Rat brain protein synthesis declines during postdevelopmental aging

Regulating translation in aging: from global to gene-specific mechanisms

Aging is characterized by a decline in various biological functions that is associated with changes in gene expression programs. Recent transcriptome-wide integrative studies in diverse organisms and tissues have revealed a gradual uncoupling between RNA and protein levels with aging, which highlights the importance of post-transcriptional regulatory processes. Here, we provide an overview of multi-omics analyses that show the progressive uncorrelation of transcriptomes and proteomes during the course of healthy aging. We then describe the molecular changes leading to global downregulation of protein synthesis with age and review recent work dissecting the mechanisms involved in gene-specific translational regulation in complementary model organisms. These mechanisms include the recognition of regulated mRNAs by trans-acting factors such as miRNA and RNA-binding proteins, the condensation of mRNAs into repressive cytoplasmic RNP granules, and the pausing of ribosomes at specific residues. Lastly, we mention future challenges of this emerging field, possible buffering functions as well as potential links with disease.

G-quadruplexes and associated proteins in aging and Alzheimer's disease

Aging is a prominent risk factor for many neurodegenerative disorders, such as Alzheimer's disease (AD). Alzheimer's disease is characterized by progressive cognitive decline, memory loss, and neuropsychiatric and behavioral symptoms, accounting for most of the reported dementia cases. This disease is now becoming a major challenge and burden on modern society, especially with the aging population. Over the last few decades, a significant understanding of the pathophysiology of AD has been gained by studying amyloid deposition, hyperphosphorylated tau, synaptic dysfunction, oxidative stress, calcium dysregulation, and neuroinflammation. This review focuses on the role of non-canonical secondary structures of DNA/RNA G-quadruplexes (G4s, G4-DNA, and G4-RNA), G4-binding proteins (G4BPs), and helicases, and their roles in aging and AD. Being critically important for cellular function, G4s are involved in the regulation of DNA and RNA processes, such as replication, transcription, translation, RNA localization, and degradation. Recent studies have also highlighted G4-DNA's roles in inducing DNA double-strand breaks that cause genomic instability and G4-RNA's participation in regulating stress granule formation. This review emphasizes the significance of G4s in aging processes and how their homeostatic imbalance may contribute to the pathophysiology of AD.

Protein translation paradox: Implications in translational regulation of aging

Protein translation is an essential cellular process playing key roles in growth and development. Protein translation declines over the course of age in multiple animal species, including nematodes, fruit flies, mice, rats, and even humans. In all these species, protein translation transiently peaks in early adulthood with a subsequent drop over the course of age. Conversely, lifelong reductions in protein translation have been found to extend lifespan and healthspan in multiple animal models. These findings raise the protein synthesis paradox: age-related declines in protein synthesis should be detrimental, but life-long reductions in protein translation paradoxically slow down aging and prolong lifespan. This article discusses the nature of this paradox and complies an extensive body of work demonstrating protein translation as a modulator of lifespan and healthspan.

Multidimensional dynamics of the proteome in the neurodegenerative and aging mammalian brain

The amount of any given protein in the brain is determined by the rates of its synthesis and destruction, which are regulated by different cellular mechanisms. Here, we combine metabolic labeling in live mice with global proteomic profiling to simultaneously quantify both the flux and amount of proteins in mouse models of neurodegeneration. In multiple models, protein turnover increases were associated with increasing pathology. This method distinguishes changes in protein expression mediated by synthesis from those mediated by degradation. In the App^NL-F knockin mouse model of Alzheimer’s disease, increased turnover resulted from imbalances in both synthesis and degradation, converging on proteins associated with synaptic vesicle recycling (Dnm1, Cltc, Rims1) and mitochondria (Fis1, Ndufv1). In contrast to disease models, aging in wild-type mice caused a widespread decrease in protein recycling associated with a decrease in autophagic flux. Overall, this simple multidimensional approach enables a comprehensive mapping of proteome dynamics and identifies affected proteins in mouse models of disease and other live animal test settings.

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Multidimensional proteomic screen to detect imbalances in mouse models of disease.

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Increased proteome turnover in multiple symptomatic neurodegeneration mouse models.

