Generation and Characterization of the First Murine Model of Alzheimer's Disease with Mutated AβPP Inserted in a BALB/c Background (C.B6/J-APPswe)

BACKGROUND

Numerous mouse models of Alzheimer's disease (AD) are available, but all suffer from certain limitations, thus prompting further attempts. To date, no one model exists with amyloidopathy in a BALB/c strain.

OBJECTIVE

To generate and characterize the C.B6/J-APPswe mouse, a model of AD with a mutated human gene for the amyloid-β protein precursor (AβPP) inserted in a BALB/c background.

METHODS

We analyzed five groups at different ages (3, 6, 9, 12, and 16-18 months) of C.B6/J-APPswe and wild-type mice (50% males and 50% females) for the main hallmarks of AD by western blotting, amyloid-β (Aβ) ELISA, immunocytochemistry, electrophysiology, and behavioral tests.

RESULTS

The C.B6/J-APPswe mouse displays early AβPP and Aβ production, late amyloid plaques formation, high level of tau phosphorylation, synaptic deficits (reduced density and functional impairment due to a reduced post-synaptic responsiveness), neurodegeneration caused by apoptosis and necroptosis/necrosis, microgliosis, astrocytic abnormalities, and sex-related differences in explorative behavior, anxiety-like behavior, and spatial long-term and working memories. Social housing is feasible despite the intra-cage aggressiveness of male animals.

CONCLUSION

C.B6/J-APPswe mice develop most of the distinctive features of AD and is a suitable model for the study of brain atrophy mechanisms and of the differences between males and females in the onset of cognitive/non-cognitive deficits.

The effect of astaxanthin on the aging rat brain: gender-related differences in modulating inflammation

BACKGROUND

Astaxanthin (Ax) is a ketocarotenoid of the xanthophyll family with activities such as antioxidation, preservation of the integrity of cell membranes and protection of the redox state and functional integrity of mitochondria. The aim of this study was to investigate potential gender-related differences in the effect of Ax on the aging rat brain.

RESULTS

In females, interleukin 1 beta (IL1β) was significantly lower in treated rats in both cerebral areas, and in the cerebellum, treated animals also had significantly higher IL10. In males, no differences were found in the cerebellum, but in the hippocampus, IL1β and IL10 were significantly higher in treated rats.

CONCLUSION

These are the first results to show gender-related differences in the effect of Ax on the aging brain, emphasizing the necessity to carefully analyze female and male peculiarities when the anti-aging potentialities of this ketocarotenoid are evaluated. The observations lead to the hypothesis that Ax exerts different anti-inflammatory effects in female and male brains.

Early selective vulnerability of synapses and synaptic mitochondria in the hippocampal CA1 region of the Tg2576 mouse model of Alzheimer's disease

Increasing experimental evidence indicates that synaptic alterations play a key role in cognitive decline in Alzheimer's disease (AD). Functional and structural synaptic changes progressively take place, beginning in the early phase of AD, mainly triggered by intracellular accumulation of soluble amyloid-β (Aβ) oligomers. These peptides also accumulate within mitochondria, heavily affecting their function and morphology, particularly in synaptic compartments. To better understand the role of mitochondrial impairment in synaptic alterations during the early stages of AD, a morphological investigation was performed by means of electron microscopy in the hippocampus of 3 month-old Tg2576 and transgene-negative littermate mice. In the stratum moleculare of CA1 pyramidal cells (SMCA1) of transgenic animals compared to controls, we found significantly larger and less numerous synapses, with a significantly reduced fraction of the perforated subtype, as well as significantly smaller and more numerous mitochondria. In contrast, no differences between the two groups of mice were found in the inner molecular layer of the dentate gyrus. The reduction of synaptic contacts in SMCA1 indicates a precocious vulnerability of this region, and the synaptic enlargement may reflect a compensating process aimed at maintaining the overall contact density. Accordingly, mitochondrial modifications may represent a plastic reactive phenomenon aimed at sustaining the increased energy needs for synaptic remodeling, since mitochondrial morphology was perfectly preserved and smaller mitochondria are metabolically more efficient. Thus, morphological changes occurring at synaptic level in SMCA1 of 3 month-old Tg2576 mice might reflect a precocious vulnerability associated with a residual plastic reactivity which may slow down functional alterations.

