Project description:Hyperactivation of the complement system, a major component of innate immunity, has been recognized as one of the core clinical features in severe covid-19 patients. However, how the virus escapes the targeted elimination by the network of activated complement pathways still remains an enigma. Here, we identified SARS-CoV-2-encoded ORF8 protein as one of the major binding partners of human complement C3/C3b components and their metabolites. Our results demonstrated that preincubation of ORF8 with C3/C3b in the fluid phase has two immediate functional consequences in the alternative pathway; this preincubation inhibits factor I-mediated proteolysis and blocks factor B zymogen activation into active Bb. ORF8 binding results in the occlusion of both factor H and factor B from C3b, rendering the complexes resistant to factor I-mediated proteolysis and inhibition of pro-C3-convertase (C3bB) formation, respectively. We also confirmed the complement inhibitory activity of ORF8 in our hemolysis-based assay, where ORF8 prevented human serum-induced lysis of rabbit erythrocytes with an IC50 value of about 2.3 μM. This inhibitory characteristic of ORF8 was also supported by in-silico protein-protein docking analysis, as it appeared to establish primary interactions with the β-chain of C3b, orienting itself near the C3b CUB (C1r/C1s, Uegf, Bmp1) domain like a peptidomimetic compound, sterically hindering the binding of essential cofactors required for complement amplification. Thus, ORF8 has characteristics to act as an inhibitor of critical regulatory steps in the alternative pathway, converging to hasten the decay of C3-convertase and thereby, attenuating the complement amplification loop.
Project description:SARS-CoV-2 infection triggers cytokine-mediated inflammation, leading to a myriad of clinical presentations in COVID19. The SARS-CoV-2 ORF8 is a secreted and rapidly evolving glycoprotein. Patients infected with SARS-CoV-2 ORF8-deleted variants are associated with mild disease outcomes, but the molecular mechanism this behind is unknown. Here, we report that SARS-CoV-2 ORF8 is a viral cytokine that is similar but distinct from interleukin 17A (IL-17A) as it induces stronger and broader human IL-17 receptor (hIL-17R) signaling than IL-17A. ORF8 primarily targeted blood monocytes and induced the heterodimerization of hIL-17RA and hIL-17RC, triggering robust inflammatory response. Transcriptome analysis revealed that besides its activation of the hIL-17R pathway, ORF8 upregulated gene expressions for fibrosis signaling and coagulation dysregulation. A naturally occurring ORF8 L84S variant that highly associated with mild COVID-19 showed reduced hIL-17RA binding and attenuated inflammatory responses. This study discovers SARS-CoV-2 ORF8 as a viral mimicry of IL-17 cytokine to contribute COVID-19 severe inflammation.
Project description:Prenatal SARS-CoV-2 infection is associated with higher rates of pregnancy and birth complications, despite that vertical transmission rates are thought to be low. Here, multi-omics analyses of human placental tissues, cord tissues/plasma, and amniotic fluid from 23 COVID-19 mother-infant pairs revealed robust inflammatory responses in both maternal and fetal compartments. Pronounced expression of complement proteins (C1q, C3, C3b, C4, C5) and inflammatory cytokines (TNF, IL-1α, and IL-17A/E) was detected in the fetal compartment of COVID-19-affected pregnancies. While approximately 26% of fetal tissues were positive for SARS-CoV-2 RNA, more than 60% of fetal tissues contained SARS-CoV-2 ORF8 proteins, suggesting transplacental transfer of this viral accessory protein. ORF8-positive fetal compartments exhibited increased inflammation and complement activation compared to ORF8-negative COVID-19 pregnancies. In human placental trophoblasts in vitro, exogenous ORF8 exposure resulted in complement activation and inflammatory responses. Co-immunoprecipitation analysis demonstrated that ORF8 binds to C1q specifically by interacting with a 15-peptide region on ORF8 (C37-A51) and the globular domain of C1q subunit A. In conclusion, an ORF8-C1q-dependent complement activation pathway was identified in COVID-19-affected pregnancies, likely contributing to fetal inflammation independently of fetal virus exposure.
