Prospects for research on the modulation of gene activity during brain aging

This brief review is concerned with prospects of the role of modulated gene expression in the brain during aging and in two age-related neurological diseases: Parkinson's and Alzheimer's diseases. Two key mechanisms involved in the disturbance of neuronal function during aging, i. e. deafferentation syndromes (as a result of the impairment of afferent influences) and steroid-induced neuronal changes, have been studied. The author suspects that many aspects of cell aging in the brain represent the influence of the environmental factors. The conception of new therapeutic approaches to the treatment of Alzheimer's disease has been developed.     

EEG correlation and impulse activity of neuronal populations of individual structures of the cat brain during elaboration and reproduction of motor and alimentary reactions in instrumental conditioned reflexes]

Stable changes in EEG and spike activity of neuronal populations in different brain formations were studied on models of instrumental conditioned reflexes: motor and motor alimentary. A depencence has been established of the EEG amplitude-frequency parameters in the motor and striate cortical zones and the hippocampus on definite changes of unit spike activity in these areas. Simultaneous recording of the EEG and the spike activity of neuronal populations helps to elucidate the neurophysiological nature of individual rhythms of bio-electrical activity. Learned animals exhibit a stable reproduction of the spatial-temporal EEG patterns and motor alimentary reactions when automatic presentation of reinforcement is changed over to an arbitrary one.     

Neurotrophins and the primate central nervous system: A minireview

The central nervous system (CNS) of primates is more complex than the CNS of other mammals. Details of the development and aging of the primate CNS have recently been revealed by various neurobiological techniques. It has become clear that the primate CNS has unique characteristics, for example, the capacity for the overproduction and elimination of fibers and synapses. Some differences have also been found in the distribution of and changes with development in levels of various neuroactive substances. Recent discoveries of a variety of neurotrophins in the mammalian CNS have led to research on the neurobiology of these molecules in the primate CNS. The distribution of and changes with development in levels of nerve growth factor (NGF) in the primate CNS are closely correlated with the cholinergic system of the basal forebrain. The administration of NGF into the monkey brain prevents the degeneration of the cholinergic neurons of the basal forebrain after axotomy, a result that suggests that neurotrophins might be very valuable agents for the future treatment of neurological diseases, such as Alzheimer's and Parkinson's diseases. This review is dedicted to Dr. Hans Thoenen.     

A look inside the diabetic brain: Contributors to diabetes-induced brain aging

Central nervous system (CNS) complications resulting from diabetes is a problem that is gaining more acceptance and attention. Recent evidence suggests morphological, electrophysiological and cognitive changes, often observed in the hippocampus, in diabetic individuals. Many of the CNS changes observed in diabetic patients and animal models of diabetes are reminiscent of the changes seen in normal aging. The central commonalities between diabetes-induced and age-related CNS changes have led to the theory of advanced brain aging in diabetic patients. This review summarizes the findings of the literature as they relate to the relationship between diabetes and dementia and discusses some of the potential contributors to diabetes-induced CNS impairments.     

Perspectives on MAO-B in aging and neurological disease

The catecholamine-oxidizing enzyme monoamine oxidase-B (MAO-B) has been hypothesized to be an important determining factor in the etiology of both normal aging and age-related neurological disorders such as Parkinson's disease (PD). Catalysis of substrate by the enzyme produces H2O2 which is a primary originator of oxidative stress which in turn can lead to cellular damage. MAO-B increases with age as does predisposition towards PD which has also been linked to increased oxidative stress. Inhibition of MAO-B, along with supplementation of lost dopamine via L-DOPA, is one of the major antiparkinsonian therapies currently in use. In this review, we address several factors contributing to a possible role for MAO-B in normal brain aging and neurological disease and also discuss the use of MAO-B inhibitors as drug therapy for these conditions.     

