An essential role for the antiviral endoribonuclease, RNase-L, in antibacterial immunity

Type I IFNs were discovered as the primary antiviral cytokines and are now known to serve critical functions in host defense against bacterial pathogens. Accordingly, established mediators of IFN antiviral activity may mediate previously unrecognized antibacterial functions. RNase-L is the terminal component of an RNA decay pathway that is an important mediator of IFN-induced antiviral activity. Here, we identify a role for RNase-L in the host antibacterial response. RNase-L^−/− mice exhibited a dramatic increase in mortality after challenge with Bacillus anthracis and Escherichia coli; this increased susceptibility was due to a compromised immune response resulting in increased bacterial load. Investigation of the mechanisms of RNase-L antibacterial activity indicated that RNase-L is required for the optimal induction of proinflammatory cytokines that play essential roles in host defense from bacterial pathogens. RNase-L also regulated the expression of the endolysosomal protease, cathepsin-E, and endosome-associated activities, that function to eliminate internalized bacteria and may contribute to RNase-L antimicrobial action. Our results reveal a unique role for RNase-L in the antibacterial response that is mediated through multiple mechanisms. As a regulator of fundamental components of the innate immune response, RNase-L represents a viable therapeutic target to augment host defense against diverse microbial pathogens.     

Patterns and plasticity in RNA-protein interactions enable recruitment of multiple proteins through a single site

mRNA control hinges on the specificity and affinity of proteins for their RNA binding sites. Regulatory proteins must bind their own sites and reject even closely related noncognate sites. In the PUF [Pumilio and fem-3 binding factor (FBF)] family of RNA binding proteins, individual proteins discriminate differences in the length and sequence of binding sites, allowing each PUF to bind a distinct battery of mRNAs. Here, we show that despite these differences, the pattern of RNA interactions is conserved among PUF proteins: the two ends of the PUF protein make critical contacts with the two ends of the RNA sites. Despite this conserved "two-handed" pattern of recognition, the RNA sequence is flexible. Among the binding sites of yeast Puf4p, RNA sequence dictates the pattern in which RNA bases are flipped away from the binding surface of the protein. Small differences in RNA sequence allow new modes of control, recruiting Puf5p in addition to Puf4p to a single site. This embedded information adds a new layer of biological meaning to the connections between RNA targets and PUF proteins.     

Molecular basis of bacterial protein Hen1 activating the ligase activity of bacterial protein Pnkp for RNA repair

Ribotoxins cleave essential RNAs for cell killing in vivo, and the bacterial polynucleotide kinase-phosphatase (Pnkp)/hua enhancer 1 (Hen1) complex has been shown to repair ribotoxin-cleaved RNAs in vitro. Bacterial Pnkp/Hen1 is distinguished from other RNA repair systems by performing 3'-terminal 2'-O-methylation during RNA repair, which prevents the repaired RNA from repeated cleavage at the same site. To ensure the opportunity of 2'-O-methylation by bacterial Hen1 during RNA repair and, therefore, maintain the quality of the repaired RNA, Pnkp/Hen1 has evolved to require the participation of Hen1 in RNA ligation, because Pnkp alone is unable to carry out the reaction despite possessing all signature motifs of an RNA ligase. However, the precise role of Hen1 in RNA ligation is unknown. Here, we present the crystal structure of an active RNA ligase consisting of the C-terminal half of Pnkp (Pnkp-C) and the N-terminal half of Hen1 (Hen1-N) from Clostridium thermocellum. The structure reveals that the N-terminal domain of Clostridium thermocellum (Cth) Hen1, shaped like a left hand, grabs the flexible insertion module of CthPnkp and locks its conformation via further interaction with the C-terminal addition module of CthPnkp. Formation of the CthPnkp-C/Hen1-N heterodimer creates a ligation pocket with a width for two strands of RNA, depth for two nucleotides, and the adenosine monophosphate (AMP)-binding pocket at the bottom. The structure, combined with functional analyses, provides insight into the mechanism of how Hen1 activates the RNA ligase activity of Pnkp for RNA repair.     

Eukaryotic initiation factor 2alpha phosphorylation is required for B-cell maturation and function in mice

Background

The control of translation initiation is a crucial component in the regulation of gene expression. The eukaryotic initiation factor 2α (eIF2α) mediates binding of the initiator transfer-messenger-RNA to the AUG initiation codon, and thus controls a rate-limiting step in translation initiation. Phosphorylation of eIF2α at serine 51 is linked to cellular stress response and attenuates translation initiation. The biochemistry of translation inhibition mediated by eIF2α phosphorylation is well characterized, yet the physiological importance in hematopoiesis remains only partially known.

