Differential effects of aging on dendritic spines in visual cortex and prefrontal cortex of the rhesus monkey.

Aging decreases the density of spines and the proportion of thin spines in the non-human primate (NHP) dorsolateral prefrontal cortex (dlPFC). In this study, we used confocal imaging of dye-loaded neurons to expand upon previous results regarding the effects of aging on spine density and morphology in the NHP dlPFC and compared these results to the effects of aging on pyramidal neurons in the primary visual cortex (V1). We confirmed that spine density, and particularly the density of thin spines, decreased with age in the dlPFC of rhesus monkeys. Furthermore, the average head diameter of non-stubby spines in the dlPFC was a better predictor than chronological age of the number of trials required to reach criterion on both the delayed response test of visuospatial working memory and the delayed nonmatching-to-sample test of recognition memory. By contrast, total spine density was lower on neurons in V1 than in dlPFC, and neither total spine density, thin spine density, nor spine size in V1 was affected by aging. Our results highlight the importance and selective vulnerability of dlPFC thin spines for optimal prefrontal-mediated cognitive function. Understanding the nature of the selective vulnerability of dlPFC thin spines as compared to the resilience of thin spines in V1 may be a promising area of research in the quest to prevent or ameliorate age-related cognitive decline.

Alterations of white matter tracts following neurotoxic hippocampal lesions in macaque monkeys: a diffusion tensor imaging study.

Diffusion tensor imaging (DTI) is a valuable tool for assessing presumptive white matter alterations in human disease and animal models. The current study used DTI to examine the effects of selective neurotoxic lesions of the hippocampus on major white matter tracts and anatomically related brain regions in macaque monkeys. Two years postlesion, structural MRI, and DTI sequences were acquired for each subject. Volumetric assessment revealed a substantial reduction in the size of the hippocampus in experimental subjects, averaging 72% relative to controls, without apparent damage to adjacent regions. DTI images were processed to yield measures of fractional anisotropy (FA), apparent diffusion coefficient (ADC), parallel diffusivity (lADC), and perpendicular diffusivity (tADC), as well as directional color maps. To evaluate potential changes in major projection systems, a region of interest (ROI) analysis was conducted including the corpus callosum, fornix, temporal stem, cingulum bundle, ventromedial prefrontal white matter, and optic radiations. Lesion-related abnormalities in the integrity of the fiber tracts examined were limited to known hippocampal circuitry, including the fornix and ventromedial prefrontal white matter. These findings are consistent with the notion that hippocampal damage results in altered interactions with multiple memory-related brain regions, including portions of the prefrontal cortex.

Contribution of ovarian steroid production to urinary estrone conjugate concentrations in Macaca mulatta.

This study was designed to test the hypothesis that basal estrone conjugate (E1C) profiles do not accurately detect ovarian function when ovarian estrogen production is low or absent. We employed surgical removal of active ovaries from laboratory rhesus macaques to simulate an acute decline in ovarian estrogen production. In the first experiment, urine samples collected prior to and following ovariectomy (Ovx) were subjected to high-performance liquid chromatography (HPLC) separation. Eluates were then assayed for E1C immunoreactive components. The results indicated a modest decrease in total immunoreactive polar conjugates following ovariectomy, with no substantial change in the overall retention profile. In the second experiment, estradiol (E2) cypionate injections were used to replace the E2 component of ovarian estrogen production in the treated (Tx) group, while the control group (C) received only vehicle. Urine samples were hydrolyzed and individual estrogens were separated by celite chromatography prior to immuno-assay. Both the Tx and C groups exhibited similar urinary excretion levels of estrone (E1), E2, and E1C prior to Ovx (Pre-Ovx) and after Ovx (Post-Ovx), but there were significant differences between groups after treatment (Post-Tx). Significant differences were observed in the Tx group's excretion of E1, E2, and E1C in the Pre- vs. Post-Ovx samples and in the Post-Ovx and Post-Tx samples. The C group also showed the expected significant differences in the Pre- vs. Post-Ovx samples, as well as in the Pre-Ovx and Post-Tx samples. The results indicate that the use of E1C measurements is clearly a suitable method for monitoring ovarian function in intact, cycling animals, but urinary E2 measurements are required to verify loss of follicular activity.

Hippocampal dependent learning ability correlates with N-methyl-D-aspartate (NMDA) receptor levels in CA3 neurons of young and aged rats.

