Cdc42 regulates cytokine expression and trafficking in bronchial epithelial cells

Identification of bronchial epithelial genes associated with type 2 eosinophilic inflammation in asthma

BACKGROUND

Airway inflammation plays a critical role in asthma pathogenesis and pathophysiology, but the molecular pathways contributing to airway inflammation are not fully known, particularly type 2 (T2) inflammation characterized by both eosinophilia and higher fractional exhaled nitric oxide (Feno) levels.

OBJECTIVE

We sought to identify genes whose level of expression in epithelial brushing samples were associated with both bronchoalveolar lavage (BAL) eosinophilia and generation of Feno.

METHODS

We performed segmental allergen bronchoprovocation (SBP-Ag) in participants with asthma, then RNA sequencing analyses of BAL cells and brushing samples before and 48 hours after SBP-Ag to identify regulation of eosinophil recruitment and Feno changes.

RESULTS

Allergen bronchoprovocation increased Feno levels, which correlated with eosinophilia. Thirteen genes were identified in brushing samples, whose expression changed in response to SBP-Ag and correlated with both airway eosinophilia and Feno levels after SBP-Ag. Among these 13 genes, epithelial cell product CDH26/cadherin-26 contributed to the amplification of T2 inflammation, as reflected by eosinophilia and Feno, and causal mediation analyses with pro-T2 and proeosinophilic cytokine mediators in BAL fluids. Among the genes associated with reduced eosinophilia and Feno, HEY2 is known to enhance cell proliferation, migration, invasion, and epithelial-to-mesenchymal transition, as well as to reduce apoptosis.

CONCLUSION

This unbiased RNA sequencing analysis in participants with allergic asthma revealed several epithelial cell genes, particularly CDH26, that may be critical for the development or augmentation of T2 inflammation in asthma.

TLR5 activation in respiratory epithelial cells orchestrate mucosal Th17 response through both indirect and direct pathways

BACKGROUND

Flagellin, a potent mucosal adjuvant administered via the intranasal route, has been widely recognized for its capacity to enhance immune responses against diverse pathogens. However, the effects and the underlying mechanisms by which flagellin modulates CD4+ T cell differentiation remain incompletely understood.

METHODS

Recombinant flagellin proteins, including full-length flagellin (SF) and a TLR5-binding deficient variant (SFΔ90-97), were produced and purified. An OT-II derived CD4+ T cell adoptive transfer model, a classical intranasal immunization model and dendritic cell (DC)-CD4+ T co-culturing system were used. The proliferation and differentiation of CD4+ T cells were analyzed using flow cytometry analysis. RNA sequencing and neutralizing antibody blocking experiments were performed to determine the essential cytokines involved in flagellin modulated Th17 differentiation.

RESULTS

Flagellin preferentially promotes Th17 cells differentiation. Respiratory epithelial cells (RECs), acting as sentinel cells, are the first to encounter exogenous stimuli during intranasal immunization. Flagellin stimulates the secretion of various soluble cytokines by binding to TLR5 on the surface of RECs, with GM-CSF facilitating the functional activation of airway DCs. GM-CSF-conditioned DCs exhibit upregulated IL-6 expression which in turn drives the polarization of naïve CD4+ T cells toward the Th17 phenotype. Furthermore, TLR5-regulated REC-derived IL-6 synergizes with TLR5-modulated DCs to amplify Th17 polarization signals, thereby enhancing the Th17 induction.

CONCLUSION

Flagellin preferentially induced a Th17-enhanced immune response and RECs were highlighted its essential roles during this process through both indirect and direct pathways. For indirect pathway, RECs modulate DC function through GM-CSF. Moreover, RECs directly contribute to Th17 differentiation by secreting IL-6.

CDC42 Regulates the ERK Pathway to Improve Oxygen‒Glucose Deprivation/Reoxygenation-Induced Neural Oxidative Stress and Apoptosis

CDC42 regulates neural morphology, differentiation, and injury and modifies oxidative stress and neural immune infiltration, but its effect on oxygen-glucose deprivation/reoxygenation (OGD/R)-induced neural injury has not been reported. Therefore, this study aimed to investigate the effects of CDC42 overexpression on neural injury and oxidative stress during the OGD/R process. The OGD/R cellular model was established by culturing HT22 cells in glucose-free medium under hypoxic conditions for 2, 4, or 6 h and then transferring them to complete medium and a standard environment for another 24 h. CDC42 and negative control overexpression vectors (oeCDC42 and oeNC) were transfected into HT22 cells; afterwards, PD98059, a specific ERK inhibitor, was added along with or without oeCDC42. CDC42 expression, cell viability, and superoxide dismutase (SOD) activity were reduced, but cell apoptosis and reactive oxygen species (ROS) were elevated after OGD/R induction in a time-dependent manner. oeCDC42 decreased cell apoptosis and ROS and increased SOD activity in OGD/R-induced HT22 cells, but it did not significantly increase cell viability. Moreover, oeCDC42 positively regulated p-ERK and p-c-Fos expression. In addition, PD98059 decreased cell viability and SOD activity but increased cell apoptosis and ROS in OGD/R-induced HT22 cells; moreover, the effects of PD98059 combined with oeCDC42 also showed similar trends compared to oeCDC42 alone regarding the above indexes. CDC42 can ameliorate OGD/R-induced neural oxidative stress and apoptosis by regulating the ERK pathway.

