Abstract
Inflammation is characteristic of most clinical disorders that challenge the neural control of breathing. Since inflammation modulates neuroplasticity, we studied the impact of inflammation caused by prolonged intermittent hypoxia on an important form of respiratory plasticity, acute intermittent hypoxia (three, 5 min hypoxic episodes, 5 min normoxic intervals) induced phrenic long-term facilitation (pLTF). Because chronic intermittent hypoxia elicits neuroinflammation and pLTF is undermined by lipopolysaccharide-induced systemic inflammation, we hypothesized that one night of intermittent hypoxia (IH-1) elicits spinal inflammation, thereby impairing pLTF by a p38 MAP kinase-dependent mechanism. pLTF and spinal inflammation were assessed in anesthetized rats pretreated with IH-1 (2 min hypoxia, 2 min normoxia; 8 h) or sham normoxia and allowed 16 h for recovery. IH-1 (1) transiently increased IL-6 (1.5 ± 0.2-fold; p = 0.02) and inducible nitric oxide synthase (iNOS) (2.4 ± 0.4-fold; p = 0.01) mRNA in cervical spinal homogenates, (2) elicited a sustained increase in IL-1β mRNA (2.4 ± 0.2-fold; p < 0.001) in isolated cervical spinal microglia, and (3) abolished pLTF (−1 ± 5% vs 56 ± 10% in controls; p < 0.001). pLTF was restored after IH-1 by systemic NSAID administration (ketoprofen; 55 ± 9%; p < 0.001) or spinal p38 MAP kinase inhibition (58 ± 2%; p < 0.001). IH-1 increased phosphorylated (activated) p38 MAP kinase immunofluorescence in identified phrenic motoneurons and adjacent microglia. In conclusion, IH-1 elicits spinal inflammation and impairs pLTF by a spinal p38 MAP kinase-dependent mechanism. By targeting inflammation, we may develop strategies to manipulate respiratory motor plasticity for therapeutic advantage when the respiratory control system is compromised (e.g., sleep apnea, apnea of prematurity, spinal injury, or motor neuron disease).
Introduction
Inflammation is prevalent in most clinical disorders challenging ventilatory control, including obstructive sleep apnea (OSA), apnea of prematurity, neurodegenerative disorders, and spinal cord injury. Nevertheless, we know very little concerning interactions between inflammation and any aspect of the neural control of breathing (Huxtable et al., 2011).
Systemic inflammation affects CNS function, including neuroplasticity (Di Filippo et al., 2008; Teeling et al., 2010; Huxtable et al., 2011). However, the impact of inflammation on neuroplasticity is complex, both initiating and undermining distinct forms of neuroplasticity. For example, inflammation initiates plasticity in the spinal dorsal horn, contributing to chronic pain (Woolf and Salter, 2000) via mechanisms involving interactions between spinal microglia and second-order sensory neurons (Coull et al., 2005). Similarly, chronic sustained hypoxia elicits inflammation and sensory plasticity in the carotid body chemoreceptors (Liu et al., 2009), which may contribute to increased carotid body sensitivity during ventilatory acclimatization (Bisgard, 2000). In marked contrast, inflammation undermines other forms of CNS plasticity, including activity-dependent hippocampal synaptic plasticity (Vereker et al., 2000) and spinal instrumental learning (Shaw et al., 2001). Thus, it is of interest to study the impact of inflammation on different forms of respiratory plasticity (Huxtable et al., 2011, 2013; Vinit et al., 2011).
Mild systemic inflammation induced by low-dose lipopolysaccharides elicits spinal inflammation and abolishes phrenic long-term facilitation (pLTF), a form of spinal, respiratory, motor plasticity elicited by acute intermittent hypoxia (AIH; Huxtable et al., 2013). The nonsteroidal anti-inflammatory drug ketoprofen restores pLTF (Huxtable et al., 2013), confirming the role of inflammation. Here, we investigate the impact of a unique form of inflammation induced by one night of intermittent hypoxia in rats (IH-1; 8 h intermittent hypoxia, 16 h recovery). IH-1 mimics aspects of intermittent hypoxia experienced in a single night of OSA, but without preexisting comorbidities (e.g., obesity, hypertension; Gozal and Kheirandish-Gozal, 2008). Although 12 h of intermittent hypoxia elicits cortical and hippocampal inflammation, its impact on spinal inflammation has not been reported (Li et al., 2003, 2004). Here, we test the hypothesis that IH-1 elicits spinal inflammation, thereby undermining AIH-induced pLTF. Furthermore, we test the hypothesis that spinal p38 MAP kinase (MAPK), a key molecule initiating and responding to inflammation (Widmann et al., 1999), plays a key role in the mechanism of pLTF impairment.
