Importantly,

we found that proinflammatory cytokines may

Importantly,

we found that proinflammatory cytokines may be dysregulated by a decreased STAT5. STAT5 normally stimulates an inflammatory response during bacterial infection [[36]]. Park et al. [[37]] have shown that Cav1 is a negative regulator of JAK2/STAT5a signaling in the mammary gland. This negative regulation may occur through direct molecular interaction owing to structural homology between Cav1 and SOCS-1 or SOCS3 [[38]]. Our data suggest that the GSK3β−β-catenin−Akt axis may be related PCI-32765 ic50 to a decreased STAT5 profile, making a connection from Cav1 deficiency to the exacerbated inflammatory response. Although the above research begins to hint at some important answers, it is not known why decreased STAT5 functionality leads to an increased proinflammatory cytokine profile. Previous reports have shown that Akt can connect

to STAT5 and regulate neuroprotective activity or cancer development [[39]]. However, little is known as to the specific functions of the GSK3β−β-catenin−Akt axis in bacterial infection. We hypothesized that decreased STAT5 may be regulated by changes in GSK3β or from the loss of Akt/β-catenin activity (at middle or late phases of infection), since our in vitro assays indicated an increase in pSTAT5 at early phases of infection. Following PIP3 and PI3K activation, Akt activation is required to regulate apoptosis against LPS or other oxidants [[40]], which could also be associated with a heightened inflammatory response. Akt is negatively regulated under Cav1 deficiency, while GSK3β is upregulated. Fostamatinib As feedback, Akt can inhibit GSK3β, thereby reducing the negative regulation of GSK3β in cellular processes. We assumed that an excessive inflammatory response and inefficient apoptotic clearance of dead cells lead to severe lung injury. Thus, an interaction between Akt and Cav1 may broadly impact the cytokine production and disease process.

Downregulation of Akt and STAT5 was initiated to counteract the loss of Cav1, but failed to eradicate the invading bugs. As a result, IL-6 and related cytokines could not be properly controlled by feedback signaling, Sinomenine contributing to the severe infection seen in cav1 KO mice. In summary, our studies illustrate a typical phenotype in cav1 KO mice following K. pneumoniae infection, characterized by increased bacterial burdens in the lung, decreased survival, severe lung injury, and increased inflammatory response. Furthermore, the increased impairment of the immune system in these KO mice is at least in part attributed to a regulatory function of the STAT5 pathway, which is, in turn, influenced by a GSK3β−β-catenin−Akt axis. Our studies have also characterized a novel role of Cav1 in infection resistance and explored its involvement with the Akt-STAT5 cross-talk, whose underlying mechanisms warrant further study. More specifically, our data may shed light on the pathogenesis of K. pneumoniae infection and suggest a novel therapeutic target.

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