Divalent ions tune the kinetics of a bacterial GTPase center rRNA folding transition from secondary to tertiary structure

Welty, Robb; Pabit, Suzette A.; Katz, Andrea M.; Calvey, George D.; Pollack, Lois; Hall, Kathleen B.

doi:10.1261/rna.068361.118

Cited by 16 publications

(27 citation statements)

References 93 publications

(126 reference statements)

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“…In solution, thermodynamic studies of GAC folding showed that, in a background of KCl, divalent ions were necessary to stabilize the tertiary structure [17][18][19][20]. In our previous kinetic studies of Mg 2+ -dependent GAC tertiary folding, we found that the transition from secondary structure to tertiary structure has four intermediate states [21]. Our kinetic scheme for GAC folding includes two steps of divalent ion binding within the first 100 ms.…”

Section: Introductionmentioning

confidence: 69%

“…We needed to use several complementary methods to dissect the global and local responses of the GAC RNA to L11 CTD binding within our kinetic framework for GAC tertiary folding [21]. First, to determine the GAC tertiary fold in the absence of protein, we crystallized and determined the structure of the E. coli 58 nt domain.…”

Section: Resultsmentioning

confidence: 99%

“…To examine the global parameters of the RNA ensembles when bound by L11, we utilized small-angle X-ray scattering (SAXS). We previously found [21] that the scattering properties of the GAC RNA are sensitive to ion-induced folding: the GAC secondary structure has a calculated radius of gyration (Rg) of ~25 Å, while its folded tertiary structure has Rg = 21.3 ± 0.5 Å in the presence of Mg 2+ . Now we compare the dimensions of the GAC RNA when L11 CTD is bound, to measure what effect, if any, the protein has on the compaction of the RNA or the conformational ensemble.…”

Section: Saxsmentioning

confidence: 99%

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Ribosomal Protein L11 Selectively Stabilizes a Tertiary Structure of the GTPase Center rRNA Domain

Welty

Rau

Pabit

et al. 2020

Journal of Molecular Biology

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The GTPase Center (GAC) RNA domain in bacterial 23S rRNA is directly bound by ribosomal protein L11, and this complex is essential to ribosome function. Previous cocrystal structures of the 58-nucleotide GAC RNA bound to L11 revealed the intricate tertiary fold of the RNA domain, with one monovalent and several divalent ions located in specific sites within the structure. Here, we report a new crystal structure of the free GAC that is essentially identical to the L11-bound structure, which retains many common sites of divalent ion occupation. This new structure demonstrates that RNA alone folds into its tertiary structure with bound divalent ions. In solution, we find that this tertiary structure is not static, but rather is best described as an ensemble of states. While L11 protein cannot bind to the GAC until the RNA has adopted its tertiary structure, new experimental data show that L11 binds to Mg 2+-dependent folded states, which we suggest lie along the folding pathway of the RNA. We propose that L11 stabilizes a specific GAC RNA tertiary state, corresponding to the crystal structure, and that this structure reflects the functionally critical conformation of the rRNA domain in the fully assembled ribosome.

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Section: Introductionmentioning

confidence: 69%

Section: Resultsmentioning

confidence: 99%

Section: Saxsmentioning

confidence: 99%

See 1 more Smart Citation

Ribosomal Protein L11 Selectively Stabilizes a Tertiary Structure of the GTPase Center rRNA Domain

Welty

Rau

Pabit

et al. 2020

Journal of Molecular Biology

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“…Mechanisms of Mg 2+ ‐regulated crowding effects on transcription and translation are still unclear. Recent studies on the effect of Mg 2+ on tRNA folding might provide some clues . Strulson et al.…”

Section: Resultsmentioning

confidence: 99%

Macromolecular crowding effects on transcription and translation are regulated by free magnesium ion

2019

Biotech and App Biochem

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Cell‐free metabolic engineering is an emerging and promising alternative platform for the production of fuels and chemicals. In recent years, macromolecular crowding effect, which is an important function in living cells but ignored in cell‐free systems, has been transferred to cell‐free protein synthesis (CFPS). However, inhibitory effects of crowding agents on CFPS were frequently observed, and the mechanism is unclear. In this study, free Mg2+ was found to be a key factor that can regulate the macromolecular crowding effect on in vitro transcription, in vitro translation, and coupled transcript/translation. Addition of crowding agents (20% of Ficoll‐70 or Ficoll‐400) enhanced in vitro transcription at an index of free Mg2+ concentration (IFMC) below 2 mM but inhibited the transcription when the IFMC was higher than 2 mM. Similarly, Ficoll‐400 enhanced in vitro translation and coupled transcription/translation at a lower IFMC (0.1–2 mM) and inhibited the reactions at higher IFMC (>2 mM). Based on the results, CFPS systems could be further optimized by adjusting the content of crowding agents and the IFMC. Besides, the results also indicate that macromolecular crowding effect is important for maintaining the efficiency of in vivo transcription and translation which occur at a low intracellular IFMC (<1 mM).

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“…As a consequence, ion-RNA interactions during the folding process has been the subject of extensive experimental and theoretical studies. [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21] From the theory of ion-induced shape changes in polyelectrolytes (PEs), it follows that divalent ions (such as Mg 2+ and Ca 2+ ) should be more efficient than monovalent ions in neutralizing the phosphate charges 30 in RNAs. 22,23 The physically appealing counterion condensation (CIC) theory could be used to estimate the fraction of condensed ions onto PEs with regular (rod-like or spherical) shape, and account for the phenomenon of entropically-driven counterion release in which monovalent ions are replaced by divalent ions.…”

mentioning

confidence: 99%

Charge density of cation determines inner versus outer shell coordination to phosphate in RNA

Nguyên

Thirumalai

2020

Preprint

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Divalent cations are often required to fold RNA, which is a highly charged polyanion. Condensation of ions, such as Mg2+ or Ca2+, in the vicinity of RNA renormalizes the effective charges on the phosphate groups, thus minimizing the intra RNA electrostatic repulsion. The prevailing view is that divalent ions bind diffusively in a non-specific manner. In sharp contrast, we arrive at the exact opposite conclusion using a theory for the interaction of ions with the phosphate groups using RISM theory in conjunction with simulations based on an accurate Three Interaction Site RNA model. The divalent ions bind in a nucleotide-specific manner using either the inner (partially dehydrated) or outer (fully hydrated) shell coordination. The high charge density Mg2+ ion has a preference to bind to the outer shell whereas the opposite is the case for Ca2+. Surprisingly, we find that bridging interactions, involving ions that are coordinated to two or more phosphate groups, play a crucial role in maintaining the integrity of the folded state. Their importance could become increasingly prominent as the size of the RNA increases. Because the modes of interaction of divalent ions with DNA are likely to be similar, we propose that specific inner and outer shell coordination could play a role in DNA condensation, and perhaps genome organization as well.

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Divalent ions tune the kinetics of a bacterial GTPase center rRNA folding transition from secondary to tertiary structure

Cited by 16 publications

References 93 publications

Ribosomal Protein L11 Selectively Stabilizes a Tertiary Structure of the GTPase Center rRNA Domain

Ribosomal Protein L11 Selectively Stabilizes a Tertiary Structure of the GTPase Center rRNA Domain

Macromolecular crowding effects on transcription and translation are regulated by free magnesium ion

Charge density of cation determines inner versus outer shell coordination to phosphate in RNA

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