the elderly population. Nutritional factors play a major role in the immune responses of aged individuals and the present review shows that nutritional influences on immune responses are of great consequence in aged individuals, even in the very healthy elderly.

Keywords

InfectionAgeingImmune systemNutritional status
Type
Symposium on ’Nutrition, infection and immunity‘
Information
Proceedings of the Nutrition Society , Volume 58 , Issue 3 , August 1999 , pp. 685 - 695
Copyright
Copyright © The Nutrition Society 1999

References

Abo, T (1992) Extrathymic differentiation of T lymphocytes and its biological function. Biology in Medical Research 13, 139.Google Scholar
Alès-Martinez, JE, Alvarez-Mon, M, Merino, F, Bonilla, F, Martinez, C, Durantez, A & De La Hera, A (1988) Decreased TcR-CD3-T cell numbers in healthy aged humans. Evidence that T cell defects are masked by a reciprocal increase of TcR-CD3- CD2+ natural killer cells. European Journal of Immunology 18, 18271830.CrossRefGoogle Scholar
Amorin-Cruz, JA, Moreiras, O & Brzozowska, A (1996) Longitudinal changes in the intakes of vitamins and minerals of elderly Europeans. European Journal of Clinical Nutrition 50, Suppl. 2, S77S85.Google Scholar
Arreaza, EE, Gibbons, JJ, Sisking, GW & Weksler, ME (1993) Lower antibody response to tetanus toxoid associated with higher auto-anti-idiotype antibody in old compared with young humans. Clinical and Experimental Immunology 92, 169176.Google Scholar
Barrat, F, Lesourd, BM, Louise, A, Boulouis, HJ, Vincent-Naulleau, S, Thibault, D, Neway, T, Sanaa, M & Pilet, Ch (1997) Surface antigens expression in spleen cells of C57 Bl/6 mice during aging: influence of sex and breeding. Clinical and Experimental Immunology 107, 593600.Google Scholar
Batory, G, Janeso, A, Puskas, E, Redei, A & Lengyei, E (1984) Antibody and immunoglobulin levels in aged humans. Archives of Gerontology and Geriatrics 3, 175188.CrossRefGoogle ScholarPubMed
Ben-Yehuda, A, Szabo, P & Weksler, ME (1994) Age associated changes in the B-cell: effect of age on RAG-1 gene expression in murine bone marrow. Immunology Letters 40, 287290.CrossRefGoogle ScholarPubMed
Bogden, JD, Oleske, JM, Lavenhar, MA, Munves, EM, Kemp, FW, Bruening, KS, Holding, KJ, Denny, TN, Guarino, MA & Holland, BK (1990) Effects of one year of supplementation with zinc and other micronutrients on cellular immunity in the elderly. Journal of the American College of Nutrition 9, 214225.CrossRefGoogle ScholarPubMed
Bogden, JD, Bendich, A, Kemp, FW, Bruening, KS, Shurrick, JH, Denny, T, Baker, H & Louria, DB (1994) Daily micronutrient supplements enhanced delayed-hypersensitivity skin test responses in older people. American Journal of Clinical Nutrition 60, 437447.Google Scholar
Boukaïba, N, Flament, C, Acher, S, Chappuis, Ph, Pian, A, Fusselier, M, Dardenne, M & Lemonnier, D (1993) A physiological amount of zinc supplementation: effects on nutritional, lipid, and thymic status in an elderly population. American Journal of Clinical Nutrition 57, 566572.Google Scholar
Bruley-Roseet, M & Payelle, B (1987) Deficient tumor specific immunity in old mice: in vivo mediation by suppressor cells, and correction of the defect interleukin 2 by supplementation in vitro but not in vivo. Journal of Immunology 17, 307312.Google Scholar
