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16 results on '"Oren, Iris"'

1. Amyloid Beta and Tau Cooperate to Cause Reversible Behavioral and Transcriptional Deficits in a Model of Alzheimer’s Disease

Author

Pickett, Eleanor K., Herrmann, Abigail G., McQueen, Jamie, Abt, Kimberly, Dando, Owen, Tulloch, Jane, Jain, Pooja, Dunnett, Sophie, Sohrabi, Sadaf, Fjeldstad, Maria P., Calkin, Will, Murison, Leo, Jackson, Rosemary J., Tzioras, Makis, Stevenson, Anna, d’Orange, Marie, Hooley, Monique, Davies, Caitlin, Colom-Cadena, Marti, Anton-Fernandez, Alejandro, King, Declan, Oren, Iris, Rose, Jamie, McKenzie, Chris-Anne, Allison, Elizabeth, Smith, Colin, Hardt, Oliver, Henstridge, Christopher M., Hardingham, Giles E., and Spires-Jones, Tara L.

Published
2019
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5. Circadian and Brain State Modulation of Network Hyperexcitability in Alzheimer’s Disease

Author

Brown, Rosalind, Lam, Alice D., Gonzalez-Sulser, Alfredo, Ying, Andrew, Jones, Mary, Chou, Robert Chang-Chih, Tzioras, Makis, Jordan, Crispin Y., Jedrasiak-Cape, Izabela, Hemonnot, Anne-Laure, Abou Jaoude, Maurice, Cole, Andrew J., Cash, Sydney S., Saito, Takashi, Saido, Takaomi, Ribchester, Richard R., Hashemi, Kevan, and Oren, Iris

Subjects
Male, Confirmation, Amyloid beta-Peptides, Epilepsy, circadian cycle, Mice, Transgenic, Circadian Rhythm, Mice, Inbred C57BL, Disease Models, Animal, Mice, Alzheimer Disease, 3.6, Cortical Excitability, Animals, Disorders of the Nervous System, Female, Electrocorticography, Sleep Stages, Nerve Net, Alzheimer’s disease
Abstract

Network hyperexcitability is a feature of Alzheimer’ disease (AD) as well as numerous transgenic mouse models of AD. While hyperexcitability in AD patients and AD animal models share certain features, the mechanistic overlap remains to be established. We aimed to identify features of network hyperexcitability in AD models that can be related to epileptiform activity signatures in AD patients. We studied network hyperexcitability in mice expressing amyloid precursor protein (APP) with mutations that cause familial AD, and compared a transgenic model that overexpresses human APP (hAPP) (J20), to a knock-in model expressing APP at physiological levels (APPNL/F). We recorded continuous long-term electrocorticogram (ECoG) activity from mice, and studied modulation by circadian cycle, behavioral, and brain state. We report that while J20s exhibit frequent interictal spikes (IISs), APPNL/F mice do not. In J20 mice, IISs were most prevalent during daylight hours and the circadian modulation was associated with sleep. Further analysis of brain state revealed that IIS in J20s are associated with features of rapid eye movement (REM) sleep. We found no evidence of cholinergic changes that may contribute to IIS-circadian coupling in J20s. In contrast to J20s, intracranial recordings capturing IIS in AD patients demonstrated frequent IIS in non-REM (NREM) sleep. The salient differences in sleep-stage coupling of IIS in APP overexpressing mice and AD patients suggests that different mechanisms may underlie network hyperexcitability in mice and humans. We posit that sleep-stage coupling of IIS should be an important consideration in identifying mouse AD models that most closely recapitulate network hyperexcitability in human AD.

Published
2018
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6. Maintained memory and long‐term potentiation in a mouse model of Alzheimer's disease with both amyloid pathology and human tau.

Author

Tulloch, Jane, Netsyk, Olga, Pickett, Eleanor K., Herrmann, Abigail G., Jain, Pooja, Stevenson, Anna J., Oren, Iris, Hardt, Oliver, and Spires‐Jones, Tara L.