Design and Methods

Using hematopoietic stem cells carrying a non-phosphorylatable mutant form of eIF2α (eIF2αAA), we examined the efficiency of reconstitution in wild-type and B-cell-deficient microMT C57BL/6 recipients in two independent models.

Results

We provide evidence that phosphorylation-deficient eIF2α mutant hematopoietic stem cells may repopulate lethally irradiated mice but have a defect in the development and maintenance of newly formed B cells in the bone marrow and of naïve follicular B cells in the periphery. The mature B-cell compartment is markedly reduced in bone marrow, spleen and peripheral blood, and B-cell receptor-mediated proliferation in vitro and serum immunoglobulin secretion in vivo are impaired.

Conclusions

The data suggest that regulation of translation through eIF2α phosphorylation is dispensable in hematopoietic reconstitution but essential during late B-cell development.     

Proline to Threonine Mutation at Position 162 of NS5B of Classical Swine Fever Virus Vaccine C Strain Promoted Genome Replication and Infectious Virus Production by Facilitating Initiation of RNA Synthesis

The 3′untranslated region (3′UTR) and NS5B of classical swine fever virus (CSFV) play vital roles in viral genome replication. In this study, two chimeric viruses, vC/SM3′UTR and vC/b3′UTR, with 3′UTR substitution of CSFV Shimen strain or bovine viral diarrhea virus (BVDV) NADL strain, were constructed based on the infectious cDNA clone of CSFV vaccine C strain, respectively. After virus rescue, each recombinant chimeric virus was subjected to continuous passages in PK-15 cells. The representative passaged viruses were characterized and sequenced. Serial passages resulted in generation of mutations and the passaged viruses exhibited significantly increased genomic replication efficiency and infectious virus production compared to parent viruses. A proline to threonine mutation at position 162 of NS5B was identified in both passaged vC/SM3′UTR and vC/b3′UTR. We generated P162T mutants of two chimeras using the reverse genetics system, separately. The single P162T mutation in NS5B of vC/SM3′UTR or vC/b3′UTR played a key role in increased viral genome replication and infectious virus production. The P162T mutation increased vC/SM3′UTR_P162T replication in rabbits. From RNA-dependent RNA polymerase (RdRp) assays in vitro, the NS5B containing P162T mutation (NS5B_P162T) exhibited enhanced RdRp activity for different RNA templates. We further identified that the enhanced RdRp activity originated from increased initiation efficiency of RNA synthesis. These findings revealed a novel function for the NS5B residue 162 in modulating pestivirus replication.     

Quaking I controls a unique cytoplasmic pathway that regulates alternative splicing of myelin-associated glycoprotein

Precise control of alternative splicing governs oligodendrocyte (OL) differentiation and myelination in the central nervous system (CNS). A well-known example is the developmentally regulated expression of splice variants encoding myelin-associated glycoprotein (MAG), which generates two protein isoforms that associate with distinct cellular components crucial for axon-glial recognition during myelinogenesis and axon-myelin stability. In the quakingviable (qk(v)) hypomyelination mutant mouse, diminished expression of isoforms of the selective RNA-binding protein quaking I (QKI) leads to severe dysregulation of MAG splicing. The nuclear isoform QKI-5 was previously shown to bind an intronic element of MAG and modulate alternative exon inclusion from a MAG minigene reporter. Thus, QKI-5 deficiency was thought to underlie the defects of MAG splicing in the qk(v) mutant. Surprisingly, we found that transgenic expression of the cytoplasmic isoform QKI-6 in the qk(v) OLs completely rescues the dysregulation of MAG splicing without increasing expression or nuclear abundance of QKI-5. In addition, cytoplasmic QKI-6 selectively associates with the mRNA that encodes heterogeneous nuclear ribonucleoprotein A1 (hnRNPA1), a well-characterized splicing factor. Furthermore, QKI deficiency in the qk(v) mutant results in abnormally enhanced hnRNPA1 translation and overproduction of the hnRNPA1 protein but not hnRNPA1 mRNA, which can be successfully rescued by the QKI-6 transgene. Finally, we show that hnRNPA1 binds MAG pre-mRNA and modulates alternative inclusion of MAG exons. Together, these results reveal a unique cytoplasmic pathway in which QKI-6 controls translation of the splicing factor hnRNPA1 to govern alternative splicing in CNS myelination.     

