Transmissible long-term neuroprotective and pro-cognitive effects of 1-42 beta-amyloid with A2T icelandic mutation in an Alzheimer's disease mouse model.

The amyloid cascade hypothesis assumes that the development of Alzheimer's disease (AD) is driven by a self-perpetuating cycle, in which ß-amyloid (Aß) accumulation leads to Tau pathology and neuronal damages. A particular mutation (A673T) of the amyloid precursor protein (APP) was identified among Icelandic population. It provides a protective effect against Alzheimer- and age-related cognitive decline. This APP mutation leads to the reduced production of Aß with A2T (position in peptide sequence) change (Aßice). In addition, Aßice has the capacity to form protective heterodimers in association with wild-type Aß. Despite the emerging interest in Aßice during the last decade, the impact of Aßice on events associated with the amyloid cascade has never been reported. First, the effects of Aßice were evaluated in vitro by electrophysiology on hippocampal slices and by studying synapse morphology in cortical neurons. We showed that Aßice protects against endogenous Aß-mediated synaptotoxicity. Second, as several studies have outlined that a single intracerebral administration of Aß can worsen Aß deposition and cognitive functions several months after the inoculation, we evaluated in vivo the long-term effects of a single inoculation of Aßice or Aß-wild-type (Aßwt) in the hippocampus of transgenic mice (APPswe/PS1dE9) over-expressing Aß1-42 peptide. Interestingly, we found that the single intra-hippocampal inoculation of Aßice to mice rescued synaptic density and spatial memory losses four months post-inoculation, compared with Aßwt inoculation. Although Aß load was not modulated by Aßice infusion, the amount of Tau-positive neuritic plaques was significantly reduced. Finally, a lower phagocytosis by microglia of post-synaptic compounds was detected in Aßice-inoculated animals, which can partly explain the increased density of synapses in the Aßice animals. Thus, a single event as Aßice inoculation can improve the fate of AD-associated pathology and phenotype in mice several months after the event. These results open unexpected fields to develop innovative therapeutic strategies against AD.

Long term worsening of amyloid pathology, cerebral function, and cognition after a single inoculation of beta-amyloid seeds with Osaka mutation.

Alzheimer's disease (AD) is characterized by intracerebral deposition of abnormal proteinaceous assemblies made of amyloid-ß (Aß) peptides or tau proteins. These peptides and proteins induce synaptic dysfunctions that are strongly correlated with cognitive decline. Intracerebral infusion of well-defined Aß seeds from non-mutated Aß1-40 or Aß1-42 peptides can increase Aß depositions several months after the infusion. Familial forms of AD are associated with mutations in the amyloid precursor protein (APP) that induce the production of Aß peptides with different structures. The Aß Osaka (Aßosa mutation (E693Δ)) is located within the Aß sequence and thus the Aßosa peptides have different structures and properties as compared to non-mutated Aß1-42 peptides (Aßwt). Here, we wondered if a single exposure to this mutated Aß can worsen AD pathology as well as downstream events including cognition, cerebral connectivity and synaptic health several months after the inoculation. To answer this question we inoculated Aß1-42-bearing Osaka mutation (Aßosa) in the dentate gyrus of APPswe/PS1dE9 mice at the age of two months. Their cognition and cerebral connectivity were analyzed at 4 months post-inoculation by behavioral evaluation and functional MRI. Aß pathology as well as synaptic density were evaluated by histology. The impact of Aßosa peptides on synaptic health was also measured on primary cortical neurons. Remarkably, the intracerebral administration of Aßosa induced cognitive and synaptic impairments as well as a reduction of functional connectivity between different brain regions, 4 months post-inoculation. It increased Aß plaque depositions and increased Aß oligomers. This is the first study showing that a single, sporadic event as Aßosa inoculation can worsen the fate of the pathology and clinical outcome several months after the event. It suggests that a single inoculation of Aß regulates a large cascade of events for a long time.

Effect of Aß Oligomers on Neuronal APP Triggers a Vicious Cycle Leading to the Propagation of Synaptic Plasticity Alterations to Healthy Neurons.

