Increased Expression of Cathepsins E and D in Reactive Microglial Cells Associated with Spongiform Degeneration in the Brain Stem of Senescence-Accelerated Mouse

Senescence-accelerated mouse (SAM) P8 and P10 exhibit a spongy degeneration, especially in the brain stem, and a brain atrophy mainly in the frontal portion of the cerebral cortex, respectively, with advancing age. In an attempt to clarify the role of two distinct intracellular aspartic proteinases, cathepsins E (CE) and D (CD), in these age-related pathological changes, accumulation and localization of these enzymes were investigated in the brain stem and the cerebral cortex of SAMP8 and P10 and in the senescence-resistant control SAMR1 with four different age groups (1 week and 2, 6, and 12 months). In the brain stem of SAMP8, a marked spongy degeneration was observed at more than 2 months of age. The same degree of spongy degeneration was also observed in the brain stem of age-matched SAMP10 but not SAMR1. The nonlysosomal enzyme CE was barely detectable in the brain stem of all three strains at 1 week of age, but it was markedly accumulated in the brain stem of SAMP8 and P10 at 2 months of age. The lysosomal enzyme CD was found in relatively high concentration in the brain stem of all three strains at 1 week of age. At 2 months of age, CD contents were significantly increased in the brain stem of SAMP8 and P10 compared with those of age-matched SAMR1. At the light-microscopic level, increased immunoreactivities for CE in the brain stem of 2-month-old SAMP8 and P10 were found in reactive microglial cells clustered at the spongy areas but not in microglial cells with resting or ramified morphology and astrocytes. The increased immunoreactivity for CD was observed mainly in reactive astrocytes and partially in reactive microglial cells. Immunoblotting analyses revealed that CE in the brain stem of 2-month-old SAMP10 consisted of only the mature form of 42 kDa, whereas CD in this tissue is composed of mainly the mature form of 44 kDa and partially its degradation products. On the other hand, there was a marked brain atrophy mainly in the frontal portion of the cerebral cortex of 6-month-old SAMP10 but not in age-matched SAMP8 or SAMR1. Although CE was not detectable even in the atrophied cortical area of SAMP10, CD contents in the cerebral cortex slightly increased with senescence in all three strains. These results strongly suggest that CE and CD are upregulated in reactive glial cells and are closely linked with the progression of the spongiform degeneration in the brain stem of SAMP8 and P10, but not in the atrophy developed in the cerebral cortex of SAMP10.     

Age-related changes in uptake and release on L-[3H]noradrenaline in brain slices of senescence accelerated mouse

High K+ and N-methyl-D-aspartate (NMDA) evoked L-[3H]noradrenaline (NA) release to a similar degree in the brain slices of 1-month-old senescence-accelerated resistant mice (SAM-R/1) and senescence-accelerated prone mice (SAM-P/8). However, 30 mM KCl-induced L-[3H]NA release significantly diminished in SAM-P/8 from 3 to 12 months without changing in SAM-R/1. In addition, NMDA-induced L-[3H]NA release was also reduced at 3 months and lowered to a level of spontaneous release at 12 months in SAM-P/8, but no age-related changes in SAM-R/1 were observed. It is suggested that NA release from NA nerve terminals responsive to depolarization is reduced in SAM-P/8 at an earlier stage than in SAM-R/1. Furthermore, NMDA receptors which could be localized in the soma and/or nerve terminals, seem to be involved in NA release and to be decreased with advancing age in SAM-P/8.     

Cholinergic deficits in the septal-hippocampal pathway of the SAM-P/8 senescence accelerated mouse

