Explore the vast range of titles available.

Key message Tobacco etch virus accumulation declined in Nicotiana benthamiana eEF1Bγ gene-edited lines, suggesting that eEF1Bγ may be a host factor for this virus. Viruses use host factors to replicate and move from cell to cell. Therefore, the editing of genes encoding viral host factors that are not essential for plant survival enables the rapid development of plants with durable virus resistance. Eukaryotic initiation factors, such as eIF4E and eIF4G, function as host factors for viral infection, and loss-of-function mutations of these factors lead to virus resistance. Broadening the spectrum of host factor targets would help expand resources for engineering virus resistance. In this study, we tested whether editing the eukaryotic translation elongation factor gene eEF1Bγ would produce virus-resistant plants. Accordingly, we targeted the four eEF1Bγ genes in Nicotiana benthamiana for editing using virus-induced gene editing (VIGE) with Tobacco rattle virus (TRV). Although we attempted to obtain plants edited for all four eEF1Bγ homologs, we failed to identify such plants. Instead, we obtained plants with three of the four homologs knocked out, harboring 1-bp insertion/deletions resulting in premature stop codons. These eEF1Bγ -edited plants did not exhibit resistance to Potato virus X (PVX), Tobacco mosaic virus (TMV), or Tomato bushy stunt virus (TBSV) but showed reduced accumulation of Tobacco etch virus (TEV) compared to wild-type plants. These findings demonstrate the feasibility of conferring resistance in plants through gene editing of eEF1Bγ , underscoring the importance of exploring diverse host factor targets for comprehensive virus resistance.

The world is facing a global pandemic of COVID-19 caused by the SARS-CoV-2 coronavirus. Here we describe a collection of codon-optimized coding sequences for SARS-CoV-2 cloned into Gateway-compatible entry vectors, which enable rapid transfer into a variety of expression and tagging vectors. The collection is freely available. We hope that widespread availability of this SARS-CoV-2 resource will enable many subsequent molecular studies to better understand the viral life cycle and how to block it.

Tobacco etch virus (TEV) protease is a 27‐kDa catalytic domain of the polyprotein nuclear inclusion a (NIa) in TEV, which recognizes the specific amino acid sequence ENLYFQG/S and cleaves between Q and G/S. Despite its substrate specificity, its use is limited by its autoinactivation through self‐cleavage and poor solubility during purification. It was previously reported that T17S/N68D/I77V mutations improve the solubility and yield of TEV protease and S219 mutations provide protection against self‐cleavage. In this study, we isolated TEV proteases with S219N and S219V mutations in the background of T17S, N68D, and I77V without the inclusion body, and measured their enzyme kinetics. The kcat of two isolated S219N and S219V mutants in the background of T17S, N68D, and I77V mutations was highly increased compared to that of the control, and S219N was twofold faster than S219V without Km change. This result indicates that combination of these mutations can further enhance TEV activity. The use of tobacco etch virus (TEV) protease is limited by its poor solubility and self‐inactivation. We analyzed the effect of quadruple mutations (T17S, N68D, I77V, and S219X), which affect solubility and inhibit autoinactivation in TEV protease. In a background of T17S, N68D, and I77V mutations, soluble S219N mutant TEV protease serves as a more efficient catalyst than soluble S219V mutant.

Summary CRISPR/Cas has revolutionized genome engineering in plants. However, the use of anti‐CRISPR proteins as tools to prevent CRISPR/Cas‐mediated gene editing and gene activation in plants has not been explored yet. This study describes the characterization of two anti‐CRISPR proteins, AcrIIA4 and AcrVA1, in Nicotiana benthamiana. Our results demonstrate that AcrIIA4 prevents site‐directed mutagenesis in leaves when transiently co‐expressed with CRISPR/Cas9. In a similar way, AcrVA1 is able to prevent CRISPR/Cas12a‐mediated gene editing. Moreover, using a N. benthamiana line constitutively expressing Cas9, we show that the viral delivery of AcrIIA4 using Tobacco etch virus is able to completely abolish the high editing levels obtained when the guide RNA is delivered with a virus, in this case Potato virus X. We also show that AcrIIA4 and AcrVA1 repress CRISPR/dCas‐based transcriptional activation of reporter genes. In the case of AcrIIA4, this repression occurs in a highly efficient, dose‐dependent manner. Furthermore, the fusion of an auxin degron to AcrIIA4 results in auxin‐regulated activation of a downstream reporter gene. The strong anti‐Cas activity of AcrIIA4 and AcrVA1 reported here opens new possibilities for customized control of gene editing and gene expression in plants.

