Krystyna R. Isaacs

Exercise and the brain: angiogenesis in the adult rat cerebellum after vigorous physical activity and motor skill learning.

This study compared the morphology of cerebellar cortex in adult female rats exposed for 1 month to repetitive exercise, motor learning, or an inactive condition. In the exercise conditions, rats that were run on a treadmill or housed with access to a running wheel had a shorter diffusion distance from blood vessels in the molecular layer of the paramedian lobule when compared to rats housed individually or rats that participated in a motor skill learning task. Rats taught complex motor skills substantially increased the volume of the molecular layer per Purkinje neuron and increased blood vessel number sufficiently to maintain the diffusion distance. These results dissociate angiogenesis associated with increased neuropil volume (as seen in the motor learning group) from angiogenesis associated with increased metabolic demands (as seen in the exercise groups). While the volume fraction of mitochondria did not differ among groups, the mitochondrial volume fraction per Purkinje cell was significantly increased in the motor skill rats. This appears to parallel the previously reported increase in synapses and associated neuropil volume change.

LOSS OF PROTEINS REGULATING SYNAPTIC PLASTICITY IN NORMAL AGING OF THE HUMAN BRAIN AND IN ALZHEIMER DISEASE

Recent studies suggest that the cognitive impairment associated with normal aging is due to neuronal dysfunction rather than to loss of neurons or synapses. To characterize this dysfunction, molecular indices of neuronal function were quantified in autopsy samples of cerebral cortex. During normal aging, the most dramatic decline was found in levels of synaptic proteins involved in structural plasticity (remodeling) of axons and dendrites. Alzheimer disease, the most common cause of dementia in the elderly, was associated with an additional 81% decrease in levels of drebrin, a protein regulating postsynaptic plasticity. Disturbed mechanisms of plasticity may contribute to cognitive dysfunction during aging and in Alzheimer disease.

Synapse formation occurs in association with the induction of long-term potentiation in two-year-old rat hippocampus in vitro

Following induction of long-term potentiation in subfield CA1 of the hippocampal slice from 26-month-old rats, shaft synapse numbers increased by 44% and sessile spine synapses (synapses on stubby, headless spines) by 72%, with the more common mushroom-shaped spine synapses statistically unaltered. These effects are smaller than in prior work with young adults, whereas population spike amplitude changes were comparable to young adults. Reasons for the discrepancy are unclear, but the results confirm continuing capacity for induction of LTP in aged rats and indicate that substantial synaptogenic capacity also persists, but may be impaired, at these ages.

Mapping of the colocalization of calretinin and tyrosine hydroxylase in the rat substantia nigra and ventral tegmental area

The distribution of calretinin (CR), a calcium binding protein, was compared with that of tyrosine hydroxylase (TH), the rate-limiting enzyme in the synthesis of dopamine, throughout the rostrocaudal extent of the rat subsantia nigra (SN) and ventral tegmental area (VTA). After mapping the cells using double-labelling immunofluorescence, it was possible to distinguish three distinct cell types: cells immunoreactive for CR only, cells immunoreactive for TH only, and cells in which the two proteins were colocalized (CR+TH). Colocalized cells in rat brain sections comprised approximately 40–55% of the fluorescent labelled cells in the SN compacta, 30–40% in the VTA, and 55–80% in the SN lateralis. Colocalized cells in the SN reticulata were infrequent except in the more caudal sections where a majority of the TH-immunoreactive cells also contained CR. The percentage of CR cells that contained TH was approximately 80% in the SN compacta and averaged 65% in the VTA. Overall, the percentage of TH-immunoreactive cells which also contained CR was approximately 50% in the SN compacta and 45% in the VTA. These data reveal a significant degree of colocalization of CR in dopamine-producing cells of the SN and VTA and suggest the need for studies concerning the fate of these individual cell types following experimental manipulations.

Calretinin mRNA and immunoreactivity in the medullary reticular formation of the rat: colocalization with glutamate receptors

Calretinin-positive cells were identified in the medullary reticular formation of the rat by both immunohistochemistry and in situ hybridization histochemistry. In addition, double immunocytochemical labeling was used to examine the degree of colocalization of calretinin with GluR2/R3, GluR4 and GluR5-7 glutamate receptor subtypes. Results indicated regional variation in calretinin expression across reticular formation regions with the exception of the largest cells which were mostly calretinin-positive. Calretinin mRNA was particularly abundant in the parvocellular reticular nucleus. Most calretinin-immunoreactive cells also expressed at least one of the glutamate receptor subtypes examined with the exception of the smallest calretinin-positive cells of the parvocellular reticular formation which were generally not immunoreactive for any of the glutamate receptors examined. Calretinin immunoreactivity was colocalized with immunoreactivity for all three glutamate receptor subtypes examined in most of the large cells of the reticular formation. Immunoreactivity for the GluR4 antibody was least abundant in the reticular formation and GluR4 immunoreactive cells were least likely to co-express calretinin. These results suggest that calretinin and glutamate receptor antibodies may be used to identify specific subsets of reticular formation neurons.

Cerebellar volume decreases in the tottering mouse are specific to the molecular layer

The volume of the cerebellum as a whole and the volume of the molecular layer per Purkinje cell in adult tottering (tg/tg) and tottering/leaner (tg/tg(la)) mice were reduced when compared with normal age-matched wild type mice (+/+). No changes in the volume of the granule cell layer or white matter layer were detected, suggesting that the mutation effects were limited to the molecular layer of the cerebellum. The density of Purkinje cells and the total number of Purkinje cells did not vary between groups. The cerebellar and body weights were decreased in tg/tg and tg/tg(la) mice compared with +/+ mice.