This study is the first step toward an understanding of intermittent hypoxia-induced inflammation and its impact on respiratory motor plasticity. Our results are relevant to many clinical disorders associated with chronic intermittent hypoxia (CIH), such as obstructive sleep apnea and apnea of prematurity. On the other hand, ongoing inflammation may undermine the ability to harness “low-dose” intermittent hypoxia therapeutically as a means of restoring motor function in clinical disorders that cause paralysis, such as spinal injury and ALS (Dale et al., 2014).
Materials and Methods
All experiments were approved by the Animal Care and Use Committee at the School of Veterinary Medicine, University of Wisconsin–Madison, and conform to policies outlined in the National Institutes of Health Guide for the Care and Use of Laboratory Animals. Experiments were performed on 3–4 month old male Sprague Dawley rats (Harlan colony 211, 300–450 g). Rats were housed under standard conditions, with food and water ad libitum and a 12 h light/dark cycle.
Experimental groups
Rats were placed individually in cylindrical Plexiglas chambers for 8 h (9 A.M. to 5 P.M., the rats' inactive period) with ClearH2O hydrogel to provide nutrition and hydration. Gas flow (4 L/min) and concentrations were regulated by mass flow controllers (Teledyne; Hastings Instruments) and a customized computer program (LabVIEW 2009, Service Pack 1, version 9.0.1; National Instruments). Gas concentrations were continuously monitored (Gemini; CWE Inc.). Rats were exposed to IH-1 (2 min, 10.5% O2; 2 min normoxic intervals; 8 h during the rats' inactive period) or continuous normoxia (Nx; 8 h). Exposures occurred the day before electrophysiology experiments and tissue collection for mRNA or immunohistochemistry (see “Inflammatory gene expression” and “Immunofluorescence”, below). In some cases, rats were sacrificed immediately after exposures for mRNA analysis.
To study the impact of IH-1 on pLTF, rats were assigned to three groups: (1) Nx (n = 6), (2) IH-1 (n = 6), and (3) time controls (four Nx, two IH-1; total, n = 6). In subsequent neurophysiological studies, rats received intraperitoneal injections of the nonsteroidal anti-inflammatory drug ketoprofen [keto; (S)-(+)-ketoprofen; 12.5 mg/kg; Sigma] or vehicle (veh; 50% ethanol and saline, 100 μl/kg) and were divided into three groups: (1) Nx + keto (n = 7), (2) IH-1 + keto (n = 6), and (3) time control + keto (three Nx, three IH-1; total, n = 6). In the final experimental series, rats were instrumented with intrathecal catheters at C4 to deliver a p38 MAP kinase inhibitor (4-[4-(4-fluorophenyl)-5-(4-pyridinyl)-1H-imidazol-2-yl]phenol (SB 202190); 1 mm; p38 inhib; Tocris Bioscience) as described previously (Baker-Herman and Mitchell, 2002; MacFarlane and Mitchell, 2009). Fifteen minutes before AIH, 12 μl (2 μl/30 s) of SB 202190 or vehicle (artificial CSF) were given, and the rats were divided into six groups: (1) Nx + veh (n = 9), (2) IH-1+ veh (n = 6), (3) time control + veh (six Nx, two IH-1; total, n = 8), (4) Nx + p38 inhib (n = 7), (5) IH-1 + p38 inhib (n = 7), and (6) time control + p38 inhib (three Nx, two IH-1; total n = 5).
Inflammatory gene expression
Sample preparation.