Cell Division Cycle 42 Improves Renal Functions, Fibrosis, Th1/Th17 Infiltration and Inflammation to Some Degree in Diabetic Nephropathy

Our two previous studies observed that cell division cycle 42 (CDC42) was lower and correlated with improved renal function and inflammation in diabetic nephropathy (DN) patients, and CDC42 inhibited renal tubular epithelial cell fibrosis and inflammation under high glucose condition. Sequentially, this current study aimed to investigate the effect of CDC42 on improving renal function, fibrosis, and inflammation in DN mice, and its interaction with T cell receptor (TCR) related pathways. Mice were treated by streptozotocin to construct early-stage DN model, then transfected with CDC42 overexpression adenovirus, followed by simultaneous treatment of LY294002 (PI3K/AKT inhibitor) and CI-1040 (ERK inhibitor), respectively. CDC42 reduced blood glucose, creatinine, and 24 h urine protein in DN mice, but only showed a tendency to decrease blood urea nitrogen without statistical significance. Hematoxylin&eosin staining revealed that CDC42 descended the glomerular volume, basement membrane thickness, and inflammatory cell infiltration in kidney. Meanwhile, CDC42 lowered fibronectin, TGF-β1, and Collagen I expressions in kidney, but not decreased α-SMA significantly. Besides, CDC42 decreased T-helper (Th) 1 and Th17 cells in kidney, and reduced serum IFN-γ, IL-1β, IL-17A, and TNF-α but not IL-6. Regarding TCR-related pathways, CDC42 activated AKT and ERK pathways but not JNK pathway. However, the treatment of LY294002 and CI-1040 had limited effect on attenuating CDC42's functions on renal function and fibrotic markers. CDC42 improves renal functions, fibrosis, Th1/Th17 infiltration and inflammation to some degree in DN mice, these functions may be independent to AKT and ERK pathways.

Inflammatory gene regulation by Cdc42 in airway epithelial cells

Cytokine release from airway epithelial cells is a key immunological process that coordinates an immune response in the lungs. We propose that the Rho GTPase, Cdc42, regulates both transcription and trafficking of cytokines, ultimately affecting the essential process of cytokine release and subsequent inflammation in the lungs. Here, we examined the pro-inflammatory transcriptional profile that occurs in bronchial epithelial cells (BEAS-2B) in response to TNF-α using RNA-Seq and differential gene expression analysis. To interrogate the role of Cdc42 in inflammatory gene expression, we used a pharmacological inhibitor of Cdc42, ML141, and determined changes in the transcriptomic profile induced by Cdc42 inhibition. Our results indicated that Cdc42 inhibition with ML141 resulted in a unique inflammatory phenotype concomitant with increased gene expression of ER stress genes, Golgi membrane and vesicle transport genes. To further interrogate the inflammatory pathways regulated by Cdc42, we made BEAS-2B knockdown strains for the signaling targets TRIB3, DUSP5, SESN2 and BMP4, which showed high differential expression in response to Cdc42 inhibition. Depletion of DUSP5 and TRIB3 reduced the pro-inflammatory response triggered by Cdc42 inhibition as shown by a reduction in cytokine transcript levels. Depletion of SESN2 and BMP4 did not affect cytokine transcript level, however, Golgi fragmentation was reduced. These results provide further evidence that in airway epithelial cells, Cdc42 is part of a signaling network that controls inflammatory gene expression and secretion by regulating Golgi integrity. Summary sentence:We define the Cdc42-regulated gene networks for inflammatory signaling in airway epithelial cells which includes regulation of ER stress response and vesicle trafficking pathways.

Increase in venous thromboembolism in SARS-CoV-2 infected lung tissue: proteome analysis of lung parenchyma, isolated endothelium, and thrombi

AIMS

COVID-19 pneumonia is characterized by an increased rate of deep venous thrombosis and pulmonary embolism. To better understand the pathophysiology behind thrombosis in COVID-19, we performed proteomics analysis on SARS-CoV-2 infected lung tissue.

METHODS

Liquid chromatography mass spectrometry was performed on SARS-CoV-2 infected postmortem lung tissue samples. Five protein profiling analyses were performed: whole slide lung parenchyma analysis, followed by analysis of isolated thrombi and endothelium, both stratified by disease (COVID-19 versus influenza) and thrombus morphology (embolism versus in situ). Influenza autopsy cases with pulmonary thrombi were used as controls.

RESULTS

Compared to influenza controls, both analyses of COVID-19 whole-tissue and isolated endothelium showed upregulation of proteins and pathways related to liver metabolism including urea cycle activation, with arginase being among the top upregulated proteins in COVID-19 lung tissue. Analysis of isolated COVID-19 thrombi showed significant downregulation of pathways related to platelet activation compared to influenza thrombi. Analysis of isolated thrombi based on histomorphology shows that in situ thrombi have significant upregulation of coronavirus pathogenesis proteins.

CONCLUSIONS

The decrease in platelet activation pathways in severe COVID-19 thrombi suggests a relative increase in venous thromboembolism, as thrombi from venous origin tend to contain fewer platelets than arterial thrombi. Based on histomorphology, in situ thrombi show upregulation of various proteins related to SARS-CoV-2 pathogenesis compared to thromboemboli, which may indicate increased in situ pulmonary thrombosis in COVID-19. Therefore, this study supports the increase of venous thromboembolism without undercutting the involvement of in situ thrombosis in severe COVID-19.