Late-long-term potentiation magnitude, but not Aβ levels and amyloid pathology, is associated with behavioral performance in a rat knock-in model of Alzheimer disease

Cleavage of Amyloid precursor protein by β- and γ-secretases lead to Aβ formation. The widely accepted pathogenic model states that these mutations cause AD via an increase in Aβ formation and accumulation of Aβ in Amyloid plaques. APP mutations cause early onset familial forms of Alzheimer’s disease (FAD) in humans. We generated App−Swedish (Apps) knock−in rats, which carry a pathogenic APP mutation in the endogenous rat App gene. This mutation increases β-secretase processing of APP leading to both augmented Aβ production and facilitation of glutamate release in Apps/s rats, via a β-secretase and APP−dependent glutamate release mechanism. Here, we studied 11 to 14-month-old male and female Apps/s rats. To determine whether the Swedish App mutation leads to behavioral deficits, Apps/s knock-in rats were subjected to behavioral analysis using the IntelliCage platform, an automated behavioral testing system. This system allows behavioral assessment in socially housed animals reflecting a more natural, less stress-inducing environment and eliminates experimenter error and bias while increasing precision of measurements. Surprisingly, a spatial discrimination and flexibility task that can reveal deficits in higher order brain function showed that Apps/s females, but not Apps/s male rats, performed significantly worse than same sex controls. Moreover, female control rats performed significantly better than control and Apps/s male rats. The Swedish mutation causes a significant increase in Aβ production in 14-month-old animals of both sexes. Yet, male and female Apps/s rats showed no evidence of AD−related amyloid pathology. Finally, Apps/s rats did not show signs of significant neuroinflammation. Given that the APP Swedish mutation causes alterations in glutamate release, we analyzed Long-term potentiation (LTP), a long-lasting form of synaptic plasticity that is a cellular basis for learning and memory. Strikingly, LTP was significantly increased in Apps/s control females compared to both Apps/s sexes and control males. In conclusion, this study shows that behavioral performances are sex and App-genotype dependent. In addition, they are associated with LTP values and not Aβ or AD-related pathology. These data, and the failures of anti-Aβ therapies in humans, suggest that alternative pathways, such as those leading to LTP dysfunction, should be targeted for disease-modifying AD therapy.

[1]  L. D’Adamio,et al.  Initial assessment of the spatial learning, reversal, and sequencing task capabilities of knock-in rats with humanizing mutations in the Aβ-coding region of App , 2022, PloS one.

[2]  L. D’Adamio,et al.  A familial Danish dementia rat shows impaired presynaptic and postsynaptic glutamatergic transmission , 2021, The Journal of biological chemistry.

[3]  R. Velazquez,et al.  Sex differences in the IntelliCage and the Morris water maze in the APP/PS1 mouse model of amyloidosis , 2021, Neurobiology of Aging.

[4]  Siqiang Ren,et al.  TNF-α-mediated reduction in inhibitory neurotransmission precedes sporadic Alzheimer's disease pathology in young Trem2R47H  rats. , 2020, The Journal of biological chemistry.

[5]  M. Tambini,et al.  Microglia TREM2R47H Alzheimer-linked variant enhances excitatory transmission and reduces LTP via increased TNF-α levels , 2020, eLife.

[6]  M. Tambini,et al.  Knock-in rats with homozygous PSEN1L435F Alzheimer mutation are viable and show selective γ-secretase activity loss causing low Aβ40/42 and high Aβ43 , 2020, The Journal of Biological Chemistry.

[7]  M. Tambini,et al.  Trem2 Splicing and Expression are Preserved in a Human Aβ-producing, Rat Knock-in Model of Trem2-R47H Alzheimer’s Risk Variant , 2020, Scientific Reports.

[8]  M. Tambini,et al.  Opposite changes in APP processing and human Aβ levels in rats carrying either a protective or a pathogenic APP mutation , 2020, eLife.

[9]  M. Tambini,et al.  Facilitation of glutamate, but not GABA, release in Familial Alzheimer's APP mutant Knock‐in rats with increased β‐cleavage of APP , 2019, Aging cell.

[10]  Xinran Liu,et al.  Tuning of Glutamate, But Not GABA, Release by an Intrasynaptic Vesicle APP Domain Whose Function Can Be Modulated by β- or α-Secretase Cleavage , 2019, The Journal of Neuroscience.

[11]  N. Pedersen,et al.  Differences Between Women and Men in Incidence Rates of Dementia and Alzheimer's Disease. , 2018, Journal of Alzheimer's disease : JAD.

[12]  H. Eichenbaum Prefrontal–hippocampal interactions in episodic memory , 2017, Nature Reviews Neuroscience.

[13]  Nan Wu,et al.  Effects of GABAB receptors in the insula on recognition memory observed with intellicage , 2017, Behavioral and Brain Functions.

[14]  S. Itohara,et al.  Cognitive deficits in single App knock-in mouse models , 2016, Neurobiology of Learning and Memory.