Hippocampal N-methyl-D-Aspartate (NMDA) receptors mediate mechanisms of cellular plasticity critical for spatial learning in rats. The present study examined the relationship between spatial learning and NMDA receptor expression in discrete neuronal populations, as well as the degree to which putative age-related changes in NMDA receptors are coupled to the effects of normal aging on spatial learning. Young and aged Long-Evans rats were tested in a Morris water maze task that depends on the integrity of the hippocampus. Levels of NR1, the obligatory subunit for a functional NMDA receptor, were subsequently quantified both biochemically by Western blot in whole homogenized hippocampus, and immunocytochemically by using a high-resolution confocal laser scanning microscopy method. The latter approach allowed comprehensive, regional analysis of discrete elements of excitatory hippocampal circuitry. Neither method revealed global changes, nor were there region-specific differences in hippocampal NR1 levels between young and aged animals. However, across all subjects, individual differences in spatial learning ability correlated with NR1 immunofluorescence levels selectively in CA3 neurons of the hippocampus. Parallel confocal microscopic analysis of the GluR2 subunit of the alpha-amino-3-hydroxy-5-methyl-4-isoxazole proprionic acid (AMPA) receptor failed to reveal reliable differences as a function of age or spatial learning ability. This analysis linking age, performance, and NR1 levels demonstrates that although dendritic NR1 is generally preserved in the aged rat hippocampus, levels of this receptor subunit in selective elements of hippocampal circuitry are linked to spatial learning. These findings suggest that NMDA receptor abundance in CA3 bears a critical relationship to learning mediated by the hippocampus throughout the life span.

Circuit-specific alterations in hippocampal synaptophysin immunoreactivity predict spatial learning impairment in aged rats.

The present study examined the long-standing concept that changes in hippocampal circuitry contribute to age-related learning impairment. Individual differences in spatial learning were documented in young and aged Long-Evans rats by using a hippocampal-dependent version of the Morris water maze. Postmortem analysis used a confocal laser-scanning microscopy method to quantify changes in immunofluorescence staining for the presynaptic vesicle glycoprotein, synaptophysin (SYN), in the principal relays of hippocampal circuitry. Comparisons based on chronological age alone failed to reveal a reliable difference in the intensity of SYN staining in any region that was examined. In contrast, aged subjects with spatial learning deficits displayed significant reductions in SYN immunoreactivity in CA3 lacunosum-moleculare (LM) relative to either young controls or age-matched rats with preserved learning. SYN intensity values for the latter groups were indistinguishable. In addition, individual differences in spatial learning capacity among the aged rats correlated with levels of SYN staining selectively in three regions: outer and middle portions of the dentate gyrus molecular layer and CA3-LM. The cross-sectional area of SYN labeling, by comparison, was not reliably affected in relation cognitive status. These findings are the first to demonstrate that a circuit-specific pattern of variability in the connectional organization of the hippocampus is coupled to individual differences in the cognitive outcome of normal aging. The regional specificity of these effects suggests that a decline in the fidelity of input to the hippocampus from the entorhinal cortex may play a critical role.

Morphometric studies of the aged hippocampus: I. Volumetric analysis in behaviorally characterized rats.

The present investigation examined the structural integrity of the aged hippocampus by using computer-aided morphometry to quantify the volume of principal hippocampal circuits in young, mature adult, and aged Long-Evans rats. A key feature of the experimental design was that the status of hippocampal-dependent learning and memory was documented prior to histologic evaluation. The following regions, which were visualized by using Timm staining, were included in the analysis: 1) outer portions of the dentate gyrus molecular layer (OML) innervated by the lateral entorhinal cortex, 2) middle portions of the molecular layer (MML) that receive input from the medial entorhinal cortex, 3) the commissural/associational zone (IML) immediately adjacent to the granule cell layer, and 4) the hilus and mossy fiber projection to the CA3 pyramidal cell field (MF). To identify morphometric changes that emerge during the same segment of the life span as age-related learning impairment, analysis of the volumetric results focused on comparisons between the mature adult group and the aged group. Among the individual regions that were analyzed, age-related decreases in total volume were restricted to the MML. This effect, however, occurred against a background of other, subtle changes that, together, reflected substantial reorganization in the normal balance of hippocampal circuitry. Age-related decreases in the proportion of the molecular layer (ML) that comprises the MML were accompanied by a corresponding increase in relative IML volume. The ratio between the volumes of the MML and the MF also displayed significant age-related decline. Overall, aging affected septal levels of the hippocampus disproportionately, and, with the exception of MML/MF volume ratio, the temporal hippocampus was spared. Finally, the status of spatial learning among the aged animals correlated selectively with decreases in the MML/ML and MML/MF ratios. These results demonstrate that the effects of aging are regionally selective and circuit specific, and they suggest that connectional reorganization may contribute to age-related decline in the computational functions of the hippocampus.