Alterations of excitatory synaptic function are the strongest correlate to the pathologic disturbance of cognitive ability observed in the early stages of Alzheimer's disease (AD). This pathologic feature is driven by amyloid-ß oligomers (Aßos) and propagates from neuron to neuron. Here, we investigated the mechanism by which Aßos affect the function of synapses and how these alterations propagate to surrounding healthy neurons. We used complementary techniques ranging from electrophysiological recordings and molecular biology to confocal microscopy in primary cortical cultures, and from acute hippocampal and cortical slices from male wild-type and amyloid precursor protein (APP) knock-out (KO) mice to assess the effects of Aßos on glutamatergic transmission, synaptic plasticity, and dendritic spine structure. We showed that extracellular application of Aßos reduced glutamatergic synaptic transmission and long-term potentiation. These alterations were not observed in APP KO neurons, suggesting that APP expression is required. We demonstrated that Aßos/APP interaction increases the amyloidogenic processing of APP leading to intracellular accumulation of newly produced Aßos. Intracellular Aßos participate in synaptic dysfunctions as shown by pharmacological inhibition of APP processing or by intraneuronal infusion of an antibody raised against Aßos. Furthermore, we provide evidence that following APP processing, extracellular release of Aßos mediates the propagation of the synaptic pathology characterized by a decreased spine density of neighboring healthy neurons in an APP-dependent manner. Together, our data unveil a complementary role for Aßos in AD, while intracellular Aßos alter synaptic function, extracellular Aßos promote a vicious cycle that propagates synaptic pathology from diseased to healthy neurons.SIGNIFICANCE STATEMENT Here we provide the proof that a vicious cycle between extracellular and intracellular pools of Aß oligomers (Aßos) is required for the spreading of Alzheimer's disease (AD) pathology. We showed that extracellular Aßos propagate excitatory synaptic alterations by promoting amyloid precursor protein (APP) processing. Our results also suggest that subsequent to APP cleavage two pools of Aßos are produced. One pool accumulates inside the cytosol, inducing the loss of synaptic plasticity potential. The other pool is released into the extracellular space and contributes to the propagation of the pathology from diseased to healthy neurons. Pharmacological strategies targeting the proteolytic cleavage of APP disrupt the relationship between extracellular and intracellular Aß, providing a therapeutic approach for the disease.

Synaptotoxicity in Alzheimer's Disease Involved a Dysregulation of Actin Cytoskeleton Dynamics through Cofilin 1 Phosphorylation.

Amyloid-ß (Aß) drives the synaptic impairment and dendritic spine loss characteristic of Alzheimer's disease (AD), but how Aß affects the actin cytoskeleton remains unknown and contentious. The actin-binding protein, cofilin-1 (cof1), is a major regulator of actin dynamics in dendritic spines, and is subject to phospho-regulation by multiple pathways, including the Rho-associated protein kinase (ROCK) pathway. While cof1 is implicated as a driver of the synaptotoxicity characteristic of the early phases of AD pathophysiology, questions remain about the molecular mechanisms involved. Cofilin-actin rods are observed in neurons exposed to Aß oligomers (Aßo) and in tissue from AD patients, and others have described an increased cofilin phosphorylation (p-cof1) in AD patients. Here, we report elevated p-cof1 of the postsynaptic enriched fraction of synaptosomes from cortical samples of male APP/PS1 mice and human AD cases of either sex. In primary cortical neurons, Aßo induced rapid actin stabilization and increased p-cof1 in the postsynaptic compartment of excitatory synapses within 30 min. Fluorescence recovery after photobleaching of actin-GFP and calcium imaging in live neurons expressing active or inactive cof1 mutants suggest that cof1 phosphorylation is necessary and sufficient for Aßo-induced synaptic impairment via actin stabilization before the reported formation of cofilin-actin rods. Moreover, the clinically available and well-tolerated ROCK inhibitor, fasudil, prevented Aßo-induced actin stabilization, synaptic impairment, and synaptic loss by blocking cofilin phosphorylation. Aßo also blocked the LTP-induced insertion of the AMPAR subunit, GluA1, at the postsynaptic density, in a fasudil-sensitive manner. These data support an important role for ROCKs and cofilin in mediating Aß-induced synaptic impairment.SIGNIFICANCE STATEMENT We report that amyloid-ß oligomers rapidly induce aberrant stabilization of F-actin within dendritic spines, which impairs synaptic strength and plasticity. Activation of the Rho-associated protein kinase (ROCK) pathway results in phosphorylation of cof1 and is sufficient to mediate Aßo-induced actin stabilization synaptic impairment and synaptic loss. Further, the ROCK inhibitor, fasudil, prevents cofilin phosphorylation, acute synaptic disruption, and synaptotoxicity in primary cortical neurons. Together, the herein presented data provide strong support for further study of the ROCK pathway as a therapeutic target for the cognitive decline and synaptotoxicity in Alzheimer's disease.