Platelets in Alzheimer's disease-associated cellular senescence and inflammation

Alzheimer's disease (AD) is a complex degenerative disorder of the brain, associated with a progressive cognitive decline. Age is the main risk factor with almost half of the population above 90 years affected by this pathology. AD and brain aging share common molecular changes, so it has been hypothesized that AD could be a form of accelerated brain aging. In this context, senescenceassociated mechanisms could be a valuable target of investigation both to analyze the causes of this disease and to define therapeutic strategies. Senescent phenotypes of glia and neurons, as well as of peripheral cells, have been described in AD. Much evidence indicate that vascular impairment is a fundamental contributor to AD pathology and platelets are generally considered a key element because they represent the link between amyloid-β (Aβ) deposition, peripheral inflammation and endothelial senescence. Both activated and senescent platelets are a source of Aβ, in addition activated platelets secrete many proinflammatory mediators that could contribute to increased peripheral inflammation and endothelial senescence. Treatments aimed to target peripheral endothelial senescence include antioxidants and some substances, such as aspirin, that modulate platelet aggregation and inflammatory response. Heparin has been proposed as a treatment for senile dementia and exhibits anti-inflammatory action as well as inhibitory effects on Aβ assembly. Identifying peripheral targets for AD treatments could also result advantageous as it would be possible to monitor directly their efficacy. Nevertheless more research is needed to clarify all the different aspects and interactions of blood cells, vascular cells and their secretory products.

Peripheral inflammatory biomarkers of Alzheimer's disease: the role of platelets

Alzheimer's disease is an age-dependent neurodegenerative disorder characterized by loss of neurons, synaptic degeneration, senile plaques and neurofibrillary tangles. Besides these hallmarks, increased accumulation of activated microglia, astrocytes and leukocytes adhering to postcapillary venules are observed in the affected brain areas, suggesting the presence of an ongoing inflammatory process. As neuroinflammation triggers the activation of peripheral immune system, many studies have analyzed circulating inflammatory biomarkers, including basal or stimulated levels of cytokines and related molecules in blood of Alzheimer's patients, but with conflicting results. Platelets are an important source of amyloid-ss (Ass) in the circulatory system and play an important pro-inflammatory role. Upon activation, they adhere to leukocytes and endothelial cells by means of adhesive proteins like P-selectin, platelet endothelial cell adhesion molecule-1 (PECAM) and intercellular adhesion molecule-1 and -2 (ICAM-1 and -2) and secrete inflammatory mediators (chemokines, interleukins). In addition, platelets contain important enzymes involved in inflammatory intermediary synthesis like phospholipase A(2) (PLA(2)) and cyclooxygenase-2 (COX-2), and recent reports demonstrated significant changes in platelet levels and activities in Alzheimer's disease. Thus, as platelets represent an important link between Ass deposition and inflammatory reactions especially at endothelial level, they can be considered a valuable cellular model to evaluate potential peripheral inflammatory biomarkers in Alzheimer's disease.

Ketogenic diets cause opposing changes in synaptic morphology in CA1 hippocampus and dentate gyrus of late-adult rats

Ketogenic diets (KDs) have beneficial effects on several diseases, such as epilepsy, mitochondriopathies, cancer, and neurodegeneration. However, little is known about their effects on aging individuals. In the present study, late-adult (19-month-old) rats were fed for 8 weeks with two medium chain triglycerides (MCT)-KDs, and the following morphologic parameters reflecting synaptic plasticity were evaluated in stratum moleculare of hippocampal CA1 region (SM CA1) and outer molecular layer of hippocampal dentate gyrus (OML DG): average area (S), numeric density (Nv(s)), and surface density (Sv) of synapses, and average volume (V), numeric density (Nv(m)), and volume density (Vv) of synaptic mitochondria. In SM CA1, MCT-KDs induced the early appearance of the morphologic patterns typical of old animals (higher S and V, and lower Nv(s) and Nv(m)). On the contrary, in OML DG, Sv and Vv of MCT-KDs-fed rats were higher (as a result of higher Nv(s) and Nv(m)) versus controls; these modifications are known to improve synaptic function and metabolic supply. The opposite effects of MCT-KDs might reflect the different susceptibility to aging processes: OML DG is less vulnerable than SM CA1, and the reactivation of ketone bodies uptake and catabolism might occur more efficiently in this region, allowing the exploitation of their peculiar metabolic properties. Present findings provide the first evidence that MCT-KDs may cause opposite morphologic modifications, being potentially harmful for SM CA1 and potentially advantageous for OML DG. This implies risks but also promising potentialities for their therapeutic use during aging.