Senescence accelerated prone mouse strains (SAM-P) and resistant strains (SAM-R) have proven useful in elucidating aspects of the aging process. The senescence accelerated mouse SAM-P/8 strain exhibits severe age-related learning and memory impairments well before the median age of survival. Disruption of the brain cholinergic system produces learning and memory impairments as severe as those seen in aging SAM-P/8 mice. Therefore, we compared the effects of aging on cholinergic parameters in the septal-hippocampal pathway, a region known to play a role in learning and memory, in SAM-P/8 mice and mice of the senescence resistant SAM-R/1 strain. Between 4 and 12 months of age we observed a 40-50% decrease in choline acetyltransferase (ChAT) activity in two of three subregions of the hippocampus in the SAM-P/8, but not the SAM-R/1 strain. Between 4 and 12 months, SAM-P/8 mice also showed a 40-50% decrease in ChAT activity in the septal region that was maximal by 8 months of age. By contrast, these age-related changes were not observed in the control SAM-R/1 mouse strain. The changes in ChAT in the SAMP/8 mouse strain were limited to the septal-hippocampal cholinergic pathway. There were no differences in ChAT activity in the nucleus basalis of Meynert, nor any of several neocortical areas to which it projects. To determine the neurochemical specificity of these alterations, the activity of glutamic acid decarboxylase (GAD), was also measured in the septum and hippocampus of SAM-P/8 mice. There were no age-related alterations in the hippocampus, but a significant 50% increase in GAD activity in the septal nucleus at 12 months of age. There were no age-related alterations in either nicotinic (3H-cytisine) or muscarinic (3H-QNB) cholinergic receptor binding in the cortex or hippocampus of SAM-P/8 mice. However, there were significant strain differences. At 2 months of age, 3H-QNB binding was higher in hippocampus of the SAM-R/1 than in SAM-P/8 mice. Similarly, 3H-cytisine binding in cortex of SAM-R/1 mice was higher at both 2 and 13 months than in SAM-P/8 mice. The results suggest that a compromised septal-hippocampal cholinergic pathway may contribute to the previously reported early onset of impaired learning and memory in the SAM-P/8 mouse strain.     

BASAL GANGLIA DEGENERATION, MYELIN ALTERATIONS, AND ENZYME INHIBITION INDUCED IN MICE BY THE PLANT TOXIN 3-NITROPROPANOIC ACID

Gould D. H.&Gustine D. L.1982 Neuropathology and Applied Neurobiology 8, 377–393
Basal ganglia degeneration, myelin alterations, and enzyme inhibition induced in mice by the plant toxin 3-nitropropanoic acid
The plant toxin, 3-nitropropanoic acid, produced topographically and morphologically distinctive lesions in mice after daily intraperitoneal injections. In the lateral caudate-putamen there were bilateral and symmetrical lesions consisting of marked swelling and pyknosis of individual cells and processes in otherwise unaffected tissue. The appearance of transitional forms and the usual post-synaptic location of the swollen processes indicated that affected cells were neurons. A few mice exhibited a more diffuse spongy change in the lateral caudate-putamen that caused major architectural changes. In the globus pallidus, entopeduncular nucleus, and anterior substantia nigra pars reticulata there was fine spongy change of the neuropil that spared cell bodies, and was primarily due to swelling of dendrites. A third lesion pattern in myelinated tracts of the midbrain, medulla, and spinal cord consisted of adaxonal, intramyelinic cleft formation. Succinate dehydrogenase activities assayed in frozen brain sections and in isolated mitochondria were markedly reduced in intoxicated mice.     

SAMP8 mice as a neuropathological model of accelerated brain aging and dementia: Toshio Takeda's legacy and future directions

Senescence accelerated mice P8 (SAMP8) show significant age‐related deteriorations in memory and learning ability in accordance with early onset and rapid advancement of senescence. Brains of SAMP8 mice reveal an age‐associated increase of PAS‐positive granular structures in the hippocampal formation and astrogliosis in the brain stem and hippocampus. A spongy degeneration in the brain stem appears at 1 month of age and reaches a maximum at 4‐8 months. In addition, clusters of activated microglia also appear around the vacuoles in the brain stem. β/A4(Aβ) protein‐like immunoreactive granular structures are observed in various regions and increase in number markedly with age. Other age‐associated histological changes include cortical atrophy, neuronal cell loss in locus coeruleus and lateral tegmental nuclei, intraneuronal accumulation of lipopigments in Purkinje cells and eosinophilic inclusion bodies in thalamic neurons. A blood–brain barrier dysfunction and astrogliosis are also prominent with advancing age in the hippocampus. These changes are generally similar to the pathomorphology of aging human brains and characterized by their association with some specific glioneuronal reactions. As for the hallmarks of Alzheimer brains, tau morphology has not yet been confirmed regardless of the age‐related increase in phosphorylated tau in SAMP8 mice brains, but early age‐related Aβ deposition in the hippocampus has recently been published. SAMP8 mice are, therefore, not only a senescence‐accelerated model but also a promising model for Alzheimer's disease and other cognitive disorders.     

Behavioral characteristics of the SAM-P/8 strain in Sidman active avoidance task

The behavior of the senescence-accelerated mouse (SAM-P/8) at the age of 1, 2, 4 and 10–11 months in Sidman active avoidance learning was analyzed, and compared to findings in the controls (SAM-R/1). At the age of 1 and 2 months, learning was comparable in these two strains. At the age of 4 and 10–11 months, SAM-P/8 but not SAM-R/1 learned active avoidance. We propose that SAM-P/8 can serve as a valid model of deficits in learning and memory.     