Cakman, I, Rohwer, J, Schûtz, RM, Kirchner, H & Rink, L (1996) Dysregulation betwen TH1 and TH2 cell sub-populations in the elderly. Mechanisms of Ageing and Development 87, 197209.CrossRefGoogle Scholar
Cannon, JG, Meydani, SN, Fielding, RA, Meydani, M, Fiatarone, MA, Farhangmehr, M, Orencole, SF, Blumberg, JB & Ewans, WJ (1991) The acute phase response in exercise. II. Associations between vitamin E, cytokines and muscle proteolysis. American Journal of Physiology 260, R1235R1240.Google Scholar
Cederholm, T, Wretling, B, Hellstrom, K, Andersson, B, Engstrom, L, Brismark, K, Scheynius, A, Faslid, J & Palmblad, J (1997) Enhanced generation of interleukins 1β and 6 may contribute to the cachexia of chronic disease. American Journal of Clinical Nutrition 65, 876882.CrossRefGoogle Scholar
Chandra, RK (1989) Nutrition, regulation of immunity and risk of infection on old age. Immunology 67, 141147.Google Scholar
Chandra, RK (1992 a) Effect of vitamin and trace-element supplementation on immune responses and infection in elderly subjects. Lancet 340, 11241127.CrossRefGoogle ScholarPubMed
Chandra, RK (editor) (1992 b) Nutrition and immunobiology: experience of an old traveller and recent observations. In Nutrition and Immunology, pp. 943. St John’s, Nfld.: ARTS Biomedical.Google Scholar
Chandra, RK (1994) Nutritional regulation of immune function at the extremes of life: in infants and in the elderly. In Malnutrition Determinants and Consequences, pp. 245251 [White, P, editor]. New York: Alan R Liss.Google Scholar
Chandra, RK & Sudhakaran, L (1990) Regulation of immune responses by vitamin B6. Annals of New York Academy of Sciences 585, 404423.Google Scholar
Chen, WF, Liu, SL, Gao, XM & Pang, XI (1987) The capacity of lymphokine production by peripheral blood lymphocytes from aged humans. Immunology Investigation 15, 575583.Google Scholar
Cossarizza, A, Ortolani, C, Paganelli, R, Monti, D, Barbieri, D, Sansoni, P, Fagiolo, U, Forti, E, Londei, M & Franceschi, C (1992) Age-related imbalance of virgin (CD45RA+) and memory (CD45RO+) cells between CD4+ and CD8+ T lymphocytes in humans: study from newborns to centenarians. Journal of Immunology Research 4, 117126.Google Scholar
Cunningham-Rundles, S, Bockam, RS, Lin, A, Giardana, PV, Hilgartner, MW, Caldwell-Brown, D & Carter, DM (1991) Physiological and pharmacological effects of zinc on immune response. Annals of the New York Academy of Sciences 590, 113122.Google Scholar
Daynes, RA, Areanéo, BA, Ershler, WB, Maloney, C, Li, GZ & Ryu, SY (1993) Altered regulation of IL-6 production with normal aging. Journal of Immunology 150, 52195230.CrossRefGoogle ScholarPubMed
Doria, G (1988) Immunoregulation in aging. International Journal of Medicine 4, 8385.Google Scholar
Engwerda, CR, Fox, BS & Handwerger, BS (1996) Cytokine production by T lymphocytes from young and old mice. Journal of Immunology 156, 36213630.Google Scholar
Ershler, WB, Sun, WH, Binkley, N, Gravenstein, S, Volk, MJ, Kamoske, G, Kloop, RG, Roecker, EB, Daynes, RA & Weindruch, R (1993) Interleukin-6 and aging: blood levels and mononuclear cell production increase with advancing age and in vitro production modifiable by dietary restriction. Lymphokine and Cytokine Research 12, 225230.Google ScholarPubMed
Fereday, A, Gibson, NR, Cox, M, Pacy, PJ & Millward, DJ (1997) Protein requirements and ageing: metabolic demand and efficiency of utilization. British Journal of Nutrition 77, 685702.Google Scholar
