Nanoscale Structure Determination of Murray Valley Encephalitis and Powassan Virus Non-coding RNAs

Mrozowich, Tyler; Henrickson, Amy; Demeler, Borries; Patel, Trushar R.

doi:10.1101/2020.01.10.901082

“…Generally, globular molecules will display a bell-shaped curve with a maximum at approximately D max /2 while elongated molecules retain non-Gaussian, asymmetrical distributions with a maximum at smaller distances which appear as shoulders. For elongated molecules, this distribution will correspond to the radius of the cross section which will generally be illustrated by a tailing of the profile at larger distances [36, 86]. This is present for both sense and antisense AluSx1 RNA whereby their respective D max /2 do not demonstrably produce an even bell-curved but rather lead into right-leaning tails reinforcing the overall elongated shape established by Figure 4C .…”

Section: Discussionmentioning

confidence: 75%

“…Furthermore, the relative foldedness of sense and antisense RNAs can be deduced from the dimensionless Kratky plot in Figure 4C . The Kratky plot depicts both sense and antisense RNAs as being elongated but relatively folded, like other ncRNA [36, 90]. Additionally, the Guinier R g and the real-space R g are close with less than 1.5% difference.…”

Section: Discussionmentioning

confidence: 99%

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Biophysical Characterisation of Human LincRNA-p21 Sense and Antisense Alu Inverted Repeats

D’Souza

¹

,

Mrozowich

²

,

Badmalia

³

et al. 2021

Preprint

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Human Long Intergenic Noncoding RNA-p21 (LincRNA-p21) is a regulatory noncoding RNA that plays an important role in promoting apoptosis. LincRNA-p21 is also critical in down-regulating many p53 target genes through its interaction with a p53 repressive complex. The interaction between LincRNA-p21 and the repressive complex is likely dependent on the RNA tertiary structure. Previous studies have determined the two-dimensional secondary structures of the sense and antisense human LincRNA-p21 AluSx1 IRs using SHAPE. However, there were no insights into its three-dimensional structure. Therefore, we in vitro transcribed the sense and antisense regions of LincRNA-p21 AluSx1 Inverted Repeats (IRs) and performed analytical ultracentrifugation, size exclusion chromatography, light scattering, and small angle X-ray scattering (SAXS) studies. Based on these studies, we determined low-resolution, three-dimensional structures of sense and antisense LincRNA-p21. By adapting previously known two-dimensional information, we calculated their sense and antisense high-resolution models and determined that they agree with the low-resolution structures determined using SAXS. Thus, our integrated approach provides insights into the structure of LincRNA-p21 Alu IRs. Our study also offers a viable pipeline for combining the secondary structure information with biophysical and computational studies to obtain high-resolution atomistic models for long noncoding RNAs.

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“…JEV viral non-coding RNAs were purified immediately after in vitro transcription using SEC, similar to previous works (16,38,39). The elution profile for JEV 5’TR (Figure 3A) indicates that the RNA elutes at approximately 11.5 mL as a single monodispersed species, evident by the typical Gaussian distribution.…”

Section: Resultsmentioning

confidence: 99%

Investigating RNA-RNA interactions through computational and biophysical analysis

Mrozowich

¹

,

Park

²

,

Waldl

³

et al. 2022

Preprint

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Many flaviviruses such as Dengue and West Nile virus undergo essential long-range interactions of their 5' and 3' terminal regions (TRs), mediated by a conserved complementary cyclization sequence. However, we lack insights into such long-range interactions for the Japanese Encephalitis virus (JEV). Here, we utilized an extensive, multi-faceted approach involving computational and biophysical tools. We performed multi-angle light scattering (SEC-MALS) to determine absolute molecular weights of JEV TRs, and their complex concluding they form a 1:1 complex and corroborated this interaction using analytical ultracentrifugation (AUC). The microscale thermophoresis (MST) experiments demonstrated that the 5' and 3' TR of JEV interact with nM affinity, which is significantly reduced without the conserved cyclization sequence. To our knowlwege, this is the first study representing the application of three key biophysical methods (AUC, MST and SEC-MALS) to study RNA-RNA interactions. Furthermore, we performed computational kinetic analyses corroborating our MST studies showing the essential role of the cyclization sequence in the RNA-RNA interaction. The binding affinity of this biologically critical event is a vital pharmacological feature that can influence potential competitive inhibition by therapeutics. This evidence can also influence pharmaceutical interventions aimed at inhibiting the conserved flavivirus cyclization, thus, interrupting replication across the flavivirus family.

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“…RNA transcripts were prepared using run-off in vitro transcriptions (IVT) as prepared previously ( 29 , 30 ). Briefly, concentrated plasmid samples were digested by XbaI restriction endonuclease (NEB, Canada).…”

Section: Methodsmentioning

confidence: 99%

Biophysical characterisation of human LincRNA-p21 sense and antisense Alu inverted repeats

D’Souza

¹

,

Mrozowich

²

,

Badmalia

³

et al. 2022

Nucleic Acids Research

Self Cite

View full text Add to dashboard Cite

Human Long Intergenic Noncoding RNA-p21 (LincRNA-p21) is a regulatory noncoding RNA that plays an important role in promoting apoptosis. LincRNA-p21 is also critical in down-regulating many p53 target genes through its interaction with a p53 repressive complex. The interaction between LincRNA-p21 and the repressive complex is likely dependent on the RNA tertiary structure. Previous studies have determined the two-dimensional secondary structures of the sense and antisense human LincRNA-p21 AluSx1 IRs using SHAPE. However, there were no insights into its three-dimensional structure. Therefore, we in vitro transcribed the sense and antisense regions of LincRNA-p21 AluSx1 Inverted Repeats (IRs) and performed analytical ultracentrifugation, size exclusion chromatography, light scattering, and small angle X-ray scattering (SAXS) studies. Based on these studies, we determined low-resolution, three-dimensional structures of sense and antisense LincRNA-p21. By adapting previously known two-dimensional information, we calculated their sense and antisense high-resolution models and determined that they agree with the low-resolution structures determined using SAXS. Thus, our integrated approach provides insights into the structure of LincRNA-p21 Alu IRs. Our study also offers a viable pipeline for combining the secondary structure information with biophysical and computational studies to obtain high-resolution atomistic models for long noncoding RNAs.

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Nanoscale Structure Determination of Murray Valley Encephalitis and Powassan Virus Non-coding RNAs

Cited by 4 publications

References 65 publications

Biophysical Characterisation of Human LincRNA-p21 Sense and Antisense Alu Inverted Repeats

Biophysical Characterisation of Human LincRNA-p21 Sense and Antisense Alu Inverted Repeats

Investigating RNA-RNA interactions through computational and biophysical analysis

Biophysical characterisation of human LincRNA-p21 sense and antisense Alu inverted repeats

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