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Healthy aging is associated with a global decrease in protein turnover.

2-Oxoglutarate-dependent dioxygenases are sensors of energy metabolism, oxygen availability, and iron homeostasis: potential role in the regulation of aging process

Recent studies have revealed that the members of an ancient family of nonheme Fe(2+)/2-oxoglutarate-dependent dioxygenases (2-OGDO) are involved in the functions associated with the aging process. 2-Oxoglutarate and O2 are the obligatory substrates and Fe(2+) a cofactor in the activation of 2-OGDO enzymes, which can induce the hydroxylation of distinct proteins and the demethylation of DNA and histones. For instance, ten-eleven translocation 1-3 (TET1-3) are the demethylases of DNA, whereas Jumonji C domain-containing histone lysine demethylases (KDM2-7) are the major epigenetic regulators of chromatin landscape, known to be altered with aging. The functions of hypoxia-inducible factor (HIF) prolyl hydroxylases (PHD1-3) as well as those of collagen hydroxylases are associated with age-related degeneration. Moreover, the ribosomal hydroxylase OGFOD1 controls mRNA translation, which is known to decline with aging. 2-OGDO enzymes are the sensors of energy metabolism, since the Krebs cycle intermediate 2-oxoglutarate is an activator whereas succinate and fumarate are the potent inhibitors of 2-OGDO enzymes. In addition, O2 availability and iron redox homeostasis control the activities of 2-OGDO enzymes in tissues. We will briefly elucidate the catalytic mechanisms of 2-OGDO enzymes and then review the potential functions of the above-mentioned 2-OGDO enzymes in the control of the aging process.

Neural Protein Synthesis during Aging: Effects on Plasticity and Memory

During aging, many experience a decline in cognitive function that includes memory loss. The encoding of long-term memories depends on new protein synthesis, and this is also reduced during aging. Thus, it is possible that changes in the regulation of protein synthesis contribute to the memory impairments observed in older animals. Several lines of evidence support this hypothesis. For instance, protein synthesis is required for a longer period following learning to establish long-term memory in aged rodents. Also, under some conditions, synaptic activity or pharmacological activation can induce de novo protein synthesis and lasting changes in synaptic transmission in aged, but not young, rodents; the opposite results can be observed in other conditions. These changes in plasticity likely play a role in manifesting the altered place field properties observed in awake and behaving aged rats. The collective evidence suggests a link between memory loss and the regulation of protein synthesis in senescence. In fact, pharmaceuticals that target the signaling pathways required for induction of protein synthesis have improved memory, synaptic plasticity, and place cell properties in aged animals. We suggest that a better understanding of the mechanisms that lead to different protein expression patterns in the neural circuits that change as a function of age will enable the development of more effective therapeutic treatments for memory loss.

Insights on eukaryotic translation initiation factor 5A (eIF5A) in the brain and aging

Long-term memory, a persistent form of synaptic plasticity, requires translation of a subset of mRNA present in neuronal dendrites during a short and critical period through a mechanism not yet fully elucidated. Western blotting analysis revealed a high content of eukaryotic translation initiation factor 5A (eIF5A) in the brain of neonatal rats, a period of intense neurogenesis rate, differentiation and synaptic establishment, when compared to adult rats. Immunohistochemistry analysis revealed that eIF5A is present in the whole brain of adult rats showing a variable content among the cells from different areas (e.g. cortex, hippocampus and cerebellum). A high content of eIF5A in the soma and dendrites of Purkinje cells, key neurons in the control of motor long-term memory in the cerebellum, was observed. Detection of high eIF5A content was revealed in dendritic varicosities of Purkinje cells. Evidence is presented herein that a reduction of eIF5A content is associated to brain aging.