Activity-dependent tau protein translocation to excitatory synapse is disrupted by exposure to amyloid-beta oligomers.

Tau is a microtubule-associated protein well known for its stabilization of microtubules in axons. Recently, it has emerged that tau participates in synaptic function as part of the molecular pathway leading to amyloid-beta (Aß)-driven synaptotoxicity in the context of Alzheimer's disease. Here, we report the implication of tau in the profound functional synaptic modification associated with synaptic plasticity. By exposing murine cultured cortical neurons to a pharmacological synaptic activation, we induced translocation of endogenous tau from the dendritic to the postsynaptic compartment. We observed similar tau translocation to the postsynaptic fraction in acute hippocampal slices subjected to long-term potentiation. When we performed live confocal microscopy on cortical neurons transfected with human-tau-GFP, we visualized an activity-dependent accumulation of tau in the postsynaptic density. Coprecipitation using phalloidin revealed that tau interacts with the most predominant cytoskeletal component present, filamentous actin. Finally, when we exposed cortical cultures to 100 nm human synthetic Aß oligomers (Aßo's) for 15 min, we induced mislocalization of tau into the spines under resting conditions and abrogated subsequent activity-dependent synaptic tau translocation. These changes in synaptic tau dynamics may rely on a difference between physiological and pathological phosphorylation of tau. Together, these results suggest that intense synaptic activity drives tau to the postsynaptic density of excitatory synapses and that Aßo-driven tau translocation to the spine deserves further investigation as a key event toward synaptotoxicity in neurodegenerative diseases.

Analysis of the TCR alpha-chain rearrangement profile in human T lymphocytes.

The size of the available human alphabeta T cell repertoire is difficult to determine and is open to debate. Empirical analysis of TCR beta-chain diversity reveals approximately 10(6) different beta chains in peripheral blood. Due in part to locus complexity, comparable information for TCR alpha is lacking. Rather, current estimates for human TCR alpha diversity, and hence, total repertoire diversity, are based on theoretical analyses that assume equal probabilities of rearrangement between any V alpha gene and J alpha gene. Here, we report on a systematic locus-wide rearrangement analysis of the TCR alpha-chain in human T cells. We first demonstrate that the V-J alpha recombination in the thymus is not random but depends on the reciprocal V alpha and J alpha position within the locus. Characterization of the frequency of gene usage combined with identification of five previously unrecognized pseudogenes enables us to empirically estimate the human TCR alpha combinatorial repertoire. The number of V-J alpha combinations achieved is approximately 44-56% of the total combinatorial possibilities, significantly lower than theoretical estimates. We also demonstrate that TCR alpha-chain diversity in peripheral T lymphocytes mimics the same general patterns of rearrangement as observed in the thymus, and these patterns appear conserved among different individuals. This unexpected observation indicates that, unlike the TCR beta locus, the human TCR alpha-chain repertoire is primarily predetermined by genetic recombination and its size is restricted by limits on the combinatorial repertoire rather than post-thymic selection.

Gene-specific signal joint modifications during V(D)J recombination of TCRAD locus genes in murine and human thymocytes.

