Abstract
In order to understand the basic mechanisms underlying the organismic aging process, considerable efforts have been devoted in the last half-century to biochemical (enzyme activity) alterations in specific tissues and organs of various organisms associated with aging. When a decline in enzyme activities with age has been found in a study, especially for key enzymes such as antioxidant enzymes, the results have often been interpreted as a cause for the aging of the entire body. Retrospectively, however, these changes turned out to be so variable—depending on species, strains and sexes of animals—that the interpretation of these results in general terms of aging became invalid. Further, unlike the prediction for the whole human body, many enzyme activities in a vital organ, such as the liver, remained unchanged, as long as the old subjects remained healthy. However, enzyme activities in old animals and humans are often more susceptible to morbidities and frailties, which themselves are often accompanied by infections and malnutrition. Despite the rather stable enzyme functions in the liver with age, a distinct and progressive decline in the lateral diffusion coefficient of proteins of hepatocyte plasma membranes has been demonstrated by fluorescence recovery after photobleaching (FRAP), which was implicated as the cause for the decline of hepatocyte functions such as ouabain (and taurocholate) hepatic uptake and their eventual biliary excretion. Since a similar decline in protein diffusion coefficients was observed in brain and muscle cells, it is likely that these changes are occurring in common with many cell types of the body, thus causing a delay in transmembrane transport of endogenous and exogenous substances whose transports are mediated by membrane proteins. In attempts to prolong the life spans of animals other than by calorie restriction, but instead using deprenyl or tetrahydrocurcumin, works by the author and coworkers are introduced and discussed. Despite limited success along these lines thus far, further attempts are encouraged, primarily to understand the mechanisms underlying organismic aging processes and to find a practical way to prolong the health span of the elderly.
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References
Adelman RC (1975) Disruption in enzyme regulation during aging. In: Parke DV (ed) Enzyme Induction. Plenum Press, London, pp 303–311
Anderson KE, Conney AH, Kappas A (1982) Nutritional influences on chemical biotransformations in humans. Nutr Rev 40(6):161–171
Au WY, Dutt AK, DeSoyza N (1985) Theophylline kinetics in chronic obstructive airway disease in the elderly. Clin Pharmacol Ther 37(4):472–478
Bickford PC, Adams CE, Boyson SJ, Curella P, Gerhardt GA, Hero C et al (1997) Long-term treatment of male F344 rats with deprenyl: Assessment of effects on longevity, behavior, and brain function. Neurobiol Aging 18:309–318
Bonde J, Pedersen LE, Bodtker S, Angelo HR, Svendsen TL, Kampmann JP (1985) The influence of age and smoking on the elimination of disopyramide. Br J Clin Pharmacol 20:453–458
Brandfonbrener M, Landowne M, Shock NW (1955) Changes in cardiac output with age. Circulation 12:557–566
Carrillo MC, Kanai S, Kitani K, Ivy GO (2000) A high dose of long term treatment with deprenyl loses its effect on antioxidant enzyme activities as well as on survivals of Fischer-344 rats. Life Sci 67:2539–2548
Carrillo MC, Kanai S, Miyasaka K, Kitai K (2002) A protein free diet uncovers the potential age-difference in the hepatic detoxifying system, glutathione S-transferase in female mice. Mech Ageing Dev 123:1617–1623
Carrillo MC, Kanai S, Sato Y, Kitani K (1992a) Age-related changes in antioxidant enzyme activities are region and organ selective as well as sex in the rat. Mech Ageing Dev 65:187–198
Carrillo MC, Kitani K, Kanai S, Sato Y, Nokubo M, Ohta M, Otsubo K (1989) Differences in the influence of diet on hepatic glutathione S-transferase activity and glutathione content between young and old C57 black female mice. Mech Ageing Dev 47:1–15
Carrillo MC, Nokubo M, Kitani K, Kanai S, Sato Y, Ohta M (1991) Different responses of subunit concentrations and enzyme activities of glutathione S-transferases (GSTs) to protein-free diet (PFD) between young and old rodent livers. In: Kitani K (ed) Liver and Aging-1990. Elsevier Science, Amsterdam, New York, Oxford, pp 75–86