The effect of aging on brain barriers and the consequences for Alzheimer’s disease development

Life expectancy has increased in most developed countries, which has led to an increase in the proportion of elderly people in the world’s population. However, this increase in life expectancy is not accompanied by a lengthening of the health span since aging is characterized with progressive deterioration in cellular and organ functions. The brain is particularly vulnerable to disease, and this is reflected in the onset of age-related neurodegenerative diseases such as Alzheimer’s disease. Research shows that dysfunction of two barriers in the central nervous system (CNS), the blood–brain barrier (BBB) and the blood–cerebrospinal fluid (CSF) barrier (BCSFB), plays an important role in the progression of these neurodegenerative diseases. The BBB is formed by the endothelial cells of the blood capillaries, whereas the BCSFB is formed by the epithelial cells of the choroid plexus (CP), both of which are affected during aging. Here, we give an overview of how these barriers undergo changes during aging and in Alzheimer’s disease, thereby disturbing brain homeostasis. Studying these changes is needed in order to gain a better understanding of the mechanisms of aging at the brain barriers, which might lead to the development of new therapies to lengthen the health span (including mental health) and reduce the chances of developing Alzheimer’s disease.     

Changes in neuronal DNA content variation in the human brain during aging

The human brain has been proposed to represent a genetic mosaic, containing a small but constant number of neurons with an amount of DNA exceeding the diploid level that appear to be generated through various chromosome segregation defects initially. While a portion of these cells apparently die during development, neurons with abnormal chromosomal copy number have been identified in the mature brain. This genomic alteration might to lead to chromosomal instability affecting neuronal viability and could thus contribute to age-related mental disorders. Changes in the frequency of neurons with such structural genomic variation in the adult and aging brain, however, are unknown. Here, we quantified the frequency of neurons with a more than diploid DNA content in the cerebral cortex of normal human brain and analyzed its changes between the fourth and ninth decades of life. We applied a protocol of slide-based cytometry optimized for DNA quantification of single identified neurons, which allowed to analyze the DNA content of about 500 000 neurons for each brain. On average, 11.5% of cortical neurons showed DNA content above the diploid level. The frequency of neurons with this genomic alteration was highest at younger age and declined with age. Our results indicate that the genomic variation associated with DNA content exceeding the diploid level might compromise viability of these neurons in the aging brain and might thus contribute to susceptibilities for age-related CNS disorders. Alternatively, a potential selection bias of "healthy aging brains" needs to be considered, assuming that DNA content variation above a certain threshold associates with Alzheimer's disease.     

Specific features of the oscillatory brain activity during the final stage of creative problem solving in young and elderly subjects

The neurophysiological mechanisms underlying retention of creative potential during aging are still poorly studied. Previously, we have identified age-related changes in the temporal dynamics of brain activity and the speed of creative problem solving at its initial stage, suggesting that younger and older subjects used different strategies. These differences in strategies may also be observed at the final stage of problem solving. Therefore, we have studied the pattern of temporal changes in the EEG spectral characteristics (event-related spectral perturbation, ERSP) in younger (N = 89, 22.1 ± 3.2 years) and older (N = 90, 64.9 ± 6.7 years) age cohorts during 600 ms before the preparation to motor response, which indicates that solution is found. The general and ageand sex-related features of the oscillatory brain activity at the final stage of problem solving were revealed. All subjects displayed statistically significant EEG temporal dynamics associated with a reduction of power reactivity of rhythms prior to the response. The age-related differences included more pronounced ERSP frontal–parietal gradient in the θ frequency range and lower ERSP values in the β frequency range in elderly subjects as compared with the younger individuals. The most pronounced age-related differences in the β₁ rhythm were observed in the posterior cortex. The age-related differences in the α₃ frequency range were mediated by the sex factor: lateral differences were pronounced only in young men, and the coefficient of hemispheric asymmetry in this group differed significantly from that in older men and younger women. These data reflect the changes in EEG that were associated with the evaluation of creative idea, making a decision about completion of the search, and intention to make a motor response that indicates that solution is found.     

