Douglas L. Rosene

A cryoprotection method that facilitates cutting frozen sections of whole monkey brains for histological and histochemical processing without freezing artifact.

Cutting frozen sections of large (greater than 60 cc) blocks of monkey brain using the conventional procedures of infiltration with 30% sucrose as a cryoprotectant before freezing with pulverized dry ice often produces unacceptable levels of freezing artifact (FA) caused by displacement of tissue by ice crystals. Experiments investigating FA utilized perfusion-fixed brains from 46 monkeys and spanned combinations of cryoprotectants (glycerol, sucrose), freezing methods (dry ice or -75 degrees C isopentane), and fixatives (10% formalin, Karnovskys or Timms). The effects were evaluated by rating of FA severity in frozen sections of whole monkey brains. Minor FA appears as enlarged capillaries, more serious FA as large vacuoles, and both first appear midway between the periphery and center of the block. Stronger fixatives increased the severity of freezing artifact. The best method for eliminating FA was graded infiltration with up to 20% glycerol and 2% DMSO (in buffer or fixative), followed by rapid freezing in -75 degrees C isopentane. Although using a glycerol-DMSO infiltration before conventional freezing with pulverized dry ice or using conventional sucrose infiltration before freezing in isopentane gave better results than sucrose infiltration and dry-ice freezing, only the combination of glycerol-DMSO infiltration and freezing in isopentane produced consistently excellent results and virtually eliminated freezing artifact. To determine the effect of freezing with dry ice or isopentane on the rate of cooling in large blocks of CNS tissue, thermocouples were embedded in an 80-cc block of albumin-gelatin and frozen with the two methods. The rate of cooling (-3.5 degrees C/min) was twice as fast using isopentane.

β-Secretase Activity Increases with Aging in Human, Monkey, and Mouse Brain

Amyloid beta protein (A beta) accumulates in the brains of aging humans, amyloid precursor protein (APP) transgenic mouse lines, and rhesus monkeys. We tested the hypothesis that aging was associated with increased activity of the beta-site amyloid precursor protein cleaving enzyme (beta-secretase, BACE) in brain. We evaluated BACE activity, BACE protein, and formic acid-extractable A beta levels in cohorts of young (4 months old) and old (14 to 18 months old) nontransgenic mice (n = 16) and Tg2576 APP transgenic mice (n = 17), young (4.4 to 12.7 years old) and old (20.9 to 30.4 years old) rhesus monkeys (n = 17), and a wide age range (18 to 92 years old) of nondemented human brains (n = 25). Aging was associated with increased brain A beta levels in each cohort. Furthermore BACE activity increased significantly with age in mouse, monkey, and human brains, independent of brain region. BACE protein levels, however, were unchanged with age. BACE activity correlated with formic acid-extractable A beta levels in transgenic mouse, nontransgenic mouse, and human cortex, but not in monkey brain. These data suggest that an age-related increase of BACE activity contributes to the increased production and accumulation of brain A beta, and potentially predisposes to Alzheimers disease in humans.

Patterns of cognitive decline in aged rhesus monkeys.

Although cognitive decline has been well established as a consequence of aging in non-human primate models, the prevalence or frequency of impairment for specific age ranges has not been described. The first aim of this study was to estimate prevalence of cognitive impairment on each of the six tests of cognitive performance by comparing the performance of early-aged (19-23 years old), advanced-aged (24-28 years old), and oldest-aged (29+ years old) monkeys to that of young adults (< 15 years old). The second aim was to derive a single overall measure of cognitive performance to help classify behavioral function in our aged monkeys. Accordingly, we obtained performance measures for these age groups on six behavioral measures: (1) acquisition of the delayed non-matching-to-sample task (DNMS); (2) performance of the DNMS with a delay of 120 sec; (3) the spatial condition of the delayed recognition span test (DRST); (4) the color condition of the DRST; (5) spatial reversal learning; and (6) object reversal learning. Early-aged monkeys displayed prevalence rates of impairment significantly greater than zero on all tasks except the DRST-color. The highest prevalence of impairment was observed in this age group in a task measuring spatial memory (DRST). Significant trends toward progressively higher impairment rates in advanced-aged and oldest-aged monkeys were observed for DNMS-acquisition, DRST-color and spatial reversal learning tasks. A linear transformation of standardized scores on the six cognitive tests was derived by means of principal components analysis (PCA). The first PCA (PCA1) included data from 30 monkeys with available data on all six measures, and yielded a composite measure which declined linearly with increasing age (r = -0.74). A second PCA (PCA2) was performed on data from 53 monkeys for which three test scores (DNMS-acquisition, DNMS-120s delay, and DRST-spatial condition) were available. The composite score derived from this analysis was highly correlated (r = 0.93) with the composite score from PCA1, suggesting that a score based on only three tests may provide an adequate classification of global cognitive ability.

Increased microglial activation and protein nitration in white matter of the aging monkey

Activated microglia are important pathological features of a variety of neurological diseases, including the normal aging process of the brain. Here, we quantified the level of microglial activation in the aging rhesus monkey using antibodies to HLA-DR and inducible nitric oxide synthase (iNOS). We observed that 3 out of 5 white matter areas but only 1 of 4 cortical gray matter regions examined showed significant increases in two measures of activated microglia with age, indicating that diffuse white matter microglial activation without significant gray matter involvement occurs with age. Substantial levels of iNOS and 3-nitrotyrosine, a marker for peroxynitrite, increased diffusely throughout subcortical white matter with age, suggesting a potential role of nitric oxide in age-related white matter injury. In addition, we found that the density of activated microglia in the subcortical white matter of the cingulate gyrus and the corpus callosum was significantly elevated with cognitive impairment in elderly monkeys. This study suggests that microglial activation increases in white matter with age and that these increases may reflect the role of activated microglia in the general pathogenesis of normal brain aging.