Reactive structural dynamics of synaptic mitochondria in ischemic delayed neuronal death

The effect of transient global ischemia on the ultrastructural features of synaptic mitochondria at the distal dendrites of CA1 hippocampal neurons was investigated in 3-month-old rats. Sham surgery was performed on age-matched controls. The number of mitochondria/microm3 of neurophils (Nv: numeric density), the mitochondrial average size (average volume: V), and longer diameter (Fmax) as well as the overall fraction of neurophils occupied by mitochondria (volume density: Vv) were measured by computer-assisted morphometry. In ischemic rats, a 10% nonsignificant decrease of Nv was found, V increased nonsignificantly by 11%, and Fmax increased nonsignificantly by 5% versus controls. As a final outcome of these balanced changes, Vv remained unchanged between the two experimental groups investigated. In ischemic animals, the percentage distribution of V showed that the population of CA1 synaptic mitochondria was composed by an increased fraction of oversized organelles, while the Fmax distribution revealed that this enlargement was due to an increased percentage of elongated organelles. Thus, the observed increase in size should not be considered as a swelling phenomenon; on the contrary, it may represent a physiological and well-documented step in mitochondrial biogenesis. The above parameters are currently supposed to provide information on the adaptive structural reorganization of mitochondrial morphology under different environmental stimulations. Conceivably, these findings document a positive reactive response to ischemia of the mitochondrial structural dynamics at CA1 synaptic terminals and suggest consideration of these organelles as reliable targets in the development of neuroprotective therapeutic interventions to treat vascular brain diseases, for example, stroke.

Experimental Apoptosis Provides Clues about the Role of Mitochondrial Changes in Neuronal Death

A quantitative morphometric study has been carried out in human neuroblastoma SK-N-BE cells to evaluate the ultrastructural features and the metabolic efficiency of mitochondria involved in the early steps of apoptosis. In mitochondria from control and apoptotic cells cytochrome oxidase (COX) activity was estimated by preferential cytochemistry. Number of mitochondria (numeric density: Nv), volume fraction occupied by mitochondria/microm3 of cytoplasm (volume density: Vv), and average mitochondrial volume (V) were calculated for both COX-positive and -negative organelles. The ratio (R) of the cytochemical precipitate area to the overall area of each mitochondrion was evaluated on COX-positive organelles to estimate the inner mitochondrial membrane fraction actively involved in cellular respiration. Following apoptotic stimulus, the whole mitochondrial population showed a significant increase of Nv and Vv, while V was significantly decreased. In COX-positive organelles higher values of Nv were found, V appeared significantly reduced, and Vv was unchanged. R was increased at a nonsignificant extent in apoptotic cells. COX-positive mitochondria accounted for 21% and 35% of the whole population in control and in apoptotic cells, respectively. These findings document that in the early stages of apoptosis the increased fraction of small mitochondria provides an adequate amount of ATP for progression of the programmed cell death and these more efficient organelles appear to represent a reactive response to the loss of metabolically impaired mitochondria. A better understanding of the mitochondrial role in neuronal apoptosis may suggest potential interventions to prevent the extensive nerve cell death typical of neurodegenerative diseases.

Age-related decline in metabolic competence of small and medium-sized synaptic mitochondria

A computer-assisted morphometric investigation of cytochrome oxidase (COX) activity, selectively evidenced by preferential diaminobenzidine cytochemistry, has been carried out on synaptic mitochondria in the cerebellar cortex of adult and old rats. The ratio (R) of the area of the cytochemical precipitate (CPA) to the overall area of each mitochondrion (MA) was calculated. R refers to the fraction of the inner mitochondrial membrane actively involved in cellular respiration, thus its quantitative estimation constitutes a reliable index of the mitochondrial metabolic competence (MMC). In adult rats a significant negative correlation between MA and R values was found, while in old animals there was just a positive trend. Paired-quartile comparisons of R values showed a significant age-related decrease in small and medium-sized mitochondria, whereas the lowest and not significant age-related reduction was found in oversized organelles. A paired decrease in number and increase in size is reported to be a general trend for mitochondria during aging, but oversized organelles, according to their low R value, constitute a scanty, though functional, compensating reaction. Thus, the present findings support the argument that the currently reported age-related cellular metabolic decay appears to rely both on the decline in MMC of the small and medium-sized mitochondria, and on their specific reduction in number. This novel result is of biological relevance since it is largely the small and medium-sized mitochondria that are required for the provision of adequate amounts of ATP for actual cellular performance, while the significantly enlarged organelles are thought to represent an intermediate ultrastructural feature in mitochondrial genesis and/or remodelling.

