Studies of aging using genetically defined rodents: a bibliography

Aging, depot origin, and preadipocyte gene expression

Fat distribution changes with aging. Inherent changes in fat cell progenitors may contribute because fat cells turn over throughout life. To define mechanisms, gene expression was profiled in preadipocytes cultured from epididymal and perirenal depots of young and old rats. 8.4% of probe sets differed significantly between depots, particularly developmental genes. Only 0.02% differed with aging, despite using less stringent criteria than for comparing depots. Twenty-five genes selected based on fold change with aging were analyzed in preadipocytes from additional young, middle-aged, and old animals by polymerase chain reaction. Thirteen changed significantly with aging, 13 among depots, and 9 with both. Genes involved in inflammation, stress, and differentiation changed with aging, as occurs in fat tissue. Age-related changes were greater in perirenal than epididymal preadipocytes, consistent with larger declines in replication and adipogenesis in perirenal preadipocytes. Thus, age-related changes in preadipocyte gene expression differ among depots, potentially contributing to fat redistribution and dysfunction.

Increased CUG triplet repeat-binding protein-1 predisposes to impaired adipogenesis with aging

Preadipocyte differentiation capacity declines between middle and old age. Expression of the adipogenic transcription factors, CCAAT/enhancer-binding protein (C/EBP) alpha and peroxisome proliferator-activated receptor gamma (PPARgamma), is lower in differentiating preadipocytes from old than young animals, although no age-related changes occur in C/EBPbeta mRNA, which is upstream of C/EBPalpha and PPARgamma. C/EBPbeta-liver-enriched inhibitory protein (C/EBPbeta-LIP), a truncated C/EBPbeta isoform that is a dominant inhibitor of differentiation, increases with aging in rat fat tissue and preadipocytes. CUG triplet repeat-binding protein-1 (CUGBP1) binds to C/EBPbeta mRNA, increasing C/EBPbeta-LIP translation. Abundance and nucleotide binding activity of CUGBP1 increased with aging in preadipocytes. CUGBP1 overexpression in preadipocytes from young animals increased C/EBPbeta-LIP and impaired adipogenesis. Decreasing CUGBP1 in preadipocytes from old rats by RNA interference reduced C/EBPbeta-LIP abundance and promoted adipogenesis. Tumor necrosis factor-alpha, levels of which are elevated in fat tissue with aging, increased CUGBP1 protein, CUGBP1 binding activity, and C/EBPbeta-LIP in preadipocytes from young rats. Thus, CUGBP1 contributes to regulation of adipogenesis in primary preadipocytes and is responsive to tumor necrosis factor-alpha. With aging, preadipocyte CUGBP1 abundance and activity increases, resulting in enhanced translation of the C/EBPbeta-LIP isoform, thereby blocking effects of adipogenic transcription factors, predisposing preadipocytes from old animals to resist adipogenesis. Altered translational processing, possibly related to changes in cytokine milieu and activation of stress responses, may contribute to changes in progenitor differentiation and tissue function with aging.

Altered expression of C/EBP family members results in decreased adipogenesis with aging

Fat mass, adipocyte size and metabolic responsiveness, and preadipocyte differentiation decrease between middle and old age. We show that expression of CCAAT/enhancer binding protein (C/EBP)-α, a key regulator of adipogenesis and fat cell function, declined substantially with aging in differentiating preadipocytes cultured under identical conditions from rats of various ages. Overexpression of C/EBPα in preadipocytes cultured from old rats restored capacity to differentiate into fat cells, indicating that downstream differentiation-dependent genes maintain responsiveness to regulators of adipogenesis. C/EBPα-expression also decreased with age in fat tissue from three different depots and in isolated fat cells. The overall level of C/EBPβ, which modulates C/EBPα-expression, did not change with age, but the truncated, dominant-negative C/EBPβ-liver inhibitory protein (LIP) isoform increased in cultured preadipocytes and isolated fat cells. Overexpression of C/EBPβ-LIP in preadipocytes from young rats impaired adipogenesis. C/EBPδ, which acts with full-length C/EBPβ to enhance adipogenesis, decreased with age. Thus processes intrinsic to adipose cells involving changes in C/EBP family members contribute to impaired adipogenesis and altered fat tissue function with aging. These effects are potentially reversible.

Preadipocyte function and aging: links between age-related changes in cell dynamics and altered fat tissue function

OBJECTIVE

To review recent findings about changes with age in the replication and differentiation of preadipocytes, the progenitor cells in fat tissue that are capable of differentiating into fat cells, and to examine possible links between these alterations and age-related changes in fat tissue function.

DESIGN

A survey and analysis of recent literature concerning changes in preadipocyte and fat cell function with age.