Subjects
LONG-term potentiation, ALZHEIMER'S disease, LONG-term memory, ANIMAL disease models, AMYLOID, LONG-term synaptic depression, HYPERACTIVITY
Abstract

One of the key knowledge gaps in the field of Alzheimer's disease research is the lack of understanding of how amyloid beta and tau cooperate to cause neurodegeneration. We recently generated a mouse model (APP/PS1 + Tau) that develops amyloid plaque pathology and expresses human tau in the absence of endogenous murine tau. These mice exhibit an age‐related behavioural hyperactivity phenotype and transcriptional deficits which are ameliorated by tau transgene suppression. We hypothesized that these mice would also display memory and hippocampal synaptic plasticity deficits as has been reported for many plaque bearing mouse models which express endogenous mouse tau. We observed that our APP/PS1 + Tau model does not exhibit novel object memory or robust long‐term potentiation deficits with age, whereas the parent APP/PS1 line with mouse tau did develop the expected deficits. These data are important as they highlight potential functional differences between mouse and human tau and the need to use multiple models to fully understand Alzheimer's disease pathogenesis and develop effective therapeutic strategies. [ABSTRACT FROM AUTHOR]

Published
2021
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7. Reducing tau ameliorates behavioural and transcriptional deficits in a novel model of Alzheimer’s disease

Author

Pickett, Eleanor K, primary, Herrmann, Abigail G, additional, McQueen, Jamie, additional, Abt, Kimberly, additional, Dando, Owen, additional, Tulloch, Jane, additional, Jain, Pooja, additional, Dunnett, Sophie, additional, Sohrabi, Sadaf, additional, Fjeldstad, Maria, additional, Calkin, Will, additional, Murison, Leo, additional, Jackson, Rosemary, additional, Tzioras, Makis, additional, Stevenson, Anna, additional, D’Orange, Marie, additional, Hooley, Monique, additional, Davies, Caitlin, additional, Oren, Iris, additional, Rose, Jamie, additional, McKenzie, Chris-Anne, additional, Allison, Elizabeth, additional, Smith, Colin, additional, Hardt, Oliver, additional, Henstridge, Christopher M, additional, Hardingham, Giles, additional, and Spires-Jones, Tara L., additional

Published
2018
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8. Circadian and Brain State Modulation of Network Hyperexcitability in Alzheimer’s Disease

Author

Brown, Rosalind, primary, Lam, Alice D., additional, Gonzalez-Sulser, Alfredo, additional, Ying, Andrew, additional, Jones, Mary, additional, Chou, Robert Chang-Chih, additional, Tzioras, Makis, additional, Jordan, Crispin Y., additional, Jedrasiak-Cape, Izabela, additional, Hemonnot, Anne-Laure, additional, Abou Jaoude, Maurice, additional, Cole, Andrew J., additional, Cash, Sydney S., additional, Saito, Takashi, additional, Saido, Takaomi, additional, Ribchester, Richard R., additional, Hashemi, Kevan, additional, and Oren, Iris, additional

Published
2018
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9. Reducing Tau Ameliorates Behavioural and Transcriptional Deficits in a Novel Model of Alzheimer's Disease

Author

Pickett, Eleanor K., primary, Herrmann, Abigail G., additional, McQueen, Jamie, additional, Abt, Kimberly, additional, Dando, Owen, additional, Tulloch, Jane, additional, Jain, Pooja, additional, Dunnett, Sophie, additional, Sohrabi, Sadaf, additional, Fjeldstad, Maria, additional, Calkin, Will, additional, Murison, Leo, additional, Jackson, Rosemary J., additional, Tzioras, Makis, additional, Stevenson, Anna, additional, d’Orange, Marie, additional, Hooley, Monique, additional, Davies, Caitlin, additional, Oren, Iris, additional, Rose, Jamie, additional, McKenzie, Chris-Anne, additional, Allison, Elizabeth, additional, Smith, Colin, additional, Hardt, Oliver, additional, Henstridge, Christopher M., additional, Hardingham, Giles, additional, and Spires-Jones, Tara L., additional

Published
2018
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13. Feedforward Inhibition Underlies the Propagation of Cholinergically Induced Gamma Oscillations from Hippocampal CA3 to CAI.

