Michael McKinney

Markers for biogenic amines in the aged rat brain: Relationship to decline in spatial learning ability

The major goal of the study was to evaluate the relationship of brain aging to individual differences in functional decline in rats. Forebrain choline-acetyltransferase (ChAT) and monoamines, including their metabolites, were examined in young and aged male Long-Evans rats in relation to their spatial learning ability. Aged rats that were unimpaired on a spatial learning task exhibited few changes in neurochemistry relative to the young group: each change in this subgroup was also evident in the remaining aged animals that were behaviorally impaired. Additional changes in neurochemical measures only found in the behaviorally impaired aged animals included decreased ChAT in the basal forebrain, striatum, and frontal cortex. A cluster analysis using the 15 neurochemical measures that were sensitive to aging yielded groupings of aged animals that differed with respect to their spatial learning ability, but not in their cue learning latencies. In this analysis the activity of ChAT in the basal forebrain and striatum appeared to be the best predictors of spatial learning impairment.

Nitric oxide synthase gene expression in cholinergic neurons in the rat brain examined by combined immunocytochemistry and in situ hybridization histochemistry.

The expression of mRNA for the calmodulin-dependent form of brain nitric oxide synthase (NOS) was examined in cholinergic cells of the rat brain using a method combining in situ hybridization histochemistry with immunocytochemistry for choline acetyltransferase (ChAT) in the same brain sections. We constructed a riboprobe specific for brain NOS by subcloning a 493 bp fragment of the coding region which displayed low homology to other forms of NOS. The general distribution of NOS mRNA was in excellent agreement with previous studies using the full-length probe or NADPH diaphorase histochemistry. NOS mRNA was observed in many brain structures and relative levels were quantitated using grain counting procedures in a number of cholinergic and non-cholinergic neuronal groups throughout the brain. In the forebrain, ChAT-immunoreactive cells or cell groups were observed in medial septum (MS), vertical limbs of diagonal band (DBV) and horizontal limbs of diagonal band (DBH), nucleus basalis magnocellularis (NBM), substantia innominata (SI), and striatum (ST). In the brainstem, the cholinergic groups studied included those located in the pedunculopontine tegmental nucleus (PPTN), the laterodorsal tegmental nucleus (LDTN), the nucleus parabigeminalis and several motor nuclei. For NOS mRNA quantitation, silver grains overlying ChAT-stained neuronal profiles in sections on emulsion-dipped slides were counted digitally. In the LDTN and PPTN, virtually all the ChAT-positive cells expressed NOS mRNA at high levels. In MS, DBV and SI, about 30-50% of the ChAT-positive cells expressed NOS mRNA at low-to-moderate levels. Less than 20% of ChAT-positive neurons in the other cholinergic populations studied expressed NOS mRNA; the NBM was one of these low-expressing populations. Many scattered non-cholinergic cells expressing NOS mRNA were found in the striatum and cerebral cortex. In other non-cholinergic regions, high NOS mRNA expression was observed in the islands of Calleja, thalamic and hypothalamic nuclei, several amygdaloid nuclei, regions related to the optic tract, the interpeduncular nucleus, and the supramammillary nucleus. The heterogeneous distribution of NOS mRNA implies complex roles for nitric oxide neurotransmission in brain function, including for the cholinergic phenotype. Additionally, given the postulated involvement of nitric oxide in neurodegeneration, the widely varying levels of expression of NOS within identified central cholinergic neurons may relate to differential vulnerability of this phenotype in disease or aging.

No loss of synaptic proteins in the hippocampus of aged, behaviorally impaired rats.

The levels of three different synaptic proteins in the hippocampus of young (6 months of age) and aged (26-27 months of age) Long Evans rats were examined using quantitative Western blotting. An important feature to this study is that prior to the neurobiological analysis, hippocampal function was determined by assessing spatial learning ability in the Morris water maze. A subset of the aged rats was impaired on the learning task while the remaining aged cohort performed within the range of young rats. The amount of immunoreactivity for synaptophysin, synaptotagmin, and synaptosomal associated protein-25 did not differ between the young and aged rats. In addition, the aged rats with severe cognitive impairment had levels of these synaptic proteins that were similar to those of the aged rats with preserved cognitive function. This finding of no change in the levels of synaptic proteins suggests that substantial synapse loss in the hippocampal formation does not underlie cognitive decline in normal aging.Until recently, the most widely used indicator of nonresponse bias was the response rate. It was apparent to most survey researchers that the response rate was an inadequate indicator of bias. This was clear, for example, from a commonly cited expression for the nonresponse bias in a mean or proportion (e.g., Lessler and Kalsbeek 1992): Eð yr 2 ynÞ 1⁄4 YR 2 1⁄2ð1 2 PÞ YN þ P YR 1⁄4 ð1 2 PÞð YR 2 YNÞ yr 1⁄4 Xr

