Degenerate In Vitro Genetic Selection Reveals Mutations That Diminish Alfalfa Mosaic Virus RNA Replication without Affecting Coat Protein Binding

Rocheleau, Gail; Petrillo, Jessica E.; Guogas, Laura M.; Gehrke, Lee

doi:10.1128/jvi.78.15.8036-8046.2004

Cited by 8 publications

(20 citation statements)

References 36 publications

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“…The A4, G3, C3, and GC3 mutations can be added to a collection of 3Ј nucleotide substitutions that disrupt replication. In general, AMV RNA replication is sensitive to nucleotide substitutions in the 3Ј UTR, and a number of changes outside of the pseudoknot have also been shown to affect viral RNA replication in this system (16,26). The molecular basis for the effects on replication is largely unknown, but others have shown that viral RNA replication can be affected by both cis and trans mutations in positive-strand RNA viruses (17).…”

Section: Discussionmentioning

confidence: 99%

“…To provide unequivocal evidence of RNA replication by detection of subgenomic RNA4, replication was activated in some experiments by a truncated RNA4 construct (AMV4-trUTR) wherein nucleotides 719 through 842 of the 3Ј untranslated region (Fig. 1B) were deleted (26).…”

Section: Methodsmentioning

confidence: 99%

“…Following the incubation period, the RNAs were precipitated by the addition of lithium chloride according to the manufacturer's protocol. Constructs encoding infectious clones of AMV RNAs were prepared as described previously (16,26). The RNA4 clone was provided by L. Sue Loesch-Fries (18).…”

Section: Methodsmentioning

confidence: 99%

“…We assayed the ability of these variant RNAs to activate replication by transfecting wild-type RNA1, -2, and -3 along with variant RNA4, as described previously (16,26). We have shown previously that, using this approach, virus replication levels correlate with CP translation efficiency (26). If the mechanism underlying the absence of replication observed using variant RNA3 constructs (Fig.…”

Section: Amv-peptide Interactions Compact the Rna Conformationmentioning

confidence: 99%

“…To distinguish between effects the pseudoknot mutations may have on replication and translation, the nucleotide changes were introduced into the full-length 3Ј UTR of RNA4. We assayed the ability of these variant RNAs to activate replication by transfecting wild-type RNA1, -2, and -3 along with variant RNA4, as described previously (16,26). We have shown previously that, using this approach, virus replication levels correlate with CP translation efficiency (26).…”

Section: Amv-peptide Interactions Compact the Rna Conformationmentioning

confidence: 99%

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Evaluation of the Conformational Switch Model for Alfalfa Mosaic Virus RNA Replication

Petrillo

Rocheleau

Kelley-Clarke

et al. 2005

J Virol

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Key elements of the conformational switch model describing regulation of alfalfa mosaic virus (AMV) replication (R. C. Olsthoorn, S. Mertens, F. T. Brederode, and J. F. Bol, EMBO J. 18:4856-4864, 1999) have been tested using biochemical assays and functional studies in nontransgenic protoplasts. Although comparative sequence analysis suggests that the 3 untranslated regions of AMV and ilarvirus RNAs have the potential to fold into pseudoknots, we were unable to confirm that a proposed pseudoknot forms or has a functional role in regulating coat protein-RNA binding or viral RNA replication. Published work has suggested that the pseudoknot is part of a tRNA-like structure (TLS); however, we argue that the canonical sequence and functional features that define the TLS are absent. We suggest here that the absence of the TLS correlates directly with the distinctive requirement for coat protein to activate replication in these viruses. Experimental data are evidence that elevated magnesium concentrations proposed to stabilize the pseudoknot structure do not block coat protein binding. Additionally, covarying nucleotide changes proposed to reestablish pseudoknot pairings do not rescue replication. Furthermore, as described in the accompanying paper (L. M. Guogas, S. M. Laforest, and L. Gehrke, J. Virol. 79:5752-5761, 2005), coat protein is not, by definition, inhibitory to minus-strand RNA synthesis. Rather, the activation of viral RNA replication by coat protein is shown to be concentration dependent. We describe the 3 organization model as an alternate model of AMV replication that offers an improved fit to the available data.Regulation of the switch between translation and replication is a fundamental problem in understanding the biology of positive-stranded RNA viruses. Olsthoorn et al. (22) published the conformational switch model to propose a mechanism for regulating the switch in alfalfa mosaic virus (AMV). The conformational switch model asserts that the 3Ј termini of the viral RNAs fold into two mutually exclusive conformations that have distinct functions, that is, pseudoknotted (coat protein [CP]-free) and extended (CP-bound) forms. In the absence of viral CP, the RNA 3Ј terminus is said to adopt a pseudoknotted tRNA-like structure (TLS) that would make it structurally homologous to many other bromovirus RNAs. Regions 1 and 2 of the viral RNA (see Fig. 1B) have the potential to form a pseudoknot, and nucleotide variations across the ilarviruses suggest covarying substitutions that would maintain the longrange pseudoknot pairing (22). Equally interesting, however, is the fact that the nucleotides in region 3 of the viral RNAs also covary with changes in region 2, thereby also maintaining the potential to form the downstream hairpin by short-range folding (hairpin from nucleotides 869 through 877) (Fig. 1B). Recent data confirm that hairpin from nucleotides 869 through 877 is present in the crystal structure of the 39-nucleotide 3Ј-terminal RNA fragment in complex with the RNA binding domain of the viral CP ...