Rats were anesthetized with isoflurane and perfused transcardially with ice-cold PBS. Cervical spinal (C3–C6) tissues were removed, homogenized, and used for quantitative PCR (hereafter referred to as “homogenates”). Microglial isolations were performed as described previously (Crain et al., 2009; Nikodemova and Watters, 2012; Huxtable et al., 2013). CD11b+ cells isolated with this method are referred to as “microglia.” The Neural Tissue Dissociation Kit, anti-PE magnetic beads, and MS columns were purchased from Miltenyi Biotec.
Reverse transcription.
RNA was isolated using the TRI-reagent (Sigma), and first-strand cDNA was synthesized from 1 μg of total RNA using M-MLV reverse transcriptase (Invitrogen) and an oligo(dT)/random hexamer cocktail (Promega). The cDNA was then used for quantitative RT-PCR using SYBR Green PCR Master Mix (Applied Biosystems).
Quantitative PCR.
Amplified cDNA was measured by fluorescence in real time using the ABI 7500 Fast Real-Time PCR System (Applied Biosystems) with the following primer sequences: IL-1β, 5′ CTG CAG ATG CAA TGG AAA GA, 5′ TTG CTT CCA AGG CAG ACT TT; IL-6, 5′ GTG GCT AAG GAC CAA GAC CA, 5′ GGT TTG CCG AGT AGA CCT CA; TNF-α, 5′ TCC ATG GCC CAG ACC CTC ACA C, 5′ TCC GCT TGG TGG TTT GCT ACG; iNOS, 5′ AGG GAG TGT TGT TCC AGG TG, 5′ TCT GCA GGA TGT CTT GAA CG; COX-2, 5′ TGT TCC AAC CCA TGT CAA AA, 5′ CGT AGA ATC CAG TCC GGG TA; 18s, 5′ CGG GTG CTC TTA GCT GAG TGT CCC G; 3′ CTC GGG CCT GCT TTG AAC AC.
All primers were designed (using Primer3 software) to span introns where possible; specificity was assessed through the NCBI BLAST. Dissociation curves had a single peak with a Tm consistent with intended amplicon sequences. Primer efficiency was calculated through serial dilutions and a standard curve.
Measurement of pLTF
The pLTF experimental protocol has been described in detail previously (Bach and Mitchell, 1996; Baker-Herman and Mitchell, 2002; Huxtable et al., 2013). In anesthetized, paralyzed, vagotomized, and pump-ventilated rats, integrated phrenic nerve activity was recorded. After stable baseline activity was obtained (>30 min), an arterial blood sample was drawn to assess PO2, PCO2, pH, and base excess (ABL 800; Radiometer). After baseline conditions were established, AIH was administered (three 5 min hypoxic episodes, 9–10.5% O2; 5 min intervals). Blood samples were taken during the first hypoxic episode and 15, 30, 60, and 90 min after AIH. Data were included in analyses only if they complied with the following criteria: (1) baseline and post-AIH PaO2 of >180 mmHg; (2) PaO2 during hypoxic episodes between 35 and 45 mmHg; (3) PaCO2 regulated within 1.5 mmHg of baseline after AIH. Upon completion of the protocols, rats were euthanized with a urethane overdose.
Phrenic motoneuron back-labeling and tissue collection
Separate rats were injected intrapleurally with cholera toxin b subunit bilaterally (25 μg/side; Calbiochem) to retrogradely label phrenic motoneurons (Mantilla et al., 2009; Guenther et al., 2010; Dale-Nagle et al., 2011; Golder et al., 2011; Dale et al., 2012; Lovett-Barr et al., 2012). Three days later, rats were exposed to IH-1 (n = 6) or normoxia (n = 6) and then transcardially perfused (16 h after IH-1) with cold PBS (0.01 m, pH 7.4; Thermo Fisher Scientific) followed by 4% paraformaldehyde (PFA; Thermo Fisher Scientific). After perfusions, spinal cords were immersion fixed in 4% PFA in 0.01 m PBS overnight at 4°C and then saturated in 20% and 30% sucrose at 4°C.