Dentatorubropallidoluysian atrophy (DRPLA): comparative pathological study on clinical groups classified into juvenile, early adult and late adult types]

We performed a clinicopathological study on 12 autopsied cases of dentatorubropallidoluysian atrophy. They were divided into 3 groups according to the age at onset: juvenile type (6 cases), early adult type (4 cases) and late adult type (2 cases). In juvenile type showing progressive myoclonus epilepsy (PME) syndrome, degeneration of the globus pallidus was more marked than that of the dentate nucleus. Mild to moderate atrophy was seen in the brain stem and spinal cord. In early adult type showing milder symptom of myoclonus and epilepsy, the globus pallidus and dentate nucleus were equally degenerated to various extents in most cases. Atrophy of the brain stem and spinal cord was mild to moderate in degree. In late adult type without PME syndrome, degeneration of the dentate nucleus was more marked than that of the globus pallidus. The brain stem and spinal cord were severely atrophic. On the other hand, the cases showing severe dentate lesion had a tendency to show severe atrophy of the brain stem and spinal cord. We consider that development of myoclonus, epilepsy and choreoathetoid movement in DRPLA patients has close relation to the extent of not only degeneration of the globus pallidus and dentate nucleus, but also atrophy of the brain stem and spinal cord.     

Inbred SAM-P/10 as a mouse model of spontaneous, inherited brain atrophy.

We developed a novel inbred strain of mouse with age-related brain atrophy and it was named "Senescence Accelerated Mouse (SAM)-P/10." Macroscopic morphometry indicated that the brains of SAM-P/10 showed age-dependent involutional changes mainly in the frontal portion of the cerebrum. The brain weight decreased by 8.6% throughout the life-span. There were no obvious defects in postnatal development. Semi-macroscopic morphometry revealed a prominent atrophy in the neocortex, olfactory cortex and amygdala. Microscopic morphometry showed that the neocortical neurons were lost with aging, with mostly the large neurons being affected which were lost by 35.6% throughout the life-span. Somata of the neocortical neurons shrank with advancing age. In a control SAM-R/1 strain with only a slight macroscopic involutional change in the brain without weight loss, neither loss of the neocortical large neurons nor shrinkage of the neocortical neurons was evident with aging. Learning and memory skills were evaluated using the one-trial passive avoidance task and conditional avoidance task. Young SAM-P/10 mice performed well in both tasks but older SAM-P/10 showed a poorer performance in both tasks, and this was even poorer than the performance of very old SAM-R/1 mice. Thus, SAM-P/10 can serve as a spontaneous animal model of brain atrophy for a variety of studies of aging of the brain. A better understanding of neurodegenerative diseases with dementia should be forthcoming.     

THE PATHOKINETICS OF ACRYLAMIDE INTOXICATION: A REASSESSMENT OF THE PROBLEM

Cavanagh J.B. 1982 Neuropathology and Applied Neurobiology 8, 315–336
The pathokinetics of acrylamide intoxication: a reassessment of the problem
Acrylamide was given intraperitoneal^ to rats (30 mg/kg/day, five times/week) for 3 weeks, and the nervous and muscle tissues were examined by conventional methods over 5 weeks. Three striking cellular changes were observed. 1 Scattered degeneration of many Purkinje cells from 5 days onwards. 2 Widespread swelling and argyrophilia of nerve terminals from 10 days in both PNS and CNS. Motor and sensory endings were equally affected in all muscles examined. Synaptic and preterminal swelling also occurred in spinal cord, brain stem, and in certain cerebellar terminals. Degeneration occasionally followed this change, particularly in sensory nerve fibres, but not necessarily. 3 Chromatolysis in spinal ganglion cells and occasionally in anterior horn cells from 7 days onwards before the onset of axonal degeneration. This unique sequence of events is discussed in the light of the metabolic and other changes described by earlier authors.     