Carrillo MC, Sato Y, Kanai S, Nokubo M, Kitani K (1992b) Difference in response of hepatic glutathione S-transferase activities to protein free diet between young and old C57 male mice. Mech Ageing Dev 65:301–311
Carrillo MC, Nokubo M, Sato Y, Kanai S, Ohta M, Kitani K (1990) Effect of protein-free diet on activities and subunits of glutathione S-transferase in livers of young and aged female rats. Mech Ageing Dev 56:237–251
Demetrius L (2004) Caloric restriction, metabolic rate, and entropy. J Gerontol Biol Sci 59A:902–915
Dirks AJ, Leeuwenburgh CL (2006) Calorie restriction in humans: Potential pitfalls and health concerns. Mech Ageing Dev 127:1–7
Fujita S, Chiba M, Suzuki M, Kitani K (1986) Effect of senescence on the hepatic metabolism of drugs affecting the central nervous system in rats and mice. In: Kitai K (ed) Liver and Aging-1986, Liver and Brain. Elsevier Science, Amsterdam, Oxford, New York, pp 115–126
Fujita S, Uesugi T, Kitagawa H, Suzuki T, Kitani K (1982) Hepatic microsomal monooxygenase and azoreductase activities in aging Fischer-344 rats. Importance of sex difference for aging study. In: Kitani K (ed) Liver and Aging-1982, Liver and Drugs. Elsevier/North-Holland Biomedical Press, Amsterdam, Oxford, New York, pp 55-71
Gallagher IM, Clow A, Glover V (1998) Long term administration of (-)deprenyl increases mortality in male Wistar rats. J Neural Transm (Suppl) 52:315–320
Goto S, Takahashi R, Kumiyama A, Radak Z, Hayashi T, Takenouchi M et al. (2001) Implications of protein degradation in aging. Ann NY Acad Sci 928:54–64
Harman D (1956) Aging: a theory based on free radical and radiation chemistry. J Gerontol 12:257–263
Harman D (1994) Free-radical theory of aging. Increasing the functional life span. In: Zs.-Nagy I, Harman D, Kitani K (eds) Pharmacology of Aging Processes. Methods of Assessment and Potential Interventions. Vol. 717 Ann NY Acad Sci, New York, pp 1–15
Ikeno Y, Cortez L, Lew C, Qi W, Chaudhur A, Richardson A (2005) Cu/Zn SOD transgenic rats show reduced oxidative damage and increased survival. Abstract, 34th Annual Meeting of the American Aging Association, Oakland, P32
Ishigami A, Goto S (1990) Age-related change in the degradation rate of ovalbumin microinjected into mouse liver parenchymal cells. Arch Biochem Biophys 277:189–195
Ivy GO, Kanai S, Ohta M, Ihara Y, Kitani K (1991a) Leupeptin causes an accumulation of lipofuscin-like substances and ubiquitin immunoreactivity in liver cells of young rats: a possible model for hepatocellular aging. In: Kitani K (ed) Liver and Aging-1990. Elsevier Science, Amsterdam, New York, Oxford, pp 109–122
Ivy GO, Kanai S, Ohta M, Sato Y, Otsubo K, Kitani K (1991b) Leupeptin causes an accumulation of lipofuscin-like substances in liver cells of young rats. Mech Ageing Dev 57:213–231
Ivy GO, Kanai S, Ohta M, Smith G, Sato Y, Kobayashi M et al (1990) Lipofuscin-like substances accumulate rapidly in brain, retina and internal organs with cysteine protease inhibition. In: Porta EA (ed) Lipofuscin and ceroid pigments. Plenum Press, New York, pp 31–47
Ivy GO, Schottler F, Wenzel J, Baudry M, Lynch G (1984) Inhibitors of lysosomal enzymes: accumulation of lipofuscin-like dense bodies in the brain. Science 226:985–987
Kamataki T, Maeda K, Shimada M, Kitani K, Nagai T, Kato R (1985) Age-related alteration in the activities of drug-metabolizing enzymes and contents of sex-specific forms of cytochrome P-450 in liver microsomes from male and female rats. J Pharmacol Exp Ther 233:222–228
Kato R, Vassanelli P, Frontino G, Chiesara E (1964) Variation in the activity of liver misrosomal drug-metabolizing enzymes in rats in relation to the age. Biochem Pharmacol 13:1037–1051
Kitani K (1988) Drugs and the ageing liver. Life Chem Rep 6:143–230
Kitani K (1991a) Aging of the liver: facts and theories. Arch Gerontol Geriatr 12:133–154
Kitani K (1999) Lateral mobility of proteins and lipids of cell surface membranes during aging: do the data support “The Membrane Hypothesis of Aging”? Mech Ageing Dev 107:299–322
Kitani K (ed) (1978) Liver and Aging-1978. Elsevier/North-Holland Biomedical Press, Amsterdam, Oxford, New York
Kitani K (ed) (1982) Liver and Aging-1982. Liver and Drugs, Elsevier Biochemical Press, Amsterdam, Oxford, New York
