Ribosomal RNA Kink-turn motif - a flexible molecular hinge

RÁZGA, Filip, Naděžda ŠPAČKOVÁ, Kamila RÉBLOVÁ, Jaroslav KOČA, Neocles B. LEONTIS a Jiří ŠPONER. Ribosomal RNA Kink-turn motif - a flexible molecular hinge. In Materials Structure in chemistry, biology, physics and technology. prve. Praha: Krystalograficka spolecnost, 2005, s. 38-38. ISBN 1221-5894.

Základní údaje

Originální název

Ribosomal RNA Kink-turn motif - a flexible molecular hinge

Název česky

Ribozomalny RNA Kink-turn motiv - flexibilny molekularny pant

Název anglicky

Ribosomal RNA Kink-turn motif - a flexible molecular hinge

Autoři

RÁZGA, Filip (703 Slovensko), Naděžda ŠPAČKOVÁ (203 Česká republika), Kamila RÉBLOVÁ (203 Česká republika), Jaroslav KOČA (203 Česká republika), Neocles B. LEONTIS (840 Spojené státy) a Jiří ŠPONER (203 Česká republika, garant)

Vydání

prve. Praha, Materials Structure in chemistry, biology, physics and technology, od s. 38-38, 1 s. 2005

Nakladatel

Krystalograficka spolecnost

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Další údaje

Jazyk

čeština

Typ výsledku

Stať ve sborníku

Obor

10403 Physical chemistry

Stát vydavatele

Česká republika

Utajení

není předmětem státního či obchodního tajemství

Kód RIV

RIV/00216224:14310/05:00013642

Organizační jednotka

Přírodovědecká fakulta

ISBN

1221-5894

UT WoS

000223795600007

Klíčová slova anglicky

RNA; Kink-turn; non-Watson-Crick base pair;

Štítky

Kink-turn, non-Watson-Crick base pair, RNA

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Anotace

V originále

Ribosomal RNA K-turn motifs are asymmetric internal loops characterized by a sharp bend in the phosphodiester backbone resulting in V shaped structures, recurrently observed in ribosomes and showing high degree of sequence conservation. We have carried out extended explicit solvent molecular dynamics simulations of selected K-turns, in order to investigate their intrinsic structural and dynamical properties. The simulations reveal an unprecedented dynamical flexibility of the K-turns around their x-ray geometries. The K-turns sample, on the nanosecond timescale, different conformational substates. The overall behaviour of the simulations suggests that the sampled geometries are essentially isoenergetic and separated by minimal energy barriers. The nanosecond dynamics of isolated K-turns can be qualitatively considered as motion of two rigid helix stems controlled by a very flexible internal loop which then leads to substantial hinge-like motions between the two stems. This internal dynamics of K-turns is strikingly different for example from the bacterial 5S rRNA Loop E motif or BWYV frameshifting pseudoknot which appear to be rigid in the same type of simulations. Bistability and flexibility of K-turns was also suggested by several recent biochemical studies. Although the results of MD simulations should be considered as a qualitative picture of the K-turn dynamics due to force field and sampling limitations, the main advantage of the MD technique is it ability to investigate the region immediately around their ribosomal-like geometries. This part of the conformational space is not well characterised by the solution experiments due to large-scale conformational changes seen in the experiments. We suggest that K-turns are well suited to act as flexible structural elements of ribosomal RNA. They can for example be involved in mediation of largescale motions or they can allow a smooth assembling of the other parts of the ribosome.

Anglicky

Ribosomal RNA K-turn motifs are asymmetric internal loops characterized by a sharp bend in the phosphodiester backbone resulting in V shaped structures, recurrently observed in ribosomes and showing high degree of sequence conservation. We have carried out extended explicit solvent molecular dynamics simulations of selected K-turns, in order to investigate their intrinsic structural and dynamical properties. The simulations reveal an unprecedented dynamical flexibility of the K-turns around their x-ray geometries. The K-turns sample, on the nanosecond timescale, different conformational substates. The overall behaviour of the simulations suggests that the sampled geometries are essentially isoenergetic and separated by minimal energy barriers. The nanosecond dynamics of isolated K-turns can be qualitatively considered as motion of two rigid helix stems controlled by a very flexible internal loop which then leads to substantial hinge-like motions between the two stems. This internal dynamics of K-turns is strikingly different for example from the bacterial 5S rRNA Loop E motif or BWYV frameshifting pseudoknot which appear to be rigid in the same type of simulations. Bistability and flexibility of K-turns was also suggested by several recent biochemical studies. Although the results of MD simulations should be considered as a qualitative picture of the K-turn dynamics due to force field and sampling limitations, the main advantage of the MD technique is it ability to investigate the region immediately around their ribosomal-like geometries. This part of the conformational space is not well characterised by the solution experiments due to large-scale conformational changes seen in the experiments. We suggest that K-turns are well suited to act as flexible structural elements of ribosomal RNA. They can for example be involved in mediation of largescale motions or they can allow a smooth assembling of the other parts of the ribosome.

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Návaznosti

MSM0021622413, záměr

Název: Proteiny v metabolismu a při interakci organismů s prostředím Investor: Ministerstvo školství, mládeže a tělovýchovy ČR, Proteiny v metabolismu a při interakci organismů s prostředím