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Amv-peptide Interactions Compact the Rna Conformationmentioning

confidence: 99%

Section: Amv-peptide Interactions Compact the Rna Conformationmentioning

confidence: 99%

See 3 more Smart Citations

Evaluation of the Conformational Switch Model for Alfalfa Mosaic Virus RNA Replication

Petrillo

Rocheleau

Kelley-Clarke

et al. 2005

J Virol

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Base‐pairing potential identified by in vitro selection predicts the kinked RNA backbone observed in the crystal structure of the alfalfa mosaic virus RNA‐coat protein complex

Boyce

Scott

Guogas

et al. 2005

J of Molecular Recognition

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The three-dimensional structure of the 3' terminus of alfalfa mosaic virus RNA in complex with an amino-terminal coat protein peptide revealed an unusual RNA fold with inter-AUGC basepairing stabilized by key arginine residues (Guogas, et al., 2004). To probe viral RNA interactions with the full-length coat protein, we have used in vitro genetic selection to characterize potential folding patterns among RNAs isolated from a complex randomized pool. Nitrocellulose filter retention, electrophoretic mobility bandshift analysis, and hydroxyl radical footprinting techniques were used to define binding affinities and to localize the potential RNA-protein interaction sites. Minimized binding sites were identified that included both the randomized domain and a portion of the constant regions of the selected RNAs. The selected RNAs, identified by their ability to bind full-length coat protein, have the potential to form the same unusual inter-AUGC Watson-Crick base pairs observed in the crystal structure, although the primary sequences diverge from the wild-type RNA. A constant feature of both the wild-type RNA and the selected RNAs is a G ribonucleotide in the third position of an AUGC-like repeat. Competitive binding assays showed that substituting adenosine for the constant guanosine in either the wild-type or selected RNAs impaired coat protein binding. These data suggest that the interactions observed in the RNA-peptide structure are likely recapitulated when the full-length protein binds. Further, the results underscore the power of in vitro genetic selection for probing RNA-protein structure and function.

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Biochemical Approaches for Characterizing RNA–Protein Complexes in Preparation for High Resolution Structure Analysis

Gomila

Gehrke

2008

Plant Virology Protocols

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RNA-protein interactions control viral RNA replication, transcription, translation, and particle assembly. Progress toward understanding the functional significance of RNA-protein complexes in the viral life cycle is hindered by the lack of high resolution structural information. Challenges to acquiring structural data include RNA's inherent instability and conformational plasticity, coupled with the comparatively high cost of generating large quantities of RNA for biophysical experiments. The potential for successful structure determination is increased by conducting biochemical experiments that outline interacting domains and identify key residues. These approaches are aimed at defining and characterizing RNA and protein substrates that are suitable for high resolution structural analysis.

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Degenerate In Vitro Genetic Selection Reveals Mutations That Diminish Alfalfa Mosaic Virus RNA Replication without Affecting Coat Protein Binding

Cited by 8 publications

References 36 publications

Evaluation of the Conformational Switch Model for Alfalfa Mosaic Virus RNA Replication

Evaluation of the Conformational Switch Model for Alfalfa Mosaic Virus RNA Replication

Base‐pairing potential identified by in vitro selection predicts the kinked RNA backbone observed in the crystal structure of the alfalfa mosaic virus RNA‐coat protein complex

Biochemical Approaches for Characterizing RNA–Protein Complexes in Preparation for High Resolution Structure Analysis

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