Full-length RNA structure prediction of the HIV-1 genome reveals a conserved core domain

Zsuzsanna Sükösd; Ebbe Sloth Andersen; Ernst Stefan Seemann; Mads Krogh Jensen; Mathias Hansen; Jan Gorodkin; Jørgen Kjems

doi:10.1093/nar/gkv1039

Full-length RNA structure prediction of the HIV-1 genome reveals a conserved core domain

Zsuzsanna Sükösd, Ebbe Sloth Andersen, Ernst Stefan Seemann, Mads Krogh Jensen, Mathias Hansen, Jan Gorodkin, Jørgen Kjems

13 Citations (Scopus)

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Abstract

A distance constrained secondary structural model of the ≈10 kb RNA genome of the HIV-1 has been predicted but higher-order structures, involving long distance interactions, are currently unknown. We present the first global RNA secondary structure model for the HIV-1 genome, which integrates both comparative structure analysis and information from experimental data in a full-length prediction without distance constraints. Besides recovering known structural elements, we predict several novel structural elements that are conserved in HIV-1 evolution. Our results also indicate that the structure of the HIV-1 genome is highly variable in most regions, with a limited number of stable and conserved RNA secondary structures. Most interesting, a set of long distance interactions form a core organizing structure (COS) that organize the genome into three major structural domains. Despite overlapping protein-coding regions the COS is supported by a particular high frequency of compensatory base changes, suggesting functional importance for this element. This new structural element potentially organizes the whole genome into three major domains protruding from a conserved core structure with potential roles in replication and evolution for the virus.

Original language	English
Journal	Nucleic Acids Research
Volume	43
Issue number	21
Pages (from-to)	10168-79
Number of pages	12
ISSN	0305-1048
DOIs	https://doi.org/10.1093/nar/gkv1039
Publication status	Published - 2 Dec 2015

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title = "Full-length RNA structure prediction of the HIV-1 genome reveals a conserved core domain",

abstract = "A distance constrained secondary structural model of the ≈10 kb RNA genome of the HIV-1 has been predicted but higher-order structures, involving long distance interactions, are currently unknown. We present the first global RNA secondary structure model for the HIV-1 genome, which integrates both comparative structure analysis and information from experimental data in a full-length prediction without distance constraints. Besides recovering known structural elements, we predict several novel structural elements that are conserved in HIV-1 evolution. Our results also indicate that the structure of the HIV-1 genome is highly variable in most regions, with a limited number of stable and conserved RNA secondary structures. Most interesting, a set of long distance interactions form a core organizing structure (COS) that organize the genome into three major structural domains. Despite overlapping protein-coding regions the COS is supported by a particular high frequency of compensatory base changes, suggesting functional importance for this element. This new structural element potentially organizes the whole genome into three major domains protruding from a conserved core structure with potential roles in replication and evolution for the virus.",

author = "Zsuzsanna S{\"u}k{\"o}sd and Andersen, {Ebbe Sloth} and Seemann, {Ernst Stefan} and Jensen, {Mads Krogh} and Mathias Hansen and Jan Gorodkin and J{\o}rgen Kjems",

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doi = "10.1093/nar/gkv1039",

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T1 - Full-length RNA structure prediction of the HIV-1 genome reveals a conserved core domain

AU - Sükösd, Zsuzsanna

AU - Andersen, Ebbe Sloth

AU - Seemann, Ernst Stefan

AU - Jensen, Mads Krogh

AU - Hansen, Mathias

AU - Gorodkin, Jan

AU - Kjems, Jørgen

PY - 2015/12/2

Y1 - 2015/12/2

N2 - A distance constrained secondary structural model of the ≈10 kb RNA genome of the HIV-1 has been predicted but higher-order structures, involving long distance interactions, are currently unknown. We present the first global RNA secondary structure model for the HIV-1 genome, which integrates both comparative structure analysis and information from experimental data in a full-length prediction without distance constraints. Besides recovering known structural elements, we predict several novel structural elements that are conserved in HIV-1 evolution. Our results also indicate that the structure of the HIV-1 genome is highly variable in most regions, with a limited number of stable and conserved RNA secondary structures. Most interesting, a set of long distance interactions form a core organizing structure (COS) that organize the genome into three major structural domains. Despite overlapping protein-coding regions the COS is supported by a particular high frequency of compensatory base changes, suggesting functional importance for this element. This new structural element potentially organizes the whole genome into three major domains protruding from a conserved core structure with potential roles in replication and evolution for the virus.

AB - A distance constrained secondary structural model of the ≈10 kb RNA genome of the HIV-1 has been predicted but higher-order structures, involving long distance interactions, are currently unknown. We present the first global RNA secondary structure model for the HIV-1 genome, which integrates both comparative structure analysis and information from experimental data in a full-length prediction without distance constraints. Besides recovering known structural elements, we predict several novel structural elements that are conserved in HIV-1 evolution. Our results also indicate that the structure of the HIV-1 genome is highly variable in most regions, with a limited number of stable and conserved RNA secondary structures. Most interesting, a set of long distance interactions form a core organizing structure (COS) that organize the genome into three major structural domains. Despite overlapping protein-coding regions the COS is supported by a particular high frequency of compensatory base changes, suggesting functional importance for this element. This new structural element potentially organizes the whole genome into three major domains protruding from a conserved core structure with potential roles in replication and evolution for the virus.

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DO - 10.1093/nar/gkv1039

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EP - 10179

JO - Nucleic Acids Research

JF - Nucleic Acids Research

IS - 21

ER -

Full-length RNA structure prediction of the HIV-1 genome reveals a conserved core domain

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