Kitani K (ed) (1986) Liver and Aging-1986. Liver and Brain, Elsevier Science Publishers, B.V., Amsterdam, Oxford, New York
Kitani K (ed.) (1991b) Liver and Aging-1990. Elsevier Science Publishers, B.V., Amsterdam, Oxford, New York
Kitani K (2005) Nutritional interventions in aging and age-associated disorders. In: Rattan SIS (ed) Aging Interventions and Therapies. World Scientific Publishers, Singapore, pp 219–245
Kitani K, Goto S (2005) Interview, "My involvement in aging research was just a series of coincidences". An interview with Kenichi Kitani. Bipogerontology 6:211–221
Kitani K, Osawa T (2005) Tetrahydrocurcumin (TC) feeding increases the life span of genetically contaminated C57BL male mice. Abtract, 34th Annual Meeting of the American Aging association, Oakland, USA, p34
Kitani K, Yokozawa T (2003) Green tea polyphenol (sunphenon) prolongs the average life span of male C57/BL mice. Abstract, 32nd Annual Meeting of American Aging Association, P8
Kitani K, Kanai S, Miura R, Morita Y, Kasahara M (1978) The effect of aging on the biliary excretion of ouabain in the rat. Exp Gerontol 13:9–17
Kitani K, Kanai S, Miyasaka K, Carrillo MC, Ivy GO (2005) Dose-dependency of life span prolongation of F344/DuCrj rats injected with (-)deprenyl. Biogerontology 6:1–6
Kitani K, Kanai S, Miyasaka K, Carrillo MC, Ivy GO (2006) The necessity of having a proper dose of (-)deprenyl (D) to prolong the life spans of rats explains discrepancies among different studies in the past. Ann New York Acad Sci 1067:375–382
Kitani K, Kanai S, Sato Y, Ohta M, Ivy GO, Carrillo MC (1993) Chronic treatment of (-)deprenyl prolongs the life span of male Fischer 344 rats. Further evidence. Life Sci 52:281–288
Kitani K, Klotz U, Kanai S, Sato Y, Ohta M, Nokubo M (1989) Age-related differences in the coordination disturbance and anticonvulsant effect of oxazepam in mice. Arch Gerontol Geriatr 9:31–43
Kitani K, Masuda Y, Sato Y, Kanai S, Ohta M, Nokubo M (1984) Increased anticonvulsant effect of phenytoin in aging BDF1 mice. J Pharmacol Exp Ther 229:231–236
Kitani K, Minami C, Isobe K, Maehara K, Kanai S and Ivy GO et al (2002a) Why(-)deprenyl prolongs survivals of experimental animals: Increase of anti-oxidant enzymes in brain and other body tissues as well as mobilization of various humoral factors may lead to systemic anti aging effects. Mech Ageing Dev 123?:1087–1100
Kitani K, Minami C, Yamamoto T, Kanai S, Ivy GO, Carrillo MC (2002b) Pharmacological interventions in aging and age-associated disorders. Potentials of propargylamines for human use. Ann New York Acad Sci 959:295–307
Kitani K, Ohta M, Kanai S, Sato Y, Nokubo M, Zs.-Nagy I (1991) Age-induced restricted mobility of proteins in hepatocyte surface membranes: A possible determinant of membrane transport function. In: Kitani K (ed) Liver and Aging-1990. Elsevier Science, Amsterdam, New York, Oxford, pp 305–318
Kitani K, Sato Y, Kanai S, Nokubo M, Ohta M, Masuda Y (1985a) Age related increased threshold for electroshock seizure in BDF1 mice. Life Sci 36:657–662
Kitani K, Sato Y, Kanai S, Nokubo M, Ohta M, Masuda Y (1985b) Increased anticonvulsant effect of phenobarbital with age in mice - A possible pharmacological index for brain aging. Life Sci 37:1451–1460
Kitani K, Sato Y, Kanai M, Nokubo M, Ohta M, Masuda Y (1987) Increasing anticonvulsant effect of AD-810 (Zonisamide) in aging BDF1 mice. Life Sci 41:1339–1344
Kitani K, Zs.-Nagy I, Kanai S, Sato Y and Ohta M (1988) Correlation between the biliary excretion of ouabain and the lateral mobility of hepatocyte plasma membrane proteins in the rat - The effects of age and spironolactone pretreatment. Hepatology 8:125–131
Knoll J (1988) The striatal dopamine dependency of life span in male rats: longevity study with (-)deprenyl. Mech Ageing Dev 46:237–262
Lindeman RD, Tobin J, Shock NW (1985) Longitudinal studies on the rate of decline in renal function with age. J Am Geriatr Soc 33(4):276–285
Martin GM (1997) The Werner mutation: does it lead to a “public” or “private” mechanism of aging? Mol Med 3:356–358
Milgram NW, Racine RJ, Nellis P, Mendonca A, Ivy GO (1990) Maintenance of L-deprenyl prolongs life in aged male rats. Life Sci 47:415–420
Ohta M, Kanai S, Sato Y, Kitani K (1988) Age-dependent decrease in the hepatic uptake and biliary excretion of ouabain in rats. Biochem Pharmacol 37:935–942