Ethanol-induced decrease of the expression of glucose transport protein (Glut3) in the central nervous system as a predisposing condition to apoptosis: the effect of age

We measured the effect of chronic ethanol administration on the expression of Glut3 in the cerebellum and hippocampus of adult and old rats. Glut3 expression significantly decreased in aging, in ethanol-treated rats vs. age-matched controls, and in adult- vs. old ethanol-treated rats. These findings lend consistent support to the hypothesis that disturbances of glucose metabolism due to ethanol may constitute an unfavorable condition predisposing to neuronal death.

Neuronal death versus synaptic pathology in Alzheimer's disease

Neuron and synapse numeric densities as well as the average size and surface density of the synaptic junctional areas were measured in the hippocampus and cerebellum of adult, old, and demented (Alzheimer's disease) patients. Our findings support the notion that synaptic loss represents per se a prominent and early damage affecting zones of the central nervous system reported to show a different vulnerability to age- and pathology-related changes.

Chronic Aluminum Administration to Old Rats Results in Increased Levels of Brain Metal Ions and Enlarged Hippocampal Mossy Fibers

The effect of chronic aluminium administration (2 g/L/6 months) was investigated in the central nervous system (CNS) of old rats. The content of Al(3+), Cu(2+), Zn(2+), and Mn(2+) was measured in prosencephalon + mesencephalon, pons-medulla, and cerebellum. The area occupied by the mossy fibers in the hippocampal CA3 zone was also measured. In Al-treated rats the contents of Al(3+), Cu(2+), Zn(2+), and Mn(2+) were significantly increased in prosencephalon + mesencephalon and pons-medulla, while no change was observed in the cerebellum except a Cu(2+) decrease. The area occupied by the mossy fibers in the CA3 field was significantly increased (+32%) in Al-treated rats. Taken together, the present findings document that the aging CNS is particularly susceptible to aluminum toxic effects that may be responsible for a consistent rise in the cell load of oxidative stress. This may contribute, as an aggravating factor, to the development of neurodegenerative events, as observed in Alzheimer disease.

Decay of Mitochondrial Metabolic Competence in the Aging Cerebellum

Cytochemically evidenced cytochrome oxidase activity was morphometrically measured in the cerebellar cortex of adult and old rats. The ratio (R) between the area of the precipitate due to the cytochemical reaction and the overall area of each mitochondrion was calculated. While in adult rats an inverse correlation between mitochondrial size and R values (r = -.905) was envisaged, in old animals increasing values of R were paired by increases in mitochondrial area (r =.561). Paired-quartile comparisons of the R values from adult and old animals documented a marked age-related impairment of the mitochondrial metabolic competence in small (I quartile: -31.6%) and medium-sized (II quartile: -26.4; III quartile: -16.4) mitochondria, while large organelles showed the lowest age-related decrease (IV quartile: -3.0%). The present findings support that a marked dysfunction of small and medium-sized mitochondria contributes to the significant decay of energy metabolism currently reported in physiological aging.

Cytochrome Oxidase Activity in Hippocampal Synaptic Mitochondria during Aging: A Quantitative Cytochemical Investigation

Synaptic mitochondria, cytochemically positive to cytochrome oxidase (COX) activity, were investigated by morphometric methods in the hippocampal dentate gyrus of adult and old rats. The number of mitochondria/microm(3) of tissue (Nv), the volume fraction occupied by mitochondria/microm(3) of tissue (Vv), the average mitochondrial volume (V), the longer mitochondrial diameter (F(max)), and the ratio R:mitochondrial area/overall area of the cytochemical precipitate due to COX activity were measured on COX-positive organelles. In old animals, Nv, Vv, V, and F(max) increased at a not significant extent; R was not significantly decreased. The complement (%) of longer organelles was higher in old animals. COX activity is currently considered an endogenous marker of neuronal oxidative metabolism; thus, although our findings refer to the discrete subpopulation of COX-positive organelles located at synaptic terminals, they support that changes of mitochondrial ultrastructure and metabolic competence may contribute to the age-related alterations of neuronal performances.

Role of Mitochondrial Deterioration in Physiological and Pathological Brain Aging

BACKGROUND

Mitochondria are widely reported to occupy a unique role in modulating cell viability, senescence and death. This is consistently supported by the multiple functions of these organelles. In addition to providing the energy for the myriad of cellular performances, mitochondria are involved in regulating thermogenesis, calcium buffering, integration of pro- and anti-apoptotic signals.

OBJECTIVE

To stress the significant importance of subtle, continuous and permanent mitochondrial alterations as key events in physiological aging and as unfavourable determinants of age-related neurodegenerative diseases.