Fernandes, G, Venkatramen, JT, Turturro, A, Attwood, VG & Hart, RW (1991) Effect of food restriction on lifespan and immune functions in long-lived Fischer-344 X Brown Norway F1 rats. Journal of Clinical Immunology 17, 8595.CrossRefGoogle Scholar
Fortes, C, Forastiere, F, Agabiti, N, Fano, V, Pacifici, R, Virgili, F, Piras, G, Guidi, L, Bartonoli, C, Tricerri, A, Ziccaro, P, Ebrahim, S & Perucci, CA (1993) The effects of zinc and vitamin A supplementation on immune response in an older population. Journal of the American Geriatrics Society 46, 1926.Google Scholar
Galan, P, Preziosi, P, Monget, AL, Richard, MJ, Arnaud, J, Lesourd, B, Girodon, F, Munoz, Alferez M-J, Bourgeois, C, Keller, H, Favier, A, Hercberg, S & the Geriatric Network MIN.VIT.AOX (1997) Effects of trace elements and/or vitamin supplementation on vitamin and mineral status, free radical metabolism and immunological markers in elderly long-term hospitalized subjects. International Journal of Vitamin and Nutrition Research 67, 450460.Google ScholarPubMed
Gamble, DA, Schwab, R, Weksler, ME & Szabo, P (1990) Decreased steady state c-myc mRNA in activated T cell cultures from old humans is caused by a smaller proportion of T cells that transcribe the c-myc gene. Journal of Immunology 114, 35693573.CrossRefGoogle Scholar
Garry, PJ, Goodwin, JS, Hunt, WC, Hooper, ER & Leonard, AG (1982) Nutritional status in a healthy elderly population: dietary and supplementation intakes American Journal of Clinical Nutrition 36, 319331.Google Scholar
Ghosh, J & Miller, RA (1995) Rapid tyrosine phosphorylation of Grb2 and She in T cells exposed to anti-CD3, anti-CD4, anti-CD45 stimuli: differential effects of ageing Mechanisms of Ageing and Development 80, 171187.Google Scholar
Goldberg, TH, Baker, DG & Shumacher, HR (1991) Interleukin-1 and the immunology of aging and disease. Aging, Immunology and Infectious Diseases 3, 8186.Google Scholar
Goodwin, JS (1992) Changes in lymphocyte sensitivity to prostaglandin E2, histamine, hydrocortosone, and X irradiation with age: studies in a healthy elderly population. Clinical and Experimental Immunology and Immunopathology 25, 243251.CrossRefGoogle Scholar
Goto, M & Nishioka, K (1989) Age- and sex-related changes of the lymphocyte subsets in healthy individuals: an analysis by two-dimensional flow cytometry. Journal of Gerontology 5, 242253.Google Scholar
Haller, J, Weggemans, RM, Lammi-Keefe, CJ & Ferry, M (1996) Changes in the vitamin status of elderly Europeans: plasma vitamins A, E, B-6, B-12, folic acid and carotenoids. European Journal of Clinical Nutrition 50, Suppl. 2, S32S46.Google Scholar
Harman, D (1995) Role of antioxidant nutrients in aging: overview. Age 18, 5162.Google Scholar
Hayek, GM, Mura, C, Wu, D, Beharka, AA, Han, SN, Paulson, E, Hwang, D & Meydani, SN (1997) Enhanced expression of inducible cyclooxygenase with age in murine macrophages. Journal of Immunology 159, 24452451.CrossRefGoogle ScholarPubMed
Hirokawa, K, Utsuyama, M, Kasai, M, Kurishima, C, Ishijima, S & Zeng, YX (1994) Understanding the mechanisms of the age changes of thymic function to promote T cell differentiation. Immunology Letters 40, 269277.Google Scholar
