Raul Andino scite author profile

The structure of a ribonucleoprotein complex formed at the 5′‐end of poliovirus RNA was investigated. This complex involves the first 90 nucleotides of poliovirus genome which fold into a cloverleaf‐like structure and interact with both uncleaved 3CD, the viral protease‐polymerase precursor, and a 36 kDa ribosome‐associated cellular protein. The cellular protein is required for complex formation and interacts with unpaired bases in one stem‐loop of the cloverleaf RNA. Amino acids within the 3C protease which are important for RNA binding were identified by site‐directed mutagenesis and the crystal structure of a related protease was used to model the RNA binding domain within the viral 3CD protein. The physiologic importance of the ribonucleic‐protein complex is suggested by the finding that mutations that disrupt complex formation abolish RNA replication but do not affect RNA translation or stability. Based on these structural and functional findings we propose a model for the initiation of poliovirus RNA synthesis where an initiation complex consisting of 3CD, a cellular protein, and the 5′‐end of the positive strand RNA catalyzes in trans the initiation of synthesis of new positive stranded RNA.

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Temporal Analysis of the Honey Bee Microbiome Reveals Four Novel Viruses and Seasonal Prevalence of Known Viruses, Nosema, and Crithidia

Runckel

et al. 2011

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Honey bees (Apis mellifera) play a critical role in global food production as pollinators of numerous crops. Recently, honey bee populations in the United States, Canada, and Europe have suffered an unexplained increase in annual losses due to a phenomenon known as Colony Collapse Disorder (CCD). Epidemiological analysis of CCD is confounded by a relative dearth of bee pathogen field studies. To identify what constitutes an abnormal pathophysiological condition in a honey bee colony, it is critical to have characterized the spectrum of exogenous infectious agents in healthy hives over time. We conducted a prospective study of a large scale migratory bee keeping operation using high-frequency sampling paired with comprehensive molecular detection methods, including a custom microarray, qPCR, and ultra deep sequencing. We established seasonal incidence and abundance of known viruses, Nosema sp., Crithidia mellificae, and bacteria. Ultra deep sequence analysis further identified four novel RNA viruses, two of which were the most abundant observed components of the honey bee microbiome (∼1011 viruses per honey bee). Our results demonstrate episodic viral incidence and distinct pathogen patterns between summer and winter time-points. Peak infection of common honey bee viruses and Nosema occurred in the summer, whereas levels of the trypanosomatid Crithidia mellificae and Lake Sinai virus 2, a novel virus, peaked in January.

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A functional ribonucleoprotein complex forms around the 5′ end of poliovirus RNA

Andino

Rieckhof

Baltimore

1990

Cell

466

469

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Switch from translation to RNA replication in a positive-stranded RNA virus

Gamarnik¹,

Andino²

1998

Genes Dev.

465

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In positive-stranded viruses, the genomic RNA serves as a template for both translation and RNA replication. Using poliovirus as a model, we examined the interaction between these two processes. We show that the RNA polymerase is unable to replicate RNA templates undergoing translation. We discovered that an RNA structure at the 5 end of the viral genome, next to the internal ribosomal entry site, carries signals that control both viral translation and RNA synthesis. The interaction of this RNA structure with the cellular factor PCBP up-regulates viral translation, while the binding of the viral protein 3CD represses translation and promotes negative-strand RNA synthesis. We propose that the interaction of 3CD with this RNA structure controls whether the genomic RNA is used for translation or RNA replication.

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Evolutionary constraints on chaperone-mediated folding provide an antiviral approach refractory to development of drug resistance

Geller¹,

Vignuzzi²,

Andino³

et al. 2007

Genes Dev.

256

272

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The genome diversity of RNA viruses allows for rapid adaptation to a wide variety of adverse conditions. Accordingly, viruses can escape inhibition by most antiviral compounds targeting either viral or host factors. Here we exploited the capacity of RNA viruses for rapid adaptation to explore the evolutionary constraints of chaperone-mediated protein folding. We hypothesized that inhibiting a host molecular chaperone required for folding of a viral protein would force the virus to evolve an alternate folding strategy. We identified the chaperone Hsp90 as an essential factor for folding and maturation of picornavirus capsid proteins. Pharmacological inhibition of Hsp90 impaired the replication of poliovirus, rhinovirus, and coxsackievirus in cell culture. Strikingly, anti-Hsp90 treatment did not yield drug-resistant viruses, suggesting that the complexity of capsid folding precludes the emergence of alternate folding pathways. These results reveal tight evolutionary constraints on chaperone-mediated protein folding, which may be exploited for viral inhibition in vivo. Indeed, Hsp90 inhibitors drastically reduced poliovirus replication in infected animals without the emergence of drug-resistant escape mutants. We propose that targeting folding of viral proteins may provide a general antiviral strategy that is refractory to development of drug resistance.[Keywords: Evolution; protein folding; Hsp90; drug resistance; antiviral; picornavirus] Supplemental material is available at http://www.genesdev.org.

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Raul Andino

Poliovirus RNA synthesis utilizes an RNP complex formed around the 5′-end of viral RNA.

Temporal Analysis of the Honey Bee Microbiome Reveals Four Novel Viruses and Seasonal Prevalence of Known Viruses, Nosema, and Crithidia

A functional ribonucleoprotein complex forms around the 5′ end of poliovirus RNA

Switch from translation to RNA replication in a positive-stranded RNA virus

Evolutionary constraints on chaperone-mediated folding provide an antiviral approach refractory to development of drug resistance

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