Figures
Abstract
The p21-activated protein kinases (Paks) have been implicated in the regulation of smooth muscle contractility, but the physiologic effects of Pak activation on airway reactivity in vivo are unknown. A mouse model with a genetic deletion of Pak1 (Pak1−/−) was used to determine the role of Pak in the response of the airways in vivo to challenge with inhaled or intravenous acetylcholine (ACh). Pulmonary resistance was measured in anesthetized mechanically ventilated Pak1−/− and wild type mice. Pak1−/− mice exhibited lower airway reactivity to ACh compared with wild type mice. Tracheal segments dissected from Pak1−/− mice and studied in vitro also exhibited reduced responsiveness to ACh compared with tracheas from wild type mice. Morphometric assessment and pulmonary function analysis revealed no differences in the structure of the airways or lung parenchyma, suggesting that that the reduced airway responsiveness did not result from structural abnormalities in the lungs or airways due to Pak1 deletion. Inhalation of the small molecule synthetic Pak1 inhibitor, IPA3, also significantly reduced in vivo airway responsiveness to ACh and 5-hydroxytryptamine (5-Ht) in wild type mice. IPA3 inhibited the contractility of isolated human bronchial tissues to ACh, confirming that this inhibitor is also effective in human airway smooth muscle tissue. The results demonstrate that Pak is a critical component of the contractile activation process in airway smooth muscle, and suggest that Pak inhibition could provide a novel strategy for reducing airway hyperresponsiveness.
Citation: Hoover WC, Zhang W, Xue Z, Gao H, Chernoff J, Clapp DW, et al. (2012) Inhibition of p21 Activated Kinase (PAK) Reduces Airway Responsiveness In Vivo and In Vitro in Murine and Human Airways. PLoS ONE 7(8): e42601. https://doi.org/10.1371/journal.pone.0042601
Editor: Martin R. J. Kolb, McMaster University, Canada
Received: May 4, 2012; Accepted: July 10, 2012; Published: August 10, 2012
Copyright: © Hoover et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by NIH-HL29289, HL074099, and American Asthma Foundation 08-0049. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Asthma is characterized by repeated episodes of reversible airway obstruction and airway hyperresponsiveness to non-specific stimuli. An effective approach for the reduction of airway hyperresponveness and obstruction has been to inhibit airway smooth muscle contraction using bronchodilators. While beta-adrenergic bronchodilators have been the primary therapy for decades; increasing concerns about the long term safety and efficacy of these agents have led to a need for novel approaches to reduce airway smooth muscle responsiveness.
The p21-activated protein kinases (Paks) have been implicated in the regulation of cell motility and contractility in many eukaryotic cell types. We therefore hypothesized that Pak might provide a novel target for the reduction of airway hyperresponsiveness [1]–[5]. Although Pak has been previously implicated in the regulation of smooth muscle contractility, the physiologic effects of Pak activation on airway reactivity in vivo are unknown [6]–[8].
Pak 1, 2 an 3 isoforms are expressed in airway smooth muscle and have been implicated in the regulation of cytoskeletal dynamics in multiple cell types [9], [10]. Pak1 is implicated in the regulation of smooth muscle cell motility and contraction and has been described as the dominant isoform in smooth muscle tissues [1], [8], [11]. In the present study, we used a mouse model with a genetic deletion of Pak1 to determine whether Pak regulates airway reactivity under physiologic conditions, and whether it could provide a target for the suppression of airway responsiveness [12]. We also tested the effects of a synthetic small molecule Pak inhibitor, IPA3, on airway reactivity in vivo [13]. IPA-3 is an allosteric Pak inhibitor that specifically inhibits the auto-activation of Pak isoforms 1, 2 and 3 [13], [14]. In addition, we evaluated the effects of Pak inhibition on the responsiveness of murine and human airway smooth muscle tissues in vitro.
Our findings demonstrate that the suppression of Pak activity reduces airway responsiveness, and suggest that Pak could be an important molecular target for the suppression of airway reactivity in vivo.
Results
Expression of Pak1 isoform is inhibited in airway tissues from Pak1−/− mice
We evaluated the expression of Pak1, Pak2 and Pak3 in WT and Pak1−/− murine tracheas and isolated murine airway smooth muscle by immunoblot. Pak1 was detected in extracts from isolated tracheal smooth muscle tissues and whole tracheas from WT mice, but not in Pak1−/− mice (Figure 1A, B). Pak2 and Pak3 isoforms were also expressed at similar levels in tracheal smooth muscle from both WT and Pak1−/− mice, indicating that the expression of Pak2 and Pak3 were not altered in the Pak1 knockout mice (Figure 1A).