Spongiform encephalopathy in mice inoculated with scrapie material of sheep origin

The authors report spongy degeneration in experimental scrapie (second passage) in mice. The scrapie agent was originally isolated from Suffolk sheep imported from Canada and diagnosed histopathologically to be infected with scrapie by intracerebral inoculation into JCL/ICR mice. Ten female SIc/ICR mice, 4 weeks of age, were injected intracerebrally in the right frontal lobus with 20 microliter of 10(-1) or 10(-4) dilution of JCR/ICR mice brain homogenate involving scrapie agent. All animals showed signs of the advanced stages of the disease, clinically manifested by lassitude, arched backs, lethargy and paresis of hind quarters. They were sacrificed five to six months post inoculation, and sections of the brain and spinal cord were examined by light and electron microscopy. Focal symmetrical spongiform lesions were seen light microscopically in the cerebral mantle, thalamus, hypothalamus, midbrain, medulla oblongata, cerebellum and cervical mark. There was evidence that these lesions tended to be more intense in the mice inoculated a higher concentration of scrapie agent. Astrocytic proliferation was present in the deep layer of cerebral gray matter, white matter, corpus callosum, dorsal part of hippocampus and thalamus. No leukocytic infiltration was observed. Electron microscopically, the spongiform lesions were shown to be caused by vacuolation or swelling within the neuropil, and vacuolation and focal swelling in the neuronal perikaryon. The changes in the neuronal perikaryon were caused by enlargement of endoplasmic reticulum and cisterns of the Golgi apparatus, accompanied by spherical swelling of a part of the cytoplasm. The vacuolation near or within the neuron produced deformation of the cell contours and displacement of the nucleus.(ABSTRACT TRUNCATED AT 250 WORDS)     

Radiation-induced nerve root degeneration and hypertrophic neuropathy in the lumbosacral spinal cord of rats: the relation with changes in aging rats

Three-month-old WAG/Rij rats were irradiated with 300 kV X-rays on the lumbar region of the spinal column with doses below the level for causing paralysis due to radiation radiculomyelopathy. 8--9 months after irradiation, degeneration of predominantly the ventral nerve roots of the cauda equina was boserved. Three stages were distinguishable: I) Demyelination and proliferation of Schwann cells; II) Local swelling of ventral nerve roots, with concentric layers of Schwann cells resembling hypertrophic neuropathy; III) Malignant Schwannoma, invading roots and spinal cord. It is concluded that the degenerative and proliferative lesions represent a continuous series of stages of slowly progressive lesions. The ventral nerve root degeneration (1st stage) is similar to that observed in aging, unirradiated rats, normally developing at the age of 18--20 months.     

Age-related changes in NMDA-induced [3H]acetylcholine release from brain slices of senescence-accelerated mouse.

From the brain slices of normal mice (ddY strain, subcloned from dd strain in National Institute of Health in Japan), N-methyl-D-aspartic acid (NMDA) at 0.01-1 mM evoked [3H]acetylcholine (ACh) release in a concentration dependent manner. [3H]ACh release evoked by 1 mM NMDA was significantly inhibited by 2-amino-5-phosphonovaleric acid (APV), phencyclidine (PCP) and 5-methyl-10,11-dihydroxy-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate (MK-801). The effects of NMDA were not seen in the Ca2+ free medium and were inhibited by physiological concentration (0.83 mM) of Mg2+. NMDA seems to cause ACh release from nerve terminals through the receptor-ion channel mediated mechanism in the mouse brain. Based upon these results, we determined the activity of a high K(+)- or NMDA-evoked [3H]ACh release using prone/8 strain of senescence-accelerated mouse (SAM-P/8) (a murine model of accelerated aging and memory dysfunction) and SAM-resistance/1 strain (SAM-R/1) (normal aging mice as the control) and these release activities were compared between both strains and during aging. [3H]ACh release evoked by 30 mM KCl was significantly lower than that of age-matched SAM-R/1 at 9 and 12 months. NMDA evoked the [3H]ACh release at 2, 6, 10 and 14 months in R/1 mice. In SAM-P/8 mice the activity of NMDA-evoked release was seen at 2 months, but markedly decreased afterwards. Nonsignificant difference was observed on the uptake of [3H]choline and on the spontaneous release of [3H]ACh between SAM-P/8 and SAM-R/1 strains, and during aging.(ABSTRACT TRUNCATED AT 250 WORDS)     

Joseph Disease with Severe Atrophy of the Brain Stem Tegmentum: Report of an Autopsied Case

