Neuronal internalization of immunoglobulin G injected into the mouse brain by a novel absorption strategy to avoid unwanted interaction with immune complex using centrifugal filtration.

Monoclonal immunoglobulin-G (IgG) antibodies are now emerging as therapeutic tools to tackle various disorders, including those affecting the brain. However, little is known about how these IgG molecules behave in the brain. To better understand the potential behavior of IgG molecules in the brain, here we established a specific protocol to immunolocalize rat IgG injected into mouse striatum with an anti-rat IgG antibody. Using double immunolabeling, IgG-like immunoreactivity (IR) was mainly found in neurons but scarcely observed in glia 1 h after intrastriatal injection of IgG, whereas some surrounding glia contained IgG-like IR 24 h after injection. However, preabsorption with a large excess of rat IgG to confirm the authenticity of this labeling failed to eliminate this neuronal IgG-like IR but rather exhibited nuclear staining in glial cells. Because this unexpected nuclear staining escalated with increasing amount of absorbing IgG, we postulated that this nuclear staining is due to formation of immune complex IgG-anti-IgG, which can be removed by centrifugal filtration. As expected, this nuclear staining in glial cells was eliminated after centrifugal filtration of the IgG/anti-IgG mixture, and authentic IgG-like IR was chiefly detected in the cytoplasm of neurons around the injection channel. This study is the first demonstration of neuronal redistribution of injected IgG in the mouse brain. Neuronal internalization of exogenous IgG may be advantageous especially when the therapeutic targets of monoclonal IgG are intraneuronal such as neurofibrillary tangles or Lewy bodies.