Xingyun Chen

Local Glutamate Level Dictates Adenosine A2A Receptor Regulation of Neuroinflammation and Traumatic Brain Injury

During brain injury, extracellular adenosine and glutamate levels increase rapidly and dramatically. We hypothesized that local glutamate levels in the brain dictates the adenosine–adenosine A2A receptor (A2AR) effects on neuroinflammation and brain damage outcome. Here, we showed that, in the presence of low concentrations of glutamate, the A2AR agonist 3-[4-[2-[[6-amino-9-[(2R,3R,4S,5S)-5-(ethylcarbamoyl)-3,4-dihydroxy-oxolan-2-yl]purin-2-yl]amino]ethyl]phenyl]propanoic acid (CGS21680) inhibited lipopolysaccharide (LPS)-induced nitric oxide synthase (NOS) activity of cultured microglial cells, an effect that was dependent on the protein kinase A (PKA) pathway. However, in high concentrations of glutamate, CGS21680 increased LPS-induced NOS activity in a protein kinase C (PKC)-dependent manner. Thus, increasing the local level of glutamate redirects A2AR signaling from the PKA to the PKC pathway, resulting in a switch in A2AR effects from antiinflammatory to proinflammatory. In a cortical impact model of traumatic brain injury (TBI) in mice, brain water contents, behavioral deficits, and expression of tumor necrosis factor-α, interleukin-1 mRNAs, and inducible NOS were attenuated by administering CGS21680 at post-TBI time when brain glutamate levels were low, or by administering the A2AR antagonist ZM241385 [4-(2-{[5-amino-2-(2-furyl)[1,2,4]triazolo[1,5-a][1,3,5]triazin-7-yl]amino}ethyl)phenol] at post-TBI time when brain glutamate levels were elevated. Furthermore, pre-TBI treatment with the glutamate release inhibitor (S)-4C3HPG [(S)-4-carboxy-3-hydroxyphenylglycine] converted the debilitating effect of CGS21680 administered at post-TBI time with high glutamate level to a neuroprotective effect. This further indicates that the switch in the effect of A2AR activation in intact animals from antiinflammatory to proinflammatory is dependent on glutamate concentration. These findings identify a novel role for glutamate in modulation of neuroinflammation and brain injury via the adenosine–A2AR system.

Chronic but not acute treatment with caffeine attenuates traumatic brain injury in the mouse cortical impact model

Caffeine, the most consumed psychoactive drug and non-specific adenosine receptor antagonist, has recently been shown to exert a neuroprotective effect against brain injury in animal models of Parkinsons disease (PD) and stroke. However, the effects of caffeine on traumatic brain injury (TBI) are not known. In this study, we investigated the effects of acute and chronic caffeine treatment on brain injury in a cortical-impact model of TBI in mice. Following TBI, neurological deficits, cerebral edema, as well as inflammatory cell infiltration were all significantly attenuated in mice pretreated chronically (for 3 weeks) with caffeine in drinking water compared with the mice pretreated with saline. Furthermore, we found that chronic caffeine treatment attenuated glutamate release and inflammatory cytokine production, effects that were correlated with an upregulation of brain A1 receptor mRNA. By contrast, acute treatment with caffeine (i.p. injection, 30 min before TBI) was not effective in protecting against TBI-induced brain injury. These results suggest that chronic (but not acute) caffeine treatment attenuates brain injury, possibly by A1 receptor-mediated suppression of glutamate release and inhibition of excessive inflammatory cytokine production. These results highlight the potential benefit of chronic caffeine intake for preventing TBI and provide a rationale for the epidemiological investigation of the potential association between TBI and human caffeine intake.

Genetic inactivation of adenosine A2A receptors attenuates acute traumatic brain injury in the mouse cortical impact model

The inactivation of the A(2A) receptor (A(2A)R) has been shown to neuroprotect against brain injury in several animal models of neurological disorders including stroke and Parkinsons disease. However, despite marked elevation of adenosine level, the role of the A(2A) in traumatic brain injury (TBI) remains unclear. In the present study, we investigated the effects of genetic inactivation of A(2A)Rs in the acute stage. The A(2A)R knock-out (KO) mice and their wild-type (WT) littermates were subjected to cortical impact injury by a dropping weight. The control group was only craniotomized without TBI. At 24 h post-TBI, the neurological deficit scores of the KO mice were significantly lower than that of WT littermates. Consistent with the behavioral changes, the brain water contents as well as histological changes and the TUNEL-positive cells of the injured cortex of the KO mice were significantly lower than that of WT littermates. Furthermore, the glutamate level in the cerebral spinal fluid (CSF) of the KO mice was also significantly lower than that of WT littermates. In addition, we found that at 12 h post-TBI the mRNA and protein levels of TNF-alpha and IL-1beta were higher in the KO mice than that in the WT littermates. However, at 24 h post-TBI, the level of TNF-alpha and IL-1beta continually increased in the WT mice but largely declined in the KO mice. These results suggest that the genetic inactivation of A(2A)R protects against TBI, which is mainly associated with the suppression of glutamate level.