Accumulation of nuclear DNA damage or neuron loss: molecular basis for a new approach to understanding selective neuronal vulnerability in neurodegenerative diseases

According to a long-standing hypothesis, aging is mainly caused by accumulation of nuclear (n) DNA damage in differentiated cells such as neurons due to insufficient nDNA repair during lifetime. In line with this hypothesis it was until recently widely accepted that neuron loss is a general consequence of normal aging, explaining some degree of decline in brain function during aging. However, with the advent of more accurate procedures for counting neurons, it is currently widely accepted that there is widespread preservation of neuron numbers in the aging brain, and the changes that do occur are relatively specific to certain brain regions and types of neurons. Whether accumulation of nDNA damage and decline in nDNA repair is a general phenomenon in the aging brain or also shows cell-type specificity is, however, not known. It has not been possible to address this issue with the biochemical and molecular-biological methods available to study nDNA damage and nDNA repair. Rather, it was the introduction of autoradiographic methods to study quantitatively the relative amounts of nDNA damage (measured as nDNA single-strand breaks) and nDNA repair (measured as unscheduled DNA synthesis) on tissue sections that made it possible to address this question in a cell-type-specific manner under physiological conditions. The results of these studies revealed a formerly unknown inverse relationship between age-related accumulation of nDNA damage and age-related impairment in nDNA repair on the one hand, and the age-related, selective, loss of neurons on the other hand. This inverse relation may not only reflect a fundamental process of aging in the central nervous system but also provide the molecular basis for a new approach to understand the selective neuronal vulnerability in neurodegenerative diseases, particularly Alzheimer's disease.     

Time-course of mitochondrial gene expressions in mice brains: implications for mitochondrial dysfunction, oxidative damage, and cytochrome c in aging

The study of aging is critical for a better understanding of many age-related diseases. The free radical theory of aging, one of the prominent aging hypotheses, holds that during aging, increasing reactive oxygen species in mitochondria causes mutations in the mitochondrial DNA and damages mitochondrial components, resulting in senescence. Understanding a mitochondrial gene expression profile and its relationship to mitochondrial function becomes an important step in understanding aging. The objective of the present study was to determine mRNA expression of mitochondrial-encoded genes in brain slices from C57BL6 mice at four ages (2, 12, 18, and 24 months) and to determine how these altered mitochondrial genes influence age-related changes, including oxidative damage and cytochrome c in apoptosis. Using northern blot analysis, in situ hybridization, and immunofluorescence analyses, we analyzed changes in the expression of mitochondrial RNA encoding the mitochondrial genes, oxidative damage marker, 8-hydroxyguanosine (8-OHG), and cytochrome c in brain slices from the cortex of C57BL6 mice at each of the four ages. Our northern blot analysis revealed an increased expression of mitochondrial-encoded genes in complexes I, III, IV, and V of the respiratory chain in 12- and 18-month-old C57BL6 mice compared to 2-month-old mice, suggesting a compensatory mechanism that allows the production of proteins involved in the electron transport chain. In contrast to the up-regulation of mitochondrial genes in 12- and 18-month-old C57BL6 mice, mRNA expression in 24-month-old C57BL6 mice was decreased, suggesting that compensation maintained by the up-regulated genes cannot be sustained and that the down-regulation of expression results in the later stage of aging. Our in situ hybridization analyses of mitochondrial genes from the hippocampus and the cortex revealed that mitochondrial genes were over-expressed, suggesting that these brain areas are critical for mitochondrial functions. Our immunofluorescence analysis of 8-OHG and cytochrome c revealed increased 8-OHG and cytochrome c in 12-month-old C57BL6 mice, suggesting that age-related mitochondrial oxidative damage and apoptosis are associated with mitochondrial dysfunction. Our double-labeling analysis of in situ hybridization of ATPase 6 and our immunofluorescence analysis of 8-OHG suggest that specific neuronal populations undergo oxidative damage. Further, double-labeling analysis of in situ hybridization of ATPase 6 and immunofluorescence analysis of cytochrome c suggest cytochrome c release is related to mitochondrial dysfunction in the aging C57BL6 mouse brain. This study also suggests that these mitochondrial gene expression changes may relate to the role of mitochondrial dysfunction, oxidative damage, and cytochrome c in aging and in age-related diseases such as Alzheimer's disease and Parkinson's disease.     