Functional sex differences ('sexual diergism') of central nervous system cholinergic systems, vasopressin, and hypothalamic-pituitary-adrenal axis activity in mammals: a selective review

Sexual dimorphism of the mammalian central nervous system (CNS) has been widely documented. Morphological sex differences in brain areas underlie sex differences in function. To distinguish sex differences in physiological function from underlying sexual dimorphisms, we use the term, sexual diergism, to encompass differences in function between males and females. Whereas the influence of sex hormones on CNS morphological characteristics and function of the hypothalamic-pituitary-gonadal axis has been well-documented, little is known about sexual diergism of CNS control of the hypothalamic-pituitary-adrenal (HPA) axis. Many studies have been conducted on both men and women but have not reported comparisons between them, and many animal studies have used males or females, but not both. From a diergic standpoint, the CNS cholinergic system appears to be more responsive to stress and other stimuli in female than in male mammals; but from a dimorphic standpoint, it is anatomically larger, higher in cell density, and more stable with age in males than in females. Dimorphism often produces diergism, but age, hormones, environment and genetics contribute differentially. This review focuses on the sexual diergism of CNS cholinergic and vasopressinergic systems and their relationship to the HPA axis, with resulting implications for the study of behavior, disease, and therapeutics.

The influence of Cerebrolysin and E021 on spatial navigation of 24-month-old rats

In the present study the behavioural effects of Cerebrolysin (Cere), a peptidergic nootropic drug, and E021, the concentrated peptide fraction of Cere, were investigated in 24-month-old rats. Rats passing a pretest to exclude motor- and eye-deficits were treated with either drugs or saline as control (2.5 ml/kg, intraperitoneally i.p.) for 19 days. Animals were tested in a standard Morris water maze on day 16 after pretest for 4 consecutive days (test days 1-4), eight trials per day. No significant differences of escape latency between males and females were found, therefore, results were pooled. Both Cere and E021 treated rats showed significant lower escape latencies than saline treated controls on all four test days (p < 0.01). More pronounced effects of both drugs were found for female rats. Female rats showed no significant differences in motor activity whereas drug treated males swam quicker on test day 1 (Cere p < 0.01: E021 p < 0.05) and day 2 (Cere p < 0.01). In the present experiments it was demonstrated that i.p. administration of both Cere and E021 improves the spatial learning and memory of 24 month-old male and female rats.

The effect of ageing on RNA content in neurons from the thalamic reticular nucleus visual sector

In this paper we investigate nucleic acid content in neurons from the dorsocaudal region of the thalamic reticular nucleus in ageing Wistar rats. Nucleic acid per surface unit was analysed by calculating mean extinction using cytophotometric methods. Once the mean extinction and nuclear and cytoplasmic areas were known, nucleic acid total content was calculated. There was an increase in nucleic acid total content and in nuclear and cytoplasmic areas from the age of 3 months onwards. We interpreted these findings as a compensatory response, by 'neuronal hypertrophy', to the deterioration process occurring in the ageing rats. Between the 24th and 30th month, i.e. old age, nucleic acid per surface unit and total content in the cytoplasm exhibited a considerable decrease.

Comparative neurochemical and neurobehavioral effects of repeated chlorpyrifos exposures in young and adult rats

Neonatal (7 days old) rats are markedly more sensitive than adults (3 months old) to the acute toxic effects of the insecticide, chlorpyrifos (CPF). In the present study, we have compared the effects of subacute CPF exposures in these same age groups. Repeated doses of CPF (40 mg/kg, SC, every 4 days, total of 4 doses) caused extensive inhibition of cortical, hippocampal, and striatal cholinesterase (ChE) activity in adult rats at 4 (90-92%) and 14 (71-78%) days after the last treatment. Rats treated similarly during postnatal maturation (beginning on day 7) showed a much lower degree of ChE inhibition (21-60%) at these time points. Muscarinic ([3H]quinuclidinyl benzilate, QNB) receptor binding in cortex, hippocampus, and striatum was reduced in adult brain at 4 (30-43%) and 14 (22-32%) days after the final treatment, whereas receptor densities were only marginally affected (5-11% reduction) in young rats. Basal motor activity levels were not affected in either young or adult rats as a function of CPF exposure. CPF-treated adult rats exhibited higher activity levels after challenge with scopolamine (1 mg/kg, IP) at 2, 4, 6, and 8 weeks after treatment, whereas CPF exposure did not affect the motoric response to scopolamine in rats treated during postnatal maturation. These data suggest that although neonatal rats are more sensitive to acute lethal effects from high doses of CPF, adult rats exhibit more persistent neurochemical and neurobehavioral alterations following repeated, lower-level exposures.