Septo-hippocampal cholinergic and neurotrophin markers in age-induced cognitive decline

Messenger RNA (mRNA) molecules encoding proteins related to the presynaptic cholinergic and neurotrophin systems were quantitated in the hippocampus and basal forebrain of Long-Evans rats with spatial learning ability assessed in the Morris water maze. The reverse transcriptase-polymerase chain reaction showed that the mRNAs for the low-affinity neurotrophin receptor (p75-NTR) and the growth-associated protein GAP-43 were decreased in level in the basal forebrain of aged-impaired rats. In the hippocampus of these aged-impaired rats, the mRNA for VGF, another neurotrophin-inducible gene, also was decreased. In situ hybridization histochemistry revealed that mRNAs for nerve growth factor (NGF) and brain-derived neurotrophic factor increased in level in the aged rat hippocampus; when age effects were removed, NGF mRNA level remained significantly correlated with maze performance. Enzyme-linked immunosorbent assay indicated that NGF protein was expressed at normal levels in the aged rat hippocampus. These mRNA and protein alterations may signify that a defect in neurotrophin signaling exists in the brains of aged Long-Evans rats, underlying reduced plasticity responses in the basal forebrain cholinergic system.

Survival and plasticity of basal forebrain cholinergic systems in mice transgenic for presenilin-1 and amyloid precursor protein mutant genes.

The basalo-cortical cholinergic system was characterized in mice expressing mutant human genes for presenilin-1 (PS1), amyloid precursor protein (APP), and combined PS/APP. Dual immunocytochemistry for ChAT and Aβ revealed swollen cholinergic processes within cortical plaques in both APP and PS/APP brains by 12 months, suggesting aberrant sprouting or redistribution of cholinergic processes in response to amyloid deposition. At 8 months, cortical and subcortical ChAT activity was normal (PS/APP) or elevated (PS, APP frontal cortex), while cholinergic cell counts (nBM/SI) and receptor binding were unchanged. ChAT mRNA was up-regulated in the nBM/SI of all three transgenic lines at 8 months. The data indicate that the basal forebrain cholinergic system does not degenerate in mice expressing AD-related transgenes, even in mice with extreme amyloid load. The PS1 or APP transgene appears to enhance the cholinergic phenotype in younger mice, but this involves aberrant sprouting and redistribution of cortical cholinergic processes.

Indicators of glial activation and brain oxidative stress after intraventricular infusion of endotoxin.

Glial activation and oxidative stress are both consequences of brain aging. To investigate whether glial activation causes oxidative stress or not, the immune activator, lipopolysaccharide (LPS), was intraventricularly injected into the rat brain. The expression of candidate genes were examined by in situ hybridization histochemistry (ISHH) combined with immunohistochemistry for glial markers over a period of time up to 24 h after the LPS injection. The mRNA for glial fibrillary acidic protein (GFAP) was elevated around the injection site by 2 h, and the volume of elevated expression spread to the entire brain after 6 h, with higher levels present in the injected hemisphere. The level of inducible isoform of nitric oxide synthase (i-NOS) mRNA increased in a punctate-like pattern in the region of the injection by 6 h and this response spread to the entire brain after 12 h. These results indicate that the glia are activated for at least 24 h after a single LPS injection. The mRNAs for a heat-shock protein (HSP70) and for the manganese-dependent superoxide dismutase (Mn-SOD) were elevated in the ipsilateral hemisphere as early as 2 h post-injection, but these responses subsided nearly to basal levels by 4 h. These levels of mRNAs for these genes increased again after 6 h of the LPS injection; thus, the earlier increases of the messages appeared to be associated with the survival surgery procedure. With microautoradiographic analysis, scattered OX-42 positive cells expressed i-NOS mRNA after 6 h post-injection, but elevation of Mn-SOD mRNA was not detected in either microglia or astrocytes at any time point examined. The level for Cu/Zn-SOD mRNA did not alter at any time point. The beta-amyloid precursor protein (betaAPP) mRNAs were elevated beginning at 6 h. These results indicate that chronic glial activation leads to a condition of oxidative stress in the brain. The data also suggest that LPS injection could be used to study the effects of chronic glial activation on the survival of neuronal populations that could be at risk from oxidative stress.