Hobbs, MV & Ernst, DN (1997) T cell differentiation and cytokine expression in late life. Developmental and Comparative Immunology 21, 464470.CrossRefGoogle ScholarPubMed
Huber, LA, Xu, QB, Jürgens, G, Böck, G, Buther, E, Gey, KF, Schronitzer, D, Traill, KN & Wick, G (1991) Correlation of lymphocyte lipid composition membrane microviscosity and mitogen response in the aged. European Journal of Immunology 21, 27612765.CrossRefGoogle ScholarPubMed
Huppert, FA, Solomou, W, O’Connor, S, Morgan, K, Sussams, P & Brayne, C (1998) Aging and lymphocyte subpopulations: whole-blood analysis of immune markers in a large population sample of healthy elderly individuals. Experimental Immunology 33, 593600.Google Scholar
James, K, Premchand, N, Skibinska, A, Skibinski, G, Nicol, M & Mason, JI (1997) IL-6, DHEA and the ageing process. Mechanisms of Ageing and Development 93, 1524.Google Scholar
Keen, CL & Gershwin, ME (1990) Zinc deficiency and immune function. Annual Review of Nutrition 10, 415431.CrossRefGoogle ScholarPubMed
Klasing, KC (1988) Nutritional aspects of leukocyte cytokines: critical review. Journal of Nutrition 11, 14361446.CrossRefGoogle Scholar
Krishnaraj, R (1997) Senescence and cytokines modulate the NK expression. Mechanisms of Ageing and Development 96, 89116.CrossRefGoogle ScholarPubMed
Kubo, M & Cinader, B (1990) Polymorphism of age-related changes in interleukin (IL) production: differential changes of T helper subpopulation, synthesizing IL-2, IL-3, and IL-4. European Journal of Immunology 24, 133136.Google Scholar
Lang, GA, Naryshkin, S, Schneider, DL, Mills, BJ & Lindeman, RD (1992) Low blood glutathionine levels in healthy aging adults. Journal of Laboratory and Clinical Medicine 120, 720725.Google Scholar
Lesourd, B (1990 a) Le vieillissement immunologique: influence de la dénutrition (Immune ageing: influence of nutrition). Annales de Biologie Clinique 48, 309318.Google Scholar
Lesourd, B (1990 b) La dénutrition protéique: principale cause de déficit immunitaire chez le sujet âgé (Protein malnutrition: the main cause of immunodeficiency in the elderly). Age and Nutrition 3, 132138.Google Scholar
Lesourd, B, (1992) Conséquences nutritionnelles des cytokines: facteur de gravité des hypercatabolismes chez le sujet âgé (Nutritional consequences of cytokine secretion: a prognosis factor of hypercatabolism in elderly). Age and Nutrition 3, 100109.Google Scholar
Lesourd, BM (1995) Protein undernutrition as the major cause of decreased immune function in the elderly: clinical and functional implications. Nutrition Reviews 53, S86S94.Google Scholar
Lesourd, B (1999) Immune response during disease and recovery in the elderly. Proceedings of the Nutrition Society 58, 8598.Google Scholar
Lesourd, B, Laisney, C, Salvatore, R, Meaume, S & Moulias, R (1994) Decreased maturation of T cell population factors on the appearance of double negative CD4-, CD8-, CD2+ cells. Archives of Gerontology and Geriatrics 4 Suppl., 139154.Google Scholar
Lesourd, BM & Mazari, L (1997) Immune responses during recovery from protein-energy malnutrition. Clinical Nutrition 16, Suppl. 1, 3746.Google Scholar
Lesourd, B, Mazari, L & Ferry, M (1998) The role of nutrition in immunity in the aged. Nutrition Reviews 56, S113S125.Google Scholar
Lesourd, B & Meaume, S (1994) Cell-mediated immunity changes in aging: relative importance of cell subpopulation switches and of nutritional factors. Immunology Letters 40, 235242.Google Scholar
