Interplay between hepatitis C virus and ARF4

Endothelial NMMHC IIA dissociation from PAR1 activates the CREB3/ARF4 signaling in thrombin-mediated intracerebral hemorrhage

INTRODUCTION

There is an urgent need for cerebroprotective interventions to improve the suboptimal outcomes with intracerebral hemorrhage (ICH). Despite the important role of nonmuscle myosin heavy chain IIA (NMMHC IIA) in the blood-brain barrier (BBB), its function in ICH remains unclear.

OBJECTIVES

The objective of this study is to explore how NMMHC IIA functions in ICH and to evaluate the effectiveness of targeting NMMHC IIA as a treatment for ICH.

METHODS

We firstly examined the protein expression of NMMHC IIA in clinical patients and animal models with ICH. The function of NNMMHC IIA was then corroborated by using overexpress or knockdown NMMHC IIA specifically in ECs mice and pBMECs. In addition, we explored protein interacts with NMMHC IIA and signaling pathways after ICH by LC-MS/MS and transcriptomics analysis with an emphasis on the function of PAR1 and the CREB3/ARF4 signaling pathway, and validated them in three kind of animal models. To support the clinical translation of our results, we targeted NMMHC IIA to bicalutamide selected from a library of marketed drugs and examined to validate its ameliorative effect on ICH.

RESULTS

We observed an upregulation of endothelial NMMHC IIA in the brain following the onset of ICH in both patients and mice, while inhibited NMMHC ⅡA improved ICH induced by thrombin, warfarin or tissue plasminogen activator (tPA) after ischemic stroke. Mechanistically, the head domain of NMMHC IIA interacted with protease-activated receptor 1 (PAR1) at the 380-430 aa region and subsequently dissociated and activated the CREB3/ARF4 signaling pathway. We found that bicalutamide and blebbistatin could bind to NMMHC IIA and effectively protect mice from thrombin-mediated ICH.

CONCLUSION

The findings indicated that NMMHC IIA dissociated from PAR1 and activated CREB3/ARF4 pathway, which aggravated BBB damage induced by thrombin. This suggested that NMMHC IIA was a novel potential therapeutic target for BBB-related diseases.

COVID-19 Salivary Protein Profile: Unravelling Molecular Aspects of SARS-CoV-2 Infection

COVID-19 is the most impacting global pandemic of all time, with over 600 million infected and 6.5 million deaths worldwide, in addition to an unprecedented economic impact. Despite the many advances in scientific knowledge about the disease, much remains to be clarified about the molecular alterations induced by SARS-CoV-2 infection. In this work, we present a hybrid proteomics and in silico interactomics strategy to establish a COVID-19 salivary protein profile. Data are available via ProteomeXchange with identifier PXD036571. The differential proteome was narrowed down by the Partial Least-Squares Discriminant Analysis and enrichment analysis was performed with FunRich. In parallel, OralInt was used to determine interspecies Protein-Protein Interactions between humans and SARS-CoV-2. Five dysregulated biological processes were identified in the COVID-19 proteome profile: Apoptosis, Energy Pathways, Immune Response, Protein Metabolism and Transport. We identified 10 proteins (KLK 11, IMPA2, ANXA7, PLP2, IGLV2-11, IGHV3-43D, IGKV2-24, TMEM165, VSIG10 and PHB2) that had never been associated with SARS-CoV-2 infection, representing new evidence of the impact of COVID-19. Interactomics analysis showed viral influence on the host immune response, mainly through interaction with the degranulation of neutrophils. The virus alters the host’s energy metabolism and interferes with apoptosis mechanisms.

Toxoplasma gondii SAG1 targeting host cell S100A6 for parasite invasion and host immunity

Toxoplasma gondii surface antigen 1 (TgSAG1) is a surface protein of tachyzoites, which plays a crucial role in toxoplasma gondii infection and host cell immune regulation. However, how TgSAG1 regulates these processes remains elucidated. We utilized the biotin ligase -TurboID fusion with TgSAG1 to identify the host proteins interacting with TgSAG1, and identified that S100A6 was co-localized with TgSAG1 when T. gondii attached to the host cell. S100A6, either knocking down or blocking its functional epitopes resulted in inhibited parasites invasion. Meanwhile, S100A6 overexpression in host cells promoted T. gondii infection. We further verified that TgSAG1 could inhibit the interaction of host cell vimentin with S100A6 for cytoskeleton organization during T. gondii invasion. As an immunogen, TgSAG1 could promote the secretion of tumor necrosis factor alpha (TNF-α) through S100A6-Vimentin/PKCθ-NF-κB signaling pathway. In summary, our findings revealed a mechanism for how TgSAG1 functioned in parasitic invasion and host immune regulation.

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TgSAG1 interacts with host protein S100A6 then regulates T. gondii infection

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TgSAG1 could regulate binding vimentin with S100A6 during T. gondii infection

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TgSAG1 regulate TNFα secretion through S100A6-vimentin/PKCθ-NF-κB signaling pathway

Key components of COPI and COPII machineries are required for chikungunya virus replication

The infection of CHIKV is associated with cellular membranes; however whether early secretory pathways are involved in CHIKV replication remains unclear. In the present study, we have provided initial evidences that CHIKV requires both COPI and COPII for its replication. Small interfering RNAs against COPI components, including coatomer, ARFs or GBF1, suppress CHIKV replication. Moreover, CHIKV infection is abolished by the presence of ARF1 inhibitor brefeldin A or GBF1 inhibitor golgicide A. In addition, perturbation of COPII by silencing key components of COPII pathways leads to a reduction in CHIKV replication. Collectively, these observations demonstrate the importance of functional secretory pathways in the infectivity of CHIKV.