Regulated by pH, membrane-anchored proteins E and M play a series of roles during dengue virus maturation and membrane fusion. Our atomic model of the whole virion from cryo electron microscopy at 3.5Å resolution reveals that in the mature virus at neutral extracellular pH, the N-terminal 20-amino acid segment of M (involving three pH-sensing histidines) latches and thereby prevents spring-loaded E fusion protein from prematurely exposing its fusion peptide. This M latch was fastened at an earlier stage, during maturation at acid pH in the trans-Golgi network. At a later stage, to initiate infection in response to acid pH in the late endosome, M releases the latch and exposes the fusion peptide. Thus, M serves as a multistep chaperone of E to control the conformational changes accompanying maturation and infection. These pH-sensitive interactions could serve as targets for drug discovery.
R-type pyocins are representatives of contractile ejection systems, a class of biological nanomachines that includes, among others, the bacterial type VI secretion system (T6SS) and contractile bacteriophage tails. We report atomic models of the Pseudomonas aeruginosa precontraction pyocin sheath and tube, and the postcontraction sheath, obtained by cryo-EM at 3.5-Å and 3.9-Å resolutions, respectively. The central channel of the tube is negatively charged, in contrast to the neutral and positive counterparts in T6SSs and phage tails. The sheath is interwoven by long N- and C-terminal extension arms emanating from each subunit, which create an extensive two-dimensional mesh that has the same connectivity in the extended and contracted state of the sheath. We propose that the contraction process draws energy from electrostatic and shape complementarities to insert the inner tube through bacterial cell membranes to eventually kill the bacteria.
Cytoplasmic polyhedrosis virus (CPV) is unique within the Reoviridae family in having a turreted single-layer capsid contained within polyhedrin inclusion bodies, yet being fully capable of cell entry and endogenous RNA transcription. Biochemical data have shown that the amino-terminal 79 residues of the CPV turret protein (TP) is sufficient to bring CPV or engineered proteins into the polyhedrin matrix for micro-encapsulation. Here we report the three-dimensional structure of CPV at 3.88 A resolution using single-particle cryo-electron microscopy. Our map clearly shows the turns and deep grooves of alpha-helices, the strand separation in beta-sheets, and densities for loops and many bulky side chains; thus permitting atomic model-building effort from cryo-electron microscopy maps. We observed a helix-to-beta-hairpin conformational change between the two conformational states of the capsid shell protein in the region directly interacting with genomic RNA. We have also discovered a messenger RNA release hole coupled with the mRNA capping machinery unique to CPV. Furthermore, we have identified the polyhedrin-binding domain, a structure that has potential in nanobiotechnology applications.
Herpesviruses possess a genome-pressurized capsid. The 235-kilobase genome of human cytomegalovirus (HCMV) is by far the largest of any herpesvirus, yet it has been unclear how its capsid, which is similar in size to those of other herpesviruses, is stabilized. Here we report a HCMV atomic structure consisting of the herpesvirus-conserved capsid proteins MCP, Tri1, Tri2, and SCP and the HCMV-specific tegument protein pp150—totaling ~4000 molecules and 62 different conformers. MCPs manifest as a complex of insertions around a bacteriophage HK97 gp5–like domain, which gives rise to three classes of capsid floor–defining interactions; triplexes, composed of two “embracing” Tri2 conformers and a “third-wheeling” Tri1, fasten the capsid floor. HCMV-specific strategies include using hexon channels to accommodate the genome and pp150 helix bundles to secure the capsid via cysteine tetrad–to-SCP interactions. Our structure should inform rational design of countermeasures against HCMV, other herpesviruses, and even HIV/AIDS.