Biomolecular condensates formed via liquid–liquid phase separation of intrinsically disordered proteins (IDPs) enhance biosynthesis by concentrating clients while enabling free material exchange.A phase regulator was constructed to control the phase transition of condensates.The phase regulator includes the light-induced expression of Tobacco Etch Virus (TEV) protease and its recognition sequence within IDPs.The phase regulator realizes the programmable fluidity of condensates.The phase regulator serves as a universal tool for improving biosynthesis. Keeping condensates in liquid-like states throughout the biosynthesis process in microbial cell factories remains an ongoing challenge. Here, we present a light-controlled phase regulator, which maintains the liquid-like features of synthetic condensates on demand throughout the biosynthesis process upon light induction, as demonstrated by various live cell-imaging techniques. Specifically, the tobacco etch virus (TEV) protease controlled by light cleaves intrinsically disordered proteins (IDPs) to alter their valency and concentration for controlled phase transition and programmable fluidity of cellular condensates. As a proof of concept, we harness this capability to significantly improve the production of squalene and ursolic acid (UA) in engineered Saccharomyces cerevisiae. Our work provides a powerful approach to program the solid–liquid phase transition of biomolecular condensates for improved biosynthesis. [Display omitted] A phase regulator, comprising the light-induced expression of a protease and its recognition sequence within intrinsically disordered proteins, was constructed to control the phase transition of biomolecular condensates. This regulator can maintain the fluidity of condensates throughout the biosynthesis process and program the solid–liquid phase transition. To maintain liquid-like features of synthetic condensates on demand throughout the biosynthesis process, we developed a light-based phase regulator and realized the solid–liquid phase transition and programmable fluidity of condensates on demand during the biosynthesis process in Saccharomyces cerevisiae. This approach proved effective in improving the biosynthesis of various natural products in microbial cell factories, reaching a Technology Readiness Level (TRL) of 4. Challenges concerning the phase regulator include limited expression elements for the tobacco etch virus (TEV) protease expression system tailored for different microorganisms with distinct metabolic microenvironments. To enhance readiness, one must consider improved genetic tools to enhance the compatibility with their host microorganisms. Nevertheless, given the ongoing interest on the liquid–solid phase transition process of condensates, we anticipate that this approach will have a promising future.

Summary Viral nanoparticles (VNPs) are a new class of virus‐based formulations that can be used as building blocks to implement a variety of functions of potential interest in biotechnology and nanomedicine. Viral coat proteins (CP) that exhibit self‐assembly properties are particularly appropriate for displaying antigens and antibodies, by generating multivalent VNPs with therapeutic and diagnostic potential. Here, we developed genetically encoded multivalent VNPs derived from two filamentous plant viruses, potato virus X (PVX) and tobacco etch virus (TEV), which were efficiently and inexpensively produced in the biofactory Nicotiana benthamiana plant. PVX and TEV‐derived VNPs were decorated with two different nanobodies recognizing two different regions of the receptor‐binding domain (RBD) of the SARS‐CoV‐2 Spike protein. The addition of different picornavirus 2A ribosomal skipping peptides between the nanobody and the CP allowed for modulating the degree of VNP decoration. Nanobody‐decorated VNPs purified from N. benthamiana tissues successfully recognized the RBD antigen in enzyme‐linked immunosorbent assays and showed efficient neutralization activity against pseudoviruses carrying the Spike protein. Interestingly, multivalent PVX and TEV‐derived VNPs exhibited a neutralizing activity approximately one order of magnitude higher than the corresponding nanobody in a dimeric format. These properties, combined with the ability to produce VNP cocktails in the same N. benthamiana plant based on synergistic infection of the parent PVX and TEV, make these green nanomaterials an attractive alternative to standard antibodies for multiple applications in diagnosis and therapeutics.

The characterization of natural recessive resistance genes and Arabidopsis virus-resistant mutants have implicated translation initiation factors of the eIF4E and eIF4G families as susceptibility factors required for virus infection and resistance function. To investigate further the role of translation initiation factors in virus resistance we set up a TILLING platform in tomato, cloned genes encoding for translation initiation factors eIF4E and eIF4G and screened for induced mutations that lead to virus resistance. A splicing mutant of the eukaryotic translation initiation factor, S.l_eIF4E1 G1485A, was identified and characterized with respect to cap binding activity and resistance spectrum. Molecular analysis of the transcript of the mutant form showed that both the second and the third exons were miss-spliced, leading to a truncated mRNA. The resulting truncated eIF4E1 protein is also impaired in cap-binding activity. The mutant line had no growth defect, likely because of functional redundancy with others eIF4E isoforms. When infected with different potyviruses, the mutant line was immune to two strains of Potato virus Y and Pepper mottle virus and susceptible to Tobacco each virus. Mutation analysis of translation initiation factors shows that translation initiation factors of the eIF4E family are determinants of plant susceptibility to RNA viruses and viruses have adopted strategies to use different isoforms. This work also demonstrates the effectiveness of TILLING as a reverse genetics tool to improve crop species. We have also developed a complete tool that can be used for both forward and reverse genetics in tomato, for both basic science and crop improvement. By opening it to the community, we hope to fulfill the expectations of both crop breeders and scientists who are using tomato as their model of study.

