A. M. Palmer scite author profile

Neuronal ceroid lipofuscinoses (NCLs; Batten disease) are collectively the most frequent autosomal-recessive neurodegenerative disease of childhood, but the underlying cellular and molecular mechanisms remain unclear. Several lines of evidence have highlighted the important role that non-somatic compartments of neurons (axons and synapses) play in the instigation and progression of NCL pathogenesis. Here, we report a progressive breakdown of axons and synapses in the brains of two different mouse models of NCL: Ppt1−/− model of infantile NCL and Cln6nclf model of variant late-infantile NCL. Synaptic pathology was evident in the thalamus and cortex of these mice, but occurred much earlier within the thalamus. Quantitative comparisons of expression levels for a subset of proteins previously implicated in regulation of axonal and synaptic vulnerability revealed changes in proteins involved with synaptic function/stability and cell-cycle regulation in both strains of NCL mice. Protein expression changes were present at pre/early-symptomatic stages, occurring in advance of morphologically detectable synaptic or axonal pathology and again displayed regional selectivity, occurring first within the thalamus and only later in the cortex. Although significant differences in individual protein expression profiles existed between the two NCL models studied, 2 of the 15 proteins examined (VDAC1 and Pttg1) displayed robust and significant changes at pre/early-symptomatic time-points in both models. Our study demonstrates that synapses and axons are important early pathological targets in the NCLs and has identified two proteins, VDAC1 and Pttg1, with the potential for use as in vivo biomarkers of pre/early-symptomatic axonal and synaptic vulnerability in the NCLs.

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Gamma-Aminobutyric Acid Concentration in Brain Tissue at Two Stages of Alzheimer's Disease

Lowe¹,

Francis

Procter

et al. 1988

Brain

126

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The concentration of the inhibitory neurotransmitter, gamma-aminobutyric acid (GABA), was measured in the cerebral cortex obtained at diagnostic craniotomy from 10 patients with Alzheimer's disease of 3 yrs mean duration and 6 patients with other causes of dementia, and from 31 subjects undergoing other neurosurgical procedures (for which removal of apparently normal tissue was necessary). GABA content of 5 areas of the cerebral cortex and the cerebellar cortex was measured postmortem in the brains of 23 Alzheimer and 19 control subjects and 5 patients with other causes of dementia. Fourteen of these specimens, including 7 from patients with Alzheimer's disease of 8 yrs mean duration, were obtained within 3 h of death. These were processed in a similar manner to the neurosurgical specimens and are regarded also as fresh tissue samples. The remaining 33 specimens are regarded as conventional postmortem samples as the mean interval of death to autopsy was 21 h. GABA concentration in conventional autopsy specimens from Alzheimer subjects was not reduced as compared with controls in either cingulate or cerebellar cortex. In the inferior parietal cortex, agonal status confounded this comparison. The concentration was reduced in superior parietal, frontal and temporal cortex but there is a possibility that agonal state also confounded these comparisons. There was no deficit in GABA concentration in fresh cortical tissue from Alzheimer patients except for the temporal lobe from autopsy specimens. The content of somatostatin-like immunoreactivity was, like GABA, found to be comparable to control in some groups of Alzheimer specimens. It is argued that the deficits in autopsy samples and lack of change in surgical specimens is likely to be due to the duration of illness at the time of sampling. Losses of choline acetyltransferase activity were observed in all groups of Alzheimer specimens in all areas of brain studied. The data are consistent with other results which suggest that cholinergic under-activity is most closely related to the clinical course of Alzheimer's disease.

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Hippocampal synaptic activity, pattern separation and episodic-like memory: implications for mouse models of Alzheimer's disease pathology

Palmer

Good

2011

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The present review summarizes converging evidence from animal and human studies that an early target of amyloid pathology is synaptic activity in the DG (dentate gyrus)/CA3 network. We briefly review the computational significance of the DG/CA3 network in the encoding of episodic memory and present new evidence that the CA3/DG pattern of activation is compromised in a mouse model of amyloid pathology. In addition, we present a new behavioural method to test the prediction that amyloid-related synaptic pathology will disrupt the formation of an integrated episodic-like (what, where and when) memory in mice.

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Neurotransmitter and Metabolic Dysfunction in Alzheimer�s Dementia: Relationship to Histopathological Features

Bowen¹,

Davison²,

Francis³

et al.

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A. M. Palmer

Molecular correlates of axonal and synaptic pathology in mouse models of Batten disease

Gamma-Aminobutyric Acid Concentration in Brain Tissue at Two Stages of Alzheimer's Disease

Hippocampal synaptic activity, pattern separation and episodic-like memory: implications for mouse models of Alzheimer's disease pathology

Neurotransmitter and Metabolic Dysfunction in Alzheimer�s Dementia: Relationship to Histopathological Features

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