Effect of hypoxia on protein composition of synaptic plasma membranes from cerebral cortex during aging

The effect of hypoxia on the protein composition of synaptic plasma membranes (SPM) isolated from cerebral cortex of rats at 4, 12, and 24 months of age was investigated. The proteins were separated by SDS polyacrylamide gel electrophoresis and the percent content was evaluated by measuring the optical density of the stained gels. After hypoxic treatment various proteins showed significant changes. Some proteins were only affected at 4 and 12 months of age and not at 24 months. The various modified proteins may be identified according to their molecular weight, as follows: the 18 kDa protein with calmodulin; the 23 kDa protein with D3 subunits; the 28 kDa protein could contain the delta subunit of the Ca2+ channel. The changes in the amount of some SPM proteins during hypoxia is consistent with the alteration in membrane polarization and neurotransmission observed in this condition. The effect of aging at the synaptosomal level seems to be a selective process; after hypoxia the age-related changes of many proteins are more pronounced.

Effect of hypoxia on mitochondrial protein composition of cerebral cortex during aging

The effect of hypoxia on the protein composition of mitochondria from cerebral cortex of rats at 4, 12, and 24 months of age was investigated. The proteins were separated by electrophoresis on SDS polyacrylamide gels and the percent content was evaluated by measuring the optical density of the stained gels. The results demonstrate that hypoxic treatment causes a decrease in the amount of some proteins as follows: the 90 and the 16 kDa Mw proteins at 4 months; the 82 and the 79 kDa Mw proteins at 24 months; the 52-49, 35 and 20 kDa at all ages investigated; the 44 kDa protein at 4 and 12 months and the 28 kDa protein at 4 and 24 months of age. Our results show that hypoxic conditions affect mitochondrial protein composition to a greater extent than aging alone.

Impaired recovery of brain muscarinic receptor sites following an adaptive down-regulation induced by repeated administration of diisopropyl fluorophosphate in aged rats

Potential age-related differences in the recovery rate of brain cholinesterase activity (ChE) and muscarinic acetylcholine receptor binding sites (mAChRs) following reduction induced by repeated treatment with diisopropyl fluorophosphate (DFP) were evaluated in Sprague-Dawley rats. Male 3- and 24-month old rats were s.c. injected with DFP (doses in mg/kg: first 1.1, two of 0.7 and four of 0.35) on alternate days for 2 weeks and killed 48 hr and 7, 14, 21, 28 and 35 days after the last treatment. In the hippocampus and striatum, but not in the cerebral cortex, of control rats there was a significant age-related decline of ChE activity and maximal density of 3H-QNB binding sites (Bmax). The repeated administration of DFP during the first week caused a syndrome of cholinergic stimulation both in aged and young rats. The syndrome was more pronounced, in terms of intensity and duration (for many hours after each injection), in aged than in young animals resulting in 40 and 12% mortality, respectively; during the second week the syndrome attenuated in the two age-groups. The percentage inhibition of brain ChE at the end of DFP treatment (about 70%) did not differ between young and surviving aged rats. The down-regulation of mAChRs (without changes in affinity) was present in the three brain regions of both young and aged rats (from 20 to 40%). Factorial analysis of variance (2 ages x 2 recoveries ANOVA) showed significant differences for age, recovery rate, and significant interaction between age and recovery rate, both for ChE and mAChRs in the three brain areas. For example, cortical ChE in young rats reached pretreatment levels within 3 weeks, while hippocampal and striatal ChE activity recovered within 4 weeks; at these intervals ChE activity in aged rats was still considerably reduced (except in the striatum). Cortical and striatal mAChRs in young rats almost normalized within 1 week and hippocampal mAChR binding sites normalized within 2 weeks; at these intervals Bmax in aged rats were markedly below control levels. The overall data indicate that the recovery rate to normal baseline levels of ChE activity and mAChRs, following the termination of repeated treatment with the antiChE agent, is impaired in brain of aged rats. The delay in recovery rate is particularly evident in the cerebral cortex.