CONCLUSIONS

Intrinsic aging changes in fat cells and preadipocytes as well as in factors extrinsic to fat tissue (such as food intake and absorption and hormonal status) contribute to age-related alterations in fat tissue function and cellularity. Changes with age in preadipocyte number, replicative potential, and capacity for differentiation, which may be linked to aging changes in fat cell size, number, and function, have been identified. The decline in preadipocyte capacity for differentiation and the associated decline in fat cell lipogenic capacity may be particularly important in contributing to the decrease in fat mass and alterations in fat tissue function that occur between middle- and old age. These declines result from blunting of the changes in gene expression that occur during preadipocyte differentiation and may, in turn, be related to altered regulation of particular transcription factors that control the preadipocyte differentiation program and maintenance of fat cell function.

Responses of young and aged Fischer 344 rat inferior colliculus neurons to binaural tonal stimuli

The inferior colliculus (IC) is one nucleus of the central auditory system which displays age-related changes. Inputs to the IC use primarily the amino acid neurotransmitters glutamate and gamma-aminobutryic acid (GABA). Neurochemical and anatomical studies of the Fischer 344 (F344) rat IC have shown decreases in GABA and GABA receptor levels (see Caspary et al., 1995 for review). GABA neurotransmission affects binaural response properties in the IC (Faingold et al., 1991a, b; Vater et al., 1992a; Park and Pollak, 1993, 1994). We hypothesized that aged F344 rats would show alterations in binaural IC neuronal response properties due to an imbalance in the relative levels of inhibition and excitation. Extracellular recordings from 189 single units localized to the IC of anesthetized aged (24 month) F344 rats were compared to those obtained from 221 IC units in young adult (3 month) animals. Quantitative analyses were performed to determine the distribution of ipsilateral and binaural rate/intensity functions (RIFs) in the central nucleus of the IC and external cortex of the IC units. The majority of IC units in both young and aged F344 rats were not responsive to monaural ipsilateral characteristic frequency tone bursts. Although there was some shift in the distribution of binaural RIF shapes with age, it was not statistically significant. The shift included a reduction in the percentage of units classified as E/I (excited by contralateral stimulation/ipsilaterally inhibited during binaural stimulation), but an increase with age in the percentage of units classified as E/f (excited by contralateral stimulation/ further facilitated by the addition of low intensity ipsilateral stimulation, but inhibited by higher intensity ipsilateral stimulation). Despite the role of inhibitory neurotransmission in binaural processing in the IC, age-related neurochemical deficits in the IC do not appear to result in a major deficit in the processing of simple binaural stimuli in F344 rats.

Fast axonal transport rates are unchanged in 6- and 24-month F344 rats

The maximum rate of fast axonal transport in motor axons at 6 and 24 months was measured in F344 rats. Tritiated proline was injected near sciatic motoneurons and rats were killed after 2-5 h. Nerves were processed for liquid scintillation spectroscopy and fast transport rates calculated. The rates, in 6- and 24-month rats, were 373 +/- 12 mm/day and 368 +/- 10 mm/day, respectively. Thus, the maximum fast transport rate is unchanged with age in F344 rats.

Longevity, body weight, and neoplasia in ad libitum-fed and diet-restricted C57BL6 mice fed NIH-31 open formula diet

Groups of C57BL6 mice of each sex were assigned to one of 2 dietary regimens, ad libitum (AL) or dietary restriction (DR), to study effects of food restriction on body weight, survival, and neoplasia. The AL and DR groups were subdivided into a scheduled sacrifice group for examination at 6-mo intervals, and a lifetime group to provide longevity data. Necropsies and microscopic examinations were conducted on 911 animals. In the lifetime group food consumption averaged 33.6 and 34.4 g per week by AL males and AL females, respectively; the DR counterparts were given 40% less. The diet contained 4.35 kcal/g. The average lifetime body weights were 34.8, 26.8, 22.6, and 21.6 g for AL males, AL females, DR males, and DR females, respectively, and their age at 50% survival was 27.5, 26.9, 31.7, and 33.5 mo. Maximal lifespan was increased 18% in DR males and females. Lifetime incidence of tumor-bearing mice was 89% and 86% for AL males and females, versus 64% for each sex of DR mice. Dramatic reduction occurred in female DR mice in lymphoma (9% vs 29%), pituitary neoplasms (1% vs 37%), and thyroid neoplasms (0.4% vs 8%). In males, hepatocellular tumors were reduced to 1% from 10% by DR. In contrast, the incidence of histiocytic sarcoma was increased in DR females and unaffected in DR males. Tumor onset was delayed in DR animals; 87% of all neoplasms in males and 95% in females had occurred in the AL mice by 24 mo, whereas the DR animals had only 52% and 39% of their lifetime incidence, respectively, by that age. This study provided comparative AL and DR data from C57BL6 mice examined randomly at 6-mo intervals (cross-sectional group) in parallel with data from animals in similar cohort that was unsampled and allowed to succumb naturally (longevity group). Dietary restriction reduced the lifetime percentage of tumor-bearing animals and the number of tumors per animal, and delayed the age at onset of most neoplasms.