V(D)J recombination assembles functional T-cell receptor (TCR) genes from V, D and J components in developing thymocytes. Extensive processing of V, D and J extremities before they are ligated creates a high degree of junctional diversity which results in the generation of a large repertoire of different TCR chains. In contrast, the extremities of the intervening DNA segment, which bear the recombination signal sequences, are generally held to be monomorphic, so that signal joints (SJs) consist of the perfect head-to-head juxtaposition of recombination signal extremities. We analyzed the structure of SJs generated during the recombination of TCRAD locus genes in murine and human thymocytes. Junctional diversity resulting from N nucleotide additions or from N nucleotide additions and base loss was found for each type of SJ examined. Different patterns of processing/modification were found, suggesting that different enzymatic activities operate during recombination of TCRA and TCRD genes, although they are located within the same genetic locus. Recombination of the deltaRec-1 element generates a diverse repertoire of SJs exhibiting both combinatorial and junctional diversity in murine and human thymocytes. Therefore, SJ diversity appears to be an intrinsic feature of V(D)J recombination in unmanipulated thymocytes.

p53-dependent and p53-independent pathways for radiation-induced immature thymocyte differentiation.

The pre-T-cell receptor (TCR) delivers essential survival/differentiation signals to the developing thymocytes. Severe combined immunodeficient (SCID) and recombination-activating gene (RAG)-deficient mice are unable to assemble antigen receptor genes, and therefore cannot express a pre-TCR. Consequently, T lymphocyte differentiation is arrested at an early stage in the thymus of these animals, and immature thymocytes are eliminated through apoptotic processes. This maturation arrest can be relieved and thymocyte differentiation rescued after the exposure of these mice to whole-body gamma-irradiation. Whereas the promotion of immature thymocyte survival/differentiation was shown to require p53 activity in irradiated SCID mice, it was suggested, on the other hand, that p53 activation prevents immature thymocytes survival/differentiation in irradiated RAG-deficient mice. However, SCID mice have impaired responses to ionizing radiation. In this paper, we analysed p53 requirement in radiation-induced thymocyte differentiation in CD3epsilon(Delta5/Delta5) mice, where pre-TCR deficiency also results in an early block of lymphocyte development. Our results show at the cellular and molecular levels that, in this DNA repair-proficient model, irradiation-induced thymocyte differentiation proceeds either by a p53-dependent or by a p53-independent pathway, which differ in their sensitivity to the radiation dose delivered.

T lymphocytes infiltrating the liver during chronic hepatitis C infection express a broad range of T-cell receptor beta chain diversity.

BACKGROUND/AIMS: During viral chronic hepatitis C (CHC), the intra-hepatic lymphocyte infiltrate is mainly composed of T lymphocytes expressing alphabeta T-cell receptors (TCR). Since little is known about the TCRalphabeta diversity of intra-hepatic T lymphocytes (IHL), we evaluated the IHL repertoire from CHC patients (n=8) as compared to healthy subjects (n=4), total peripheral blood mononuclear cells, and purified peripheral and intra-hepatic CD8(+) cells (n=2). METHODS: The diversity of TCRalphabeta receptors was evaluated by determining the size and the sequence of the TCRbeta chain complementarity determining region 3 (CDR3). The number of total T lymphocytes in liver was estimated by real-time quantitative reverse transcription-polymerase chain reaction of TCRalpha and CD3 epsilon transcripts. RESULTS: Our results show that transcripts encoding all TCR V beta (BV) families and all TCR J beta (BJ) segments were present in healthy and CHC livers. No biased TCR repertoire, in terms of preferential BV or BJ gene use or restricted CDR3 sequence, was observed in infected livers. When corrected for equivalent numbers of T lymphocytes, BJ segments utilization and CDR3 length diversity were similar in IHL and PBMC, indicating that the TCRbeta chain diversity is comparable in both cases. In addition, TCR diversity was similar in both peripheral and intra-hepatic CD8+ T cells. CONCLUSIONS: This study shows limited expansions of intra-hepatic T lymphocytes in CHC patients. The increase of T lymphocytes in infected livers correlates with diversification of TCR, arguing for the establishment of a multi-specific immune response.