No Pak1 was detected in extracts of isolated tracheal smooth muscle (A) or whole tracheas (B) from Pak1−/− mice. Immunoblots of tracheal smooth muscle were obtained from tracheal smooth muscle extracts pooled from 3 mice of each type. Whole trachea extracts were each from a single mouse.
Genetic Deletion of Pak1 suppresses Pulmonary Responsiveness in vivo
We evaluated the role of Pak1 in the regulation of changes in pulmonary resistance in response to ACh in vivo by comparing responses of WT and Pak1−/− mice. Dose-response curves depicting increases in pulmonary resistance above baseline for increasing concentrations of inhaled ACh are illustrated in Figure 2A. There were no significant differences in the baseline resistances for either group. However, aerosolized ACh elicited significantly smaller increases in pulmonary resistance in Pak1−/− mice compared to WT mice (P<0.05).
Resistance in response to increasing concentrations of aerosolized acetylcholine (ACh) for wild-type (WT; N = 8) and Pak1−/− mice (N = 8) (A); values are means ± SEM. There was no difference in resistance at baseline. When analyzed by repeated measures ANOVA, resistance increased with increasing ACh dose (p<0.0001), Pak1−/− mice had a significantly smaller slope of the dose response curve (p<0.03), and a significantly smaller increase in resistance compared to WT mice (p<0.03). Post-hoc analysis demonstrated Pak 1−/− compared to WT mice had significantly smaller resistances at all ACh concentrations ≥7.5 mg/ml (p<0.05). Resistance in response to increasing concentrations of intravenous acetylcholine (ACh) for wild-type (WT; N = 4) and Pak1−/− mice (N = 4) (B); values are means ± SEM. There was no difference in resistance at baseline. When analyzed by repeated measures ANOVA, resistance for Pak1−/− mice increased less with increasing ACh dose (p<0.0001) compared to WT mice. Post-hoc analysis demonstrated Pak1−/− compared to WT mice had significantly lower resistances at ACh concentrations ≥0.42 mg (p<0.05).
We also evaluated the effect of the route of agonist delivery upon airway responsiveness by performing dose-response curves in response to intravenous challenge with ACh (Figure 2B). Again, there were no significant differences for baseline resistances in animals challenged with intravenous ACh, and ACh elicited significantly smaller increases in pulmonary resistance in Pak1−/− mice compared to WT mice (P<0.05). The fact that the similar results were obtained using intravenous versus aerosolized ACh indicates the effect of Pak deletion on airway reactivity cannot be attributed to alterations in the epithelial barrier function in Pak1−/− mice.
Pharmacologic inhibition of Pak suppresses Pulmonary Responsiveness In Vivo
We evaluated the effect of a small molecule synthetic Pak inhibitor (IPA3) on pulmonary reactivity to ACh in WT mice in vivo. IPA3 allosterically inhibits the catalytic activity of Pak1, 2 and 3 isoforms [11], [12]. Pak inhibitor IPA3 (20 µl of 5 mM, 1%DMSO) or Vehicle (1% DMSO) was nebulized into the ventilator circuit 60 minutes prior to bronchial challenge with aerosolized ACh. The respiratory response to inhaled ACh of WT mice receiving IPA3 was significantly decreased compared to that of WT mice that received Vehicle alone (Figure 3A).
When assessed by repeated ANOVA, resistance increased with increasing ACh dose (p<0.0001), and IPA3 dissolved in 1% DMSO (N = 3) and aerosolized 1-hour prior to bronchial challenge of WT mice significantly reduced the slope of the increase in resistance (p<0.0001), as well as the magnitude of the increase in resistance compared to control vehicle (1%DMSO; N = 5) (p<0.001) (A). Post-hoc analysis indicated that IPA3 treatment resulted in lower resistances at MCh doses ≥33 mg/ml (p<0.05). Tracheal smooth muscle isolated from WT mice treated in vivo with IPA3 demonstrated significantly lower Pak activation as assessed by Pak T423 phosphorylation following stimulation with ACh compared to airway smooth muscle isolated from WT mice (B). Results represent 2 samples of tracheal smooth muscle from each group. Each sample consisted of pooled tracheal muscle tissues from 3 separate mice with the same treatment.