Myriad new applications of proteases would be enabled by an ability to fine-tune substrate specificity and activity. Herein we present a general strategy for engineering protease selectivity and activity by capitalizing on sequestration of the protease to be engineered within the yeast endoplasmic reticulum (ER). A substrate fusion protein composed of yeast adhesion receptor subunit Aga2, selection and counterselection substrate sequences, multiple intervening epitope tag sequences, and a C-terminal ER retention sequence is coexpressed with a protease library. Cleavage of the substrate fusion protein by the protease eliminates the ER retention sequence, facilitating transport to the yeast surface. Yeast cells that display Aga2 fusions in which only the selection substrate is cleaved are isolated by multicolor FACS with fluorescently labeled antiepitope tag antibodies. Using this system, the Tobacco Etch Virus protease (TEV-P), which strongly prefers Gin at P1 of its canonical ENLYFQ↓S substrate, was engineered to recognize selectively Glu or His at P1. Kinetic analysis indicated an overall 5,000-fold and 1,100-fold change in selectivity, respectively, for the Glu-and His-specific TEV variants, both of which retained high catalytic turnover. Human granzyme K and the hepatitis C virus protease were also shown to be amenable to this unique approach. Further, by adjusting the signaling strategy to identify phosphorylated as opposed to cleaved sequences, this unique system was shown to be compatible with the human Abelson tyrosine kinase.

Infections by plant virus generally cause disease symptoms by interfering with cellular processes. Here we demonstrated that infection of Nicotiana tabacum (N.t) by plant viruses representative of the Tobamoviridae, Potyviridae, and Potexviridae families altered accumulation of certain microRNAs (miRNAs). A correlation was observed between symptom severity and alteration in levels of miRNAs 156, 160, 164,166, 169, and 171 that is independent of viral posttranscriptional gene silencing suppressor activity. Hybrid transgenic plants that produced tobacco mosaic virus (TMV) movement protein (MP) plus coat protein (CP)T⁴²W (a variant of CP) exhibited disease-like phenotypes, including abnormal plant development. Grafting studies with a plant line in which both transgenes are silenced confirmed that the disease-like phenotypes are due to the coexpression of CP and MP. In hybrid MPxCPT⁴²W plants and TMV-infected plants, miRNAs 156, 164, 165, and 167 accumulated to higher levels compared with nontransgenic and noninfected tissues. Bimolecular fluorescence complementation assays revealed that MP interacts with CPT⁴²W in vivo and leads to the hypothesis that complexes formed between MP and CP caused increases in miRNAs that result in disease symptoms. This work presents evidence that virus infection and viral proteins influence miRNA balance without affecting posttranscriptional gene silencing and contributes to the hypothesis that viruses exploit miRNA pathways during pathogenesis.

Background To investigate the mechanism of RNA silencing suppression, the genetic transformation of viral suppressors of RNA silencing (VSRs) in Arabidopsis integrates ectopic VSR expression at steady state, which overcomes the VSR variations caused by different virus infections or limitations of host range. Moreover, identifying the insertion of the transgenic VSR gene is necessary to establish a model transgenic plant for the functional study of VSR. Methods Developing an endogenous AGO1-based in vitro RNA-inducing silencing complex (RISC) assay prompts further investigation into VSR-mediated suppression. Three P1/HC-Pro plants from turnip mosaic virus (TuMV) ( P1/HC-Pro Tu ), zucchini yellow mosaic virus (ZYMV) ( P1/HC-Pro Zy ), and tobacco etch virus (TEV) ( P1/HC-Pro Te ) were identified by T-DNA Finder and used as materials for investigations of the RISC cleavage efficiency. Results Our results indicated that the P1/HC-Pro Tu plant has slightly lower RISC activity than P1/HC-Pro Zy plants. In addition, the phenomena are consistent with those observed in TuMV-infected Arabidopsis plants, which implies that HC-Pro Tu could directly interfere with RISC activity. Conclusions In this study, we demonstrated the application of various plant materials in an in vitro RISC assay of VSR-mediated RNA silencing suppression.