Immunofluorescence
Cervical spinal cords (C3–C6) were sectioned (40 μm, transverse) using a freezing microtome (Leica SM 2000 R). Free-floating sections were washed and nonspecific binding sites blocked (1 h) with 1% bovine serum albumin (BSA; Research Products International). Tissue sections were incubated in the following antibodies (16 h, room temperature, 0.1% BSA): phospho-p38 MAPK (rabbit, 1:250; Cell Signaling Technology), cholera toxin B (goat, 1:5000; Calbiochem), and CD11b (mouse, 1:200; AbD Serotec). Subsequently, tissues were washed and incubated with secondary antibodies (2 h, room temperature): Alexa Fluor 488 donkey anti-rabbit (1:500; Invitrogen), Alexa Fluor 647 donkey anti-goat (1:1000; Invitrogen), and Alexa Fluor 594 donkey anti-mouse (1:1000; Invitrogen). Sections were washed and mounted with antifade solution (ProLong Gold anti-fade reagent; Invitrogen). Controls were run concurrently to ensure specific labeling.
Immunofluorescent images (1024 × 1024 pixels) were viewed with a Nikon C1 laser scanning confocal microscope with lambda strobing in the Nikon EZ-C1 Gold (version 3.80) confocal imaging software (2 μm step increments for z stacks). All image pairs (IH-1 vs Nx) were adjusted identically for contrast and brightness (the same adjustment was made for each image pair) using EZ-C1 FreeViewer Gold software (Nikon).
Data analysis
Gene expression.
Gene expression data were analyzed based on a relative standard curve method, as described previously (Rutledge and Côté, 2003; Huxtable et al., 2013). Statistical significance was determined for each gene by one-way ANOVA with Fisher LSD post hoc tests for individual comparisons (SigmaStat version 11; Systat Software). Differences were considered significant at p < 0.05. Values are expressed as means ± 1 SEM.
Electrophysiology.
Physiological variables and peak amplitude of integrated phrenic nerve activity were averaged for 30 bursts during baseline, hypoxic episodes (short-term hypoxic phrenic response), and 60 and/or 90 min after AIH. Phrenic nerve burst amplitude is expressed as a percentage change from baseline.
Statistical comparisons between short-term hypoxic responses were made at minute 2 of the first hypoxic episode via t tests or one-way ANOVA on Ranks (p38 MAPK data). ANOVA on Ranks was used for the p38 MAPK data since they failed normality/equal variance. Statistical comparisons for post-AIH changes in phrenic burst amplitude were made using two-way repeated measures (RM) ANOVAs with Fisher LSD post hoc tests (SigmaStat version 11; Systat Software). Differences were considered significant at p < 0.05. All values are expressed as means ± 1 SEM.
Results
IH-1 elicits cervical spinal inflammation
In spinal homogenates, IH-1 increased iNOS mRNA 2.4 ± 0.4-fold above normoxic controls (p = 0.010; Fig. 1A). In isolated spinal microglia, IL-1β mRNA was increased (2.4 ± 0.2-fold, p < 0.001) versus normoxic controls (Fig. 1B). No other genes examined (IL-6, TNFα, and COX-2) were significantly changed by IH-1 pretreatment in either homogenates or microglia (p > 0.05; Fig. 1).
Since the inflammatory response is dynamic, and to better understand the temporal dynamics of the inflammatory response following IH-1, inflammatory gene expression was also examined immediately following 8 h of IH. There was a transient, early increase in IL-6 homogenate mRNA immediately after IH (1.5 ± 0.2-fold) that was greater than IL-6 gene expression the next day (i.e., IH-1; 0.8 ± 0.1-fold; p = 0.017). After IH-1, homogenate IL-6 mRNA was not significantly different from normoxic controls (p = 0.07), demonstrating a return to control levels (Fig. 1A). In microglia, IL-1β gene expression was significantly increased after 8 h of IH (2.4 ± 0.2-fold; p < 0.001) versus normoxic controls and was not significantly different from the increase seen after IH-1 (2.4 ± 0.2-fold; p = 0.753). Homogenate iNOS gene expression (0.8 ± 0.1-fold) was not significantly different from normoxic controls (p = 0.624) immediately after 8 h of IH, but there was a small, significant reduction in iNOS gene expression versus IH-1 (2.4 ± 0.4-fold; p = 0.008), suggesting small, dynamic changes in iNOS gene expression triggered by IH for 8 h.