In separate series of experiments, tracheas were isolated from WT animals that had received nebulized IPA3 in vivo to confirm the inhibition of Pak activation by IPA3. Phosphorylation of Thr 423 in the Pak catalytic domain occurs with its activation and is critical for its full catalytic function toward exogenous substrates [15], [16]. Following removal of the epithelium from isolated tracheas, immunoblots were performed on tracheal extracts to measure the phosphorylation of Pak on tyrosine 423. ACh elicited a smaller increase in Pak phosphorylation at Thr 423 in tracheal smooth muscle from IPA3-treated animals than in tracheas from WT animals, indicating that the dose of aerosolized IPA3 was effective at inhibiting Pak activation in vivo (Figure 3B).
Genetic Deletion of Pak1 Suppresses the Contractility of isolated Tracheal segments in vitro
We evaluated the in vitro contractility of tracheal segments isolated from Pak1−/− mice. Tracheal segments from WT and Pak1−/− mice were isolated, the epithelium removed, and the segments suspended in organ chambers for the measurement of isometric contractile force in response to increasing concentrations of ACh. Tracheal segments from Pak1−/− mice developed significantly lower forces in response to ACh compared to tracheas from WT mice (P<0.05) (Figure 4).
Isometric force generation (% of maximal force to ACh stimulation in WT mice) was significantly lower in tracheas isolated from Pak1−/− (grey squares) mice compared to WT (black diamonds) mice (N = 10 or 11 in each group, p<0.01).
Genetic Deletion of Pak1 does not affect lung parenchymal structure or function
The effect of Pak1 deletion on the elastic properties of the lungs was evaluated by comparing pressure-volume curves obtained in WT and Pak1−/− animals in vivo. Mechanical ventilation was interrupted and the pulmonary system was slowly cycled between the end-expiratory pressure of 2.5 cm H2O and an airway pressure of 30 cm H2O. There were no significant differences in lung volume at 30 cm H2O between WT and Pak1−/− mice. There were also no differences in the pressure volume curves of the WT and Pak1−/− animals (Figures 5A, B).
There were no significant differences for lung volumes at 30 cmH2O (p>0.37) (A); pressure volume curves normalized to volume at 30 cmH2O (B); or Alveolar Mean Linear Intercepts (MLI) (p>0.40) (C).
Alveolar size was compared in lungs from WT and Pak1−/− animals by measuring mean linear intercepts from histological sections taken from lungs that had been formalin fixed at 30 cm H2O. There were no significant differences in mean linear intercept for WT and Pak1−/− animals, indicating no differences in alveolar size (Figure 5C).
Genetic deletion of Pak1 does not affect airway structure
The effects of Pak1 deletion on the structure of the airways were evaluated by morphometric assessments of histologic sections of lungs from WT and Pak1−/− mice. There were no significant differences in the area of the airway wall or the areas of smooth muscle and epithelium (Figure 6).
Airway wall area (A), airway smooth muscle area (B), and airway epithelium area (C) were not significantly different between the WT (black squares) and Pak1−/− (grey circles) mice when assessed by ANOVA adjusting for airway perimeter (p>0.15). (N = 5 mice in each group).
Pharmacologic inhibition of Pak inhibits Responsiveness of Murine Tracheal Segments in vitro
The effect of IPA3 on the contractility of murine tracheal segments to ACh was evaluated by concurrently stimulating pairs of tracheas with cumulative concentrations of acetylcholine (ACh) (10−9 to 10−3 M) or 5-hydroxytryptamine (5-Ht) (10−9 to 10−4) and then measuring the isometric contractile force at each concentration. The ACh or 5-Ht was then washed out and one trachea from each pair was treated with 100 µM IPA3 to inhibit PAK. The other trachea was treated with vehicle (1% DMSO). Tracheal segments were incubated in IPA3 or vehicle for 2 hours, after which a dose responsive curve to ACh or 5-Ht was repeated. The contractile responses to ACh and 5-Ht were significantly lower in tracheas treated with IPA3 compared to tracheas treated with vehicle (Figure 7).
Curves show responses of tracheal segments normalized to maximal response to ACh or 5-Ht prior to incubation with vehicle or IPA3. IPA3 treatment (open circles) significantly inhibited contractile responses to (A) ACh (n = 4) and (B) 5-Ht (n = 4) compared to responses of vehicle-treated tissues (black squares). Values are means ± SEM, significantly different, * p<0.05.
