In response to acute stress, glucocorticoids and their receptors enhance cellular resiliency and plasticity through inhibition of inflammation and apoptosis. Glucocorticoids are found in the bloodstream, where 90% of these molecules are bound to glucocorticoid-binding globulin. Only unbound glucocorticoids, the remaining 10%, can cross the blood–brain barrier and cell membranes (19). The molecules that do cross the membrane of cells, and reach the cytoplasm, bind to two types of receptors: mineralocorticoid receptors and glucocorticoid receptors. Mineralocorticoid receptors have an affinity to glucocorticoids 10 times greater than that of glucocorticoid receptors (20). Thus, of the percentage of glucocorticoid molecules that are able to cross cell membranes, only a fraction actually bind to glucocorticoid receptors (19).

Glucocorticoid receptors are found in virtually all cells of the body, including, importantly, in the microglia of the spinal cord (21, 22). In normal circumstances, glucocorticoids are anti-inflammatory. In the cytoplasm, they can bind to glucocorticoid receptors, and trigger conformational changes, which allow the glucocorticoid receptors to translocate to the cell nucleus via microtubular highways (23). Once in the nucleus, the glucocorticoid receptors can act as ligand-binding transcription factors (24). Nuclear glucocorticoid receptors regulate transcription in conjunction with a number of transcription factors, among them the activator protein 1 (AP-1) and nuclear factor-kappa B (NF-κB), which are major initiators of inflammation (see Figure 2). In the spinal cord, ligand-bound glucocorticoid receptors inhibit the activity of NF-κB, thereby impeding immune cells from expressing certain pro-inflammatory cytokines such as interleukin-6 (IL-6), tumor necrosis factor alpha (TNF-α), or IL-1β (25, 26). This occurs in microglia, but also neurons, as they can both express NF-κB (27). The inverse is also true; transcription factors involved in inflammation, such as NF-κB, can regulate the expression of the glucocorticoid receptor gene, by repressing certain promoters of this gene (26). This is referred to as reciprocal repression.

Glucocorticoid receptors, in addition to being involved in reciprocal repression with inflammation-related transcription factors, regulate the activity and expression of kinases and phosphatases such as mitogen-activated protein kinases (MAPKs), cyclin-dependent kinases (Cdks), dual-specificity phosphatases (DUSPs), and protein Y phosphatases (26). Kinases and phosphatases are essential in inflammation. They transfer and remove phosphate groups from specific substrates involved in inflammation signaling pathways, and play an important role in initiating the expression of pro-inflammatory genes. For example, in order for the IKK-NF-κB (inhibitors of kappa B kinase-NF-κB) pathway to be activated, a pathway which triggers tissue inflammation, the inhibitor of NF-κB must be dissociated (28). This is done by NF-κB-specific kinases which phosphorylate this inhibitor, thus freeing NF-κB from inhibition (26). Glucocorticoid receptors inhibit inflammatory signals by inhibiting the activity of transcription factors that initiate the expression of pro-inflammatory cytokine genes, and by inhibiting the expression of kinases and phosphatases that initiate inflammation signaling pathways.

In addition to anti-inflammatory effects, glucocorticoid receptors also possess anti-apoptotic properties. It is well-known and regular medical practice, to administer one high dose of prednisone (a corticosteroid) to patients who are extremely ill and at-risk of dying, as in the case of severe SCI (29, 30). This treatment has a dramatic effect on the patient, stabilizing his condition within minutes. This is partly because glucocorticoid receptors not only travel to the cell nucleus to inhibit pro-inflammatory cytokine gene expression, but also travel to the mitochondria to inhibit apoptosis. Specifically, ligand-bound glucocorticoid receptors in the cytoplasm can bind to B-cell CLL/lymphoma 2 (Bcl-2), which is an anti-apoptotic regulator inhibited by the gene Bad post-SCI. The ligand-bound glucocorticoid receptor-Bcl-2 complex travels to the mitochondria and halts the apoptosis cascade consisting of cytochrome c release and caspase activation (31) (see Figure 2). Studies have also shown that low doses of glucocorticoids increase mitochondrial oxidation (necessary for ATP synthesis), mitochondrial membrane potential, and mitochondrial calcium holding capacity (32). In short, glucocorticoid receptors inhibit inflammation and apoptosis in response to acute stress.

This modulatory role of glucocorticoids, for inflammation and apoptosis, has been utilized in the clinical treatment of SCI. Methylprednisolone remains the only option for therapeutic intervention in the emergency management of SCI (33), despite conflicting results both in laboratory experiments and clinical trials (34–36). Indeed, some researchers have questioned clinical trial results (37–39), while others have criticized such evaluations for focusing solely on statistical details and theoretical safety concerns (33, 40). A major concern is that the side effects of methylprednisolone outweigh its modest functional benefits. Dose curve and timing studies may be necessary to evaluate other possibly beneficial treatment regimens, such as a low methylprednisolone dose administration over an extended time period. At present, however, the clinical use of methylprednisolone remains controversial, and while a full discussion of this controversy is beyond the scope of this review [for both sides of the issue, the reader is referred to Ref. (33, 40)] empirical data does support the idea that glucocorticoids reduce apoptosis (41).