Nuclear pore complex frequency in CA1 pyramidal cells of the aging rat

The frequency and the diameter of nuclear pore complexes, and the nuclear perimeter, were studied in CA1 pyramidal cells of the hippocampi from 3-, 9-, 24-, and 30-month-old rats (Fischer 344). No changes with age in any of these parameters were observed. This finding is discussed in terms of varied responses of different brain areas to the effects of aging.

Dissociation of learning and performance deficits in aged mice

The present study was undertaken to determine whether an age-related learning deficit would occur in a complex visual discrimination task and whether the learning impairment could be separated from performance deficits. The study also sought to determine whether treatment with an inhibitor of protein synthesis, anisomycin, would impair learning in this task. Two age groups (7-10 mo; 27-30 mo) of C56BL/6j mice were given training in a five-choice, simultaneous, visual discrimination task. Errors, freezing, avoidances, and response latencies were recorded. Results revealed that the difference in errors between the two groups disappeared during the middle part of training whereas the difference in the performance measures persisted until the end of training. Anisomycin caused increased errors in the adult but not the old mice. These results indicate that old mice can learn a discrimination task as well as adults but the rate of learning is slower, whereas their physical performance on the task is persistently inferior to adult mice.

Age-dependent modifications of mitochondrial proteins in cerebral cortex and striatum of rat brain

The protein composition of free mitochondria purified from cerebral cortex and striatum during aging was analyzed by gel electrophoresis. Mitochondria were isolated from cerebral cortex and striatum of 4-, 12-, and 24-month-old rat brain. The percent amount of mitochondrial proteins after gel-electrophoretic separation was determined densitometrically. A significant decrease in the amount of two polypeptides (with molecular weights of 20 and 16 kDa, respectively) in both brain regions during aging was found. The decrease was higher in the striatum indicating a greater vulnerability of this brain area to the aging process. The age-dependent modifications of mitochondrial proteins observed may play an important role in several mitochondrial functions, such as energy transduction and transport processes as well as in structural changes occurring with age, causing altered membrane permeability and fluidity.

Age-related changes of ribonuclease activities in various regions of the rat central nervous system

Acid (pH 5.5), free, and latent alkaline (pH 7.4) RNases were assayed in homogenates of temporal cortex, hypothalamus, hippocampus, and cervicothoracic segments of spinal cord of rats at three different ages (5, 14, and 25 months old). Free alkaline RNase activity was lower (two- to fivefold) than the acid activity. Both free and inhibitor-bound alkaline RNases remained unchanged with age in all CNS regions examined. This result also indirectly indicates no change of RNase-inhibitor complex throughout aging. In contrast, the acid RNase activity showed a significant increase during aging in all tissues, with exception of the hypothalamus. Because this enzyme is localized mainly in the lysosomes, this result might be due to an increased lysosomal activity and/or to the release of hydrolases into the cytoplasm from these organelles, undergoing shrinkage and degeneration in aged animals.

Protein synthesis rates in rat brain regions and subcellular fractions during aging

In vivo protein synthesis rates in various brain regions (cerebral cortex, cerebellum, hippocampus, hypothalamus, and striatum) of 4-, 12-, and 24-month-old rats were examined after injection of a flooding dose of labeled valine. The incorporation of labeled valine into proteins of mitochondrial, microsomal, and cytosolic fractions from cerebral cortex and cerebellum was also measured. At all ages examined, the incorporation rate was 0.5% per hour in cerebral cortex, cerebellum, hippocampus, and hypothalamus and 0.4% per hour in striatum. Of the subcellular fractions examined, the microsomal proteins were synthesized at the highest rate, followed by cytosolic and mitochondrial proteins. The results obtained indicate that the average synthesis rate of proteins in the various brain regions and subcellular fractions examined is fairly constant and is not significantly altered in the 4 to 24-month period of life of rats.