Ohta M, Kitani K (1990) Age-dependent decrease in the hepatic uptake of taurocholic acid resembles that for ouabain. Biochem Pharmacol 39:1223–1228
Rao G, Xia E and Richardson A (1990) Effect of age on the expression of antioxidant enzymes in male Fischer 344 rats. Mech Ageing Dev 53:49–60
Reiss U, Gershon D (1978) Methionine sulfoxide reductase: A novel protective enzyme in liver and its potentially significant role in aging. In: Kitani K (ed) Liver and Aging-1978. Elsevier North-Holland, Amsterdam, pp 55–61
Rikans LE, Snowden CD, Moore DR (1991) Sex-dependent differences in the effect of aging on antioxidant defense mechanisms of rat liver. Biochim Biophys Acta 1074:195–200
Rodeheffer RJ, Gerstenblith G, Becker LC, Fleg JL, Weisfeidt ML, Lakatta EG (1984) Exercise cardiac output is maintained with advancing age in healthy human subjects: cardiac dilatation and increased stroke volume compensate for a dimished heart rate. Circulation 69:203–213
Rowe JW, Andres R, Tobin JD, Norris AH, Shock NW (1976) The effect of age on creatinine clearance in men: a cross-sectional and longitudinal study. J Gerontol 31(2):155–163
Schriner SE, Linford NJ, Martin GM, Treuting P, Ogburn CE, Emond M et al (2005) Extension of murine life span by overexpression of catalase targeted to mitochondria. Science 308:1909
Semsei I, Rao G, Richardson A (1991) Expression of superoxide dismutase and catalase in rat brain as a function of age. Mech Ageing Dev 58:13–19
Sonne J, Dossing M, Loft S, Andreasen PB (1985) Antipyrine clearance in pneumonia. Clin Pharmacol Ther 37(6):701–704
Williams LR, Carter DB, Dunn E, Conner JR (1995) Indicators of oxidative stress in aged Fischer 344 rats: potential for neurotrophic treatment. In: Hannin I, Fischer A, Yoshida M (eds) Alzheimer’s and Parkinson’s Disease: Recent Advances. Plenum Pub Corp, New York, pp 641–646
Wulf J, Cutler RG (1975) Altered protein hypothesis of mammalian aging process I. Thermal stability of glucose-6-phosphate dehydroenase in C57BL/6J mouse tissues. Exp Gerontol 10:101–117
Wynne HA, Cope LH, Herd B, Rawlins MD, James OF, Woodhouse KW (1990) The association of age and frailty with paracetamol conjugation in man. Age Ageing 19:419–424
Zs.-Nagy I (1991) The horizons of interdisciplinary synthesis in experimental gerontology. A review. Arch Gerontol Geriatr 12:329–349
Zs.-Nagy I (1994) The membrane hypothesis of aging. CRC Press, Boca Raton, FL
Zs.-Nagy I (2001) Enzyme activities in the light of membrane hypothesis of aging [Answer to K. Kitani, Mech Ageing Dev. 107 (1999) 299–322]. Mech Ageing Dev 122:811–821
Zs.-Nagy I, Cutler RG, Kitani K, Ohta M (1993) Comparison of the lateral diffusion constant of hepatocyte membrane proteins in two wild mouse strains of considerably different longevity: FRAP studies on liver smears. J Gerontol Biological Sci 48:B86–B92
Zs.-Nagy I, Kitani K, Ohta M and Imahori K (1986) Age-dependent decrease of the lateral diffusion constant of proteins in the plasma membrane of hepatocytes as revealed by fluorescence recovery after photo bleaching in tissue smears. Arch Gerontol Geriatr 5:131–146
Zs.-Nagy I, Ohta M, Kitani K and Imahori K (1984) An automated method for measuring lateral mobility of proteins in the plasma membrane of cells. Microskopie 41:12–25
Zs.-Nagy I, Tanaka S, Kitani K (1998) Age-dependence of the lateral diffusion coefficient of Con-A-receptor protein in the skeletal muscle membrane of C57BL/6J mice. Mech Ageing Dev 101:257–268
Zs.-Nagy I, Tanaka S, Kitani K (1999) Age-dependence of the lateral diffusion coefficient of Con-A-receptor protein in the plasma membrane of ex vivo prepared brain cortical cells of BN/BiRijHsd rats. Exp Brain Res 124:233–240
Acknowledgements
The author truly expresses his deep appreciation to all coworkers over the past 35 years who contributed to the progress in aging research in his laboratory. Special thanks are due to Dr. G.O.Ivy who carefully read the manuscript, Ms. S. Kanai and Ms. M. Ratnam for their technical help and Ms. T. Ohara for her efficient secretarial work to complete this manuscript.
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Kitani, K. What really declines with age?. AGE 29, 1–14 (2007). https://doi.org/10.1007/s11357-006-9014-8
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DOI: https://doi.org/10.1007/s11357-006-9014-8