Preservation of prefrontal cortical volume in behaviorally characterized aged macaque monkeys.

Normal aging is frequently accompanied by a decline in cognitive capacities supported by the prefrontal cortex. The principal aim of the present study was to determine whether these impairments are coupled to morphometric alterations affecting the volume of the prefrontal cortex in an established nonhuman primate model. A large sample of 19 young (4-11 years old) and 40 aged (20-32 years old) rhesus monkeys was tested using a delayed response procedure known to require the functional integrity of area 46 of the prefrontal cortex. Aged monkeys displayed robust delayed response deficits that were specifically related to the demands of testing on memory. Modern stereological methods were then used to estimate the total volume of area 46 and the volume of layer I in brains from 21 young and aged monkeys. Prefrontal cortex volume was entirely preserved in the aged monkeys as a group and among the subset of aged subjects that displayed the most severe behavioral impairment. These findings indicate that gross morphometric alterations affecting cortical volume are unlikely to account for age-related decline in the information processing capacities of area 46 in primates. Taken together, current evidence instead suggests that changes in the functional connectivity of critical cortical circuits may contribute to normal cognitive aging.

Cerebral glucose metabolism and memory in aged rhesus macaques.

Positron emission tomography and the glucose metabolic tracer [18F]fluorodeoxyglucose were used to evaluate the relationship between regional cerebral metabolic rates for glucose (rCMRglc), age, and performance on a delayed response (DR) test of memory in the aged monkey. Eleven aged animals, 21-26-years old, were included in the analysis. Regional CMRglc, normalized to values for the entire brain, were determined for the dorsal prefrontal cortex, orbitofrontal cortex, hippocampus, and temporal cortex. The aged animals exhibited significant DR deficits relative to a cohort of normal young monkeys. Variability in DR performance among the aged subjects was significantly correlated with relative hippocampal rCMRglc, and chronological age was a reliable predictor of orbitofrontal rCMRglc ratios. This pattern of results suggests that DR impairments in the aged monkey may partly reflect age-related dysfunction distributed among multiple limbic system structures that participate in normal learning and memory. Overall, the findings support the use of positron emission tomography in efforts to define the relationship between cognitive performance, age, and brain physiology in nonhuman primates.

Impaired spatial information processing in aged monkeys with preserved recognition memory.

Spatial information processing was examined in a non-human primate model of cognitive aging, using procedures formally similar to tasks designed for rats. The test apparatus was a large open field containing eight reward locations. Monkeys rapidly learned to visit each location once per trial, and probe manipulations confirmed that young animals navigated according to the distribution of cues surrounding the maze. In contrast, aged monkeys solved the task using a response sequencing strategy, independent of extramaze spatial information. Object recognition memory was normal in the aged group. The results reveal substantial correspondence in the cognitive effects of aging across rat and primate models, and they establish appropriate procedures for testing the long-standing proposal that the role of the hippocampus in normal spatial learning is similarly conserved.

Reproductive senescence predicts cognitive decline in aged female monkeys.

The present investigation provide evidences from a non-human primate model that naturally occurring menopause predicts a prominent signature of age-related cognitive decline. Young and aged rhesus monkeys were tested on a delayed response (DR) task known to the sensitive to aging, and reproductive status was evaluated according to menstrual cyclicity and urinary hormone profiles. Peri-/postmenopausal monkeys exhibited significant DR impairments relative to either age-matched premenopausal females, or young control subjects. In addition, markers of endocrine decline in the aged animals were selectively correlated with behavioral performance measures that distinguished premenopausal and peri-/postmenopausal monkeys. These results document that menopause is coupled to cognitive decline in the monkey, and they establish a valuable primate model for defining the effects of endocrine aging on brain and behavioral function.

The use of animal models to study the effects of aging on cognition.

This review addresses the importance of animal models for understanding the effects of normal aging on the brain and cognitive functions. First, studies of laboratory animals can help to distinguish between healthy aging and pathological conditions that may contribute to cognitive decline late in life. Second, research on individual differences in aging, a theme of interest in studies of elderly human beings, can be advanced by the experimental control afforded in the use of animal models. The review offers a neuropsychological framework to compare the effects of aging in human beings, monkeys, and rodents. We consider aging in relation to the role of the medial temporal lobe in memory, the information processing functions of the prefrontal cortex in the strategic use of memory, and the regulation of attention by distributed neural circuitry. We also provide an overview of the neurobiological effects of aging that may account for alterations in psychological functions.