Muscarinic receptor plasticity in the brain of senescent rats: down-regulation after repeated administration of diisopropyl fluorophosphate

Potential age-related differences in the response of Fischer 344 rats to subchronic treatment with diisopropylfluorophosphate (DFP) were evaluated in terms of brain cholinesterase (ChE) inhibition and muscarinic receptor sites. Male 3- and 24-month old rats were sc injected with sublethal doses of DFP (first dose 1.6, subsequent doses 1.1 mg/kg on alternate days) for 2 weeks and killed 48 hrs after the last treatment. In the cerebral cortex, hippocampus and striatum of control rats a significant age-related reduction of ChE and of maximum number of 3H-QNB binding sites (Bmax) was observed. The administration of DFP to senescent rats resulted in more pronounced and longer lasting syndrome of cholinergic stimulation, with marked body weight loss and 60% mortality. The percentage inhibition of brain ChE induced by DFP (over 80% in all regions) did not differ between young and senescent rats. As expected, in young rats DFP caused a significant decrease of Bmax (without apparent changes in affinity), which in the cerebral cortex reached about 40%. In the surviving senescent rats, the percentage decrease of Bmax due to DFP with respect to age-matched controls was very similar to that of young animals, especially in the cerebral cortex. Thus, there is great variability in the response of aged rats to DFP treatment, from total failure of adaptive mechanisms resulting in death to considerable muscarinic receptor plasticity. The data support the view that the ability of central neurotransmitter systems to compensate for pathological or xenobiotic induced insult is an essential part of the aging process.

Absence of age differences in protein synthesis by rat brain, measured with an initiating cell-free system

A cell-free protein synthesis system was derived from brains of young (3 month) and old (greater than 23 month) male Fischer-344 rats in order to examine brain protein synthesis in relation to age. The system was shown to be capable of reinitiating protein synthesis in vitro, and of synthesizing protein from exogenously added mRNA. Optimal ionic conditions for amino acid incorporation were 200 mM potassium ion and 5 mM magnesium ion, and amino acid incorporation depended on addition of ATP, GTP, and an energy-generating system (creatine phosphate and creatine phosphokinase). Amino acid incorporation was sensitive to the initiation inhibitors aurintricarboxylic acid and sodium fluoride. Optimal conditions were independent of the age of the rat from which the brain was taken. There was no statistically significant relation (p greater than 0.05) between capacity of amino acid incorporation and age. The aggregation state of brain polyribosomes also did not differ between young (3 month) and old (30 month) rats. The results suggest that overall brain protein synthesis capacity is age-invariant in the rat.

Decreased transcription of neuronal polyadenylated RNA during senescence in nuclei from rat brain cortex

Neuronal and glial cell-enriched nuclei were prepared from the brain cortex of rats of different ages for study of alterations in the synthesis of cellular RNA with age. RNA synthesis by isolated neuronal nuclei was substantially reduced in senescent rats, whereas that of glial nuclei remained constant throughout development. The nuclear content of polyadenylic acid-containing RNA in neurons was particularly decreased in old rats. The results show that the activity of the chromatin-bound neuronal RNA polymerase declines during senescence, an observation indicating an age-related reduction in template activity in neuronal nuclei. The activity of nuclear poly(adenylate) polymerase also progressively decreases in aging neurons. The decrease in the transcription and polyadenylation of nuclear RNA may contribute to the decline in neuronal protein synthesis observed in old animals.

Preparation of a cell-free extract from rat brain which can initiate protein synthesis in vitro

A cell-free protein synthesis system, derived from brains of 3 mo-old male Fischer-344 rats, has been characterized. The optimum conditions for amino acid incorporation in the system were 5 mM magnesium ion and 200 mM potassium ion. Incorporation depended on the addition of ATP, GTP, and an energy-generating system, and was sensitive to addition of the drugs aurintricarboxylic acid and sodium fluoride, inhibitors of initiation of protein synthesis. Both 40S and 80S initiation complexes were labeled in vitro, using [35S]methionine. Such labeling was sensitive to the protein synthesis inhibitors, aurintricarboxylic acid and sodium fluoride. The system, which can initiate protein synthesis, should be of use for examining mechanisms which underlie alterations in rat brain protein synthesis induced by various treatments.