Ski, a modulator of wound healing and scar formation in the rat skin and rabbit ear.

We recently demonstrated that Ski is a novel wound healing‐related factor that promotes fibroblast proliferation and inhibits collagen secretion. Here, we show that increasing local Ski expression by gene transfer not only significantly accelerated wound healing by relieving inflammation, accelerating re‐epithelialization and increasing formation of granulation tissue, but also reduced scar formation by decreasing collagen production in rat dermal wounds. Similarly, ski gene transfer accelerated wound healing, reduced the protuberant height and volume of scars and increased collagen maturity in a hypertrophic scar model in the rabbit ear. Conversely, reducing Ski expression in the wound by RNA interference resulted in significantly slower wound healing and increased scar area in rat dermal wounds. We demonstrated that these effects of Ski are associated with transforming growth factor‐β‐mediated signalling pathways through both Smad2/3‐dependent and Smad‐independent pathways. Together, our results define a dual role for Ski in promoting wound healing and alleviating scar formation, identifying a new target for therapeutic approaches to preventing scar hyperplasia and accelerating wound healing. Copyright

Adenosine A2A receptor deficiency alleviates blast-induced cognitive dysfunction

Traumatic brain injury (TBI), particularly explosive blast-induced TBI (bTBI), has become the most prevalent injury among military personnel. The disruption of cognitive function is one of the most serious consequences of bTBI because its long-lasting effects prevent survivors fulfilling their active duty and resuming normal civilian life. However, the mechanisms are poorly understood and there is no treatment available. This study investigated the effects of adenosine A2A receptor (A2AR) on bTBI-induced cognitive deficit, and explored the underlying mechanisms. After being subjected to moderate whole-body blast injury, mice lacking the A2AR (A2AR knockout (KO)) showed less severity and shorter duration of impaired spatial reference memory and working memory than wild-type mice did. In addition, bTBI-induced cortical and hippocampal lesions, as well as proinflammatory cytokine expression, glutamate release, edema, cell loss, and gliosis in both early and prolonged phases of the injury, were significantly attenuated in A2AR KO mice. The results suggest that early injury and chronic neuropathological damages are important mechanisms of bTBI-induced cognitive impairment, and that the impairment can be attenuated by preventing A2AR activation. These findings suggest that A2AR antagonism is a potential therapeutic strategy for mild-to-moderate bTBI and consequent cognitive impairment.

The essential role for c-Ski in mediating TGF-β1-induced bi-directional effects on skin fibroblast proliferation through a feedback loop

The bi-directional regulation of TGF-beta1 (transforming growth factor-beta1) on fibroblast proliferation with stimulation at low concentration, but inhibition at high concentration, has important significance during tissue repair. The mechanism has not been defined. c-Ski is a major co-repressor of TGF-beta1/Smad3 signalling; however, the exact role of c-Ski in the bi-directional regulation of fibroblast proliferation remains to be determined. In the present study, we established a dose-effect relationship of bi-directional regulation of TGF-beta1-mediated proliferation in rat skin fibroblasts, and found that c-Ski overexpression promoted fibroblast proliferation by inhibiting Smad3 activity. Importantly, c-Ski expression was decreased at the high concentration of TGF-beta1, but increased at the low concentration of TGF-beta1. This dose-dependent change in TGF-beta1 action did not affect Smad3 phosphorylation or nuclear translocation, but altered Smad3 DNA-binding activity, transcriptional activity and expression of the downstream gene p21 that both increased at the high concentration and decreased at the low concentration. Furthermore, c-Ski overexpression exerted synergistic stimulation with TGF-beta1 at the low concentration, but reversed the inhibitory effect of TGF-beta1 at high concentrations, while knockdown of c-Ski by RNA interference abrogated bi-directional role of TGF-beta1 on fibroblast proliferation. Thus our data reveal a new mechanism for this bi-directional regulation, i.e. c-Ski expression change induced by low or high TGF-beta1 concentration in turn determines the promoting or inhibiting effects of TGF-beta1 on fibroblast proliferation, and suggests an important role of c-Ski that modulates the local availability of TGF-beta1 within the wound repair microenvironment.