Learning and memory for hierarchical relationships in the monkey: effects of aging.

Young and aged rhesus monkeys were tested on 2 versions of a transitive inference task measuring learning and memory for hierarchical relationships. Animals initially acquired 4 object discrimination problems arranged such that the relationship between the stimuli followed the hierarchy A > B > C > D > E. The second version of the task was similar but involved a series of 7 objects. Learning and memory for the hierarchical relationships were evaluated during probe trials in which novel pairs of nonadjacent items (e.g., B and D) were presented for a response. Standard task accuracy measures failed to distinguish young and aged subjects at any point in training. In contrast, response latency effects that are indicative of relational information processing in young monkeys were entirely absent in aged subjects. The findings highlight the value of a relational memory framework for establishing a detailed neuropsychological account of cognitive aging in the monkey.

Preserved neuron number in the hippocampus of aged rats with spatial learning deficits.

Hippocampal neuron loss is widely viewed as a hallmark of normal aging. Moreover, neuronal degeneration is thought to contribute directly to age-related deficits in learning and memory supported by the hippocampus. By taking advantage of improved methods for quantifying neuron number, the present study reports evidence challenging these long-standing concepts. The status of hippocampal-dependent spatial learning was evaluated in young and aged Long-Evans rats using the Morris water maze, and the total number of neurons in the principal cell layers of the dentate gyrus and hippocampus was quantified according to the optical fractionator technique. For each of the hippocampal fields, neuron number was preserved in the aged subjects as a group and in aged individuals with documented learning and memory deficits indicative of hippocampal dysfunction. The findings demonstrate that hippocampal neuronal degeneration is not an inevitable consequence of normal aging and that a loss of principal neurons in the hippocampus fails to account for age-related learning and memory impairment. The observed preservation of neuron number represents an essential foundation for identifying the neurobiological effects of hippocampal aging that account for cognitive decline.

Memory systems in normal and pathological aging.

Normal memory depends on a number of interdependent systems whose specialized contributions are dissociable at both cognitive and neurobiological levels of analysis. Guided by this multiple systems view of memory, this review provides a selective survey of recent studies on cognitive and neurobiological aging. Taken together, the results suggest that memory decline in human aging partly reflects a compromise of executive memory processes supported by frontal lobe regions of the brain, combined with a deterioration of explicit memory capacities supported by the hippocampal system. Defining how deficits in multiple memory systems interact to account for cognitive aging remains a significant challenge.

Individual differences in the cognitive and neurobiological consequences of normal aging.

Defining the neural basis of age-related cognitive dysfunction is a major goal of current research on aging. Compelling evidence from laboratory animals and humans indicates that aging does not inevitably lead to cognitive decline. Conducting neurobiological investigations in subjects that have previously undergone behavioral characterization has therefore emerged as a promising strategy for identifying those alterations in brain structure and function that are specifically associated with age-related cognitive impairment.

Cholinergic cell loss and hypertrophy in the medial septal nucleus of the behaviorally characterized aged rhesus monkey.

Quantitative studies were conducted to determine the number and size of cholinergic neurons in the medial septal nucleus of four aged (23-25 years old) and four young (10-12 years old) rhesus monkeys. All of the animals had been tested on an extensive battery of learning and memory tasks prior to these experiments. Two of the aged monkeys displayed a pattern of recognition memory deficits that resembled the effects of medial temporal lobe damage. The postmortem anatomical data were analyzed in relation to both the age and behavioral status of the animals. Across all rostrocaudal levels of the medial septal nucleus, there was a 19.3% decrease in the number of cholinergic neurons in the aged monkeys. The loss was regionally selective, however, and ranged from a low of 6.2% rostrally to 40.9% caudally. The degree of cell loss was similar in both memory-impaired and memory-unimpaired aged animals. Morphological analysis also revealed that the mean cross-sectional area of cholinergic neurons was significantly larger in the aged animals. At caudal levels, the increase in average cell size was at least partly due to a disproportionate loss of small to medium size neurons. At rostral levels of the medial septal nucleus, however, where there was minimal cell loss, a clear hypertrophy of cholinergic neurons was evident. Interestingly, the cell hypertrophy observed at these rostral levels was present only in brains from the behaviorally impaired aged monkeys. These findings represent the first morphological demonstration of alterations in cholinergic neurons in the aged nonhuman primate.(ABSTRACT TRUNCATED AT 250 WORDS)