Age and sex-dependent decreases in ChAT in basal forebrain nuclei

Microdissection techniques were utilized to measure the activity of choline acetyltransferase (ChAT) (enzyme responsible for synthesis of acetylcholine) in individual basal forebrain nuclei of aged (24 month) and young (4 month) male and female rats. Small but consistent decreases in the activity of ChAT in aged rats were found, and the location of the changes was dependent on the sex of the rat. Aged female rats showed approximately 30% lower ChAT and 40% lower acetylcholinesterase (AChE) activity in the ventral globus pallidus (vGP). Aged males did not show decreased ChAT in the vGP but activity in the medial aspect of the horizontal diagonal band nucleus was 50% lower than in the young males. ChAT activity in four other closely aligned basal forebrain nuclei was not different between the young and aged rats. Analysis of cell number, density and area in the vGP by AChE histochemistry showed no significant differences between aged and young females. In addition, age and sex-dependent changes were measured in pituitary glucose-6-phosphate dehydrogenase activity. The relationship of the changes to age-dependent decrements in memory, the possible influence of gonadal hormones on aging, and the mechanisms responsible for age-related declines in ChAT activity are discussed.

Effects of dietary choline on memory and brain chemistry in aged mice

The purpose of this study was to investigate in more detail the characteristics of the age-related extension of the retrograde amnesia gradient previously demonstrated in a passive avoidance task [6]. In Experiment 1, it was found that while 2-3 month old mice were susceptible to the amnesic effects of anisomycin (ANI) only when given prior to 15 min post-training, memory of 14-16 month old mice was susceptible to disruption when ANI was given as late as 20 min post-training, and retention of 17-20 month old mice was impaired when ANI was injected even as late as 30 min after training. Experiment 2 examined whether the age-related change in susceptibility to the effects of ANI could be ameliorated by chronic pretreatment with a choline-enriched diet. Results showed that ANI injected 20 min after training did not induce amnesia in choline treated mice (14.5 month old), but did induce amnesia when injected 15 min post training. Subsequent assay of choline acetyltransferase (ChAT) and tyrosine hydroxylase (TH) activity showed that choline treatment significantly reduced ChAT activity but did not affect TH activity. It appears that dietary choline treatment can render new long-term memories less susceptible to disruption following training.

Brain catecholamine content and turnover in aging rats

The content and turnover of catecholamines were evaluated in various brain regions of young adult (4-months) and aged (24-months) male rats. Turnover was assessed from the concentrations of acid metabolites and the decline of catecholamine content after synthesis blockade with alpha-methyl-p-tyrosine. Dopamine was reduced by aging in striatum, mesolimbic areas, and hypothalamus. Dopamine metabolites and turnover rate were significantly lower in striatum and mesolimbic areas of aged than of young animals. Hypothalamic norepinephrine content and turnover rate were unchanged in aged compared to young rats but its metabolite (MHPG-SO4) was increased in the cortex. These findings point to an extensive impairment of brain dopamine metabolism in aging rats, whereas norepinephrine seems to be less impaired.

Modified composition of major ontogenetically regulated mRNAs and proteins in the cerebellum of old and of staggerer mice

The macromolecular composition of the cerebellum was examined in young and old mice, and in staggerer mutant mice, as compared with their background control strain. We examined the in vitro translation products of cerebellum mRNA, which reflect the biosynthetic potential of cell bodies endogenous to the cerebellum. Simultaneously, we examined the composition of the major cerebellum proteins, which includes the contribution of incoming fibers, in addition to the proteins composing cerebellar cells. Changes in the concentrations of various major proteins and a significant reduction in the translational efficiency of RNA were observed in the cerebellum of old BALB/c mice. This reduction probably does not reflect a specific damage to interneurons, since RNA from the cerebellum of 5-month-old staggerer mice was as efficient in translation in vitro as RNA from the cerebellum of mice from C57B6J normal background strain. Several of the major cerebellar proteins were identified by 2-dimensional gel electrophoresis. Changes were observed at the level of and the microheterogeneity of tubulin from the cerebellum of old, as compared with young mice. The aging-related modifications in cerebellar tubulin may be regulated at the level of mRNA, since mRNA from the cerebellum of old mice appeared to produce lower amounts of a polypeptide band co-migrating with tubulin. When compared with translation products directed by mRNA from normal cerebellum, most of the major identified polypeptides produced by mRNA from staggerer cerebellum showed marked differences in their relative intensity. Thus, this mutation appears to change the composition of cerebellar mRNA. These differences were analyzed together with previously obtained data on the composition of translation products during development of normal and of irradiation-agranulated cerebellum. The combined analysis of cerebellar mRNA products permits us to tentatively assign defined protein markers to specific cerebellar cell types and periods in development.