Inhibition of SARS-CoV-2 Replication by a Small Interfering RNA Targeting the Leader Sequence

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has infected almost 200 million people worldwide and led to approximately 4 million deaths as of August 2021. Despite successful vaccine development, treatment options are limited. A promising strategy to specifically target viral infections is to suppress viral replication through RNA interference (RNAi). Hence, we designed eight small interfering RNAs (siRNAs) targeting the highly conserved 5′-untranslated region (5′-UTR) of SARS-CoV-2. The most promising candidate identified in initial reporter assays, termed siCoV6, targets the leader sequence of the virus, which is present in the genomic as well as in all subgenomic RNAs. In assays with infectious SARS-CoV-2, it reduced replication by two orders of magnitude and prevented the development of a cytopathic effect. Moreover, it retained its activity against the SARS-CoV-2 alpha variant and has perfect homology against all sequences of the delta variant that were analyzed by bioinformatic means. Interestingly, the siRNA was even highly active in virus replication assays with the SARS-CoV-1 family member. This work thus identified a very potent siRNA with a broad activity against various SARS-CoV viruses that represents a promising candidate for the development of new treatment options.     

Translation of hepatitis C virus RNA

The 341-nucleotide 5' non-translated region is the most conserved part of the hepatitis C virus (HCV) genome. It contains a highly structured internal ribosomal entry site (IRES) that mediates cap-independent initiation of translation of the viral polyprotein by a mechanism that is unprecedented in eukaryotes. The first step in translation initiation is assembly of eukaryotic initiation factor (eIF) 3, eIF2, GTP, initiator tRNA and a 40S ribosomal subunit into a 43S preinitiation complex. The HCV IRES recruits this complex and directs its precise attachment at the initiation codon to form a 48S complex in a process that does not involve eIFs 4A, 4B or 4F. The IRES contains sites that bind independently with the eIF3 and 40S subunit components of 43S complexes, and structural determinants that ensure the correct spatial orientation of these binding sites so that the 48S complex assembles precisely at the initiation codon.     

INAUGURAL ARTICLE by a Recently Elected Academy Member:Kinetic pathway of 40S ribosomal subunit recruitment to hepatitis C virus internal ribosome entry site

Translation initiation can occur by multiple pathways. To delineate these pathways by single-molecule methods, fluorescently labeled ribosomal subunits are required. Here, we labeled human 40S ribosomal subunits with a fluorescent SNAP-tag at ribosomal protein eS25 (RPS25). The resulting ribosomal subunits could be specifically labeled in living cells and in vitro. Using single-molecule Förster resonance energy transfer (FRET) between RPS25 and domain II of the hepatitis C virus (HCV) internal ribosome entry site (IRES), we measured the rates of 40S subunit arrival to the HCV IRES. Our data support a single-step model of HCV IRES recruitment to 40S subunits, irreversible on the initiation time scale. We furthermore demonstrated that after binding, the 40S:HCV IRES complex is conformationally dynamic, undergoing slow large-scale rearrangements. Addition of translation extracts suppresses these fluctuations, funneling the complex into a single conformation on the 80S assembly pathway. These findings show that 40S:HCV IRES complex formation is accompanied by dynamic conformational rearrangements that may be modulated by initiation factors.Protein synthesis is a central process in health and disease (1, 2). The basic steps in translation have been mapped by genetic, biochemical, structural, and mechanistic studies. However, how translation is regulated and subverted, for example, during viral infection, remains poorly understood, especially in eukaryotes. All viruses compete for the cellular translation machinery to synthesize viral proteins required for virus proliferation. To that end, many viruses contain a structured internal ribosome entry site (IRES) in the 5′ untranslated region of their genome, which allows them to bypass the requirement for certain translation initiation factors. How IRESs achieve this goal remains unclear.Recently, it has been shown that structurally and evolutionarily very diverse IRESs, such as hepatitis C virus (HCV) IRES, cricket paralysis virus (CrPV) IRES (3), and others (4), require ribosomal protein eS25 (RPS25) for efficient translation initiation, indicating that RPS25/IRES interactions could be a universal feature of IRES-mediated translation. RPS25 is located on the back of the head of the 40S ribosomal subunit, distal to the mRNA entry channel but proximal to different IRES RNAs as shown by cryo-EM structures of 80S:CrPV IRES and 80S:HCV IRES complexes. RPS25 is not essential for cap-dependent translation, suggesting that IRES/RPS25 interactions are required to bypass the requirement for the full set of initiation factors (3).Translation initiation is a multistep process, with kinetics and dynamic interrogation refractory to conventional biochemical and biophysical methods. Single-molecule approaches provide insight into compositional and conformational dynamics of these asynchronous processes by following individual molecular events in real time. In bacteria, single-molecule methods allow direct observation of the multiple initiation pathways and conformational rearrangements that guide translation initiation (5, 6). The lack of fluorescently labeled components of translation initiation has prevented application of the single-molecule methods to study the mechanism of translation initiation in humans.Here, we demonstrate an approach to create fluorescently labeled 40S ribosomal subunits from human cells. Using these subunits, we measure the kinetics and conformational pathway of 40S subunit recruitment to the HCV IRES. First, we created RPS25 KO cell lines using the clustered regularly interspaced short palindromic repeat (CRISPR)-Cas system. Next, we expressed RPS25 as a C-terminal fusion with mutant O⁶-alkylguanine DNA alkyltransferase (SNAP) as the sole source of the protein. We established biochemically that RPS25-SNAP is efficiently incorporated into functional 40S subunits, and rescues the defect in HCV IRES-mediated translation caused by RPS25 deletion. Using single-molecule fluorescence, we showed that Förster resonance energy transfer (FRET) between RPS25 and the base of domain II of the HCV IRES is dynamic. Conformational dynamics were altered by the presence of translational extract, thus indicating that conformational flexibility of RPS25 and domain II positions could be responsible for guiding downstream steps of translation initiation on HCV IRES. Finally, by measuring the kinetics of the 40S:HCV IRES interactions, we demonstrate that the rate of 40S subunit recruitment to the HCV IRES is not limited by the conformational flexibility of the free HCV IRES, and that upon 40S binding, the 40S:HCV IRES complexes are stable on the time scale of initiation. This study demonstrates the power of real-time observations of conformational and compositional dynamics during human translation initiation.     