Strain, stress, neurodegeneration and longevity

Laboratory studies indicate that the life-span of inbred rodent strains is inversely related to the intensity of their behavioral and neuroendocrine responses to stressful stimuli. In the brain, a shorter life-span is associated with accelerated age-dependent degenerative changes in specific stress-responsive neuronal systems. The evidence suggests a possible genetic linkage between the intensity of the stress response, the rate of age-dependent neurodegeneration and the individual's life expectancy. It is proposed that inherent hyper-reactivity to stressors is genetically linked to a shorter life-span and to accelerated age-dependent neurodegeneration. Several experimental approaches to test 'this stress-longevity-neurodegeneration linkage hypothesis' are outlined.

Effects of age on the pharmacokinetics of piroxicam in rats

This study examined the effects of age on the pharmacokinetics of piroxicam in rats. Two groups of rats, aged 5 and 24 months, were administered 1 mg of piroxicam per kg intravenously, and blood samples were withdrawn for up to 120 h. Protein binding studies, with pooled serum from each age group were also performed. Piroxicam concentrations were determined by HPLC analysis, and pharmacokinetic parameters were characterized by area-moment analysis. Plasma piroxicam concentrations declined in both age groups in a biexponential fashion, with half-lives of 5.9 +/- 0.7 h (mean +/- SD) in the young rats and 30.6 +/- 9.9 h in the old rats. Total clearance in the young rats was 0.048 +/- 0.012 L/h/kg, whereas that in the old rats was 0.021 +/- 0.003 L/h/kg. The steady-state volume of distribution in the young rats was 0.42 +/- 0.05 L/kg, and that in the old rats was 0.56 +/- 0.10 L/kg. There was a statistically significant difference between these parameters calculated for each age group. Piroxicam is a highly plasma protein-bound drug; the fraction unbound in the young rats was determined to be 0.067 +/- 0.022, and that in the old rats was determined to be 0.134 +/- 0.065, or twice that in the young rats. Differences in protein binding were due, in part, to a 20% decreased albumin concentration in the old rats; however, there was also a decrease in the number of binding sites and/or the binding affinity with aging.(ABSTRACT TRUNCATED AT 250 WORDS)

Genetic variability and rodent models of human aging

Inbred strains, outbred strains, and natural populations of rodents differ greatly in the amount and nature of the genetic variability they possess. Consequently, as models of human aging they vary with respect to the areas of research to which they are best suited. Inbred strains, in which all individuals are genetically identical, are best suited as models of specific disease processes and for manipulations involving tissue transplantation. Their lack of genetic variability, however, and the disruption of genetic linkage groups that occurs during inbreeding limit their value as models of more general aging processes. Outbred strains exhibit large interindividual genetic variation--a result of ongoing random accumulation of deleterious alleles with late ages of action. This makes them ideal models for studying the diversity of pathologic lesions, connections between pathologies, and susceptibility to pathologic lesions that collectively produce the reductions in reproductive capacity, physiological efficiency, and viability that are characteristic of aging. Natural populations also may exhibit relatively large amounts of interindividual genetic variability. However, difficulties with husbandry, variable parasite loads, and complex population genetics can compromise their suitability as models of human aging. Ultimately, a consideration of the range of animal models available and a more careful matching of the goals of a study with the genetic system of the model will prove fruitful to gerontology.

Relevance of the rodent model to human aging studies

Rodents have proven to be a useful general model for aging research. Although they are not necessarily appropriate for the study of such specific human age-associated diseases as atherosclerosis, rodents have provided the basis for important age-related findings in many diverse areas, including nutrition, behavior, immunology, physiology, oncology, biochemistry, and neurobiology. Contributions in these areas are briefly reviewed.

Tail-cuff detection of systolic hypertension in different strains of ageing rats

To identify rat strains suitable for studying age-related development of hypertension we compared pressures measured with the tail-cuff method in different groups of ageing Fischer 344, Wistar, or Sprague-Dawley rats. Preliminary experiments to establish optimal frequency of chronic blood pressure measurement in ageing rats showed that tail-cuff systolic pressures did not differ significantly whether taken weekly or monthly. Repeated tail-cuff measurements were comparable even when a common cuff size was used in different groups of rats with varying tail diameters. Additional studies were then carried out in 1-year old male Wistar and Sprague-Dawley rats to measure tail-cuff pressures monthly during the second year of age. Systolic and mean pressures increased progressively with age in both strains, as did body weight and heart rate, but the incidence of hypertension was higher in Sprague-Dawley than in Wistar rats. Elevations in mean pressures were sometimes more pronounced than those in systolic pressure. Two months after the last tail-cuff measurement, the presence of hypertension in Wistar rats was verified by the elevated mean pressures that were recorded from femoral artery catheters. Our results overall suggest that the predisposition to hypertension was higher in Sprague-Dawley than in Wistar or Fischer 344 rats of the same age, and also in males than in females of the same strain. Of all the different strains and sexes we compared, therefore, male Sprague-Dawley rats from 20 to 24 months of age may be the best model for studying the development of systolic hypertension with age.