Lesourd, BM, Moulias, R, Favre-Berrone, M & Rapin, CH (1992) Nutritional influences on immune responses in elderly. In Nutrition and Immunology, pp. 211223 [Chandra, RK, editor]. St John’s, NPld: ARTS Biomedical.Google Scholar
Ligthart, GJ, Corberand, JX, Fournier, C, Galanaud, P, Hijmans, W, Kennes, B, Muller-Hermelink, HK & Steinmann, GG (1984) Admission criteria for immunogerontological studies in man: the Senieur protocol. Mechanisms of Ageing and Development 28, 4755.Google Scholar
Ligthart, GJ, Van Vlokhoven, PC, Schuit, HRE & Hijmans, W (1986) The expanded null cell compartment in ageing: increase in the number of natural killer cells and changes in T-cell and NK-cells subset in human blood. Immunology 59, 353357.Google ScholarPubMed
Lipschitz, DA & Udupa, KB (1986) Influence of ageing and protein deficiency on neutrophil function. Journal of Gerontology 41, 281288.Google Scholar
Makinodan, T & Kay, MMB (1980) Age influence on the immune system. Advances in Immunology 29, 287330.Google Scholar
Mazari, L & Lesourd, B (1998) Nutritional influences on immune response in healthy aged persons. Mechanisms of Ageing and Development 104, 2540.CrossRefGoogle ScholarPubMed
Mbawuike, IN, Acuna, CL, Walz, KC, Atmar, RL, Greenberg, SB & Couch, RB (1997) Cytokines and impaired CD8+ CTL activity among elderly persons and the enhancing effect of IL-12. Mechanisms of Ageing and Development 94, 2539.Google Scholar
Meydani, SN, Barklund, MP, Lui, S, Meydani, M & Miller, RA (1990) Vitamin E supplementation enhances cell-mediated immunity in healthy elderly. American Journal of Clinical Nutrition 52, 557563.CrossRefGoogle ScholarPubMed
Meydani, SN, Meydani, M, Blumberg, JB, Lekal, S, Siber, G, Loszewski, R, Thompson, C, Pedrosa, C, Diamond, RD & Stollar, BD (1997) Vitamin E supplementation and in vivo immune responses in healthy elderly subject. Journal of the American Medical Association 277, 13801386.CrossRefGoogle Scholar
Meydani, SN, Ribaya-Mercado, JD, Russell, RB, Sahyoun, N, Morrow, FD & Gershoff, SN (1991) Vitamin B-6 deficiency impairs interleukin 2 production and lymphocyte proliferation in elderly adults American Journal of Clinical Nutrition 53, 12751280.Google Scholar
Meydani, SN, Wu, D, Santos, MS & Hayek, MG (1995) Antioxidants and immune response in aged persons: overview of the present evidence. American Journal of Clinical Nutrition 62, Suppl., 1462S1476S.Google Scholar
Miller, RA (1992) Aging and immune function. International Review of Immunology 124, 890904.Google Scholar
Miller, RA (1996) The aging immune system: primer and prospectus. Science 273, 7074.CrossRefGoogle ScholarPubMed
Moulias, R, Devillechabrolle, A, Lesourd, B, Proust, J, Marescot, MR, Doumerc, S, Favre-Berrone, M, Congy, F & Wang, A (1985) Respective roles of immune and nutritional factors in the priming of the immune responses in the elderly. Mechanisms of Ageing and Development 31, 123137.CrossRefGoogle ScholarPubMed
Moulias, R, Proust, J, Wang, A, Congy, F, Marescot, M, Devillechabrolle, A, Paris-Hamelin, A & Lesourd, B (1984) Age related increase in auto-antibodies. Lancet i, 11281129.Google Scholar
Muller, S, Chang, HC, Ward, MM, Huang, JH & Kölher, H (1986) Idiotype shifts. In Aging and the Immune Responses: Cellular and Humoral Aspects, pp. 309327 [Goidl, E, editor]. New York: Marcel Dekker.Google Scholar
