Abstract
BackgroundDiseases and disorders with a chronic neuroinflammatory component are often linked with changes in brain metabolism. Among neurodegenerative disorders, people living with human immunodeficiency virus (HIV) and Alzheimer’s disease (AD) are particularly vulnerable to metabolic disturbances, but the mechanistic connections of inflammation, neurodegeneration and bioenergetic deficits in the central nervous system (CNS) are poorly defined. The particularly interesting new cysteine histidine-rich-protein (PINCH) is nearly undetectable in healthy mature neurons, but is robustly expressed in tauopathy-associated neurodegenerative diseases including HIV infection and AD. Although robust PINCH expression has been reported in neurons in the brains of patients with HIV and AD, the molecular mechanisms and cellular consequences of increased PINCH expression in CNS disease remain largely unknown.MethodsWe investigated the regulatory mechanisms responsible for PINCH protein-mediated changes in bioenergetics, mitochondrial subcellular localization and bioenergetic deficits in neurons exposed to physiological levels of TNFα or the HIV protein Tat. Changes in the PINCH-ILK-Parvin (PIP) complex association with cofilin and TESK1 were assessed to identify factors responsible for actin depolymerization and mitochondrial mislocalization. Lentiviral and pharmacological inhibition experiments were conducted to confirm PINCH specificity and to reinstate proper protein-protein complex communication.ResultsWe identified MEF2A as the PINCH transcription factor in neuroinflammation and determined the biological consequences of increased PINCH in neurons. TNFα-mediated activation of MEF2A via increased cellular calcium induced PINCH, leading to disruption of the PIP ternary complex, cofilin activation by TESK1 inactivation, and actin depolymerization. The disruption of actin led to perinuclear mislocalization of mitochondria by destabilizing the kinesin-dependent mitochondrial transport machinery, resulting in impaired neuronal metabolism. Blocking TNFα-induced PINCH expression preserved mitochondrial localization and maintained metabolic functioning.ConclusionsThis study reported for the first time the mechanistic and biological consequences of PINCH expression in CNS neurons in diseases with a chronic neuroinflammation component. Our findings point to the maintenance of PINCH at normal physiological levels as a potential new therapeutic target for neurodegenerative diseases with impaired metabolisms.
Highlights
Diseases and disorders with a chronic neuroinflammatory component are often linked with changes in brain metabolism
PINCH is transcriptionally regulated by Myocyte enhancer factor 2A (MEF2A) under inflammatory conditions Since Tat induces tumor necrosis factor-α (TNFα) in a feed forward loop [1, 3, 5,6,7, 38, 39] (Fig. 1a), we exposed human primary neurons to Tat or TNFα to investigate the mechanisms of PINCH induction
Neurons exposed to Tat or TNFα showed significantly increased MEF2A binding to the lims1/pinch promoter (Fig. 1d), indicating
Summary
Diseases and disorders with a chronic neuroinflammatory component are often linked with changes in brain metabolism. The interesting new cysteine histidine-rich-protein (PINCH) is nearly undetectable in healthy mature neurons, but is robustly expressed in tauopathy-associated neurodegenerative diseases including HIV infection and AD. Interesting new cysteine-histidine-rich protein (PINCH) is highly expressed during development, but data from our laboratory have shown that PINCH is nearly undetectable in healthy adult brains [1,2,3,4]. PINCH is robustly expressed in the brains of patients with neuroinflammatory or neurodegenerative disease with a tauopathy component including human immunodeficiency virus (HIV) infection [1, 3, 4], Alzheimer’s disease (AD) [3], and epilepsy [2]. While the functions of the PIP complex have been extensively studied in non-neuronal cells, much less is known about the role of PIP in the central nervous system (CNS)
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