Pharmacologic inhibition of Pak inhibits Responsiveness of Human Bronchial Rings in vitro
The effect of IPA3 on the contractility of human bronchial rings to ACh was evaluated by concurrently stimulating pairs of bronchial rings with cumulative concentrations of acetylcholine (ACh) (10−9 to 10−3 M) as described above. The contractile responses to ACh were significantly lower in bronchi treated with IPA3 compared to bronchi treated with vehicle (Figure 8). The inhibition of PAK activation by IPA3 was confirmed by western blot for PAK T423 phosphorylation (data not shown).
Curves show responses of bronchial rings normalized to maximal ACh response obtained prior to incubation with vehicle or IPA3. IPA3 treatment (open circles) significantly inhibited contractile responses to ACh compared to responses of vehicle-treated bronchi (black squares). Values are means ± SEM, (n = 3 pairs of bronchi), * p<0.05.
Discussion
Our results demonstrate that inhibiting the activity of p21-activated protein kinase is an effective approach for reducing airway responsiveness in vivo. Mice with a genetic deletion of Pak1 exhibited significantly lower airway reactivity to acetylcholine in vivo, and the aerosol administration of a synthetic small molecule Pak inhibitor also reduced airway responsiveness in mice in vivo. Furthermore, isolated tracheal segments from Pak1−/− mice exhibited reduced contractility to ACh in vitro, indicating that the decrease in airway reactivity observed in vivo in Pak1−/− mice reflected a decrease in force generation by the airway smooth muscle. As no differences in the structure of the airways and lung parenchyma were detected in Pak1−/− and WT animals, decreased airway responsiveness did not appear to result from other factors that can alter airway responsiveness. Taken in sum, our observations provide strong evidence that the reduction of Pak activity lowers airway responsiveness in vivo, and that this effect is caused by a reduction in the contractility of the airway smooth muscle. The fact that Pak inhibition was also effective in reducing airway smooth muscle responsiveness in human bronchial tissues, which suggests that this approach could be effective in humans in vivo also.
We could not detect any differences in the structure or physical properties of the lungs from Pak1−/− mice as compared to WT mice. The quantity of airway smooth muscle within the airway wall was the same in the WT and Pak1−/− mice and airway morphometry was similar. There were also no differences between WT and Pak1−/− mice in lung parenchymal structure or function. These results suggest the lower level of airway reactivity in Pak1−/− mice are unlikely to be due to differences in lung structure. Previous studies that have evaluated the functions of other organ systems in Pak1−/− mice have also not detected major developmental abnormalities or organ defects [12], [17], [18]. Taken in sum, our findings in the Pak1−/− mice provide strong evidence that their decreased airway responsiveness in vivo results from the absence of Pak1 in their airway smooth muscle tissue, and that this reflects a critical role for Pak1 in the contractile activation of airway smooth muscle.
We showed that the synthetic Pak inhibitor, IPA3, was effective at inhibiting ACh-induced Pak activation in airway tissues both in vivo and in vitro. We also showed that IPA3 inhibits the contractile response of airway tissues to 5-Ht in vitro, indicating that the effects of IPA3 are not agonist-specific. IPA3 is an allosteric Pak inhibitor that binds outside the ATP-binding pocket and specifically inhibits the auto-activation of Pak isoforms 1, 2 and 3 [13], [14]. Treatment of WT mice with IPA3 inhibited airway responsiveness in vivo and in vitro similarly to that observed in the Pak1−/− mice. These results provide further support for our conclusion that the reduced airway responsiveness in Pak1−/− mice results from the loss of Pak1 activation in airway smooth muscle in response to agonist stimulation, rather than from an unidentified developmental defect caused by the absence of Pak1. IPA3 also inhibited the contractility of isolated human bronchial tissues to ACh, confirming that this inhibitor is also effective in human airway smooth muscle tissue.