Author

Zemankovics, Rita, Veres, Judit M., Oren, Iris, and Hájos, Norbert

Subjects
MEMORY, HIPPOCAMPUS (Brain), OSCILLATING chemical reactions, NEURAL transmission, KUPFFER cells
Abstract

Gamma frequency (30 - 80 Hz) oscillations are implicated in memory processing. Such rhythmic activity can be generated intrinsically in the CA3 region of the hippocampus from where it can propagate to the CAI area. To uncover the synaptic mechanisms underlying the intrahippocampal spread of gamma oscillations, we recorded local field potentials, as well as action potentials and synaptic currents in anatomically identified CAI and CA3 neurons during carbachol-induced gamma oscillations in mouse hippocampal slices. The firing of the vast majority of CA 1 neurons and all CA3 neurons was phase-coupled to the oscillations recorded in the stratum pyramidale of the CA 1 region. The predominant synaptic input to CAI interneurons was excitatory, and their discharge followed the firing of CA3 pyramidal cells at a latency indicative of monosynaptic connections. Correlation analysis of the input- output characteristics of the neurons and local pharmacological block of inhibition both agree with a model in which glutamatergic CA3 input controls the firing of CA 1 interneurons, with local pyramidal cell activity having a minimal role. The firing of phase-coupled CAI pyramidal cells was controlled principally by their inhibitory inputs, which dominated over excitation. Our results indicate that the synchronous firing of CA3 pyramidal cells rhythmically recruits CAI interneurons and that this feedforward inhibition generates the oscillatory activity in CAI. These findings identify distinct synaptic mechanisms underlying the generation of gamma frequency oscillations in neighboring hippocampal subregions. [ABSTRACT FROM AUTHOR]

Published
2013
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14. Synaptic Currents in Anatomically Identified CA3 Neurons during Hippocampal Gamma Oscillations In Vitro.

Author

Oren, Iris, Mann, Edward O., Paulsen, Ole, and Hájos, Norbert

Subjects
*INTERNEURONS, *NEURONS, *PARASYMPATHOMIMETIC agents, *HIPPOCAMPUS (Brain), *RESEARCH
Abstract

Gamma-frequency oscillations are prominent during active network states in the hippocampus. An intrahippocampal gamma generator has been identified in the CA3 region. To better understand the synaptic mechanisms involved in gamma oscillogenesis, we recorded action potentials and synaptic currents in distinct types of anatomically identified CA3 neurons during carbachol-induced (20-25 µM) gamma oscillations in rat hippocampal slices. We wanted to compare and contrast the relationship between excitatory and inhibitory postsynaptic currents in pyramidal cells and perisomatic-targeting interneurons, cell types implicated in gamma oscillogenesis, as well as in other interneuron subtypes, and to relate synaptic currents to the firing properties of the cells. We found that phasic synaptic input differed between cell classes. Most strikingly, the dominant phasic input to pyramidal neurons was inhibitory, whereas phase-coupled perisomatic-targeting interneurons often received a strong phasic excitatory input. Differences in synaptic input could account for some of the differences in firing rate, action potential phase precision, and mean action potential phase angle, both between individual cells and between cell types. There was a strong positive correlation between the ratio of phasic synaptic excitation to inhibition and firing rate over all neurons and between the phase precision of excitation and action potentials in interneurons. Moreover, mean action potential phase angle correlated with the phase of the peak of the net-estimated synaptic reversal potential in all phase-coupled neurons. The data support a recurrent mechanism of gamma oscillations, whereby spike timing is controlled primarily by inhibition in pyramidal cells and by excitation in interneurons. [ABSTRACT FROM AUTHOR]

Published
2006
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15. Synapse dysfunction in Alzheimer's disease : contributions of amyloid-beta and tau