Age related changes in blood-to-brain amino acid transport and incorporation into brain protein

Blood-to-brain amino acid transport consists of at least two components: 1. a fast rate or early process, commonly measured by the intra-carotid bolus injection method and attributed to transport across the capillary endothelium and entry into the astrocytes, and, 2. a slow rate or later component measured over 2 to 15 minutes probably associated with exit from the astrocytes and entry into the neurons. Incorporation into brain protein is temporally related to the second process. In the present study the slow and fast rate transport components and the incorporation into brain protein of tyrosine (Tyr) and Valine (Val) was measured in young adult and aged male C57BL/6 mice. The results indicate that the fast rate transport component is unaffected by age while the rates of the slow process and protein turnover show an exponential decline most marked between 3 and 8 months of age. Changes in the relative incorporation of Tyr and Val suggest that brain protein metabolism is altered qualitatively as well as quantitatively in aging, in these animals.

Memory retention in old rats: improvement by orotic acid

The effect of methylglucamine orotate (MGO) on learning and memory was investigated in 24-month-old rats using brightness discrimination in a Y-chamber and active avoidance in a shuttle box. In both learning procedures, an improvement of memory retention following 5-day MGO treatment (225 mg/kg per day) was observed. The retention of untreated old animals was significantly lower compared to 8-week-old rats. MGO treatment resulted in a significant improvement of retention in old rats, which nearly compensated for their memory deficit.

Poly(adenylate) polymerase activity of rat brain

The poly(adenylate)[poly(A)] polymerase of rat brain, as in rat liver, is located primarily in the nuclear sap when nuclei are prepared under hypertonic conditions. The enzyme can be released from nuclei in two forms. Form I is prepared by gentle incubation of nuclei at 0 degrees C in hypotonic buffer. It has a Mn optimum of 0.6 mM and a pH optimum between 8 and 9. The ATP concentration curve plateaus at 0.2 mM. The optimal poly(A) primer concentration is 600 micrograms/ml, which is three times higher than that for the enzyme similarly prepared from liver. The time course of the reaction for the form I enzyme is increasing over the first 40 min and becomes nearly linear thereafter. Form I is not stimulated by either calcium or cyclic nucleotides, but is inhibited by polyamines, pyrophosphate, and high concentrations of GTP. Form II enzyme is prepared by homogenization of nuclei in hypotonic buffer. It has the same ATP and poly(A) optima as the form I enzyme but displays linear kinetics over a 60-min time course. It is slightly stimulated by cGMP and cAMP and strongly inhibited by spermine, sodium pyrophosphate, and high concentrations of GTP.

Variations in gene expression during development of the rat cerebellum

Prominent variations in the concentration and composition of poly (A)-containing messenger RNA were found to occur during the postnatal development of the rat cerebellum. The concentration of mRNA (microgram/g cerebellar tissue) was determined to be the highest on the tenth postnatal day, at the onset of synaptogenesis. Short non-abundant mRNA chains continuously increase in amount during cerebellar development, while the fraction of long translatable mRNAs decreases. The overall ability of cerebellar mRNA to stimulate the incorporation of [35S]methionine into polypeptides in reticulocyte lysate apparently does not change. The proteins synthesized in vitro by cerebellar mRNA from different developmental stages were therefore analyzed by single and 2-dimensional gel electrophoresis. The diversity of these proteins and the levels of many of them were found to vary with cerebellar development. The newly synthesized brain forms of enolase and creatine kinase were identified by their migration coordinates in the 2-dimensional protein gels, and increase in the abundance of their directing mRNAs was found to accompany the differentiation of cerebellar interneurons. The extent of modification in cerebellar mRNA was determined to be much higher than the consequent changes in the composition of cerebellar proteins. We propose to use the ontogenetic variations in the levels of specific cerebellar mRNA species in normal and malformed cerebellum to identify proteins specific to particular types of cerebellar neurons.