Rationale: Endothelial injury is a hallmark of sepsis-induced acute respiratory distress syndrome (ARDS). Endothelial barrier integrity is regulated by the endothelial glycocalyx, a matrix of proteoglycans and glycosaminoglycans (GAGs) that lines the vascular lumen. In sepsis, this glycocalyx is degraded by heparanase, which cleaves heparan sulfate, the primary glycocalyx GAG. Glycocalyx breakdown is linked to worse sepsis outcomes, but the mechanisms inducing heparanase activity in sepsis are unknown. We previously found that plasma levels of hemoglobin released from red blood cells (cell-free hemoglobin, CFH) are elevated in clinical sepsis and correlate with higher rates of ARDS and death. CFH also worsens endothelial injury and microvascular permeability in murine sepsis. We therefore hypothesized that CFH upregulates heparanase production to drive glycocalyx shedding and inflammation in sepsis. Methods: To test the association between CFH levels, heparanase expression, and glycocalyx degradation, circulating levels of heparanase, heparan sulfate, and total GAGs were measured in 77 sepsis patients and compared across CFH quartiles. In mice with intraabdominal polymicrobial sepsis with elevated CFH (CS [cecal slurry] + intravenous [IV] CFH), plasma heparanase, total GAGs, and syndecan-1 were quantified. Whole lung and plasma pro-inflammatory cytokines were also determined to investigate the impact of CFH on inflammation in sepsis. Results: In sepsis patients, higher circulating CFH levels were associated with increased plasma heparanase (p=0.0304), total GAGs (p=0.0178), and heparan sulfate (p=0.0112). CFH also exacerbated glycocalyx degradation in murine sepsis; circulating syndecan-1 (p=0.0152) and total GAGs (p=0.0094) were elevated in animals that received CS+IV CFH compared to CS alone. This effect may be mediated by upregulation of active heparanase, which was higher in the plasma of CS+IV CFH treated animals (p=0.1333). CFH also worsened illness severity, as CS+IV CFH animals had worse sepsis severity scores (p=0.0074). Whole lung tumor necrosis factor-alpha (TNF-a; p=0.0129) and interferon-gamma (IFN-g; p=0.0264) transcript levels were increased in the CS+IV CFH group, indicating greater lung inflammation. Systemic inflammation was also enhanced in the CS+IV CFH animals, demonstrated by higher plasma TNF-a (p<0.001) and IFN-g (p=0.0221) concentrations. Conclusions: In sepsis, CFH is associated with upregulation of heparanase and endothelial glycocalyx degradation, which may disrupt the endothelial barrier, causing downstream organ injury. Future studies to define the molecular pathways that underlie these findings and their effect on endothelial permeability will be an important next step towards identifying novel treatment targets to improve outcomes for patients with sepsis-associated ARDS. Funding F30HL170483, R01HL164937, R01HL158906, R01HL150783, R01HL125371. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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