This is the first study to demonstrate a role for Pak1 in the regulation of airway responsiveness in vivo. Previous studies that have evaluated the role of Pak in the regulation of smooth muscle contractile proteins have yielded inconsistent findings. Some of these studies have shown an inhibitory effect of Pak on contractile protein activation, suggesting that it would inhibit smooth muscle contractility [9], [17], whereas other studies indicate that Pak may contribute to the activation of contractile proteins and active tension development [8], [12], [13], [19]. Most of these studies were performed using Triton skinned muscle tissues and exogenous recombinant Pak [5]–[7], [16] or by expressing recombinant Pak in cultured cells [20]. The observations obtained using these preparations may not reflect the function of endogenous Pak in intact smooth muscle tissues under physiologic conditions. The results of our current studies evaluating airway responsiveness under physiologic conditions in vivo and in vitro clearly demonstrate that Pak is a critical intermediate in the contractile activation of airway smooth muscle and that its inhibition reduces airway responsiveness.
In conclusion, our findings demonstrate that Pak is an effective molecular target for inhibiting airway smooth muscle contraction and suppressing airway reactivity in vivo. This suggests that Pak inhibition could provide a novel strategy for reducing airway hyperresponsiveness in diseases such as asthma.
Materials and Methods
Ethics Statement
The protocols for these studies were approved by the Indiana University Institutional Animal Care and Use Committee (IACUC) and Indiana University Institutional Review Board, which waived the need for written consent for the use of surgical waste material for our research study and the tissue was, and remained de-identified.
Animals
Pak1−/− mice on a C57BL/6 background were backcrossed 6 generations as previously described [10], [15]. Pak1−/− mice and Wild type (WT) C57BL/6 mice were studied at 8 weeks of age.
Human Airway Tissues
Fresh non-identified human lung tissue from surgical waste was collected within 1–2 hours of removal from the lungs and preserved in physiologic saline solution. Tissues were studied in vitro immediately after they were obtained.
In Vivo Pulmonary Measurements
WT and Pak1−/− mice were anesthetized with pentobarbital (6 mg/100 gm intra-peritoneal). Following tracheotomy, an 18- gauge cannula was inserted and securely tied with 4.0 braided silk. The animals were then mechanically ventilated with a computer-controlled small-animal ventilator (FlexiVent, SCIREQ, Montreal, Quebec) using a tidal volume of 8 mL/kg at a rate of 180 breaths/min and PEEP of 3.5 cm H20. Pulmonary resistance was measured by the computer controlled ventilator by interrupting ventilation and imposing a 2.5 Hz sinusoidal signal and then resuming ventilation.
Airway Challenge
Following measurement of baseline resistance, animals underwent airway challenge with normal saline and then increasing concentrations of acetylcholine (ACh) or methacholine (MCh) by either aerosol challenge or intravenous challenge. For aerosol challenge, 20 µL of each solution of ACh ranging from 0.3 to 50 mg/ml was nebulized in line with the ventilation circuit over 10 seconds. Resistance was then measured every 30 seconds for the next 4 minutes to record a maximal response for each ACh dose. For intravenous Challenge, increasing volumes (3–100 µL) of acetylcholine (10 mg/ml) were infused through a jugular vein catheter for 20 seconds to deliver Ach doses ranging from 0.03–1.0 mg. Measurements of resistance were obtained every 10 seconds for a minute and then the next Ach dose was administered.
Evaluation of PAK inhibitor in vivo (IPA3)
The effects of the small molecule Pak inhibitor IPA3 [13] on in vivo pulmonary responsiveness was evaluated in WT animals. IPA3 (5 mM) was dissolved in 1% DMSO and 20 µl was nebulized into the ventilator circuit 60 minutes prior to performing the Ach dose response curves. Control animals received nebulized 1% DMSO prior to bronchial challenge.
Pressure-volume curves of the lungs
The pulmonary elastic properties were evaluated from quasi-static pressure-volume curves obtained in vivo. Mechanical ventilation of the anesthetized animals was interrupted and the pulmonary system was slowly cycled between the end-expiratory pressure of 2.5 cm H2O and a maximal airway pressure of 30 cmH2O.
Measurement of Contractility of Isolated Murine Tracheal Segments and Human Bronchial Rings In Vitro
Pak1−/− and WT mice were euthanized with pentobarbital (12 mg/100 g intra-peritoneal) and intact tracheal segments were removed and dissected free of the epithelium. The isolated tracheal segments were mounted on wires and attached to Grass force transducers in tissue baths for the measurement of isometric force in response to increasing doses of ACh.
