Synchrotron infrared microspectroscopy of biological tissues: brain tissue from TgCRND8 Alzheimer’s disease mice and developing scar tissue in rats

Rak, Margaret

10 April 2007

Biological tissues were studied with synchrotron infrared (IR) microspectroscopy, a technique that allows the spatially resolved determination and mapping of multiple components in situ at high spatial resolution. The first project involved studying brain tissue from TgCRND8 mice, a transgenic model of Alzheimer’s disease (AD). AD is the main cause of dementia in the ageing population, marked by the deposition of plaques composed of the Aβ peptide. Dense-cored and diffuse plaques were IR mapped and the results correlated with histochemistry and immunostaining. Spectral analysis confirmed that congophilic plaque cores were composed of highly aggregated protein in a β-sheet conformation. The amide I maximum of plaque cores was 1623 cm-1; there was no evidence of the high frequency (1680-1690 cm-1) peak seen in in vitro Aβ fibrils and attributed to anti-parallel β-sheet. A significant elevation in phospholipids was found around dense-cored plaques in TgCRND8 mice ranging in age from 5 to 21 months. This was due to an increase in cellular membranes from dystrophic neurites and glial cells around the core, but could also contribute to Aβ aggregation through the interaction of newly secreted Aβ with phospholipids. In contrast, diffuse plaques were not associated with infrared detectable changes in protein secondary structure or relative concentrations of other tissue components. In addition, focally elevated deposits of creatine, a molecule with a crucial role in energy metabolism, were discovered in AD brain tissue with IR microspectroscopy. The creatine deposits may be a previously undiscovered disease marker. A second project was part of a larger Natural Sciences and Engineering Research Council Collaborative Health Research Project (NSERC-CHRP) to test the hypothesis that treatment with anti-oxidants, L-2-oxo-thiazolidine-4-carboxylate (OTC) and quercetin, following spinal surgery may reduce oxidative stress, inflammation, and scarring. The effect of OTC and quercetin on scar tissue formation was evaluated in rats that had undergone laminectomy. Synchrotron IR microspectroscopy data were collected on scar tissue from OTC, quercetin and saline (control) treated animals, sacrificed at 3 and 21 days post-surgery. Spectral differences could be correlated with the stages of wound healing. / May 2007

infrared

microspectroscopy

synchrotron

Alzheimer's disease

scar tissue

amyloid

plaques

infrared mapping

TgCRND8 mice

creatine

Synchrotron infrared microspectroscopy of biological tissues: brain tissue from TgCRND8 Alzheimer’s disease mice and developing scar tissue in rats

Rak, Margaret

10 April 2007

Biological tissues were studied with synchrotron infrared (IR) microspectroscopy, a technique that allows the spatially resolved determination and mapping of multiple components in situ at high spatial resolution. The first project involved studying brain tissue from TgCRND8 mice, a transgenic model of Alzheimer’s disease (AD). AD is the main cause of dementia in the ageing population, marked by the deposition of plaques composed of the Aβ peptide. Dense-cored and diffuse plaques were IR mapped and the results correlated with histochemistry and immunostaining. Spectral analysis confirmed that congophilic plaque cores were composed of highly aggregated protein in a β-sheet conformation. The amide I maximum of plaque cores was 1623 cm-1; there was no evidence of the high frequency (1680-1690 cm-1) peak seen in in vitro Aβ fibrils and attributed to anti-parallel β-sheet. A significant elevation in phospholipids was found around dense-cored plaques in TgCRND8 mice ranging in age from 5 to 21 months. This was due to an increase in cellular membranes from dystrophic neurites and glial cells around the core, but could also contribute to Aβ aggregation through the interaction of newly secreted Aβ with phospholipids. In contrast, diffuse plaques were not associated with infrared detectable changes in protein secondary structure or relative concentrations of other tissue components. In addition, focally elevated deposits of creatine, a molecule with a crucial role in energy metabolism, were discovered in AD brain tissue with IR microspectroscopy. The creatine deposits may be a previously undiscovered disease marker. A second project was part of a larger Natural Sciences and Engineering Research Council Collaborative Health Research Project (NSERC-CHRP) to test the hypothesis that treatment with anti-oxidants, L-2-oxo-thiazolidine-4-carboxylate (OTC) and quercetin, following spinal surgery may reduce oxidative stress, inflammation, and scarring. The effect of OTC and quercetin on scar tissue formation was evaluated in rats that had undergone laminectomy. Synchrotron IR microspectroscopy data were collected on scar tissue from OTC, quercetin and saline (control) treated animals, sacrificed at 3 and 21 days post-surgery. Spectral differences could be correlated with the stages of wound healing.

infrared

microspectroscopy

synchrotron

Alzheimer's disease

scar tissue

amyloid

plaques

infrared mapping

TgCRND8 mice

creatine

Synchrotron infrared microspectroscopy of biological tissues: brain tissue from TgCRND8 Alzheimer’s disease mice and developing scar tissue in rats