Hippocampal formation lesions produce memory impairment in the rhesus monkey

There is much debate over the role of temporal lobe structures in the ability to learn and retain new information. To further assess the contributions of the hippocampal formation (HF), five rhesus monkeys received stereotactically placed ibotenic acid lesions of this region without involvement of surrounding ventromedial temporal cortices. After surgery, the animals were trained on two recognition memory tasks: the Delayed Non‐Match to Sample (DNMS) task, which tests the ability to remember specific trial unique stimuli, and the Delayed Recognition Span Task (DRST), which tests the ability to remember an increasing array of stimuli. Relative to normal control monkeys, those with HF lesions demonstrated significant impairments in both learning and memory stages of the DNMS task. Additionally, the HF group was significantly impaired on spatial, color, and object versions of the DRST. Contrary to suggestions that damage to the entorhinal and parahippocampal cortices is required to produce significant behavioral deficits in the monkey, these results demonstrate that selective damage to the HF is sufficient to produce impairments on tasks involving delayed recognition and memory load. This finding illustrates the importance of the HF in the acquisition and retention of new information. Hippocampus 1999;9:562–574.

Cerebellar Purkinje Cells are Reduced in a Subpopulation of Autistic Brains: A Stereological Experiment Using Calbindin-D28k

Although a decreased number of cerebellar Purkinje cells (PCs) in the autistic brain has been widely reported with a variety of qualitative and quantitative methods, the more accurate method of cell counting with modern stereology has not yet been employed. An additional possible problem with prior reports is the use of Nissl staining to identify the PCs, as this can miss cells due to staining irregularities. In the present study, PCs were immunostained for calbindin-D28k (CB), as this has been shown to be a more reliable marker for PCs than the Nissl stain, with more than 99% of the PCs immunopositive (Whitney, Kemper, Rosene, Bauman, Blatt, J Neurosci Methods 168:42–47, 2008). Using stereology and CB immunostaining, the density of PCs was determined in serial sections from a consistently defined area of the cerebellar hemisphere in four control and six autistic brains, with the density of PCs then correlated with the clinical severity of autism. Overall, there was no significant difference in the density of PCs between the autistic and control groups. However, three of six autistic brains had PC numbers that fell within the control range, whereas the remaining three autistic brains revealed a reduction compared with the control brains. These data demonstrate that a reduction in cerebellar PCs was not a consistent feature of these autistic brains and that it occurred without discernible correlation between their density and the clinical features or severity of autism.

Effects of aging on visual recognition memory in the rhesus monkey

As part of an effort to develop a primate model of human age-related memory dysfunction, performance by six rhesus monkeys 26 to 27 years of age was compared to that of six young adult monkeys (four to five years of age) on a trial unique delayed nonmatching to sample (DNMS) task. This task assesses the monkeys ability to identify a novel from a familiar stimulus over a delay and resembles closely clinical tests that are used to assess memory function in geriatric patients. The task was presented in three stages: acquisition, delays and lists. As a group, aged monkeys were impaired relative to the young adult group on all three conditions. However, within the aged group, individual cases of efficient performance were observed. Error analyses of item positions of the lists condition revealed the absence of enhanced performance for items presented at the end of a list by aged animals, suggesting an abnormal sensitivity to proactive interference. The finding of a recognition impairment with age is in parallel with studies of normal human aging and lends support to the notion that the rhesus monkey is a suitable animal model of human aging.

Executive system dysfunction in the aged monkey: Spatial and object reversal learning

As part of the effort to characterize age-related cognitive changes in executive system function in a nonhuman primate model of human aging, the performance of seven rhesus monkeys, 20 to 28 years of age, was compared to that of five young adult monkeys, 6 to 11 years of age, on spatial and object reversal tasks. No differences in performance were found between the two groups in the initial learning of either task. On spatial reversals, aged monkeys were impaired relative to young adults, but there was no difference in overall performance between the groups on object reversals. Central to this article, a perseverative tendency was noted in the aged group on both spatial and object reversal tasks. Changes in executive system dysfunction may represent an important aspect of age-related cognitive decline.

A direct projection from the perirhinal cortex (area 35) to the subiculum in the rat

An efferent projection from the perirhinal cortex (area 35) in the rat was studied using the anterograde transport of tritiated amino acids as well as horseradish peroxidase (HRP). Following injections of either tracer in either the dorsal or ventral parts of area 35, anterogradely transported label was observed in the molecular layer of the subiculum, adjacent prosubiculum and CAla. Regardless of the dorsoventral level of the injection, the label was most dense at mid-dorsoventral levels of the subiculum and decreased in density in both the septal and temporal directions. Small injections of the same tracers made into the surrounding entorhinal, ectorhinal or prepiriform cortices did not reproduce this pattern. While the entorhinal cortex is the main cortical source of afferent input to the molecular layer of the subiculum as well as the hippocampus and dentate gyrus, the perirhinal cortex appears to constitute a complementary cortical pathway for afferent input to the subiculum.

Recognition Memory Span in Rhesus Monkeys of Advanced Age

Assessment of recognition memory was performed on eight rhesus monkeys of advanced age (25 to 27 years of age) using the delayed recognition span test (DRST). Their performance was compared to that of five young adult animals (5 to 7 years of age) on two stimulus conditions of the DRST: spatial position and color. Both trial unique and repeating series were used for each of the two conditions. As a group, aged monkeys were impaired on both the spatial and color conditions of the DRST, achieving about two-thirds of the span of the young adult group in each condition. Error analyses revealed that monkeys in the aged group also produced more perseverative responses (i.e., displacing the previously correct disk) than did young adults. Together the findings suggest that monkeys of advanced age are impaired on tasks with memory loading demand characteristics.