An autopsied case of Joseph disease with severe atrophy of the brain stem tegmentum is reported. A Japanese male noticed unsteady gait at age 30 and showed cerebellar ataxia, pyramidal signs, progressive external ophthalmoplegia, peripheral amyotrophy, sensory disturbance, and bradykinesia. He also developed mild dementia and nocturnal delirium at the terminal stage of his illness. His mother, older and younger brothers and daughter also presented progressive ataxia. The mode of inheritance is considered to be autosomal deminant. He died of cardiac failure at age 57. The autopsy revealed significant atrophy of the brain stem and spinal cord. Microscopic examination showed severe degeneration of the dentato-rubral and subthalamo-pallidal systems, pontine nuclei, spinal anterior horn, Clarke's column, accessory cuneate nucleus and spinocerebellar tract, moderate degeneration of the brain stem motor nuclei including the oculomotor nuclei and substantia nigra, and mild degeneration of the spinal posterior and intermediolateral column, and cerebellar cortex. An additional finding, which has received little attention in this disease, was severe atrophy of the brain stem tegmentum associated with degeneration of the reticular formation, raphe nuclei and locus ceruleus. The significance of brain stem tegmental atrophy in Joseph disease is discussed.     

Neuropathological findings of an autopsy case of adult β-galactosidase and neuraminidase deficiency

Summary An autopsy case of a Japanese male with familial -galactosidase and neuraminidase deficiency is reported. The clinical picture was characterized by adult onset, a gargoyle-like face, cerebellar ataxia, myoclonus, convulsions, retinal degeneration and cortical blindness.Histopathologically, most neurons seemed to have become degenerated in the whole cerebral cortex. Moreover, the calcarine cortex appeared spongy with depopulation of nerve cells. Stuffed neurons or neuronal storage changes were found throughout the brain, especially in the motor nuclei of the spinal cord and brain stem.The inclusions in the stuffed neurons revealed various profiles on the electron microscope. They were composed of membranous lamellar and/or multilamellar structures, often accompanying vacuoles and reminiscent of lipofuscin-like profiles.     

Pursuit of the origin of the large myelinated fibers of the anterolateral funiculus in the spinal cord in humans in relation to the pathomechanism in amyotrophic lateral sclerosis

To determine the origin of the large myelinated fibers in the anterolateral funiculus (ALF) in the spinal cord of humans, myelinated fibers in the ALF of the mid-cervical spinal cord were examined quantitatively. Five groups of subjects were examined, consisting of control subjects, patients with cerebral lesions and showing complete degeneration of the unilateral/bilateral pyramis of the medulla oblongata, those with lesions of the pontine tegmentum, those with lesions of the lower cervical spinal cord, and those with thoracic/lumbar lesions. The results indicate that the large myelinated fibers in the ALF of the mid-cervical spinal cord of humans originate from the tegmentum of the brain stem and the lower cervical spinal cord, and not from the cerebrum, or the thoracic or lumbar spinal cord. Thus, they are descending fibers from the brain stem tegmentum and ascending fibers from the lower cervical cord, and not corticospinal tracts or long-ascending fibers from the thoracic or lumbar spinal cord. The origin of the large myelinated fibers in the ALF of the spinal cord in humans, the number of which was severely decreased in patients with amyotrophic lateral sclerosis, is considered to be the long-descending neurons in the brain stem tegmentum and the propriospinal neurons in the spinal cord. Received: 23 December 1998 / Revised, accepted: 29 March 1999     

Ascending neuropathology in the CNS of a mutant SOD1 mouse model of amyotrophic lateral sclerosis

Transgenic mice expressing a mutated human Cu/Zn superoxide dismutase (SOD1) gene develop a motor neuron disease similar to familial amyotrophic lateral sclerosis (FALS). While the histopathology and the inflammatory reactions in the spinal cord of these mice are well described, their spatiotemporal extension into brain areas and the relationship between degenerative and inflammatory events remain obscure. In the present study, we investigated the time course and extent of degenerative changes and inflammatory reactions in the CNS during progression of the disease in a transgenic FALS model, the SOD1-G93A mouse with histological and immunohistochemical methods. Compared to non-transgenic littermates, the SOD1-G93A transgenics developed widespread degeneration in both motor and extra-motor regions up to telencephalic regions, including the cerebral cortex but sparing distinct regions like the striatum and hippocampus. We provide evidence that these degenerative processes are accompanied by intense inflammatory reactions in the brain, which spatiotemporally correlate with degeneration and comprise besides strong astro- and microgliotic reactions also an influx of peripheral immune cells such as T-lymphocytes and dendritic cells. Both degeneration and inflammatory reactions spread caudocranially, starting at 2 months in the spinal cord and reaching the telencephalon at 5 months of age. Since the corticospinal tract lacked any signs of degeneration, we conclude that the upper and the lower motor neurons degenerate independently of each other.     

