Dy the changes at the mRNA level only, which may not correspond directly to the protein expression. OSA patients have impaired endothelium-dependent vascular relaxation, as a result of reduced NO bioavailability caused byinhibitor decreased eNOS expression and/or activity [3,24,33,34,35,10]. Our data demonstrate that in mildly hypoxemic OSA patients, despite decreased eNOS mRNA, microvascular reactivity to acetylcholine treatment was almost not affected compared to the control group. We postulate that these patients likely producedFigure 3. Expression of select genes in mouse aortas is affected by IH. Mice were exposed to intermittent hypoxia (IH) or intermittent air (IA) for 4 weeks. RNA was isolated from mouse aortas followed by cDNA generation and qPCR analysis. The gene expression is presented as relative mRNA expression versus a control (IA) group. Results for each sample were normalized versus 28S. Data are presented as mean +/2 SDEV. n = 7?2. * p,0.05. doi:10.1371/journal.pone.0070559.gBiomarkers of Vascular Dysfunction in Sleep ApneaFigure 4. Expression of select genes in HMVEC exposed to IH. RNA was isolated from HMVEC exposed to IH, followed by cDNA generation and qRT-PCR analysis. The gene expression is presented as relative mRNA expression versus a control group. Results were obtained from at least 3 Epigenetic Reader Domain experiments and each sample was normalized versus 28S. Data are presented as mean +/2 SDEV. * p,0.05; *** p,0.001. doi:10.1371/journal.pone.0070559.gsufficient NO to maintain proper vasoreactivity. The molecular mechanism behind reduced eNOS mRNA levels in response to mild hypoxemia still needs to be explored.Unexpectedly, eNOS mRNA levels in severely hypoxemic OSA patients were comparable to 1315463 those in controls. However, despite adequate eNOS mRNA levels, these patients showed significantlyFigure 5. Expression of select genes in HCAEC exposed to IH. RNA was isolated from HCAEC exposed to IH, followed by cDNA generation and qRT-PCR analysis. The gene expression is presented as relative mRNA expression versus a control group. Results were obtained from at least 3 experiments and each sample was normalized versus b-actin. Data are presented as mean +/2 SDEV. * p,0.05. doi:10.1371/journal.pone.0070559.gBiomarkers of Vascular Dysfunction in Sleep Apneaimpaired microvascular reactivity, which indicates reduced eNOS activity and NO bioavailability [10]. We believe that decreased eNOS activity may result from its post-translational modification induced by OSA-triggered inflammation [8,9,10] that is validated here by significantly higher VCAM-1 expression in the severely hypoxemic group compared to control subjects. Future studies will verify this hypothesis, though eNOS function impairment by posttranslational modifications, independently from its expression levels, was already documented in response to hypoxia and in diabetic patients [35,36,37,38,39,40]. From a clinical standpoint, our data highlight the complexity of mechanisms regulating eNOS expression and activity in the context of severity of intermittent hypoxemia. Our in vivo data demonstrate upregulation of eNOS mRNA in aortas isolated from mice exposed to chronic, 23977191 4-week IH, compared to control mice. It has been previously established that in in vivo model of OSA, response to IH during mice sleep time resulted in severe hypoxemia [41]. Accordingly, we are exploring whether this OSA mouse model resembles what we observed in severely hypoxemic OSA patients, i.e., that increased eNOS mRNA.Dy the changes at the mRNA level only, which may not correspond directly to the protein expression. OSA patients have impaired endothelium-dependent vascular relaxation, as a result of reduced NO bioavailability caused bydecreased eNOS expression and/or activity [3,24,33,34,35,10]. Our data demonstrate that in mildly hypoxemic OSA patients, despite decreased eNOS mRNA, microvascular reactivity to acetylcholine treatment was almost not affected compared to the control group. We postulate that these patients likely producedFigure 3. Expression of select genes in mouse aortas is affected by IH. Mice were exposed to intermittent hypoxia (IH) or intermittent air (IA) for 4 weeks. RNA was isolated from mouse aortas followed by cDNA generation and qPCR analysis. The gene expression is presented as relative mRNA expression versus a control (IA) group. Results for each sample were normalized versus 28S. Data are presented as mean +/2 SDEV. n = 7?2. * p,0.05. doi:10.1371/journal.pone.0070559.gBiomarkers of Vascular Dysfunction in Sleep ApneaFigure 4. Expression of select genes in HMVEC exposed to IH. RNA was isolated from HMVEC exposed to IH, followed by cDNA generation and qRT-PCR analysis. The gene expression is presented as relative mRNA expression versus a control group. Results were obtained from at least 3 experiments and each sample was normalized versus 28S. Data are presented as mean +/2 SDEV. * p,0.05; *** p,0.001. doi:10.1371/journal.pone.0070559.gsufficient NO to maintain proper vasoreactivity. The molecular mechanism behind reduced eNOS mRNA levels in response to mild hypoxemia still needs to be explored.Unexpectedly, eNOS mRNA levels in severely hypoxemic OSA patients were comparable to 1315463 those in controls. However, despite adequate eNOS mRNA levels, these patients showed significantlyFigure 5. Expression of select genes in HCAEC exposed to IH. RNA was isolated from HCAEC exposed to IH, followed by cDNA generation and qRT-PCR analysis. The gene expression is presented as relative mRNA expression versus a control group. Results were obtained from at least 3 experiments and each sample was normalized versus b-actin. Data are presented as mean +/2 SDEV. * p,0.05. doi:10.1371/journal.pone.0070559.gBiomarkers of Vascular Dysfunction in Sleep Apneaimpaired microvascular reactivity, which indicates reduced eNOS activity and NO bioavailability [10]. We believe that decreased eNOS activity may result from its post-translational modification induced by OSA-triggered inflammation [8,9,10] that is validated here by significantly higher VCAM-1 expression in the severely hypoxemic group compared to control subjects. Future studies will verify this hypothesis, though eNOS function impairment by posttranslational modifications, independently from its expression levels, was already documented in response to hypoxia and in diabetic patients [35,36,37,38,39,40]. From a clinical standpoint, our data highlight the complexity of mechanisms regulating eNOS expression and activity in the context of severity of intermittent hypoxemia. Our in vivo data demonstrate upregulation of eNOS mRNA in aortas isolated from mice exposed to chronic, 23977191 4-week IH, compared to control mice. It has been previously established that in in vivo model of OSA, response to IH during mice sleep time resulted in severe hypoxemia [41]. Accordingly, we are exploring whether this OSA mouse model resembles what we observed in severely hypoxemic OSA patients, i.e., that increased eNOS mRNA.
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