Murasko, DM, Weiner, P & Kaynes, D (1987) Decline in mitogen induced proliferation of lymphocytes with increasing age. Clinical and Experimental Immunology 70, 440448.Google Scholar
Mysliwska, J, Bryl, E, Foerster, J & Mysliwski, A (1998) Increase of interleukin 6 and decrease of interleukin 2 production during the ageing process are influenced by the health status. Mechanisms of Ageing and Development 100, 313328.Google Scholar
Nafziger, J, Bessege, JP, Guillosson, JJ, Damais, C & Lesourd, B (1993) Decreased capacity of IL-1 production by monocytes of infected elderly patients. Aging, Immunology and Infectious Diseases 4, 2534.Google Scholar
Nagel, JE, Chopra, RK, Chrest, FJ, McCoy, MT, Schneider, EL, Holbrook, NJ & Adler, WH (1988) Decreased proliferation, interleukin 2 synthesis and interleukin 2 receptor expression are accompanied by decreased mRNA expression, in phytohemagglutinin-stimulated cells from elderly donors. Journal of Clinical Investigation 81, 10961102.CrossRefGoogle ScholarPubMed
Nagelkerken, L, Hertogh-Huijbregts, A, Dobber, R & Dräger, A (1991) Age-related changes in lymphokine production related to a decreased number of CD45Rbohi CD4+ T cells. European Journal of Immunology 21, 273281.CrossRefGoogle ScholarPubMed
Nakayama, KI, Nakayama, K, Negishi, I, Kuida, K, Louie, MC, Kanagawa, O, Nakauchi, H & Loh, DY (1994) Requirement for CD8 beta chain in positive selection of CD8 lineage T cells. Science 263, 11311133.CrossRefGoogle ScholarPubMed
Penn, ND, Purkins, L, Kelleher, J, Heartley, RV, Masie-Taylor, BH & Belfield, PW (1991) The effect of dietary supplementation with vitamins A, C and E on cell-mediated immune function in elderly long-stay patients: a randomized, controlled trial. Age and Aging 20, 169174.CrossRefGoogle Scholar
Perillo, NL, Neaim, F, Walford, RL & Effros, RB (1993) In vitro cellular aging in T-lymphocyte cultures: analysis of DNA content and cell size. Experimental Cell Research 207, 131135.Google Scholar
Prasad, AS, Fitzgerald, JT, Hess, JW, Kaplan, J, Pelen, F & Dardenne, M (1993) Zinc deficiency in elderly patients. Nutrition 9, 218224.Google Scholar
Proust, J, Moulias, R, Mumeron, F, Beckkhoucha, F, Bussone, M, Schmid, M & Hors, J (1982) HLA and longevity. Tissue Antigens 19, 168173.Google Scholar
Rabinowich, H, Goses, Y, Reshef, T & Klajman, A (1985) Interleukin 2 production and activity in aged humans. Mechanisms of Ageing and Development 32, 213226.Google Scholar
Rall, LC & Meydani, SN (1993) Vitamin B6 and immune competence. Nutrition Reviews 51, 217225.Google Scholar
Reibnegger, G, Hubber, LA, Jurgens, G, Schrönitzer, D, Werner, ER, Watcher, H, Wick, G & Traill, KN (1988) Approach to define ‘normal aging’ in man: immune function, serum lipids, lipoproteins and neopterin. Mechanisms of Ageing and Development 46, 6782.CrossRefGoogle ScholarPubMed
Rudd, AG & Banerjeee, DK (1989) Interleukin-1 production by human monocytes in ageing and disease. Age and Ageing 18, 4346.Google Scholar
Sanders, ME, Maggoba, MW, Sharrow, SE, Stephany, D, Springer, A, Young, HA & Shaw, S (1988) Human memory T lymphocytes express increased level of three cell adhesion molecules (LFA3, CD2, and LFA1) and three other molecules (UCHL-1, CDw29, and Pgp-1) and have enhanced IFN-γ production. Journal of Immunology 140, 14011407.Google Scholar