Spongy degeneration in the central nervous system of domestic animals

Spongy degeneration or status spongiosus of the central nervous system (CNS) was described in a number of domestic animal species, notably sheep, cattle, pigs and in one goat. The condition was characterized by diffuse or focal vacuolation, or polymicrocavitation of the CNS, particularly the white matter. The vacuolation showed a well defined pattern of distribution following a number of myelinated tracts in CNS white matter, in isolated fibres crossing grey matter in the brain stem, and along grey and white matter borders in the cerebrum and spinal cord. The vacuoles were not altered by a variety of methods of rapid brain fixation, processing and staining. The appearance of the vacuolation repeatedly favouring the same areas in the CNS in a large number of animals studied, its common origin either by hepatocerebral disease or hyperammonaemia, strongly suggests that CNS spongy degeneration of domestic animals is a distinct disease entity.     

Ultrastructural pathology of nerve fibers in calcium-induced myelopathy

Calcium has been proposed as a mediator of nerve fiber degeneration following traumatic injury of the spinal cord. It induces a spongy, necrotizing myelopathy similar in its evolution to that observed in experimental spinal cord trauma. The current study was undertaken to determine the ultrastructural changes in the central nervous system (CNS) nerve fibers associated with calcium-induced myelopathy. A 10% calcium chloride (CaCl2) solution (pH 7.4) was slowly dripped on the dorsal surface of the surgically exposed lower thoracolumbar spinal cord of adult male Sprague-Dawley rats. The posterior and lateral columns of the spinal cords were fixed and processed for electron microscopy. Controls consisted of tissue from normal and sham-operated animals, as well as those receiving equal volumes and osmolarities of sodium chloride (NaCl), magnesium chloride (MgCl2), and potassium chloride (KCl) at the same pH. In the CaCl2 treated animals, spongiosis of increasing severity developed in white matter, as the result of periaxonal, adaxonal and intramyelinic swelling. Vesicular demyelination was consistently observed, beginning within one hour (h) and progressing with increasing severity up to 24-72 h. Axonal changes included pleomorphic spheroids, granular degeneration and intra-axonal calcification. The ultrastructural changes in the nerve fibers provoked by calcium were indistinguishable from those previously reported in experimental spinal cord trauma. These observations strengthen the hypothesis that calcium initiates the nerve fiber degeneration following spinal cord injury.     

Age-related changes in radial-arm maze learning and basal forebrain cholinergic systems in senescence accelerated mice (SAM).

Age-related changes in learning performance and the brain cholinergic system were studied in a senescence accelerated mice-prone series (SAM-P/8) and a senescence accelerated mice-resistant series (SAM-R/1, control) bred under specific pathogen-free conditions. In a radial-arm maze task, SAM-P/8 mice at 4 and 12 months of age showed virtually no significant impairment in working memory or reference memory compared with SAM-R/1 mice at the same age, although they needed more time to complete a trial than SAM-R/1. In contrast, in a passive avoidance task, SAM-P/8 showed a marked age-accelerated deficit in acquisition performance relative to SAM-R/1. Also, SAM-P/8 showed an age-accelerated decrease in locomotion and rearing in an open-field box. At the end of these behavioral tasks, neurochemical analyses showed that there were no differences in the concentrations of acetylcholine (ACh) in the cortex, hippocampus, striatum, midbrain, or cerebellum between SAM-P/8 and SAM-R/1. Although SAM-P/8 mice did not demonstrate any age-accelerated decline in radial-arm maze performance, they showed a normal age-related decline particularly in working memory, equal to that observed in SAM-R/1. Also, ACh levels in the aged groups of SAM-P/8 showed a significant decrease related to normal aging in the hippocampus and striatum, and a slight decrease in the cortex compared to the young group of the same strain. Thus, we found that SAM-P/8 show dissociative effects of aging in spatial learning and passive avoidance performance.     

Experimental spongy degeneration in calves

Summary Experimental reproduction and ultrastructural findings of spongy degeneration of the central nervous system of hyperammonemic calves are described. Hyperammonemia was produced by intravenous infusion of ammonium acetate. Histologic findings were stereotyped in all calves and characterized by widespread vacuolation of white and grey matter of the brain and spinal cord. Electron microscopy revealed widespread intramyelinic vacuoles, some expansion of extracellular spaces and swollen mitochondria. There were minimal changes in neurons, axons and glia, and little evidence of myelin breakdown. Hyperammonemia may be one of the pathogeneses involved in the CNS spongy degeneration in man and domestic animals affected with hepatocerebral diseases and some hereditary disorders.