Development of the Paramedian Lobule of the Cerebellum in Wild-Type and Tottering Mice

The mutant mouse tottering, (tg/tg), and the compound heterozygote mouse (tg/tg1a) exhibit three neurological disorders: ataxia, petit mal-like absence seizures and myoclonic intermittent movement disorders which are independent of the absence seizures. The tottering mouse carries an autosomal recessive single gene mutation on chromosome 8, and behavioral symptoms are first observed in the 3rd to 4th week of age. Using an additional genetic marker, Oligosyndactyly (Os), it is possible to distinguish tg/tg and tg/tg1a mice from wild-type mice at birth; nonaffected heterozygous littermates carry the Os mutation while tottering and compound heterozygous mice do not carry the Os gene. Similar to neurons found elsewhere in the brain, cerebellar Purkinje cells in both the wild-type and mutant mice were found to decrease in diameter with maturation. Forebrain weight, hindbrain weight, Purkinje cell dimensions and the thickness of the molecular layer in the paramedian lobule of the cerebellum in mutant mice were found to be reduced in mutants after, but not prior to the onset of behavioral symptoms.

Vulnerability to Calcium-Induced Neurotoxicity in Cultured Neurons Expressing Calretinin

Calretinin (CR) is a calcium-binding protein purported to have neuroprotective properties. This study was designed to characterize the types of neurons containing CR in two different primary cultures and to determine which, if any, CR-immunoreactive (CR-ir) neurons are resistant to excitotoxic insults. Calretinin-containing neurons in cortical primary cultures derived from E14 rat embryos were not resistant to either kainic acid or a brief calcium overload induced by the calcium ionophore A23187. Equal proportions of CR-ir and GABAergic cortical neurons were lost after a 24-h exposure to 100 or 500 microM kainic acid. A 3 microM, 3-h exposure to A23187 induced equivalent amounts of cell loss in both the total cell and CR-ir cortical neuron culture populations. Cortical cultures grown for 6-7 days were more vulnerable than 12- to 13-day-old cultures to short-term, low-concentration treatments of A23187. Older cultures, however, were more severely affected when examined 24 h after a 3-h exposure to A23187. Calretinin-immunoreactive neurons derived from the diencephalon were relatively more resistant than cortical neurons to kainic acid at 6-7 days in vitro. In cortical or diencephalic cultures, CR was rarely coexpressed with GABA or calbindin D-28k. No vasoactive intestinal peptide, substance P, or parvalbumin was detected in CR-ir neurons in either culture system. We suggest that the presence of CR alone is not sufficient to spare neurons from a toxic calcium overload. Calretinin may still buffer calcium at low concentrations or be a component in a calcium-based signal transduction system.

Differential effects of excitatory amino acids on mesencephalic neurons expressing either calretinin or tyrosine hydroxylase in primary cultures

In mesencephalic primary cultures derived from E14 rat embryos, calretinin- and tyrosine hydroxylase-immunoreactive neurons comprised 2% and 5% of the total cell population, respectively, at 6-7 days in vitro. The number of calretinin-immunoreactive neurons was unchanged after a 12- or 24-h exposure to 500 microM kainic acid (KA), but a 50% cell loss was detected after a 48-h exposure to KA. Tyrosine hydroxylase-immunoreactive neurons demonstrated a 50% and 67% cell loss at 24- and 48-h exposures to 500 microM KA. A 500 microM N-methyl-D-aspartic acid (NMDA) incubation for 24 h had no effect on calretinin-immunoreactive cell number, but did significantly reduce tyrosine hydroxylase-immunoreactive cell numbers by 26%. In tyrosine hydroxylase-immunoreactive cells, exposure to KA appeared to stimulate the retraction of the neuritic tree and to cause somatic swelling. In contrast, calretinin-immunoreactive neurons developed larger and more complex neuritic trees after a 24-h exposure to 500 microM KA but not NMDA. Immunohistochemical colocalization studies revealed that all tyrosine hydroxylase-immunoreactive and the majority of calretinin-immunoreactive neurons expressed the glutamate receptor subunits GluR2-R3. Very low levels of NMDAR1 receptor subunits were detected on cells in this culture and GluR4 receptor subunits were not detectable. Our experiments showed that glutamate receptors present in both calretinin- and tyrosine hydroxylase-immunoreactive cells were functional, since phosphorylated cAMP/Ca2+ response element-binding protein levels were increased in both cell types after 10 or 30 min exposures to 500 microM KA. The present results indicate that in the mesencephalic cultures tyrosine hydroxylase-immunoreactive cells are more vulnerable to KA excitotoxicity than calretinin-immunoreactive neurons.

Quadruple colocalization of calretinin, calcitonin gene-related peptide, vasoactive intestinal peptide, and substance P in fibers within the villi of the rat intestine

Double-labeling immunofluoresenct histochemistry demonstrates that calretinin, a calcium-binding protein, coexists with calcitonin gene-related peptide, vasoactive intestinal peptide, and substance P in the fibers innervating the lamina propria of the rat intestinal villi. An acetylcholinesterase histochemical stain revealed that the majority of calretinin-containing cells in the myenteric ganglia were cholinergic and that about one half of the submucosal calretinin-containing cells colocalized with acetylcholinesterase. In situ hybridization studies confirmed the presence of calretinin mRNA in the dorsal root ganglia, and a ribonuclease protection assay verified the presence of calretinin message in the intestine. The coexistence of calretinin in calcitonin-gene-related-peptide-containing cells that also contained substance P and vasoactive intestinal polypeptide in the dorsal root ganglia suggest that these ganglia are the source of the quadruple colocalization within the sensory fibers of the villi. Although the function of calretinin in these nerves is unknown, it is hypothesized that the coexistence of three potent vasodilatory peptides influences the uptake of metabolized food products within the vasculature of the villi.