Topographic associations between DNA fragmentation and Alzheimer's disease neuropathology in the hippocampus

To identify whether the process of apoptosis bears a topographic relationship to selected aspects of Alzheimers disease (AD) pathology, we used an in situ nick translation method (TUNEL) to map DNA fragmentation in hippocampal sections immunostained for abnormally phosphorylated tau, which exists in the neurofibrillary tangles (NFTs) and in the dystrophic neurites associated with senile plaques. To ascertain associations of DNA fragmentation with glia, TUNEL was combined with immunohistochemistry for the astrocyte marker, glial fibrillary acidic protein (GFAP), or the microglial antigen OX-42. Consistent with previous reports, the incidence of putative DNA fragmentation detected by TUNEL was much higher in the AD brain, compared to non-demented subjects. While most TUNEL-positive cells did not exhibit any systematic topographic relationship to senile plaques, which were visualized by immunostain of abnormally phosphorylated tau for dystrophic neurites, DNA fragmentation was found frequently within cells containing NFTs. In hippocampal sections prepared to visualize glia, DNA fragmentation was not observed in GFAP-positive astrocytes, but some OX-42-positive microglia exhibited TUNEL signals. Other TUNEL-positive cells were found frequently in proximity to glia. The data suggest that cells compromised by the deposition of NFTs are prone to initiate the process of apoptosis. Furthermore, some glial populations appear to be apoptotic in the AD brain.

Hippocampal muscarinic receptor function in spatial learning-impaired aged rats

Efficiency of coupling of hippocampal muscarinic receptors to phosphoinositide (PI) turnover was investigated in behaviorally characterized young and aged Long-Evans rats using hippocampal minces and the method of partial receptor alkylation of Furchgott. Densities of the m1, m2, and m3 receptor proteins were determined using specific antibodies and immunoprecipitation. Spatial learning ability was quantified using a water maze. There were no differences in the levels of muscarinic receptor proteins between young and aged (27 months) rats or in rats with impaired spatial learning. The dissociation constant (KD) for the agonist oxotremorine-M and the KD/EC50 ratio, an indicator of receptor-effector coupling efficiency were similar in young and aged rats. However, the maximal PI turnover response to oxotremorine-M was decreased in impaired aged rats and this parameter was highly correlated with the spatial learning index (R = -0.825; p < 0.001). A reduction in effector stimulation in the absence of changes in receptor protein or coupling efficiency suggests that dysfunction in the hippocampal muscarinic receptor systems occurs at the level of phospholipase C or beyond.

Potencies and stereoselectivities of enantiomers of huperzine A for inhibition of rat cortical acetylcholinesterase

The stereoselectivities and mechanisms of the inhibition of rat cortical acetylcholinesterase by the enantiomers of huperzine A were determined. (-)-Huperzine A was the more potent enantiomer with a Ki value of 8 nM. (+)-Huperzine A inhibited the enzyme 38-fold less potently with a Ki value of 300 nM. Racemic huperzine A was about two-fold less potent than the more active isomer, (-)-huperzine A. The mechanism of inhibition of acetylcholinesterase for all three drugs was of the mixed linear competitive type.

Chapter 40: Muscarinic receptor subtype-specific coupling to second messengers in neuronal systems

Publisher Summary A major challenge in the study of muscarinic receptor function relates to the multiplicity of expression of isoforms of this receptor. However, research efforts in the past decade have defined the extent of this multiplicity, as well as provided clues as to the relative abundances of the members of this family within brain regions. One of the outcomes of cloning work is the finding of relatively selective coupling of these proteins to second messenger systems. Muscarinic effects are frequently described as “slow” in comparison with nicotinic effects mainly because their modulation of ion fluxes is indirect, being mediated by GTP-binding proteins and/or the formation of second messengers. The ion fluxes most often affected are those for the potassium and calcium ions. This chapter describes how functional coupling to effector systems has been used to reveal the probable identities of muscarinic receptor subtypes in regions of the brain involved in memory, control of voluntary motor function, or other important behaviors.