Project description:SARS-CoV-2 emerged in China at the end of 2019 and caused the global pandemic of COVID-19, a disease with high morbidity and mortality. While our understanding of this new virus is rapidly increasing, gaps remain in our understanding of how SARS-CoV-2 can effectively suppress host cell antiviral responses. Recent work on other viruses has demonstrated a novel mechanism through which viral proteins can mimic critical regions of human histone proteins. Histone proteins are responsible for governing genome accessibility and their precise regulation is critical for a cell’s ability to control transcription and respond to viral threats. Here, we show that the protein encoded by ORF8 (Orf8) in SARS-CoV-2 functions as a histone mimic of the ARKS motif in histone 3. Orf8 is associated with chromatin, binds to numerous histone-associated proteins, and is itself acetylated within the histone mimic site. Orf8 expression in cells disrupts multiple critical histone post-translational modifications (PTMs) including H3K9ac, H3K9me3, and H3K27me3 and promotes chromatin compaction while Orf8 lacking the histone mimic motif does not. Further, SARS-CoV-2 infection in human cell lines and postmortem patient lung tissue cause these same disruptions to chromatin. However, deletion of the Orf8 gene from SARS-CoV-2 largely blocks its ability to disrupt host-cell chromatin indicating that Orf8 is responsible for these effects. Finally, deletion of the ORF8 gene affects the host-cell transcriptional response to SARS-CoV-2 infection in multiple cell types and decreases the replication of SARS-CoV-2 in human induced pluripotent stem cell-derived lung alveolar type 2 (iAT2) pulmonary cells. These findings demonstrate a novel function for the poorly understood ORF8-encoded protein and a mechanism through which SARS-CoV-2 disrupts host cell epigenetic regulation. Finally, this work provides a molecular basis for the finding that SARS-CoV-2 lacking ORF8 is associated with decreased severity of COVID-19.
Project description:Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) emerged at the end of 2019 and caused the devastating global pandemic of coronavirus disease 2019 (COVID-19), in part because of its ability to effectively suppress host cell responses1-3. In rare cases, viral proteins dampen antiviral responses by mimicking critical regions of human histone proteins4-8, particularly those containing post-translational modifications required for transcriptional regulation9-11. Recent work has demonstrated that SARS-CoV-2 markedly disrupts host cell epigenetic regulation12-14. However, how SARS-CoV-2 controls the host cell epigenome and whether it uses histone mimicry to do so remain unclear. Here we show that the SARS-CoV-2 protein encoded by ORF8 (ORF8) functions as a histone mimic of the ARKS motifs in histone H3 to disrupt host cell epigenetic regulation. ORF8 is associated with chromatin, disrupts regulation of critical histone post-translational modifications and promotes chromatin compaction. Deletion of either the ORF8 gene or the histone mimic site attenuates the ability of SARS-CoV-2 to disrupt host cell chromatin, affects the transcriptional response to infection and attenuates viral genome copy number. These findings demonstrate a new function of ORF8 and a mechanism through which SARS-CoV-2 disrupts host cell epigenetic regulation. Further, this work provides a molecular basis for the finding that SARS-CoV-2 lacking ORF8 is associated with decreased severity of COVID-19.
Project description:As the world continues to fight the coronavirus pandemic caused by SARS‐CoV‐2, we are gaining valuable insights by comparing this virus to other human coronaviruses such as SARS‐CoV and MERS‐CoV that have also caused outbreaks. Coronaviruses infect many animal species, but disease severity varies between strains. Viral accessory proteins are generally implicated in increased infectivity, pathogenicity, and virulence. The accessory protein open reading frame 8 (ORF8), although not essential for viral replication, appears to play a critical role in disease severity by inhibiting multiple pathways of the immune response. Furthermore, the ORF8 gene is found within a highly variable portion of the genome, increasing the possibility of dangerous mutant forms arising. Structure‐based design of therapeutics holds great promise for effective targeting of such rapidly evolving threats. Thus, we designed physical models and computer representations of ORF8, based on the published structure 7JTL, to better evaluate the structural features responsible for viral pathogenicity. ORF8 exists as a homodimer held together by amino acid residues that interact through hydrophobic interactions, hydrogen bonding, a salt bridge, and a disulfide bond. These interactions occur in a region referred to as the covalent interface. Another interface, referred to as the noncovalent interface, exists between separate homodimers and results in oligomerization. The homodimers in the oligomer are held together by an intermolecular beta sheet that is stabilized by an extensive hydrophobic surface. These two dimerization interfaces are unique to SARS‐CoV‐2 and have been proposed to be involved in the protein's ability to evade and suppress the host immune response. The computer and physical representations allow for better visualization of the ORF8 structure to evaluate the role of the multimeric structure. ORF8 has been found to interact with various host proteins, including Interleukin‐17 Receptor A (IL17RA), a pro‐inflammatory cytokine. To further corroborate the existence of this interaction and to better understand the role oligomerization might play in pathogenicity, we assessed the possible interactions of ORF8 (7JTL) and IL17RA (5N9B) through theoretical modeling using available tools such as HDOCK. A better understanding of these inter‐subunit interactions may improve our understanding of the unique mechanism the virus uses to evade the immune system and may be instrumental in the development of effective therapeutics.