Adenosine A2A receptors in both bone marrow cells and non-bone marrow cells contribute to traumatic brain injury

J. Neurochem. (2010) 113, 1536–1544.

c-Ski promotes skin fibroblast proliferation but decreases type I collagen: implications for wound healing and scar formation.

Background.  Accelerating wound healing is always accompanied by excessive scar formation. The focus in chronic wounds has been promoting the proliferation of tissue repair cells while decreasing collagen deposition. Smad3 null mice display more rapid wound closure and reduced scar formation. We hypothesized that c‐Ski, acting as a co‐repressor of transforming growth factor‐β1/Smad3 in epithelial cells and as a complicated regulator of embryo fibroblast proliferation, may play such a role through modulation of skin fibroblast function.

Expression and possible mechanism of c-ski, a novel tissue repair-related gene during normal and radiation-impaired wound healing

C‐ski is a complicated regulating factor for fibroblast proliferation and an important co‐repressor of Smad3. Although inhibiting Smad3 activity can markedly promote wound healing because Smad3 mediates the role of transforming growth factor‐β in inhibiting cell proliferation and inducing cell apoptosis; there has been no report on whether c‐ski is expressed during wound healing and the relationship between its expression and wound healing. By establishing animal models of normal and radiation‐impaired wound healing and using immunohistochemistry, in situ hybridization, and reverse transcription‐polymerase chain reaction, we found that c‐ski was expressed after wounding and reached its peak on day 9 and then significantly decreased. C‐ski was present in all repair cells, and was especially prominent in fibroblasts. Compared with the control side, the irradiated side showed a lower expression of c‐ski on postwound days 3–9, but higher on day 15, and not significantly different after the wound was healed. The expression of Smad3 was in contrast to the c‐ski and cellular proliferation was similar to that of c‐ski expression. The apoptosis index was significantly higher on the irradiated side on days 3–9 compared with the control side. In vitro, 3‐(4,5‐dimethylthiazol‐2‐yl)‐2,5‐diphenyltetrazolium bromide results showed that c‐ski could reverse the inhibitory role of Smad3 on fibroblast proliferation. Flow cytometry analysis found that c‐ski also diminished fibroblast apoptosis induced by Smad3 transfection. These results suggest that there is not only obvious expression of this regulatory protein but there is also a significant change in the levels of c‐ski during wound healing. Its in vivo expression pattern and experiments in vitro suggest that c‐ski may be involved in tissue repair by repressing Smad3 activity. Radiation can reduce c‐ski and increase Smad3 expression, resulting in elevated Smad3 activity, resulting in diminished cell proliferation, cell apoptosis, and wound‐healing delays.

Differential Alteration of Heat Shock Protein 90 in Mice Modifies Glucocorticoid Receptor Function and Susceptibility to Trauma

Heat shock protein 90 (Hsp90), encoded by the murine hsp84 and hsp86 genes in mice, is a pivotal regulator of glucocorticoid receptor (GR) function in the hypothalamus-pituitary-adrenal axis and affords stress protection. To explore the underlying molecular mechanisms of strain susceptibility to traumatic stress, we investigated the alteration by Hsp90 of the function of the glucocorticoid-glucocorticoid receptor (GC-GR) pathway in attenuating stress responses in C57BL/6 and BALB/c mice using the whole-body blast injury (WBBI) model. We found that C57BL/6 mice had a lower WBBI-induced mortality, higher nuclear GR level, and higher glucocorticoid-response element (GRE) binding activity than BALB/c mice. This study is the first report identifying four genetic variations of the murine hsp84 gene: 226A>C, 996G>C, 1483G>C, and 2000G>T. These nucleotide changes occur in the functional domains associated with the nuclear/cytosolic translocation of GR, GR-Hsp90 interaction, ATP binding, and self-dimerization of Hsp90, respectively. Further, we used a specific Hsp90 inhibitor, geldanamycin (GA), to assess the role of Hsp90 in the discriminative traumatic response in C57BL/6 mice. Pretreatment with GA reduced nuclear GR levels and GRE binding activity, and enhanced WBBI-induced mortality. These findings suggest that Hsp90 may underlie the strain-selective (C57BL/6 versus BALB/c) susceptibility to WBBI by mediating the nuclear translocation of GRs and GRE binding. Thus, pharmacological manipulation of Hsp90 may represent a therapeutic strategy to modify the function of the GC-GR pathway and traumatic stress response.