Quantification of Tau-A in serum after brain injury: a comparison of two analytical platforms, ELISA and electrochemiluminescence immunoassay.

BACKGROUND: Previous studies have indicated the utility of the ADAM10-generated fragment of tau, Tau-A, as marker of neuronal damage. However, the sensitivity of the ELISA-based system was limited. OBJECTIVES: We utilized the extensive dynamic range of electrochemiluminescence compared to colorimetric assessment to improve the sensitivity of the Tau-A assay and investigate Tau-A levels after brain injury. METHODS: We converted the Tau-A competitive ELISA to a competitive electrochemiluminescence-based immunoassay, Tau-A ECLIA, and compared the methods by measuring serum samples in a TBI (n = 40) and a stroke cohort (n = 64). RESULTS: The Tau-A ECLIA was technically robust. Only 1% of the samples was below the detection limit in the ECLIA compared to 10.6% in the ELISA . Tau-A measured in both assays could discriminate between patients with a TBI and non-trauma controls (ELISA: p = 0.0005, ECLIA: p = 0.0002). The increased dynamic range of the Tau-A ECLIA also allowed discrimination between healthy controls from patients with hemorrhagic (p = 0.0172) and severe ischemic stroke (p = 0.0118) respectively, as well as patients with mild ischemic stroke from severe (p = 0.0445). CONCLUSIONS: The Tau-A ECLIA was characterized by dynamic range compared to the ELISA, which facilitated a better separation between the patient groups. Tau-A warrants further investigation as a neuronal injury associated marker.

Peripheral Tumor Necrosis Factor-Alpha (TNF-α) Modulates Amyloid Pathology by Regulating Blood-Derived Immune Cells and Glial Response in the Brain of AD/TNF Transgenic Mice.

Increasing evidence has suggested that systemic inflammation along with local brain inflammation can play a significant role in Alzheimer's disease (AD) pathogenesis. Identifying key molecules that regulate the crosstalk between the immune and the CNS can provide potential therapeutic targets. TNF-α is a proinflammatory cytokine implicated in the pathogenesis of systemic inflammatory and neurodegenerative diseases, such as rheumatoid arthritis (RA) and AD. Recent studies have reported that anti-TNF-α therapy or RA itself can modulate AD pathology, although the underlying mechanism is unclear. To investigate the role of peripheral TNF-α as a mediator of RA in the pathogenesis of AD, we generated double-transgenic 5XFAD/Tg197 AD/TNF mice that develop amyloid deposits and inflammatory arthritis induced by human TNF-α (huTNF-α) expression. We found that 5XFAD/Tg197 mice display decreased amyloid deposition, compromised neuronal integrity, and robust brain inflammation characterized by extensive gliosis and elevated blood-derived immune cell populations, including phagocytic macrophages and microglia. To evaluate the contribution of peripheral huTNF-α in the observed brain phenotype, we treated 5XFAD/Tg197 mice systemically with infliximab, an anti-huTNF-α antibody that does not penetrate the blood-brain barrier and prevents arthritis. Peripheral inhibition of huTNF-α increases amyloid deposition, rescues neuronal impairment, and suppresses gliosis and recruitment of blood-derived immune cells, without affecting brain huTNF-α levels. Our data report, for the first time, a distinctive role for peripheral TNF-α in the modulation of the amyloid phenotype in mice by regulating blood-derived and local brain inflammatory cell populations involved in ß-amyloid clearance.SIGNIFICANCE STATEMENT Mounting evidence supports the active involvement of systemic inflammation, in addition to local brain inflammation, in Alzheimer's disease (AD) progression. TNF-α is a pluripotent cytokine that has been independently involved in the pathogenesis of systemic inflammatory rheumatoid arthritis (RA) and AD. Here we first demonstrate that manipulation of peripheral TNF-α in the context of arthritis modulates the amyloid phenotype by regulating immune cell trafficking in the mouse brain. Our study suggests that additionally to its local actions in the AD brain, TNF-α can also indirectly modulate amyloid pathology as a regulator of peripheral inflammation. Our findings may have significant implications in the treatment of RA patients with anti-TNF-α drugs and in the potential use of TNF-targeted therapies for AD.

Genetic Deletion of Tumor Necrosis Factor-α Attenuates Amyloid-ß Production and Decreases Amyloid Plaque Formation and Glial Response in the 5XFAD Model of Alzheimer's Disease.

Increasing evidence suggests that neuroinflammation comprises a major characteristic of Alzheimer's disease (AD). Tumor necrosis factor-α (TNF-α) is a pleiotropic pro-inflammatory cytokine implicated in neurodegenerative diseases including AD, and has been proposed as a potent therapeutic target for AD. Although a number of studies focusing on pharmacological or genetic manipulation of TNF-α and its receptors in AD mice have provided significant knowledge regarding the role of TNF-α signaling pathway in the pathogenesis of AD, the consequences of TNF-α genetic deletion have not been thoroughly examined. Here, we focused on the effect of TNF-α deficiency on the amyloid phenotype of 5XFAD mice. Our analysis revealed that amyloid deposition, amyloid-ß (Aß) levels, and AßPP-carboxyterminal fragments are significantly reduced in the brains of 5XFAD/TNF-α-/- mice compared to the 5XFAD/TNF-α+/+. We found decreased protein levels of ß- and α-secretases in the 5XFAD/TNF-α-/- brains, suggesting for an effect of TNF-α on AßPP processing and Aß generation. We also show for the first time that TNF-α affects PS1in vivo, as 5XFAD mice lacking TNF-α expression display reduced PS1-carboxyterminal fragments implying for diminished PS1 activity. Moreover, TNF-α deficiency decreases microglial and astrocytic activation and significantly restricts the phagocytic activity of macrophages against Aß, supporting for reduced responsiveness of phagocytes toward Aß. Overall, our results reveal that TNF-α genetic deletion in 5XFAD mice attenuates amyloid plaque formation by lowering Aß generation through the reduction of functionally active PS1 and ß-secretase rather than promoting Aß clearance by phagocytic cells. Our data further suggest TNF-α inhibition as a therapeutic approach for AD.