IH-1 abolishes AIH-induced pLTF
Normoxia-pretreated rats exhibited normal pLTF 60 min after AIH (56 ± 10%, p < 0.001; Fig. 2A). In contrast, pLTF was no longer evident after IH-1 pretreatment (−1 ± 5%, p = 0.866; Fig. 2B), despite no significant (p = 0.967) change in the short-term hypoxic phrenic responses between groups (normoxia, 76 ± 8%; IH-1, 76 ± 11%; Fig. 2D). pLTF was not apparent in time control rats (no AIH) pretreated with IH-1 or normoxia (8 ± 10%, p = 0.320; Fig. 2C). At 60 min, phrenic burst amplitude in Nx + AIH-treated rats was significantly greater than in IH-1 + AIH-treated (p < 0.001) and time control rats (p < 0.001), but there was no significant difference between IH-1 + AIH and time controls (p = 0.336).
Ketoprofen restores pLTF after IH-1
We hypothesized that systemic administration of the NSAID ketoprofen would restore pLTF by reducing systemic inflammation. Ketoprofen (12.5 mg/kg, i.p.) was administered to all groups 3 h before the pLTF protocol. Two groups received AIH: Nx + keto and IH-1 + keto. A third time control group did not receive AIH (time control + keto; three Nx, three IH-1).
Ketoprofen restored pLTF after IH-1 (Fig. 3) but had no significant effect on the short-term hypoxic phrenic response in Nx + keto-treated (93 ± 9%) or IH-1 + keto-treated (116 ± 16%) rats (p = 0.215, t test; Fig. 3D). Nx + keto-treated rats exhibited normal pLTF (34 ± 10%, p < 0.001; Fig. 3A,E) that was significantly greater than time control + keto rats (8 ± 15%, p = 0.003; Fig. 3C). Time controls did not exhibit significant changes in phrenic burst amplitude as expected (Fig. 3E). IH-1 + keto rats exhibited significant AIH-induced pLTF (55 ± 9%, p < 0.001; Fig. 3B), and this effect was not different from Nx + keto (p = 0.221; Fig. 3E). IH-1 + keto rats had significantly greater pLTF than time control + keto rats (p < 0.001; Fig. 3E).
Spinal p38 MAPK inhibition restores pLTF after IH-1
We tested the role of spinal p38 MAPK in IH-1 impairment of pLTF since it is activated by multiple proinflammatory molecules and, in turn, triggers additional inflammation. Intrathecal pretreatment with a p38 MAPK inhibitor (SB 202190, 1 mm) (1) did not alter baseline phrenic burst amplitude or other physiological variables (see Table 3) and (2) had no effect on the short-term hypoxic phrenic response (Nx + veh, 123 ± 17%; IH-1 + veh, 100 ± 19%; Nx + p38 inhib, 100 ± 17%; IH-1 + p38 inhib, 108 ± 7%; p = 0.948; Fig. 4D), but (3) restored pLTF in IH-1-pretreated rats (Fig. 4).
Spinal p38 MAPK inhibition did not affect pLTF in normoxia-pretreated rats (Fig. 4A,E). Nx + veh- and Nx + p38 inhib-treated rats both exhibited significant pLTF (p < 0.001) 60 min (51 ± 17% and 64 ± 14%, respectively; data not shown) and 90 min after AIH (57 ± 19% and 73 ± 15%, respectively; Fig. 4A,E) and were not different from each other at either time point (60 min, p = 0.382; 90 min, p = 0.266). Spinal p38 MAPK inhibition enhanced pLTF in IH-1-pretreated rats (p < 0.001; Fig. 4B,E); this pLTF was significantly greater than time control + veh (60 min, 20 ± 11%, p = 0.029; 90 min, 13 ± 11%, p = 0.008) and time control + p38 inhib rats (60 min, 2 ± 11%, p = 0.003; 90 min, −8 ± 13%, p < 0.001). With IH-1 + p38 MAPK inhibition, AIH-induced pLTF was greater than in IH-1 + veh at 60 min (21 ± 6%, p = 0.046; data not shown) and 90 min (11 ± 14%, p = 0.018; Fig. 4E) after AIH, but was not greater than in Nx + veh (60 min, p = 0.890; 90 min, p = 0.289) or Nx + p38-pretreated rats (60 min, p = 0.487; 90 min, p = 0.289; Fig. 4E). IH-1 + veh rats did not exhibit pLTF at 60 or 90 min.