RESULTS

Any dysfunction of these organelles may constitute a serious threat for cellular health status and survival, particularly of post-mitotic nerve and muscle cells. Mitochondrial deterioration may affect discrete features of the organelles (such as their structural dynamics, genetics and physiology) and lead to a progressive functional impairment.

CONCLUSIONS

A variety of mitochondrial tasks, while hampering the possibility to recover the organelles' dysfunctions, offer different and reliable opportunities for therapeutic interventions.

GAP-43 mRNA detection by in situ hybridization, direct and indirect in situ RT-PCR in hippocampal and cerebellar tissue sections of adult rat brain

The growth-associated protein GAP-43 is a presynaptic membrane phosphoprotein that is expressed at high levels during development and axonal growth. To evaluate the cellular distribution of GAP-43 mRNA in the hippocampus and cerebellum of adult rats we applied in situ hybridization (ISH) as well as direct and indirect in situ RT-PCR using biotin as a reporter molecule. ISH resulted in a positive signal in most cerebellar granular cells and in 30% of hippocampal CA3 neurons. Direct in situ RT-PCR yielded cells with strong signals in every region investigated, with elevated background levels most likely related to incorporation of labeled nucleotides into non-specific amplicons through internal priming and DNA repair activity. Indirect in situ RT-PCR turned out to be the best approach for detecting GAP-43 mRNA positive cells. Cerebellar cells exhibiting a positive signal for GAP-43 mRNA were of the granular cell type (98%). Hippocampal neurons with a positive reaction for GAP-43 mRNA included all the neuron groups analyzed, namely CA1 (99%) and CA3 pyramidal cells (94%) and dentate gyrus granule cells (92%). Dentate gyrus granule cells have not tested positive for GAP-43 mRNA detection by molecular morphology analysis. These data show that in normal rats GAP-43 mRNA is present in different cell populations of hippocampal formation, supporting the role of this protein in the ongoing processes of synaptic plasticity.

Inverse correlation between mitochondrial size and metabolic competence: a quantitative cytochemical study of cytochrome oxidase activity

Mitochondria are topologically closed bilayered systems where the synthesis of adenosine triphosphate (ATP) from adenosine diphosphate (ADP) and inorganic phosphate occurs via oxidative phosphorylation. The ordered architecture (and its extension) of the mitochondria (i.e. inner membrane, outer membrane and cristae) constitutes a critical topographic arrangement for their energy-providing mechanisms. Thus, quantitative estimations of the ultrastructural features of organelles preferentially stained by means of function-related cytochemical reactions reliably report on their potential to supply adequate amounts of ATP. On the basis of this rationale, we carried out a computer-assisted cytochemical study of cytochrome oxidase (COX) activity on mitochondria of different size in the cerebellar cortex of adult rats. The total intra-mitochondrial area of the cytochemical precipitates (CPA)/mitochondrion, the area (MA) and the longer diameter (F(max)) of COX-positive organelles were measured. The ratio (R): CPA/MA was also calculated and referred to as the percentage of mitochondrial inner membrane area involved in COX activity. The regression analysis of R vs MA showed a significant inverse correlation (r=-0.905). The fourfold increase in MA from quartiles I to IV was matched by increases in F(max) and CPA, respectively, but it was also related to a 25% decrease in R. By matching quantitative cytochemical estimations of COX activity within mitochondria with the morphometric assessment of their ultrastructural features, the present study correlates size to the metabolic competence of COX-positive organelles. Quantitative cytochemistry of COX activity is currently regarded as a reliable marker of cellular metabolism; thus our findings support the hypothesis that enlargements in size are inversely correlated with the mitochondrial metabolic competence.

Beta-amyloid fragment 25-35 selectively damages platelets from patients with Alzheimer's disease

In order to analyze the metabolic response of AD patient platelets to beta-amyloid, we have carried out fluorimetric measurements of intracellular calcium and an ultrastructural survey of platelets exposed to the beta-amyloid active fragment 25-35 (betaA(25-35)). Since it is not possible to analyze directly the damaged neurons in AD, the study of peripheral blood cells, especially platelets, may be of great value for the investigation of the toxic effects of beta-amyloid on AD neuronal cells.