Rak, Margaret

10 April 2007

Biological tissues were studied with synchrotron infrared (IR) microspectroscopy, a technique that allows the spatially resolved determination and mapping of multiple components in situ at high spatial resolution. The first project involved studying brain tissue from TgCRND8 mice, a transgenic model of Alzheimer’s disease (AD). AD is the main cause of dementia in the ageing population, marked by the deposition of plaques composed of the Aβ peptide. Dense-cored and diffuse plaques were IR mapped and the results correlated with histochemistry and immunostaining. Spectral analysis confirmed that congophilic plaque cores were composed of highly aggregated protein in a β-sheet conformation. The amide I maximum of plaque cores was 1623 cm-1; there was no evidence of the high frequency (1680-1690 cm-1) peak seen in in vitro Aβ fibrils and attributed to anti-parallel β-sheet. A significant elevation in phospholipids was found around dense-cored plaques in TgCRND8 mice ranging in age from 5 to 21 months. This was due to an increase in cellular membranes from dystrophic neurites and glial cells around the core, but could also contribute to Aβ aggregation through the interaction of newly secreted Aβ with phospholipids. In contrast, diffuse plaques were not associated with infrared detectable changes in protein secondary structure or relative concentrations of other tissue components. In addition, focally elevated deposits of creatine, a molecule with a crucial role in energy metabolism, were discovered in AD brain tissue with IR microspectroscopy. The creatine deposits may be a previously undiscovered disease marker. A second project was part of a larger Natural Sciences and Engineering Research Council Collaborative Health Research Project (NSERC-CHRP) to test the hypothesis that treatment with anti-oxidants, L-2-oxo-thiazolidine-4-carboxylate (OTC) and quercetin, following spinal surgery may reduce oxidative stress, inflammation, and scarring. The effect of OTC and quercetin on scar tissue formation was evaluated in rats that had undergone laminectomy. Synchrotron IR microspectroscopy data were collected on scar tissue from OTC, quercetin and saline (control) treated animals, sacrificed at 3 and 21 days post-surgery. Spectral differences could be correlated with the stages of wound healing.

infrared

microspectroscopy

synchrotron

Alzheimer's disease

scar tissue

amyloid

plaques

infrared mapping

TgCRND8 mice

creatine

Implication des métabolites de l'APP dans les troubles mnésiques précoces chez la souris TgCRND8, un modèle de la maladie d'Alzheimer / Differential contribution of APP metabolites to early memory deficits in a TgCRND8 mouse model of Alzheimer’s disease

Hamm - Haouari, Valentine

06 December 2016

La maladie d’Alzheimer (MA) est une pathologie neurodégénérative communément caractérisée par une perte progressive de la mémoire. L’étiologie de la MA demeure incertaine à ce jour ce qui complique l’élaboration de stratégies thérapeutiques permettant de l’éradiquer. L’accumulation des échecs thérapeutiques pourrait en partie s’expliquer par le fait que l’hypothèse amyloïde, qui met en avant l’implication prépondérante du peptide bêta-amyloïde (Aβ) dans la physiopathologie de la MA, serait incomplète. En utilisant un modèle murin transgénique de la MA, la souris TgCRND8, j’ai pu compléter l’hypothèse amyloïde en proposant l’implication, en plus de l’Aβ, du fragment carboxy-terminal bêta (β-CTF). Ces deux métabolites amyloïdogéniques de l’APP seraient responsables de l’altération de formes différentes de mémoire. Le dosage de ces métabolites dans l’hippocampe, suite au traitement chronique des souris avec un inhibiteur de β ou de γ-secrétase, a mis en évidence que le β-CTF serait responsable de l’atteinte de la mémoire impliquée dans la détection du remplacement d’un objet, alors que l’Aβ perturberait la mémoire permettant la détection du déplacement d’un objet. Ces travaux suggèrent qu’il serait judicieux de développer de nouvelles stratégies thérapeutiques qui diminuent à la fois les niveaux cérébraux des deux fragments amyloïdogéniques, le β-CTF et l’Aβ. / Alzheimer’s disease (AD) is a neurodegenerative pathology commonly characterized by a progressive memory loss. To these days, AD’s etiology has remained unclear which complicates the development of therapeutic strategies enabling to eradicate the pathology. The accumulation of therapeutic failures could partly be explained by the fact that the amyloid hypothesis, which highlights the leading involvement of the amyloid beta peptide (Aβ) in the physiopathology of AD, could be incomplete. Using a transgenic mouse model of AD, the TgCRND8 mice strain, I expanded the amyloid hypothesis, suggesting the involvement of the beta carboxy-terminal fragment (β-CTF), in addition to Aβ. These two amyloidogenic metabolites could be responsible for the alteration of different forms of memory. The dosage of these metabolites, after mice chronic treatment with either a β- or a γ-secretase inhibitor, highlighted the fact that β-CTF could be responsible for the deterioration of the memory involved in the detection of the replacement of an object. As for Aβ, it could disrupt the memory allowing the detection of the displacement of an object. This work suggests that it would be judicious to develop therapeutic strategies reducing brain levels of both amyloid fragments, β-CTF and Aβ.

Maladie d’Alzheimer

Souris TgCRND8

Β-CTF

Aβ

Inhibiteurs des secrétases β et γ

Activité oscillatoire

Parvalbumine

Anti-inflammatoires non stéroïdiens

Alzheimer’s disease

TgCRND8 mice

Β-CTF

Aβ

Β- and γ-secretase inhibitors

Oscillatory activity

Parvalbumin

Non-steroidal anti-inflammatory drugs

572.8

616.83