Author

Pickett, Eleanor Kay, Spires-Jones, Tara, and Oren, Iris

Subjects
616.8, Alzheimer's disease, synapses, amyloid-beta plaques, tau tangles, plaques, oligomers
Abstract

Alzheimer's disease (AD) is characterised by memory loss, insidious cognitive decline, profound neurodegeneration, and the extracellular accumulation of amyloid-beta (Aβ) peptide in senile plaques and intracellular accumulation of tau in neurofibrillary tangles. Synaptic dysfunction and loss is the strongest pathological correlate of cognitive decline in AD with increasing evidence implicating neuropathological forms of both amyloid-beta and tau protein in this process. A large amount of evidence suggests that oligomeric forms of Aβ, associated with senile plaques, are toxic to synapses but the precise localisation of Aβ and which forms are synaptotoxic remain unknown. Using the high-resolution technique, array tomography, this thesis characterised the synaptic localisation of different forms of Aβ oligomers in a mouse model of amyloidopathy. These results show that different oligomeric Aβ species are present in both presynapses and postsynapses. This study highlights the potential of array tomography for rapid testing of aggregation state specific Aβ antibodies in brain tissue. Following these results, the presence of tau at synapses was examined. Despite the knowledge that tau spreads through defined synaptic circuits, it is currently unknown whether synapse loss occurs before the accumulation of tau or as a consequence. To address this, array tomography was used to examine a mouse model in which mutant P301L human tau is expressed primarily in the entorhinal cortex (rTgTauEC). It has previously been shown that rTgTauEC mice exhibit neuronal loss in the entorhinal cortex and synapse density loss in the middle molecular layer (MML) of the dentate gyrus at 24 months of age. The density of tau-expressing and total presynapses, and the spread of tau into the postsynapse in the MML of 3-6, 9, and 18 month old mice were examined. No loss of synapse density was observed in the MML up to 18 months of age, even in axons expressing tau. Despite the maintenance of synapse density, we see spread of human tau from presynaptic terminals to postsynaptic compartments in the MML at very early ages. This indicates that the spread of tau through neural circuits is not due to the degeneration of axon terminals and is an early feature of the disease process. Following examination of both synaptic amyloid-beta and tau in separate models, this thesis then examined how these two proteins may be synergistically working together to drive synaptic pathology. To investigate this a novel mouse model was used in which amyloid-beta deposits are present in combination with non-mutated human tau expression (APP/PS1 + hTau). These results suggested that the addition of human tau expression does not increase plaque associated synapse loss, neither does it increase the proportion of synapses colocalising with amyloid-beta. Similarly the presence of human tau at individual postsynapses was not enhanced in the presence of oligomeric Aβ. Surprisingly, intact long-term recognition memory was observed in APP/PS1 + hTau mice. However a hyperactive phenotype was detected in these mice that could be prevented upon tau suppression. This suggests a synergistic relationship may exist in the presentation of this phenotype. Finally in the last part of this thesis, synapses from post-mortem human Alzheimer's disease and age-matched controls were investigated. It has previously been suggested that both amyloid-beta and tau can interfere with mitochondrial transport to the synapse and mitochondrial function. For this reason the presence of synaptic mitochondria at both the presynapse and postsynapse was determined in order to investigate any alteration in the diseased state. A reduction in the proportion of presynapses with multiple mitochondria present was detected in anterior/posterior transverse temporal cortex (BA41/42). This was not observed in dorsolateral prefrontal cortex (BA46), suggesting either a selective vulnerability of the former brain region or a selective resistance of the latter brain region, to mitochondrial depletion at the synapse. The findings presented in this thesis demonstrate that when investigated in isolation, pathological forms of amyloid-beta are present at a subset of synapses where they may contribute to toxicity, whilst the spread of tau protein is an early feature of the disease process and occurs prior to overt synapse loss. This thesis also explores the proposed synergistic relationship between amyloid-beta and tau using a novel mouse model and human post-mortem brain tissue. Since these two proteins both have been implicated in synaptic dysfunction, investigating Aβ and tau in new mouse models and human brain tissue will be instrumental in furthering our understanding of mechanisms and features of synaptotoxicity that could be important therapeutic targets.