Roles of individual domains in the function of DHX29, an essential factor required for translation of structured mammalian mRNAs

On most eukaryotic mRNAs, initiation codon selection involves base-by-base inspection of 5′ UTRs by scanning ribosomal complexes. Although the eukaryotic initiation factors 4A/4B/4G can mediate scanning through medium-stability hairpins, scanning through more stable structures additionally requires DHX29, a member of the superfamily 2 DEAH/RNA helicase A (RHA) helicase family that binds to 40S subunits and possesses 40S-stimulated nucleoside triphosphatase (NTPase) activity. Here, sequence alignment and structural modeling indicated that DHX29 comprises a unique 534-aa–long N-terminal region (NTR), central catalytic RecA1/RecA2 domains containing a large insert in the RecA2 domain, and the C-terminal part, which includes winged-helix, ratchet, and oligonucleotide/oligosaccharide-binding (OB) domains that are characteristic of DEAH/RHA helicases. Functional characterization revealed that specific ribosomal targeting is required for DHX29’s activity in initiation and is determined by elements that map to the NTR and to the N-terminal half of the winged-helix domain. The ribosome-binding determinant located in the NTR was identified as a putative double-stranded RNA-binding domain. Mutational analyses of RecA1/RecA2 domains confirmed the essential role of NTP hydrolysis for DHX29’s function in initiation and validated the significance of a β-hairpin protruding from RecA2. The large RecA2 insert played an autoinhibitory role in suppressing DHX29’s intrinsic NTPase activity but was not essential for its 40S-stimulated NTPase activity and function in initiation. Deletion of the OB domain also increased DHX29''s basal NTPase activity, but more importantly, abrogated the responsiveness of the NTPase activity to stimulation, which abolished DHX29''s function in initiation. This finding suggests that the OB domain, which is specific for DEAH/RHA helicases, plays an important role in their NTPase cycle.     

Replication Activities of Major 5′ Terminally Deleted Group-B Coxsackievirus RNA Forms Decrease PCSK2 mRNA Expression Impairing Insulin Maturation in Pancreatic Beta Cells

Emergence of 5′ terminally deleted coxsackievirus-B RNA forms (CVB-TD) have been associated with the development of human diseases. These CVB-TD RNA forms have been detected in mouse pancreas during acute or persistent experimental infections. To date, the impact of the replication activities of CVB-TD RNA forms on insulin metabolism remains unexplored. Using an immunocompetent mouse model of CVB3/28 infection, acute and persistent infections of major CVB-TD populations were evidenced in the pancreas. The inoculation of mice with homogenized pancreases containing major CVB-TD populations induced acute and chronic pancreatic infections with pancreatitis. In the mouse pancreas, viral capsid protein 1 (VP1) expression colocalized with a decrease in beta cells insulin content. Moreover, in infected mouse pancreases, we showed a decrease in pro-hormone convertase 2 (PCSK2) mRNA, associated with a decrease in insulin plasmatic concentration. Finally, transfection of synthetic CVB-TD50 RNA forms into cultured rodent pancreatic beta cells demonstrated that viral replication with protein synthesis activities decreased the PCSK2 mRNA expression levels, impairing insulin secretion. In conclusion, our results show that the emergence and maintenance of major CVB-TD RNA replicative forms in pancreatic beta cells can play a direct, key role in the pathophysiological mechanisms leading to the development of type 1 diabetes.