Chronic administration of EGb 761 modulates synaptic and mitochondrial plasticity in adult vitamin E-deficient rats

A computer-assisted morphometric study has been carried out on synaptic junctions and synaptic mitochondria in the dentate gyrus supragranular layer of vitamin E-deficient rats undergone chronic administration of the extract EGb 761 from Ginkgo biloba leaves (100 mg/kg body weight, daily, from 4 to 7 months of age). Control animals were fed with the vitamin E-deficient diet from 1 to 7 months of age. Numeric density (Nv), surface density (Sv) and average size of the synaptic junctions (S), mitochondrial numeric density (Nvm), volume density (Vv) and average volume (V) were the measured parameters. In EGb 761-treated animals, Nv was significantly increased and S significantly decreased, while Sv was unchanged. EGb 761 administration resulted in an increased percentage of synapses of smaller size. In EGb 761-treated rats, Nvm significantly increased and V significantly decreased, while no significant difference of Vv was found. The population of synaptic mitochondria in EGb 761 -treated animals was composed of a higher number of smaller organelles. The measured parameters report on the structural dynamics of synapses and mitochondria, thus our findings support that EGb 761 administration is able to improve the physiological adaptive capacities of the investigated structures by a positive modulation of their morphofunctional features.

Morphometry of E-PTA stained synapses at the periphery of pathological lesions

We carried out a novel application of the disector sampling and counting method, in a biopsy material from the pathologic human brain, to estimate the synaptic structural dynamics, quantitatively. Parietal cortex biopsies of adult (mean age: 40.0 years) and old (mean age: 66.2 years) patients having undergone surgical intervention were investigated. The tissue samples were excised at the periphery of meningioma masses. Synaptic contact zones were stained en bloc by the ethanol phosphotungstic acid (E-PTA) preferential technique which selectively enhances both the pre- and post-synaptic paramembranous material separated by a sharp cleft against a very faint background, thus facilitating and objectifying synaptic morphometry. The disector method, associated with currently used morphometric formulas, enabled us to measure the number of synapses/m3 of tissue (numeric density: Nv); the total area of the synaptic contact zones/m3 of tissue (surface density: Sv) and the average synaptic size (S). In old vs. adult patients, Nv decreased by 7.5% (Mean (SEM): Adult 2.0040(0.0452); Old 1.6780(0.0623)), while S increased by 17.5% (Adult 0.0203(0.0026); Old 0.0246(0.0035)). Sv did not show any age-related difference. The same negative correlation between Nv and S has also been reported in physiological aging, and this suggests the active presence of age-related synaptic restructuring mechanisms in the nervous tissue surrounding a tumoral mass.

Morphometry of age pigment (lipofuscin) and of ceroid pigment deposits associated with vitamin E deficiency

Consistent amounts of lipofuscin and of ceroid pigment associated with vitamin E deficiency are reported to represent morphological correlates of aging and increased oxidative stress. A reliable quantification of these yellow autofluorescent deposits is of critical biological significance, thus we carried out a computer-assisted morphometric study on the accumulation of lipofuscin in physiological aging and of ceroid pigment in vitamin E deficiency, respectively. The total area and the size distribution of lipofuscin or ceroid pigment deposits were measured in CA3 hippocampal pyramidal neurons of 6-, 12-, 18- and 25-month-old rats, as well as in vitamin E deficient animals of 18 months of age. An increase in the mean total area of lipofuscin and ceroid pigment was found in aging and in vitamin E deficiency. In both conditions, the proportion of large discrete deposits also increased. The similarity of changes observed in old and adult vitamin E deficient animals suggests that the underlying processes initiated by the absence of alpha-tocopherol from the diet of adult rats and in physiological aging may share some common mechanisms.

Morphometric investigations of the mitochondrial damage in ceroid lipopigment accumulation due to vitamin E deficiency

Numeric (Nv) and volume (Vv) densities, as well as the average size (skeleton: Sk) of synaptic mitochondria from adult, normally fed and adult, vitamin E deficient animals (11 months of age) were semiautomatically measured by computer-assisted morphometry in the cerebellar granular layer. Nv, Vv and the average mitochondrial volume (V) were measured on perikaryal Purkinje cell organelles preferentially stained for succinic dehydrogenase (SDH) activity. Adult vitamin E deficient animals showed a significant decrease of Nv, a significant increase of Sk and an unchanged value of Vv. While in adult normally fed animals the mitochondria of increased size (Sk>5 microm) were 5.3%, in the adult vitamin E deficient rats this fraction accounted for 25.5%. In Purkinje cell perikarya, vitamin E deficiency resulted in a significant decrease of Vv, Nv and V, as well as a steeper reduction of the percentage of SDH-positive mitochondria of larger size. Taken together, these findings document that vitamin E deficiency is responsible of mitochondrial morphometric alterations in adult rats. Structurally deteriorated mitochondria are reported to play a role in producing increased amounts of free radicals, which can facilitate the accumulation of ceroid pigment.