In some experiments, tracheas were isolated from WT mice to evaluate the effect of Pak inhibition on the contractile responses of airway tissues. Dose-response curves to ACh (10−9 to 10−3 M) or 5-hydroxytryptamine (5-Ht) (10−9 to 10−4 M) were performed after 30 min incubation in physiologic saline. After washing the agonists from the tissues, one of each pair of the tracheal segments was treated with 100 µM IPA3 dissolved in 1% DMSO for 2 hours and the other segment was treated with 1% DMSO alone. A dose-response curve to ACh or 5-HT was then repeated on each pair of tissues concurrently.
Human bronchial rings (5 mm diameter, 2 mm wide) were dissected from lung specimens and cleaned of connective tissue. Rings were attached to force transducers as described above and equilibrated in a tissue bath for 30–60 min. Two rings were obtained from each lung specimen and studied concurrently. Dose-response curves to ACh (10−9 to 10−3 M) were performed after 30 min incubation in physiologic saline. After washing ACh from the tissue, one of the bronchial rings was treated with 100 µM IPA3 dissolved in 1% DMSO for 2 hours and the other ring was treated with 1% DMSO alone. A dose-response curve to ACh was then repeated on each tissue concurrently. Tissues from each group were quick frozen in liquid nitrogen for biochemical analysis to confirm the inhibition of Pak activation by IPA3.
Analysis of protein expression and phosphorylation
Proteins were extracted from pulverized murine tracheal smooth muscle, whole murine tracheal segments or human bronchial rings. Tissue extracts were then boiled in sample buffer (1.5% dithiothreitol, 2% SDS, 80 mM Tris-HCl (pH 6.8), 10% glycerol and 0.01% Bromophenol Blue) for 5 min, separated using SDS polyacrylamide gel electrophoresis (SDS-PAGE), and transferred to nitrocellulose. Membranes were probed with antibodies followed by horseradish peroxidase (HRP)-conjugated secondary antibodies (Ig) (Jackson, Immunoresearch Co.). Proteins were visualized by enhanced chemiluminescence (ECL). Antibodies against Pak1, Pak2, Pak3 and Pak Thr423 were obtained from Cell Signaling.
Lung and Airway Histology
Lung were excised and fixed with 10% formalin at a distending pressure of 20 cm H2O, sectioned into blocks, embedded in paraffin, and a 5-µm-thick section were stained with Masson's Trichrome. Tissues were visualized by light microscopy and images captured with a digital camera (SPOT, Diagnostic Instruments, Inc, MI), and morphometric measurements from the fixed tissues were obtained from the digital images using imaging software (Metamorph, version 5.01r, Universal Imaging). For airways, the internal perimeters were calculated from the luminal border of the airway epithelium. The cross-sectional areas of the airway wall, airway smooth muscle and epithelium were determined by point counting, as previously described [21]. For the parenchyma, alveolar size was quantified by measuring the mean linear intercept, which is the number of alveolar walls intersecting a line of known length [22], [23].
Author Contributions
Conceived and designed the experiments: WCH JC DWC SJG RST. Performed the experiments: WCH WZ ZX HG. Analyzed the data: WCH WZ ZX HG SJG RST. Contributed reagents/materials/analysis tools: JC DWC. Wrote the paper: WCH SJG RST.
References
- 1. Dechert MA, Holder JM, Gerthoffer WT (2001) p21-activated kinase 1 participates in tracheal smooth muscle cell migration by signaling to p38 Mapk. American Journal of Physiology - Cell Physiology 281: C123–C132.
- 2. Knaus UG, Bokoch GM (1998) The p21Rac/Cdc42-activated kinases (PAKs). International Journal of Biochemistry & Cell Biology 30: 857–862.
- 3. Pacheco A, Chernoff J (2010) Group I p21-activated kinases: emerging roles in immune function and viral pathogenesis. International Journal of Biochemistry & Cell Biology 42: 13–16.
- 4. Sells MA, Knaus UG, Bagrodia S, Ambrose DM, Bokoch GM, et al. (1997) Human p21-activated kinase (Pak1) regulates actin organization in mammalian cells. Current Biology 7 (3) 202–10.
- 5. Zhao Z-s, Manser E (2005) PAK and other Rho-associated kinases–effectors with surprisingly diverse mechanisms of regulation. Biochemical Journal 386: 201–214.
- 6. McFawn PK, Shen L, Vincent SG, Mak A, Van Eyk JE, et al. (2003) Calcium-independent contraction and sensitization of airway smooth muscle by p21-activated protein kinase. American Journal of Physiology - Lung Cellular & Molecular Physiology 284: L863–L870.
