Meghan S. Warden scite author profile

A presumed RNA cloverleaf (5 ′ ′ ′ ′ ′ CL), located at the 5 ′ ′ ′ ′ ′-most end of the noncoding region of the enterovirus genome, is the primary established site for initiation of genomic replication. Stem-loop B (SLB) and stem-loop D (SLD), the two largest stemloops within the 5 ′ ′ ′ ′ ′ CL, serve as recognition sites for protein interactions that are essential for replication. Here we present the solution structure of rhinovirus serotype 14 5 ′ ′ ′ ′ ′ CL using a combination of nuclear magnetic resonance spectroscopy and smallangle X-ray scattering. In the absence of magnesium, the structure adopts an open, somewhat extended conformation. In the presence of magnesium, the structure compacts, bringing SLB and SLD into close contact, a geometry that creates an extensive accessible major groove surface, and permits interaction between the proteins that target each stem-loop.

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Structure of RNA Stem Loop B from the Picornavirus Replication Platform

Warden

Tonelli

Cornilescu

et al. 2017

Biochemistry

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The presumptive RNA cloverleaf at the start of the 5′-untranslated region of the picornavirus genome is an essential element in replication. Stem loop B (SLB) of the cloverleaf is a recognition site for the host polyC-binding protein, which initiates a switch from translation to replication. Here we present the solution structure of human rhinovirus isotype 14 SLB using nuclear magnetic resonance spectroscopy. SLB adopts a predominantly A-form helical structure. The stem contains five Watson–Crick base pairs and one wobble base pair and is capped by an eight-nucleotide loop. The wobble base pair introduces perturbations into the helical parameters but does not appear to introduce flexibility. However, the helix major groove appears to be accessible. Flexibility is seen throughout the loop and in the terminal nucleotides. The pyrimidine-rich region of the loop, the apparent recognition site for the polyC-binding protein, is the most disordered region of the structure.

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pH-Induced Folding of the Caspase-Cleaved Par-4 Tumor Suppressor: Evidence of Structure Outside of the Coiled Coil Domain

et al. 2018

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Prostate apoptosis response-4 (Par-4) is a 38 kDa largely intrinsically disordered tumor suppressor protein that functions in cancer cell apoptosis. Par-4 down-regulation is often observed in cancer while up-regulation is characteristic of neurodegenerative conditions such as Alzheimer’s disease. Cleavage of Par-4 by caspase-3 activates tumor suppression via formation of an approximately 25 kDa fragment (cl-Par-4) that enters the nucleus and inhibits Bcl-2 and NF-ƙB, which function in pro-survival pathways. Here, we have investigated the structure of cl-Par-4 using biophysical techniques including circular dichroism (CD) spectroscopy, dynamic light scattering (DLS), and intrinsic tyrosine fluorescence. The results demonstrate pH-dependent folding of cl-Par-4, with high disorder and aggregation at neutral pH, but a largely folded, non-aggregated conformation at acidic pH.

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Tetramer formation by the caspase‐activated fragment of the Par‐4 tumor suppressor

et al. 2019

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The prostate apoptosis response‐4 (Par‐4) tumor suppressor can selectively kill cancer cells via apoptosis while leaving healthy cells unharmed. Full length Par‐4 has been shown to be predominantly intrinsically disordered in vitro under neutral conditions. As part of the apoptotic process, cellular Par‐4 is cleaved at D131 by caspase‐3, which generates a 24 kDa C‐terminal activated fragment (cl‐Par‐4) that enters the nucleus and inhibits pro‐survival genes, thereby preventing cancer cell proliferation. Here, the structure of cl‐Par‐4 was investigated using CD spectroscopy, dynamic light scattering, intrinsic tyrosine fluorescence, and size exclusion chromatography with mutli‐angle light scattering. Biophysical characterization shows that cl‐Par‐4 aggregates and is disordered at low ionic strength. However, with increasing ionic strength, cl‐Par‐4 becomes progressively more helical and less aggregated, ultimately forming largely ordered tetramers at high NaCl concentration. These results, together with previous results showing induced folding at acidic pH, suggest that the in vivo structure and self‐association state of cl‐Par‐4 may be strongly dependent upon cellular environment.

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Structural Biology of the Enterovirus Replication-Linked 5′-Cloverleaf RNA and Associated Virus Proteins

Pascal

Garimella

Warden

et al. 2020

Microbiol Mol Biol Rev

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SUMMARY Although enteroviruses are associated with a wide variety of diseases and conditions, their mode of replication is well conserved. Their genome is carried as a single, positive-sense RNA strand. At the 5′ end of the strand is an approximately 90-nucleotide self-complementary region called the 5′ cloverleaf, or the oriL. This noncoding region serves as a platform upon which host and virus proteins, including the 3B, 3C, and 3D virus proteins, assemble in order to initiate replication of a negative-sense RNA strand. The negative strand in turn serves as a template for synthesis of multiple positive-sense RNA strands. Building on structural studies of individual RNA stem-loops, the structure of the intact 5′ cloverleaf from rhinovirus has recently been determined via nuclear magnetic resonance/small-angle X-ray scattering (NMR/SAXS)-based methods, while structures have also been determined for enterovirus 3A, 3B, 3C, and 3D proteins. Analysis of these structures, together with structural and modeling studies of interactions between host and virus proteins and RNA, has begun to provide insight into the enterovirus replication mechanism and the potential to inhibit replication by blocking these interactions.

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Meghan S. Warden

Conformational flexibility in the enterovirus RNA replication platform

Structure of RNA Stem Loop B from the Picornavirus Replication Platform

pH-Induced Folding of the Caspase-Cleaved Par-4 Tumor Suppressor: Evidence of Structure Outside of the Coiled Coil Domain

Tetramer formation by the caspase‐activated fragment of the Par‐4 tumor suppressor

Structural Biology of the Enterovirus Replication-Linked 5′-Cloverleaf RNA and Associated Virus Proteins

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