[15]  P. Castillo,et al.  APP and APLP2 interact with the synaptic release machinery and facilitate transmitter release at hippocampal synapses , 2015, eLife.

[16]  S. Ovsepian,et al.  Pharmacological Inhibition of BACE1 Impairs Synaptic Plasticity and Cognitive Functions , 2015, Biological Psychiatry.

[17]  Xinran Liu,et al.  APP Is Cleaved by Bace1 in Pre-Synaptic Vesicles and Establishes a Pre-Synaptic Interactome, via Its Intracellular Domain, with Molecular Complexes that Regulate Pre-Synaptic Vesicles Functions , 2014, PloS one.

[18]  A. Singleton,et al.  TREM2 variants in Alzheimer's disease. , 2013, The New England journal of medicine.

[19]  Lukas N. Mueller,et al.  Interactome of the amyloid precursor protein APP in brain reveals a protein network involved in synaptic vesicle turnover and a close association with Synaptotagmin-1. , 2012, Journal of proteome research.

[20]  L. D’Adamio,et al.  Inhibition of γ-secretase worsens memory deficits in a genetically congruous mouse model of Danish dementia , 2012, Molecular Neurodegeneration.

[21]  O. Arancio,et al.  β- but not γ-secretase proteolysis of APP causes synaptic and memory deficits in a mouse model of dementia , 2012, Molecular Neurodegeneration.

[22]  C. Robertson,et al.  Amyloid Precursor Protein Revisited , 2011, The Journal of Biological Chemistry.

[23]  Toshihiro Endo,et al.  Automated test of behavioral flexibility in mice using a behavioral sequencing task in IntelliCage , 2011, Behavioural Brain Research.

[24]  C. Thiel,et al.  Amyloid Precursor Protein Is Trafficked and Secreted via Synaptic Vesicles , 2011, PloS one.

[25]  Oliver Gruber,et al.  Conditioned response suppression in the IntelliCage: assessment of mouse strain differences and effects of hippocampal and striatal lesions on acquisition and retention of memory , 2010, Behavioural Brain Research.

[26]  O. Arancio,et al.  Danish dementia mice suggest that loss of function and not the amyloid cascade causes synaptic plasticity and memory deficits , 2010, Proceedings of the National Academy of Sciences.

[27]  R. Tanzi,et al.  Identification of NEEP21 as a β-Amyloid Precursor Protein-Interacting Protein In Vivo That Modulates Amyloidogenic Processing In Vitro , 2010, The Journal of Neuroscience.

[28]  P. Wong,et al.  BACE1 Knock-Outs Display Deficits in Activity-Dependent Potentiation of Synaptic Transmission at Mossy Fiber to CA3 Synapses in the Hippocampus , 2008, The Journal of Neuroscience.

[29]  Shaomin Li,et al.  Amyloid-β protein dimers isolated directly from Alzheimer's brains impair synaptic plasticity and memory , 2008, Nature Medicine.

[30]  G. Collingridge,et al.  Presynaptic mechanisms involved in the expression of STP and LTP at CA1 synapses in the hippocampus , 2007, Neuropharmacology.

[31]  K. Blennow,et al.  Intrathecal inflammation precedes development of Alzheimer’s disease , 2003, Journal of neurology, neurosurgery, and psychiatry.

[32]  Carl W. Cotman,et al.  Common Structure of Soluble Amyloid Oligomers Implies Common Mechanism of Pathogenesis , 2003, Science.

[33]  J. Sutcliffe,et al.  Heterogeneous expression of the triggering receptor expressed on myeloid cells‐2 on adult murine microglia , 2002, Journal of neurochemistry.

[34]  C. Plata-salamán,et al.  Inflammation and Alzheimer’s disease , 2000, Neurobiology of Aging.

[35]  B. Winblad,et al.  Excessive production of amyloid beta-protein by peripheral cells of symptomatic and presymptomatic patients carrying the Swedish familial Alzheimer disease mutation. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[36]  B. Winblad,et al.  Increased β‐amyloid release and levels of amyloid precursor protein (APP) in fibroblast cell lines from family members with the Swedish Alzheimer's disease APP670/671 mutation , 1994, FEBS letters.

[37]  E. Kandel,et al.  Recruitment of long-lasting and protein kinase A-dependent long-term potentiation in the CA1 region of hippocampus requires repeated tetanization. , 1994, Learning & memory.

[38]  D. Selkoe,et al.  Mutation of the β-amyloid precursor protein in familial Alzheimer's disease increases β-protein production , 1992, Nature.

[39]  L. Squire,et al.  The medial temporal lobe memory system , 1991, Science.

[40]  Brenda Milner,et al.  The role of the right hippocampus in the recall of spatial location , 1981, Neuropsychologia.

[41]  W. Regehr,et al.  Short-term synaptic plasticity. , 2002, Annual review of physiology.

[42]  Ove Almkvist,et al.  Early diagnosis of Alzheimer dementia based on clinical and biological factors , 1999, European Archives of Psychiatry and Clinical Neuroscience.