Glial cells in the central nervous system (CNS) maintain the homeostasis of the internal environment. Glial cells and especially astrocytes (AS) form glial scars through activation and proliferation. AS secrete a variety of inhibitory factors stimulated by injury, ischemia, blood-brain barrier damage, inflammatory reaction, abnormal metabolism and oxidative stress. These external factors critically affect axon regeneration and recovery of neurological function in the CNS (1). Increased expression of glial fibrillary acidic protein (GFAP) is one of the most important markers of AS activation (2). Culturing neurons and AS together show that local inflammatory response is significantly enhanced by inhibiting GFAP production (3). GFAP inhibition increased neuronal death, suggesting the protective effects of GFAP in the nervous system injury (3). The AS intermediate filament protein system, which includes GFAP, is not only an important component of the cytoskeleton but also a vital signaling system that responds to a variety of stress conditions, and regulates cell size, migration and survival via multiple proteins (4). The 14-3-3 protein is widely distributed in all tissues and is one of the most abundant proteins in CNS, accounting for 1% of soluble protein content (5). 14-3-3 proteins are involved in regulating most critical cell activities, including signal transduction, cell cycle regulation, apoptosis, cytoskeleton dynamics, ionic, and protein transmembrane transport, making 14-3-3 a potential therapeutic target for many conditions (6). In this study, we generated an in vivo injury model with AS to study the expression of GFAP and 14-3-3ε.

Our studies suggest that expression of GFAP and 14-3-3ε increase with time during hypoxia, and that GFAP and 14-3-3ε co-localize in the cytoplasm in cultured AS. AS are involved in most critical aspects of CNS function. i) AS provide support and energy nutrition for neuronal survival, development, differentiation, and regeneration (7). ii) AS contribute to neurotransmitter uptake and degradation, regulating the synaptic connections, and signal transduction (8). iii) AS have immune activity, expressing signal of MHCII molecules and co-stimulatory, and participating in antigen presentation and activation of T cells (9). iv) AS play an important role in the formation of the endothelial barrier, maintaining their morphology, releasing a variety of chemical substances, and regulating the permeability of endothelia cells as an important component of CNS blood-brain barrier (10). v) AS regulate the immune inflammatory reaction of CNS by secreting cytokine and inflammatory factors, thereby contributing complex behavior of the whole body, such as pain, appetite, sleep and mood through the circulatory system (11). AS can also clear the excitatory glutamate and potassium ions at the site of injury and play a protective role in the survival of neurons (12). AS can secrete Wnt3, interleukin (IL)-1, IL-6, insulin-like growth factor binding protein 6, and other substances to promote the colonization of stem cells, providing a favorable microenvironment for nerve regeneration (13).

GFAP is an intermediate filament protein with a diameter of 8–9 nm that is present mainly in AS. GFAP has no special contribution in the normal nervous system, but plays a vital role in the glial scar and the activation of AS. Activation of AS and expression of GFAP inhibits inflammatory response after injury, effectively limiting the damage within a controllable region (14). Treatment with the dopaminergic neurotoxin MPTP selectively damaged the nerve endings and started AS activation, which induced and promoted transcription and translation of GFAP by JAK/STAT3 signaling pathway (15). The expression of GFAP and vimentin was inhibited in GFAP^−/− and Vim^−/− transgenic mice, which demonstrated that infarct area after ischemic stroke in transgenic mice were significantly increased compared with the control group. In the ischemia injury GOD model, generation and accumulation of ROS increased significantly in transgenic group, resulting in more nerve cell death, suggesting that GFAP was particularly important to reduce oxidative stress injury in the acute phase of the cells (16). With the continued progress of the injury and AS activation, GFAP expression increased progressively becoming an important factor in promoting glial cicatrization, although it was not conducive in restoring nerve function and nerve regeneration (17). How to effectively take advantage of GFAP protective role in early response to damage, while finding the right time to inhibit its activity to prevent the formation of glial scar, are important questions for future study.

Inflammation, vascular dementia, cancer, metabolic diseases, epilepsy, mental disorders, and other nervous system disorders lead to abnormal expression of 14-3-3 in the cerebrospinal fluid. For this, 14-3-3 is considered a marker of damaged nerve cells and its level of expression may be related to the extent of injury (18). 14-3-3ε binding to the multiple molecules of the Ras/MAPK signaling pathway has critical functions as a cytoskeletal protein and regulates protein synthesis, metabolism, DNA damage and repair, and the cell cycle (19). Chronic high expression of 14-3-3ε during injury inhibits AS apoptosis after injury (20) and promotes the activation of AS by inflammation reaction in early response through the ERK1/2 and NF-κB signaling pathways (21). In addition, activated MAPK pathway secretes TNF-α, IL-1β, and other inflammatory mediators, indirectly activates the JAK/STAT3 pathway, promotes AS activation and secreting GFAP, and many other inflammatory factors, which increase the inflammatory immune response to damage, further altering the function of synapses and neurons (22).