Effects of estradiol and aging on fine manual performance in female rhesus monkeys

Aging is characterized by a progressive deterioration of motor function related to dysfunctions of the nigrostriatal system. Because estrogen has been reported to protect dopaminergic neurons and to improve the motor deficits associated with Parkinson's disease, we hypothesized that it would partially reverse the age-related decline of motor function in normal aging. We tested the effects of estrogen treatment and withdrawal on fine motor performance in five aged (21-24 years old) and five young (6-9 years old) ovariectomized female rhesus monkeys. The tests required the monkeys to use each hand to retrieve a Life Saver candy from metal rods bent in shapes of different complexity. Monkeys were tested twice a week for 8 consecutive weeks, during treatment with placebo or ethinyl estradiol (EE(2)) in alternating 14-day blocks. Each behavioral test was videotaped and subsequently scored for the duration and the success of the first trial on each shape. Both groups of monkeys improved rapidly with practice in speed and success of retrieval. The older monkeys were slower but as successful as the young monkeys in retrieving the candy. The left hand was faster than the right hand for both the aged and young females. We failed to detect any effect of EE(2) treatment on speed or success of retrieval in either group. These results confirm the slowing of fine motor performance with aging in female rhesus monkeys. They also indicate that estradiol, at least as administered in this study, does not benefit fine manual performance.     

Neurophysiological and Neuropsychological Indicators of the Efficiency of the Rehabilitation of Patients with Parkinsonism

This work experimentally showed the possibility of using neurophysiological and neuropsychological indicators of the efficiency of rehabilitation to better understand brain mechanisms of the syndrome and the compensation of deficiencies using a model of rehabilitation of motor and cognitive functions in patients with Parkinson's disease. A study paradigm was developed in three patients with a predominantly akinetic–rigid form of parkinsonism. The methods of the study included clinical neurological, neuropsychological, neurophysiological, and psychometric analyses. A positive correlation was found between clinical, psychometric, and neuropsychological measures, and a positive correlation between neurophysiological and neuropsychological measures was found only in the subject with the minimum dysfunction in this group, with the shortest period of illness, and predominantly right-hemispheric lateralization of the processes.     

Substantia nigra degeneration and tyrosine hydroxylase depletion caused by excess S-adenosylmethionine in the rat brain

The major symptoms of Parkinson's disease (PD) are tremors, hypokinesia, rigidity, and abnormal posture, caused by degeneration of dopamine (DA) neurons in the substantia nigra (SN) and deficiency of DA in the neostriatal dopaminergic terminals. Norepinephrine, serotonin, and melanin pigments are also decreased and cholinergic activity is increased. The cause of PD is unknown. Increased methylation reactions may play a role in the etiology of PD, because it has been observed recently that the CNS administration of S-adenosyl-l-methionine (SAM), the methyl donor, caused tremors, hypokinesia, and rigidity; symptoms that resemble those that occur in PD. Furthermore, many of the biochemical changes seen in PD resemble changes that could occur if SAM-dependent methylation reactions are increased in the brain, and interestingly,l-DOPA, the most effective drug used to treat PD, reacts avidly with SAM. So methylation may be important in PD; an idea that is of particular interest because methylation reactions increase in aging, the symptoms of PD are strikingly similar to the neurological and functional changes seen in advanced aging, and PD is age-related. For methylation to be regarded as important in PD it means that, along with its biochemical reactions and behavioral effects, increased methylation should also cause specific neuronal degeneration. To know this, the effects of an increase in methylation in the brain were studied by injecting SAM into the lateral ventricle of rats. The injection of SAM caused neuronal degeneration, noted by a loss of neurons, gliosis, and increased silver reactive fibers in the SN. The degeneration was accompanied with a decrease in SN tyrosine hydroxylase (TH) immunoreactivity, and degeneration of TH-containing fibers. At the injection site in the lateral ventricle it appears that SAM caused a weakening or dissolution of the intercellular substances; observed as a disruption of the ependymal cell layer and the adjacent caudate tissues. SAM may also cause brain atrophy; evidenced by the dilation of the cerebral ventricle. Most of the SAM-induced anatomical changes that were observed in the rat model are similar to the changes that occur in PD, which further support a role of SAM-dependent increased methylation in PD.     