- 7. Van Eyk JE, Arrell DK, Foster DB, Strauss JD, Heinonen TY, et al. (1998) Different molecular mechanisms for Rho family GTPase-dependent, Ca2+-independent contraction of smooth muscle. Journal of Biological Chemistry 273: 23433–23439.
- 8. Wang R, Li QF, Anfinogenova Y, Tang DD (2007) Dissociation of Crk-associated substrate from the vimentin network is regulated by p21-activated kinase on ACh activation of airway smooth muscle. American Journal of Physiology - Lung Cellular & Molecular Physiology 292 (1) L240–8.
- 9. Bokoch GM (2003) Biology of the p21-activated kinases. Annual Review of Biochemistry 72: 743–781.
- 10. Molli PR, Li DQ, Murray BW, Rayala SK, Kumar R (2009) PAK signaling in oncogenesis. Oncogene 28: 2545–2555.
- 11. Wirth A, Schroeter M, Kock-Hauser C, Manser E, Chalovich JM, et al. (2003) Inhibition of contraction and myosin light chain phosphorylation in guinea-pig smooth muscle by p21-activated kinase 1. Journal of Physiology 549: 2–500.
- 12. Allen JD, Jaffer ZM, Park S-J, Burgin S, Hofmann C, et al. (2009) p21-activated kinase regulates mast cell degranulation via effects on calcium mobilization and cytoskeletal dynamics. Blood 113: 2695–2705.
- 13. Deacon SW, Beeser A, Fukui JA, Rennefahrt UEE, Myers C, et al. (2008) An isoform-selective, small-molecule inhibitor targets the autoregulatory mechanism of p21-activated kinase. Chemistry & Biology 15: 322–331.
- 14. Yi C, Maksimoska J, Marmorstein R, Kissil JL (2010) Development of small-molecule inhibitors of the group I p21-activated kinases, emerging therapeutic targets in cancer. Biochemical Pharmacology 80: 683–689.
- 15. Gatti A, Huang Z, Tuazon PT, Traugh JA (1999) Multisite autophosphorylation of p21-activated protein kinase gamma-PAK as a function of activation. Journal of Biological Chemistry 274: 8022–8028.
- 16. Zenke FT, King CC, Bohl BP, Bokoch GM (1999) Identification of a central phosphorylation site in p21-activated kinase regulating autoinhibition and kinase activity. Journal of Biological Chemistry 274: 32565–32573.
- 17. McDaniel AS, Allen JD, Park S-J, Jaffer ZM, Michels EG, et al. (2008) Pak1 regulates multiple c-Kit mediated Ras-MAPK gain-in-function phenotypes in Nf1+/− mast cells. Blood 112: 4646–4654.
- 18. Wang Z, Oh E, Clapp DW, Chernoff J, Thurmond DC (2011) Inhibition or Ablation of p21-activated Kinase (PAK1) Disrupts Glucose Homeostatic Mechanisms in Vivo. Journal of Biological Chemistry 286: 41359–41367.
- 19. Foster DB, Shen LH, Kelly J, Thibault P, Van Eyk JE, et al. (2000) Phosphorylation of caldesmon by p21-activated kinase. Implications for the Ca(2+) sensitivity of smooth muscle contraction. Journal of Biological Chemistry 275: 1959–1965.
- 20. Murthy KS, Zhou H, Grider JR, Brautigan DL, Eto M, et al. (2003) Differential signalling by muscarinic receptors in smooth muscle: m2-mediated inactivation of myosin light chain kinase via Gi3, Cdc42/Rac1 and p21-activated kinase 1 pathway, and m3-mediated MLC20 (20 kDa regulatory light chain of myosin II) phosphorylation via Rho-associated kinase/myosin phosphatase targeting subunit 1 and protein kinase C/CPI-17 pathway. Biochemical Journal 374: 1–55.
- 21. Xue Z, Zhang L, Liu Y, Gunst SJ, Tepper RS (2008) Chronic inflation of ferret lungs with CPAP reduces airway smooth muscle contractility in vivo and in vitro. Journal of Applied Physiology 104: 610–615.
- 22. Xue Z, Zhang L, Ramchandani R, Liu Y, Antony VB, et al. (2005) Respiratory system responsiveness in rabbits in vivo is reduced by prolonged continuous positive airway pressure. Journal of Applied Physiology 99: 677–682.
- 23. Thurlbeck W (1967) Internal surface area and other measurements in emphysema. Thorax 22: 483–496.