Effect of advanced age on p-aminohippurate-induced inhibition of renal tubular secretion in male Fischer 344 rats

The effect of aging on glomerular filtration, effective renal plasma flow and on the responsiveness of the renal tubular anion secretory system to inhibition by 4-aminobenzoylglycine (p-aminohippurate, PAH) was examined in young (5-month) and old (22-month) Fischer 344 male rats. Plasma clearance, protein binding and renal extraction of [131I]o-iodohippurate, [125I]iothalamate and HPLC-purified [99mTc]mercaptoacetyltriglycine (MAG3), were used as in vivo probes of renal function. The effect of advanced age, without concomitant PAH, on the disposition of these markers was initially determined in ketamine anesthetized, temperature-maintained male rats, ages 5, 14 and 22 months by means of constant infusion clearance studies. Aging per se decreased (P less than 0.05) the kidney-weight normalized or body weight-normalized GFR and effective renal plasma flow rates. GFR values averaged 1.67, 1.43 and 1.32 ml/min per g kidney for the 5-, 14- and 22-month-old rats, respectively. Kidney- or body weight-normalized clearances of MAG3 and o-iodohippurate showed similar (25-27%) decreases, whereas the absolute values (ml/min) for GFR, o-iodohippurate and MAG3 clearance rates were not altered by aging. The effective filtration fraction, extraction ratio and plasma protein binding were also unchanged by advanced age. Overall, the age-related decreases in renal function were minimal in Fischer-344 rats, compared to other species. Differences in data normalization, species and gender account, in part, for discrepancies observed when comparing results in different studies on the effects of advanced age on renal function. Subsequently, we examined the effect of aging on the renal responsiveness to inhibition of tubular anion secretion using constant rate PAH infusion studies, adjusted for age-related changes in renal function. Aging did not alter PAH-induced inhibition of iodohippurate secretion. Inhibition of MAG3 elimination was more pronounced in the old rats compared to the young controls.

Enhanced sympathetic mediation of chronotropic baroreflexes in old Sprague-Dawley rats

We compared reflex heart rate responses elicited during intravenous infusions of phenylephrine or sodium nitroprusside in conscious 4- and 24-month-old male Sprague-Dawley rats to determine whether baroreflex regulation changes with age. Underlying neural mechanisms were assessed by repeating baroreflex tests following cholinergic blockade with methylatropine or beta-adrenergic blockade with propranolol. Basal blood pressures always tended to be higher, while corresponding heart rates were lower, in old than in young rats. Reflex bradycardia (but not tachycardia) was initially weaker in 24-month-old rats as were reductions in both reflex bradycardia and tachycardia after cholinergic blockade. On the other hand, the reduction in reflex tachycardia following beta-adrenergic blockade in old rats was more pronounced and almost equal to that produced by combined cholinergic and beta-adrenergic blockade. From these results we conclude that with old age in male Sprague-Dawley rats, just as has been shown previously in Fischer 344 rats, predominant efferent pathways for regulating heart rate reflexes are also altered to become almost exclusively beta-adrenergic or sympathetic.

Mediation of reflex tachycardia becomes exclusively beta-adrenergic in old Fischer 344 rats

To study how baroreflex regulation changes with age we compared reflex heart rate responses elicited in awake Fischer 344 rats of different ages during intravenous infusions of phenylephrine or sodium nitroprusside. Underlying neural mechanisms were assessed by repeating baroreflex tests following cholinergic blockade with methylatropine or beta-adrenergic blockade with propranolol. Basal heart rates always tended to be lower in old than in young rats, but the differences became statistically significant only after beta-adrenergic or combined cholinergic and beta-adrenergic blockade. Most reflex heart rate responses (i.e. except reflex tachycardia in males during depressor responses to sodium nitroprusside) were initially weaker in old than in younger rats. Reflex bradycardia and tachycardia were reduced equally in both age groups after cholinergic blockade, but were reduced more in old than in young rats after beta-adrenergic blockade. beta-adrenergic blockade alone reduced reflex tachycardia as much as did combined blockade thereby suggesting that the predominant neural mechanism was beta-adrenergic. Taken altogether these results are compatible with the interpretation that efferent pathways for mediating heart rate reflexes in Fischer 344 rats are altered with age such that as parasympathetic mediation diminishes, residual mediation particularly of reflex tachycardia, becomes almost exclusively beta-adrenergic or sympathetic.