Increased phosphorylated p38 MAPK protein in motor neurons and microglia
Since spinal p38 MAPK inhibition restored pLTF after IH-1, we evaluated IH-1 effects on dually phosphorylated (enzymatically activated) p38 MAPK expression in phrenic motor neurons by immunofluorescence. At low magnification (20×), some phospho-p38 MAPK-positive cells were visible in normoxia-treated rats, and some of these were colocalized with cholera toxin B-labeled phrenic motoneurons and CD11b+ cells (used to identify microglia) in the C3–C6 ventral horn (Fig. 5A, top). After IH-1, more phrenic motoneurons and nearby microglia were positive for phospho-p38 MAPK, and staining intensity within cells appeared to increase (Fig. 5A, bottom). This difference between normoxia and IH-1 is emphasized at higher magnification of the phrenic motor nucleus (100×; Fig. 5B, from boxed region in A). These qualitative results suggest that IH-1 increased activated p38 MAPK in both microglia and identified phrenic motoneurons.
Physiological variables
In all groups, AIH significantly reduced PaO2 and mean arterial pressure (MAP) during hypoxia (Hx) (Tables 1⇓–3). In time controls pretreated with IH-1 or normoxia, rats had slightly lower pH values at 60 min versus the IH-1 and normoxia groups (Table 1). In rats treated with IH-1,keto + AIH, arterial pH was reduced versus Nx,keto + AIH and time controls (Table 2). Additionally, PaO2 in Nx,keto + AIH rats did not fully recover to baseline levels 60 min after AIH (p = 0.002); it was significantly reduced from IH-1 + keto (p = 0.004) and time control + keto (p = 0.001) 60 min after AIH (Table 2). Since PaO2 was >180 mmHg at all times, we do not believe such minor PaO2 fluctuation affected our results. PaCO2 was also significantly higher at 60 min in IH-1,keto + AIH rats versus baseline (p = 0.038) and during hypoxia (p = 0.002), but was not different from other groups at this same time (Table 2), reflecting higher group variability; nevertheless, it remained within acceptable levels of baseline (see Materials and Methods). Small differences in pH and mean arterial pressure after AIH were evident in some groups (Table 3), but remained within acceptable limits (see Materials and Methods). Similar changes in all treatment groups likely reflect time-dependent changes in this anesthetized experimental preparation.
Discussion
Although inflammation is prominent in most clinical disorders challenging the control of breathing, little is known concerning how inflammation alters any aspect of ventilatory control. Here, we studied a novel inflammatory stimulus induced by 8 h of intermittent hypoxia during the rat's subjective night (inactive period). Even one “night” of intermittent hypoxia elicits spinal inflammation (demonstrated in microglial gene expression), which subsequently undermines AIH-induced pLTF (demonstrated by reversal after ketoprofen administration). A key molecule in the mechanism whereby IH-1 induced inflammation impairs pLTF is p38 MAPK. Thus, collective evidence demonstrates that a physiologically relevant stimulus (IH-1) impairs respiratory motor plasticity due to spinal inflammation by a p38 MAPK-dependent mechanism. This is the first demonstration that spinal p38 MAPK is a key link between inflammation and pLTF. Thus, p38 MAPK is a molecule of considerable interest in exploring ways of minimizing pathology due to intermittent hypoxia, or in our efforts to harness “low-dose” intermittent hypoxia to treat diverse clinical disorders that impair movement, such as spinal injury and ALS (Dale et al., 2014).
