cis -Acting Elements Required for Efficient Packaging of Brome Mosaic Virus RNA3 in Barley Protoplasts

In Brome mosaic virus (BMV), genomic RNA1 (gB1) and RNA2 (gB2), encoding the replication factors, are packaged into two separate virions, whereas genomic RNA3 (gB3) and its subgenomic coat protein (CP) mRNA (sgB4) are copackaged into a third virion. In vitro assembly assays performed between a series of deletion variants of sgB4 and wild-type (wt) CP subunits demonstrated that packaging of sgB4 is independent of sequences encoding the CP open reading frame. To confirm these observations in vivo and to unravel the mechanism of sgB4 copackaging, an Agrobacterium-mediated transient in vivo expression system (P. Annamalai and A. L. N. Rao, Virology 338:96-111, 2005) that effectively uncouples replication from packaging was used. Cultures of agrotransformants, engineered to express sgB4 and CP subunits either transiently (sgB4 Trans and CP Trans ) or in replication-dependent transcription and translation when complemented with gB1 and gB2 (sgB4 Rep and CP Rep ), were mixed in all four pair-wise combinations and infiltrated to Nicotiana benthamiana leaves to systematically evaluate requirements regulating sgB4 packaging. The data revealed that (i) in the absence of replication, packaging was nonspecific, since transiently expressed CP subunits efficiently packaged ubiquitous cellular RNA as well as transiently expressed sgB4 and its deletion variants; (ii) induction of viral replication increased specificity of RNA packaging; and most importantly, (iii) efficient packaging of sgB4, reminiscent of the wt scenario, is functionally coupled not only to its transcription via replication but also to translation of CP from replication-derived mRNA, a mechanism that appears to be conserved among positive-strand RNA viruses of plants (this study), animals (flock house virus), and humans (poliovirus).Packaging of viral genomes by structural protein components leading to the assembly of infectious progeny virions is an essential step in the life cycle of plus-strand RNA viruses pathogenic to humans, animals, insects, and plants (28,33). The assembly of infectious virions is a carefully orchestrated process that maintains a high degree of precision and specificity, requiring protein subunits interacting with each other and with viral nucleic acids (5). The majority of RNA viruses infecting eukaryotic cells are assembled in the cytoplasm, and therefore an opportunity exists to copackage cellular RNA. However, remarkably mature virions exclusively contain viral RNA, with the exception of a few viruses, such as human immunodeficiency virus, whose virions contain cellular tRNAs. The mechanism and factors that regulate this specificity are not fully understood. However, a high degree of specificity between sequence-and/or structure-dependent interactions of RNA and coat protein (CP) operates during the assembly process (28, 33). Thus, knowledge of detailed mechanisms by which viruses assemble and package their genomes into structurally stable virions is an important prerequisite for understanding overall biology of eukaryotic RNA viru...

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Packaging of Brome Mosaic Virus Subgenomic RNA Is Functionally Coupled to Replication-Dependent Transcription and Translation of Coat Protein

Panneerselvam

Rao

2006

“…Sequences for BMV RNA encapsidation are only beginning to be elucidated (20,22,23). The sequences required for RNA replication and transcription are somewhat better characterized, and the RNA motifs that bind the replicase in vitro and direct RNA synthesis have been mapped (17,19,80,84).…”

mentioning

confidence: 99%

Interaction between Brome Mosaic Virus Proteins and RNAs: Effects on RNA Replication, Protein Expression, and RNA Stability

Gopinath

Dragnea

Kao

2005

Brome mosaic virus (BMV) RNA replication has been examined in a number of systems, including Saccharomyces cerevisiae. We developed an efficient T-DNA-based gene delivery system using Agrobacterium tumefaciens to transiently express BMV RNAs in Nicotiana benthamiana. The expressed RNAs can systemically infect plants and provide material to extract BMV replicase that can perform template-dependent RNA-dependent RNA synthesis in vitro. We also expressed the four BMV-encoded proteins from nonreplicating RNAs and analyzed their effects on BMV RNA accumulation. The capsid protein that coinfiltrated with constructs expressing RNA1 and RNA2 suppressed minus-strand levels but increased plus-strand RNA accumulation. The replication proteins 1a and 2a could function in trans to replicate and transcribe the BMV RNAs. None of the BMV proteins or RNA could efficiently suppress posttranscriptional silencing. However, 1a expressed in trans will suppress the production of a recombinant green fluorescent protein expressed from the nontranslated portions of BMV RNA1 and RNA2, suggesting that 1a may regulate translation from BMV RNAs. BMV replicase proteins 1a did not affect the accumulation of the BMV RNAs in the absence of RNA replication, unlike the situation reported for S. cerevisiae. This work demonstrates that the Agrobacterium-mediated gene delivery system can be used to study the cis-and trans-acting requirements for BMV RNA replication in plants and that significant differences can exist for BMV RNA replication in different hosts.Successful viral infection requires specific interactions between the viral genomic RNAs and viral proteins (13). The interactions are likely complex since the virus needs to regulate the amount and timing of RNA synthesis and then escape or counteract cellular defenses (44,54,70,74,90,95). We use brome mosaic virus (BMV) as a model system to analyze the interaction of viral proteins and RNAs.BMV belongs to the alphavirus-like superfamily of plant and animal positive-strand RNA viruses. A number of different systems have been used to analyze the requirements for BMV RNA replication and spread. These include the BMV RNA replicase that can direct RNA synthesis in vitro (1, 88), barley and tobacco protoplasts that can be transfected with BMV RNAs (25,35,48), plants that can be used to analyze local and systemic infections (28,57,68), and Saccharomyces cerevisiae, which is permissive for BMV RNA replication and transcription (39). These diverse systems have yielded useful insights into the mechanism of viral infection. Furthermore, the results from different systems are generally in agreement, but some notable differences have been observed (31,65,86).The BMV genome is divided into three capped RNAs, designated RNA1, RNA2, and RNA3 (2). The RNAs make four proteins. RNA1 encodes the multifunctional protein 1a, which methylates and caps BMV RNAs (3, 47) and transports BMV RNAs and the replication-associated proteins to the site of RNA replication (18,24,77,87). RNA2 encodes protein 2a, the RNA-depende...

“…In many cases, virus capsid proteins have been found to bind specific high-affinity sequences and/or structures on viral RNA, which helps to preclude encapsidation of host RNAs (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17). In the case of the satellite tobacco necrosis virus (STNV) and MS2 bacteriophage, specific RNA sequences may not exist; rather, the genome may contain numerous distinct but functionally similar packaging sites (e.g., small stem-loops) that are bound simultaneously but independently by multiple coat protein (CP) subunits (4,18,19).…”

mentioning

confidence: 99%

Encapsidation of Host RNAs by Cucumber Necrosis Virus Coat Protein during both Agroinfiltration and Infection

Ghoshal

Theilmann

Reade

et al. 2015