Published
2018

16. Short and long-term plasticity modulates the brain-wide interactions of the hippocampus : a combined electrophysiology-fMRI study

Author

Moreno, Andrea, Morris, Richard, and Oren, Iris

Subjects
hippocampus, plasticity, neocortex, frequency, modulation, fMRI, electrophysiology, LFP, mPFC, rat, propagation, activity, network, STP, LTP
Abstract

This thesis examines the functional connectivity of the hippocampus with the rest of the brain, with a focus on the neocortex. The hypothesis explored, in an animal model, is whether the frequency-dependent behaviour of certain brain connectivity relationships applies to hippocampal-neocortical connections. To encompass the temporal and spatial resolution necessary to do this, two main techniques are used in combination in most of the experimental work hereby presented: (1) electrophysiological recordings of local field potentials (LFPs), and (2) functional activity recordings of blood oxygenation level dependent (BOLD) signal using functional magnetic resonance imaging (fMRI). The main hypothesis is that the frequency-dependent behaviour of specific hippocampal synapses imposes the rules of extra-hippocampal activity propagation and hippocampal-neocortical interactions. The main discovery is that short and long-term plasticity modulates network activation, a finding suggesting a possible mechanism that could mediate the encoding and consolidation of memory traces. Chapters 1 to 3 introduce the vast literature review in which this project lies, and the general methods utilised. Chapter 4 (first experimental chapter) describes, using electrophysiology in rats, the evoked response of the main hippocampal output (CA1 neurons) when its major input (CA3 pyramidal cells) is activated at frequencies that in subsequent experiments were used to build brain-wide functional maps. CA1 spiking activity is found to be optimal in maintaining the amplitude of the population spike (PS) at beta frequencies (10-20 Hz), whereas lower (< 10 Hz) and higher (> 20 Hz) frequencies are normally less effective. Chapter 5 describes, using fMRI, how these intra-hippocampal activity patterns relate to long-range activity propagation in fMRI experiments. Hippocampal activation exhibits a linear monotonic increase with evoked frequency, whilst a network of selected structures is activated preferentially when beta frequencies are applied (mainly neocortical structures like the prefrontal and parietal cortices, motor and sensory cortices, and some subcortical structures like the nucleus accumbens and the striatum). This data is highly correlated with the PS recorded in CA1 and with multi-unit activity (MUA) and single-unit activity (SUA) simultaneously recorded in the medial prefrontal cortex (mPFC), one of the structures receiving propagated activity at beta frequencies, as described in Chapter 6. As mPFC also receives hippocampal input at a restricted beta frequency range stimulation of the dorsal hippocampus, Chapter 7 describes the use of a combined electrophysiology/fMRI approach to identify the pathway responsible for activity propagation. We performed microsurgery lesions to investigate the pathway responsible for the polysynaptic propagation of activity. Findings indicate that the septo-temporal longitudinal pathway is the one leading information transfer from dorsal to ventral hippocampus in the rat, and from there directly to the ventral subiculum, apparently by-passing entorhinal cortex. Last, in Chapter 8 the effect of durable modifications of synaptic weights by long-term potentiation (LTP) in the previously described frequency-dependent activity propagation is also described and contextualized in the memory trace consolidation framework, both electrophysiologically (Chapter 5) and with fMRI (Chapter 6). LTP is a long-lasting change in synaptic weights that, at the CA3-CA1 synapse, is capable of modifying hippocampal-neocortical connections such as to open the opportunity for higher frequency patterns (> 40 Hz) to propagate to neocortical structures. These results suggest that, by means of frequency-coding, the hippocampus normally regulates propagation of selected information to the neocortex, but that at specific moments (e.g. when the hippocampus undergoes LTP) this regulation broadens to permit high-frequency information to pass through and affect neural activity in the cortex. It is a beautifully simple mechanism that merits further detailed examination in a multi-disciplinary manner as outlined in Chapters 9 and 10.

Published
2017

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