Our results have profound implications concerning the potential impact of even a single night of sleep apnea. In individuals with subclinical OSA, exacerbating factors such as alcohol consumption or acute respiratory infection may tip the balance, transiently increasing the frequency of apneas during sleep. Increased apnea frequency may trigger inflammation, undermining compensatory mechanisms such as pLTF or upper airway LTF, thereby leading to further apneas (i.e., positive feedback loop).
The IH-1 protocol used here differs quantitatively from frequently studied CIH protocols, which typically last for days (Almendros et al., 2014; Navarrete-Opazo and Mitchel, 2014). CIH enhances carotid body hypoxic sensitivity (Peng et al., 2003; Rey et al., 2004; Prabhakar et al., 2007; Pawar et al., 2008), but the extent of carotid body inflammation was not studied. Increased carotid body hypoxic sensitivity could arise from differential effects of inflammation on sensory versus motor plasticity (Huxtable et al., 2011), or because CIH elicits qualitatively/quantitatively different inflammation versus IH-1. The lack of change in the short-term hypoxic response after IH-1 suggests IH-1 does not elicit carotid body inflammation and/or plasticity similar to CIH.
Differences in the quality or quantity of CIH- versus IH-1-induced inflammation may account for differences in the impact of CIH versus IH-1 preconditioning on AIH-induced pLTF. CIH (5 min hypoxic episodes, 5 min intervals, 12 h/d, 7 d during the active period) actually enhances pLTF (Ling et al., 2001) and ventilatory LTF (McGuire et al., 2003, 2004), possibly due to qualitative differences in inflammatory signaling molecules and/or increased expression of trophic factors known to promote respiratory plasticity (Baker-Herman et al., 2004; Dale-Nagle et al., 2011; Dale et al., 2012). After IH-1, the negative effects of inflammation may predominate, undermining respiratory motor plasticity. The presence or absence of respiratory plasticity after prolonged IH may be determined by the duration of IH exposure, diurnal variations, the inflammatory cascade, expression of proplasticity molecules (e.g., growth/trophic factors), and/or other yet to be determined factors (Mateika and Narwani, 2009).
A fundamental understanding of mechanisms undermining AIH-induced motor plasticity is of considerable interest in the treatment of multiple clinical disorders since repetitive (low-dose) acute intermittent hypoxia has been applied therapeutically to restore breathing capacity in rodent models of cervical spinal injury (Lovett-Barr et al., 2012) and ALS (Nichols et al., 2013), and in humans with chronic, incomplete spinal injuries (Tester et al., 2014). Such therapeutic intermittent hypoxia also restores nonrespiratory motor functions, such as leg strength (Trumbower et al., 2012) and walking ability (Lovett-Barr et al., 2012; Hayes et al., 2014) in both rodent models and humans with chronic, incomplete spinal injuries. Since patients with spinal injury and ALS are prone to systemic infections and inflammation, inflammation may undermine the therapeutic efficacy of low-dose IH. Judicious application of anti-inflammatory drugs in association with therapeutic IH may enhance its effectiveness. Here, we have begun to elucidate means of counteracting the impact of inflammation on AIH-induced motor plasticity.
Systemic ketoprofen restores pLTF, demonstrating that inflammation per se undermines pLTF following IH-1. Ketoprofen is a potent anti-inflammatory and analgesic agent used in many species, including humans (Foster et al., 1988) and rats (Foster and Jamali, 1988; Carabaza et al., 1996). Ketoprofen inhibits prostaglandin and leukotriene synthesis (Netter et al., 1985; Walker, 1995; Cabré et al., 1998) by inhibiting the enzymatic activities of both COX-1 and COX-2 peripherally (Gynther et al., 2010; Kokki, 2010), though some work suggests that it can have direct effects centrally (Netter et al., 1985; Mannila et al., 2006) or when modified to increase blood–brain barrier permeability (Gynther et al., 2010). As such, pLTF rescue by ketoprofen most likely results from (1) directly diminishing CNS inflammation; (2) altering systemic inflammation, thereby decreasing transduction of systemic inflammatory signals via the vagus nerve (Hansen et al., 1998); (3) decreasing systemic expression of cytokines that cross the blood–brain barrier (Carson et al., 2006); and/or (4) preventing blood–brain barrier disruption and alteration of the brain's microenvironment (Lim and Pack, 2013). Although systemic NSAIDs do not localize the relevant inflammation, pLTF rescue by ketoprofen confirms that IH-1-induced inflammation undermines pLTF. Targeted inflammatory treatments would be advantageous since chronic NSAID use causes gastrointestinal and cardiovascular problems.