Indeed, early animal studies on the use of glucocorticoids following SCI posited that methylprednisolone improved recovery by reducing secondary processes of injury, such as secondary ischemia (42), lipid peroxidation, (42, 43) and apoptosis (44). Because the methylprednisolone dose demonstrating some success in the multicenter, double-blind randomized clinical trial NASCIS II was much higher (30 mg/kg bolus, 5.4 mg/kg maintenance per hour) than that required for glucocorticoid receptor activation, it has also been suggested that the beneficial properties of methylprednisolone treatment following SCI may not involve the glucocorticoid receptors, or at least not only involve glucocorticoid receptor related mechanisms (30). Bracken et al. (30) suggested that instead, methylprednisolone at such a high dose may work through its facilitation of blood flow through the injured cord and inhibition of lipid peroxidation. In any case, based on the modulation of inflammation and apoptosis discussed above, there should be potential for the use of glucocorticoids from a theoretical perspective.

The timing of a therapeutic intervention, in regulating the glucocorticoid response, would be critical for efficacy. Interestingly, the efficacy of methylprednisolone is also contingent on the timing of the therapeutic intervention (30, 34). Various pro-inflammatory genes are up-regulated immediately following SCI. For example, the NF-κB gene, which acts as a transcription factor to initiate the transcription of various gene types, including genes encoding for pro-inflammatory cytokines such as IL-6 and TNF-α (45, 46), is up-regulated as early as 30 min post-injury in a rodent model of contusion injury (47). This up-regulation continues for at least 72 h, and occurs in neurons, macrophages (microglia), and endothelial cells of the injured spinal cord (47). Methylprednisolone, which is generally considered to have the greatest therapeutic impact when administered in the 8-h following SCI (30), has been found to inhibit the activation of NF-κB and downstream production of pro-inflammatory cytokines such as TNF-α (48). Indeed, in one early rodent study, methylprednisolone administered at 30 mg/kg intravenously inhibited IL-6 expression and NF-κB activity by 55% (48).

Recently, it has been suggested that inhibiting the inhibitor of κB kinase (IKK) might also be useful for post-SCI therapy. IKK, by phosphorylating the IkB, leads to its ubiquitination and degradation by proteases, thus activating the NF-κB complex (49). In a rodent study of SCI, inhibiting IKK was found to prevent neutrophil infiltration as well as inhibiting the activity of caspase-3 (by modulating Bcl-2 expression), thus reducing apoptosis in the injured spinal cord (50). These studies support the potential of methylprednisolone treatment, modulating NF-κB and Bcl-2 activity in the acute phase of SCI. However, methylprednisolone is not always an efficient line of treatment (36). The past and present environment experienced by the patient may critically modulate the molecular cascades activated with glucocorticoid administration. Indeed, exposure to a chronic stressor is linked to glucocorticoid resistance and epigenetic changes that may result in increased unbound glucocorticoid expression and exacerbation of inflammation and apoptosis.

Glucocorticoid resistance and epigenetics explain two different modifications of glucocorticoid receptor function, but one can safely argue that both may occur in synergy. When individuals suffer an SCI, for example, placing them at high-risk of suffering from chronic psychological stress (95, 96), past exposure to a stressful environment resulting in epigenetic changes that compromise glucocorticoid receptor sensitivity and function would lead to high levels of inflammation and apoptosis post-SCI, decreasing the tissue remaining at the injury site and undermining recovery of function.

Figure 3 illustrates the proposed glucocorticoid receptor mechanism through which changes triggered by the early-life and adult life environment could affect patients’ psychological stress response, and it in turn could influence processes of inflammation and apoptosis important to SCI injury and recovery. In early-life, a non-stressful environment (indicated by the happy face icon in Figure 3), can promote stress resilience. This in turn leads to decreased levels of circulating glucocorticoids, and a decreased psychological stress response. Conversely, a stressful environment (indicated by the sad face icon in Figure 3) caused, for example, by physical or emotional abuse, poverty, or racism can decrease stress resilience. As a result, there are increased levels of circulating glucocorticoids, and an increased psychological stress response. Likewise, following SCI in adult life, a “non-stressful” environment (i.e., strong social support and good coping skills) may contribute to decreased psychological stress response. Again, in this case too, a stressful environment (for example due to lack of social support, perceived loneliness, or discrimination) may contribute to an increased psychological stress response. Importantly, the glucocorticoid receptors are not only involved in the stress response, but also in the inflammation and apoptosis processes. Therefore, as shown in Figure 3, these mechanisms do not only impact the psychological stress response, but also the processes of inflammation and apoptosis.

In addition to the increase in inflammation due to chronically elevated glucocorticoids levels and the glucocorticoid resistance that ensues, protracted exposure to cytokines, as a result of illness (i.e., SCI) or chronic stress, can also affect glucocorticoid receptor function and lead to increased inflammation. The signaling pathways of pro-inflammatory cytokines, such as NF-κB, MAPKs, and cyclooxygenase can affect the translocation of glucocorticoid receptors from the cytoplasm of the cell to the nucleus, or the ability of the glucocorticoid receptor to function as a transcription factor (97, 98). The result is increased production of pro-inflammatory cytokines.

This is paramount to SCI research, as chronic elevated pro-inflammatory cytokine levels can harm functional recovery, and contribute to the development of chronic pain (64, 99). Indeed, chronic inflammation resulting from the injury leads to a wide range of clinical conditions such as decreased pulmonary function (100), neuropathic pain (101–103), compromised physical recovery (104, 105), and exacerbated depressive symptoms (106). Moreover, SCI-induced chronic inflammation can result in infections and cardiovascular diseases, two leading causes of death after SCI (107).