Alterations of markers related to synaptic function in aging rat brain, in normal conditions or under conditions of long-term dietary manipulation

Neurochemical alterations of markers related to synaptic function are potential candidates for age-related impairment of brain function and cognition. The process of aging, including brain aging, can be counteracted to some degree by maintaning animals in long-term conditions of caloric restriction, or supplementing their diet with antioxidant substances. We report here that the age-related decline of the cholinergic and GABAergic systems, that takes place in some CNS regions of aged rats, is not affected by maintaining them under conditions of dietary restriction and, therefore, of reduced calorie intake, from the 12th to the 30th month of age. We also notice the same lack of effect by adding, during the same period, the aging rat diet with the potential antioxidant substance, N-acetylcysteine (NAC). The same dietary manipulations are also unable to counteract the derangement of the first step of the main biosynthetic pathway for polyamines, putative neuromodulators in the CNS, that occurs in the aged spinal cord. Some age-related alterations in the expression of different subunits of the NMDA-type glutamate receptors in some CNS regions of aged rats were instead, at least in some cases, counteracted by long-term dietary manipulation.     

Phenotypic and gene expression modification with normal brain aging in GFAP-positive astrocytes and neural stem cells

Astrocytes secrete growth factors that are both neuroprotective and supportive for the local environment. Identified by glial fibrillary acidic protein (GFAP) expression, astrocytes exhibit heterogeneity in morphology and in the expression of phenotypic markers and growth factors throughout different adult brain regions. In adult neurogenic niches, astrocytes secrete vascular endothelial growth factor (VEGF) and fibroblast growth factor-2 (FGF-2) within the neurogenic niche and are also a source of special GFAP-positive multipotent neural stem cells (NSCs). Normal aging is accompanied by a decline in CNS function and reduced neurogenesis. We asked whether a decreased availability of astrocyte-derived factors may contribute to the age-related decline in neurogenesis. Determining alterations of astrocytic activity in the aging brain is crucial for understanding CNS homeostasis in aging and for assessing appropriate therapeutic targets for an aging population. We found region-specific alterations in the gene expression of GFAP, VEGF, and FGF-2 and their receptors in the aged brain corresponding to changes in astrocytic reactivity, supporting astrocytic heterogeneity and demonstrating a differential aging effect. We found that GFAP-positive NSCs uniquely coexpress both VEGF and its key mitotic receptor Flk-1 in both young and aged hippocampus, indicating a possible autocrine/paracrine signaling mechanism. VEGF expression is lost once NSCs commit to a neuronal fate, but Flk-1-mediated sensitivity to VEGF signaling is maintained. We propose that age-related astrocytic changes result in reduced VEGF and FGF-2 signaling, which in turn limits NSC and progenitor cell maintenance and contributes to decreased neurogenesis.     

Age Related Changes in Metabolite Concentrations in the Normal Spinal Cord

Magnetic resonance spectroscopy (MRS) studies have previously described metabolite changes associated with aging of the healthy brain and provided insights into normal brain aging that can assist us in differentiating age-related changes from those associated with neurological disease. The present study investigates whether age-related changes in metabolite concentrations occur in the healthy cervical spinal cord. 25 healthy volunteers, aged 23–65 years, underwent conventional imaging and single-voxel MRS of the upper cervical cord using an optimised point resolved spectroscopy sequence on a 3T Achieva system. Metabolite concentrations normalised to unsuppressed water were quantified using LCModel and associations between age and spinal cord metabolite concentrations were examined using multiple regressions. A linear decline in total N-Acetyl-aspartate concentration (0.049 mmol/L lower per additional year of age, p = 0.010) and Glutamate-Glutamine concentration (0.054 mmol/L lower per additional year of age, p = 0.002) was seen within our sample age range, starting in the early twenties. The findings suggest that neuroaxonal loss and/or metabolic neuronal dysfunction, and decline in glutamate-glutamine neurotransmitter pool progress with aging.     

Stimulation on demand: closing the loop on deep brain stimulation

High-frequency open-loop deep brain stimulation (DBS) has been used to alleviate Parkinson's symptoms for almost 20 years. In this issue of Neuron, Rosin et?al. present a closed-loop real-time approach that improves DBS and shines light on the etiology of motor symptoms in Parkinson's disease.