Spinal p38 MAPK inhibition also rescues pLTF, demonstrating that (1) the relevant inflammation is localized within cervical spinal segments encompassing the phrenic motor nucleus, and (2) p38 MAPK is a key link between IH-1-induced inflammation and pLTF suppression. Because inflammation has complex temporal dynamics and involves numerous molecules, we targeted p38 MAPK because it is a convergent, downstream molecule activated by many proinflammatory molecules (Widmann et al., 1999). p38 MAPK also increases posttranslational modification and gene transcription of inflammatory molecules, thereby propagating ongoing inflammation (Kaminska, 2005; Clark et al., 2009). Here, we provide the first demonstration that p38 MAPK is critical for IH-1 pLTF impairment. Consistent with this hypothesis, activated p38 MAPK increases within phrenic motoneurons and adjacent microglia. It is not yet clear whether p38 MAPK orchestrates the relevant inflammation or is a convergent, downstream molecule that directly impairs pLTF. Furthermore, it is not yet clear whether the relevant p38 MAPK activity is within phrenic motoneurons, adjacent microglia, or both. Microglial p38 MAPK plays a key role in neuroplasticity after spinal nerve ligation (Tsuda et al., 2004; Katsura et al., 2006; Ji and Suter, 2007) and spinal cord injury (Hains and Waxman, 2006), and it is associated with other conditions causing chronic pain (Boyle et al., 2006; Cui et al., 2006). Additional research is needed to understand specific p38 MAPK actions following IH-1.
While the p38 MAPK inhibitor used here (SB 202190) is reported to be a selective p38 MAPK inhibitor (Manthey et al., 1998; Lv et al., 2013), other p38 MAPK inhibitors with similar chemical structures (e.g., 4-[5-(4-fluorophenyl)-2-[4-(methylsulfonyl)phenyl]-1H-imidazol-4-yl]pyridine (SB 203580)) inhibit cyclooxygenase enzymatic activity (Borsch-Haubold et al., 1998). Although, no studies are available concerning the actions of SB 202190 on cyclooxygenase activity, we cannot completely rule out cyclooxygenase inhibition as a contributor to pLTF rescue post-IH-1.
In conclusion, we demonstrate a clear link between systemic inflammation initiated by physiologically relevant intermittent hypoxia and impaired respiratory motor plasticity. Even one night (8 h) of intermittent hypoxia abolishes pLTF by inducing cervical spinal inflammation. We demonstrate the role of IH-1 induced inflammation and refine our understanding by demonstrating that spinal inflammation is key, and that p38 MAPK is a likely key molecule linking that inflammation with pLTF.
It is essential to understand the impact of inflammation on the neural control of breathing, including respiratory plasticity. In clinical conditions associated with systemic inflammation, inflammation may undermine respiratory plasticity, potentially explaining at least some differences in carotid body and ventilatory LTF reported in humans following CIH or with OSA (Mateika and Narwani, 2009). Although it is unclear whether plasticity stabilizes or destabilizes breathing, understanding links between inflammation and respiratory plasticity is necessary to determine functional outcomes and appropriate treatments. Understanding and targeting relevant proinflammatory molecules may lead to new therapeutic interventions that restore plasticity in breathing and nonrespiratory motor functions in devastating disorders that compromise ventilatory capacity.
Footnotes
This work was supported by NIH Grant HL111598, the Francis Family Foundation (A.G.H.), an American Physiological Society undergraduate summer research fellowship (T.J.P.), and T32 HL007654 (S.M.S.). We thank B. Wathen for designing the intermittent hypoxia exposure chambers.
The authors declare no competing financial interests.
- Correspondence should be addressed to Dr. Gordon Mitchell, McKnight Brain Institute and Department of Physical Therapy, University of Florida, Gainesville, FL 32608. gsmitche{at}phhp.ufl.edu