Age-related effects of moderate alcohol consumption on GAP-43 levels in rat hippocampus

The effects of moderate intake of ethanol and ageing were investigated on the levels of the growth-associated protein GAP-43, whose expression has been used as an indicator of axonal growth during development, regeneration and remodelling of synaptic connections. Groups of female Wistar rats (12 and 24 months of age), were alcohol-fed for one month while age-matched control groups received an isocaloric diet. A quantitative evaluation of GAP-43 was performed in hippocampus and in hippocampal selected areas in view of the vulnerability of this complex to alcohol aggression by means of two different methods, namely Western blot analysis and immunohistochemistry. While the former measures total extractable GAP-43, the latter allows visualisation of in situ changes in topographical distribution of GAP-43. Western blot analysis revealed an age-dependent reduction (-47%) and an ethanol-associated increase (81%) of GAP-43 demonstrated only in the old group. Conversely, quantitative immunohistochemistry of GAP-43 in the entire hippocampus showed a non-significant ethanol-related decrement in 24-month-old rats (-30%), although the age-dependent reduction was confirmed. Ageing was associated with a decrement of GAP-43 immunostaining in CA3 stratum radiatum (CA3) and in inner molecular layer of dentate gyrus (IML). Treatment determined a decrease of GAP-43 immunostaining in adult rat CA3 and IML and no change in CA1 stratum radiatum (CA1). Our results suggest that immunohistochemistry evaluation underestimates GAP-43 levels in ethanol-treated animals possibly as a consequence of conformational changes induced by alcohol, resulting in non-targeting of the specific antibody. Western blot analysis demonstrate that although there is a reduction of GAP-43 levels in hippocampus of aged rats, this structure retain a remarkable potential to compensate for ethanol toxicity during ageing.

Succinic dehydrogenase activity in human muscle mitochondria during aging: a quantitative cytochemical investigation

A quantitative cytochemical study has been carried out on succinic dehydrogenase (SDH) activity in biopsy samples of vastus lateralis (VL) and anterior tibialis (AT) muscles from healthy men undergoing orthopaedic surgery. According to their age, the patients were divided into: young (25.0+/-4.4 years), middle-aged (50.4+/-7.5 years) and old (75.5+/-3.9 years) groups. Bioptically excised samples were processed for copper ferrocyanide preferential SDH cytochemistry. By a computer-assisted image analyser, we calculated the ratio (R): overall area of the precipitates due to the enzyme activity/area of each mitochondrion. No significant difference was found among the three age groups, despite an 8% increase of R in the adult vs. the other groups. R values are related to mitochondrial morphofunctional features since they may be modulated by enzyme activity and the physico-chemical conditions of the organelle membranes. Thus, R quantitation enables to estimate the mitochondrial capacities for adenosinetriphosphate provision. In this context, our present findings confirm previous data reporting a substantial age-related stability of muscle mitochondrial enzyme levels. In aging, energy-deficient sarcomeres are supported to be negatively selected and eliminated, while the surviving ones appear to maintain an adequate SDH activity.

Mapping of mitochondrial metabolic competence by cytochrome oxidase and succinic dehydrogenase cytochemistry

To map the mitochondrial capacity to provide adenosine triphosphate (ATP), the activities of cytochrome oxidase (COX) and succinic dehydrogenase (SDH) were respectively evidenced by diaminobenzidine (DAB) and copper ferrocyanide cytochemical techniques in the cerebellar cortex of adult rats. Sampling of the positive mitochondria was carried out by the disector procedure. The ratio (R) overall area of the precipitates due to COX activity within the single mitochondrion/area of the same organelle was automatically calculated to estimate enzyme activity vs mitochondrial size. The number of SDH-positive mitochondria/microm(3) of tissue (numeric density, Nv) was morphometrically calculated. Cytochemistry of key enzymes of the respiratory chain enables measurement of the actual capacity of individual mitochondria to provide ATP. This quantitative estimation allows morphofunctional mapping of the mitochondrial metabolic competence in discrete tissue and/or cellular compartments. (J Histochem Cytochem 49:1191-1192, 2001)

Cellular distribution of GAP-43 mRNA in hippocampus and cerebellum of adult rat brain by in situ RT-PCR