Shearer, GM (1997) Th1/Th2 changes in aging. Mechanisms of Ageing and Development 94, 15.Google ScholarPubMed
Sindermann, J, Kruse, A, Frercks, HJ, Schutz, RM & Kirchner, H (1993) Investigations of the lymphokine system in elderly individuals. Mechanisms of Ageing and Development 70, 149159.CrossRefGoogle ScholarPubMed
Steinmann, GG, Klaus, B & Muller-Hermelink, HK (1985) The involution of the ageing human thymic epithelium is independent of puberty. Scandinavian Journal of Immunology 22, 563575.Google Scholar
Stulning, TM, Bühler, E, Böck, G, Kirchebner, C, Schönitzer, D & Wick, G (1995) Altered switch in lipid composition during T cell blast transformation in the healthy elderly. Journal of Gerontology 50A, 383390.Google Scholar
Talbott, MC, Miller, LT & Kerkvliet, NI (1987) Pyridoxine supplementation: effect on lymphocyte responses in elderly persons. American Journal of Clinical Nutrition 46, 659664.Google Scholar
Thoman, ML (1997) Effects of the aged microenvironment on CD4+ T cell maturation. Mechanisms of Ageing and Development 96, 7588.CrossRefGoogle ScholarPubMed
Traill, KN, Schönitzer, D, Jürgens, G, Böck, G, Pfeilschifter, R, Hilchenbach, M, Holasek, A, Förster, O & Wick, G (1985) Age related changes in lymphocyte subset proportions, surface differentiation antigen density and plasma membrane fluidity: application of the Eurage Senieur Protocol admission criteria. Mechanisms of Ageing and Development 33, 3966.Google Scholar
Tyan, ML (1981) Marrow stem cells during development and aging. In Handbook of Immunology and Aging, pp. 87102 [Kay, MMB and Makinodan, T, editors]. New York: CRC Press.Google Scholar
Utsuyama, M, Kasai, M, Kurashima, C & Hirokawa, K (1997) Age influence on the thymic capacity to promote differentiation of T cells: induction of different composition of T cells subsets by aging thymus. Mechanisms of Ageing and Development 58, 167177.Google Scholar
Venkatraman, JT, Attwood, VG, Turturro, A, Hart, RW & Fernandes, G (1994) Maintenance of virgin T-cells and immune functions by food restriction during aging in long-lived B6D2F1 female mice. Aging, Immunology and Infectious Diseases 5, 1326.Google Scholar
Weksler, ME (1995) Immune senescence: deficiency or dys-regulation. Nutrition Reviews 53, S3S7.Google Scholar
Welle, S, Thornton, C & Jozefowicz, R (1993) Myofibrillar protein synthesis in young and old men. American Journal of Physiology 264, E693E698.Google Scholar
Wick, G & Grubeck-Lowenstein, B (1997) Primary and secondary alterations of immune reactivity in the elderly: impact of dietary factors and disease. Immunological Reviews 160, 171184.Google Scholar
Wick, G, Huber, LA, Xu, Q, Jarosch, E, Schönitzer, D & Jürgens, G (1991) The decline of the immune response during aging: the role of an altered lipid metabolism. Annals of the New York Academy of Sciences 621, 277290.Google Scholar
Yarasheski, KE, Zachwieja, JJ & Bier, DM (1993) Acute effects of resistance exercise on muscle protein synthesis rate in young and elderly men and women. American Journal of Physiology 265, E210E214.Google Scholar
Yong-Xing, M, Yue, Z, Zan-Shun, W, Chuan-Fu, W, Su-Ying, C, Mao-Tong, Z, Gong-Liang, Z, Su-Qin, Z, Jian-Gang, Z, Qi, G & Lin, H (1997) HLA and longevity or aging among Shanghai Chinese. Mechanisms of Ageing and Development 94, 191198.CrossRefGoogle Scholar