Arrestins comprise a family of signal regulators of G-protein-coupled receptors (GPCRs), which include arrestins 1 to 4. While arrestins 1 and 4 are visual arrestins dedicated to rhodopsin, arrestins 2 and 3 (Arr2 and Arr3) are β-arrestins known to regulate many nonvisual GPCRs. The dynamic and promiscuous coupling of Arr2 to nonvisual GPCRs has posed technical challenges to tackle the basis of arrestin binding to GPCRs. Here we report the structure of Arr2 in complex with neurotensin receptor 1 (NTSR1), which reveals an overall assembly that is strikingly different from the visual arrestin-rhodopsin complex by a 90°rotation of Arr2 relative to the receptor. In this new configuration, intracellular loop 3 (ICL3) and transmembrane helix 6 (TM6) of the receptor are oriented toward the N-terminal domain of the arrestin, making it possible for GPCRs that lack the C-terminal tail to couple Arr2 through their ICL3. Molecular dynamics simulation and crosslinking data further support the assembly of the Arr2-NTSR1 complex. Sequence analysis and homology modeling suggest that the Arr2-NTSR1 complex structure may provide an alternative template for modeling arrestin-GPCR interactions.
evere acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has caused a global pandemic of coronavirus disease 2019 (COVID-19), with over 84.66 million infections and 1.83 million deaths as reported on 3 January 2021 (refs. 1,2). SARS-CoV-2 is a positive-sense, single-stranded RNA virus. SARS-CoV-2 and several related beta-coronaviruses, including SARS-CoV and Middle East respiratory syndrome coronavirus (MERS-CoV), are highly pathogenic. Infections can lead to severe acute respiratory syndrome, loss of lung function and, in severe cases, death. Compared to SARS-CoV and MERS-CoV, SARS-CoV-2 has a higher capacity of human-to-human infections, which resulted in the rapidly growing pandemic 3. Finding an effective treatment for COVID-19, potentially also through drug repurposing, is an urgent but unmet medical need. Suramin (Fig. 1a) is a century-old drug that has been used to treat African sleeping sickness and river blindness 4,5. It has also been shown to be effective in inhibiting the replication of a wide range of viruses, including enteroviruses 6 , Zika virus 7 , Chikungunya 8 and Ebola viruses 9. The viral inhibition mechanisms of suramin are diverse, including inhibition of viral attachment, viral entry and release from host cells in part through interactions with viral capsid proteins 7,8,10,11. Recently, suramin has been shown to inhibit SARS-CoV-2 infection in cell culture by preventing cellular entry of the virus 12. Here we report that suramin is also a potent inhibitor of the SARS-CoV-2 RNA-dependent RNA polymerase (RdRp), an essential enzyme for the viral life cycle. The potency of suramin in biochemical RdRp inhibition assays is at least 20-fold more potent than remdesivir, the current Food and Drug Administration-approved nucleotide drug for the treatment of COVID-19. The activity of suramin in cell-based viral inhibition is similar to remdesivir because the highly negative charge of suramin prevents efficient cellular uptake. A cryogenic electron microscopy (cryo-EM) structure reveals that suramin binds to the RdRp active site, blocking the binding of both RNA template and primer strands. These results provide a structural template for the design of next generation suramin derivatives as SARS-CoV-2 RdRp inhibitors. Structural basis for inhibition of the SARS-CoV-2 RNA polymerase by suramin Wanchao Yin 1,
Summary Viruses in the Reoviridae, like the triple-shelled human rotavirus and the single-shelled insect cytoplasmic polyhedrosis virus (CPV), all package a genome of segmented dsRNAs inside the viral capsid and carry out endogenous mRNA synthesis through a transcriptional enzyme complex (TEC). By direct electron-counting cryoEM and asymmetric reconstruction, we have determined the organization of the dsRNA genome inside quiescent CPV (q-CPV) and the in situ atomic structures of TEC within CPV in both quiescent and transcribing (t-CPV) states. We show that the total 10 segmented dsRNAs in CPV are organized with 10 TECs in a specific, non-symmetric manner, with each dsRNA segment attached directly to a TEC. TEC consists of two extensively-interacting subunits: an RNA-dependent RNA polymerase (RdRP) and an NTPase VP4. We find that the bracelet domain of RdRP undergoes significant conformational change when converted from q-CPV to t-CPV, leading to formation of the RNA template entry channel and access to the polymerase active site. An N-terminal helix from each of two subunits of the capsid shell protein (CSP) interacts with VP4 and RdRP. These findings establish the link between sensing of environmental cues by the external proteins and activation of endogenous RNA transcription by the TEC inside the virus.
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