The growth-associated protein GAP-43 is a presynaptic membrane phosphoprotein that plays a key role in guiding the growth of axons and in modulating the formation of new synapses. To identify the cells that synthesize GAP-43 mRNA, we applied direct in situ reverse transcription-polymerase chain reaction (in situ RT-PCR) in cerebellum and hippocampus of adult rat brain. In situ RT-PCR revealed GAP-43 mRNA in cerebellar granule cells, in Purkinje cells and in some interneurons of the molecular layer. Previous in situ hybridization studies had demonstrated a dense label throughout the granular layer of the cerebellar cortex but no labeling of other cerebellar neurons. Hippocampal cells showing distinct GAP-43 mRNA signal after in situ RT-PCR were CA1 and CA3 pyramidal neurons, CA4 hilar cells, and dentate gyrus granule cells, whereas in situ hybridization studies had detected GAP-43 mRNA only in CA3 and CA1 pyramidal neurons. Our data indicate that GAP-43 mRNA is widely distributed, suggesting that many cell types are potentially involved in synaptic plasticity events. (J Histochem Cytochem 49:1195-1196, 2001)

Distribution of map2 in hippocampus and cerebellum of young and old rats by quantitative immunohistochemistry

The microtubule-associated protein MAP2 is a cytoskeletal protein that plays a regulatory role in neuronal plasticity and in maintaining the morphology of differentiated neurons. MAP2 distribution was assessed in hippocampus and cerebellum of young and old rats by quantitative immunohistochemistry. In old vs young rats, densitometric analysis showed a significant decrease of MAP2 immunoreactivity in the hippocampus CA1 field (-93%), whereas no difference was found in cerebellar MAP2 distribution. These preliminary data suggest that in areas of the brain involved in memory acquisition and consolidation, MAP2-dependent neuroplasticity and structural integrity are significantly decreased in aging.

Quantitative cytochemical mapping of mitochondrial enzymes in rat cerebella

Mitochondrial metabolic competence, defined as the organelle's capacity to provide adequate amounts of ATP in due time, appears to constitute an important determinant in several biological processes and pathological conditions. Thus, the assessment of the metabolic efficiency of the mitochondrial population in a given tissue area or cellular compartment may provide clues to identifying alterations of the cellular bioenergetic machinery, which may constitute a predisposing condition leading to impaired organ and system functions. In the cerebellar cortex of adult rats, the activities of the enzymes cytochrome oxidase (COX) and succinic dehydrogenase (SDH) were, respectively, evidenced by means of the diaminobenzidine and copper ferrocyanide preferential cytochemical techniques. At the electron microscope, the activities of these two key molecules of the respiratory chain were clearly visualised as dark precipitates at the inner mitochondrial membrane sites where COX and SDH are located. By means of the disector method, unbiased mitochondrial samplings were carried out to measure: the number of mitochondria/microm(3) of tissue (numeric density: Nv); the mitochondrial volume fraction/microm(3) of tissue (volume density: Vv) and the average mitochondrial volume (V) both on COX- and SDH-positive organelles in the cerebellar glomeruli and Purkinje cells, respectively. The ratio R (total area of the precipitates due either to COX or SDH activity within the single mitochondrion/area of the same organelle) was also evaluated to get information on the enzyme activity related to mitochondrial size.The documented accumulation of mutant mitochondrial DNA particularly in postmitotic cells results in a marked heteroplasmy (mixtures of normal and mutated genomes) at mitochondrial and cellular levels, thus the cellular potential for energy production is demanded to a mosaic of organelles with different functional capabilities. Assessment of the mitochondrial mosaic outline by means of quantitative cytochemistry of key enzymes of the respiratory chain, such as COX and SDH, may allow for the morphofunctional metabolic mapping of mitochondrial efficiency in discrete cellular or tissue compartments.

Quantitative immunohistochemistry of glucose transport protein (Glut3) expression in the rat hippocampus during aging

Immunohistochemistry of Glut3 (45 kD), an integral membrane peptide mediating the transport of glucose in neurons, was carried out in the hippocampus of 3- and 28-month-old rats to assess the effect of age on energy metabolism. Free-floating sections of fixed-frozen hippocampi were processed for quantitative immunohistochemistry of Glut3. A rabbit affinity-purified antibody identified Glut3 immunoreactivity. Glut3 staining was intense in neuropil, axons, and dendrites, whereas nerve cell bodies were unstained. With aging, Glut3 reactivity was significantly decreased in the inner molecular layer of the hippocampal dentate gyrus (-46%) and the mossy fibers of the CA3 sector (-34%), whereas the stratum radiatum of CA1 did not show any difference due to age. These data document an age-dependent decrease in Glut3 expression in discrete areas of rat hippocampus. Glut3 constitutes the predominant glucose transporter in neurons and is found abundantly in regions with high synaptic density characterized by frequent bursts of function-adequate metabolic activity. Our findings therefore lend further support to the critical role of an impaired metabolism in age-related brain dysfunctions and disease.(J Histochem Cytochem 49:671-672, 2001)