On the mechanism of RNA phosphodiester backbone cleavage in the absence of solvent

Riml, Christian; Glasner, Heidelinde; Rodgers, M. T.; Micura, Ronald; Breuker, Kathrin

doi:10.1093/nar/gkv288

Cited by 26 publications

(44 citation statements)

References 94 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We instead attribute this phenomenon to charge redistribution within fragment ions by proton transfer according to Coulombic repulsion, [18] after backbone cleavage but before complex dissociation, that can weaken or strengthen individual interactions differently in different fragment ions,which in turn affects the competition between complementary c and y fragments for tat. In this scenario,anelectrostatic interaction of residue 6ofc 6 with tat can be sufficiently strong to compete with the interactions between the complementary fragment y 25 and tat, whereas in the c 7 , c 8 ,a nd c 9 ions,n egative charge will move away from residue 6t ot he terminal residues 7, 8, and 9, respectively, [18] thus weakening the electrostatic interaction of residue 6with tat. This does not exclude the possibility of tat interactions with residues 7, 8, and 9b ut suggests that they must be substantially weaker than that between tat and residue 6ofc 6 .…”

mentioning

confidence: 99%

Native Top‐Down Mass Spectrometry of TAR RNA in Complexes with a Wild‐Type tat Peptide for Binding Site Mapping

Schneeberger

Breuker

2016

Angew Chem Int Ed

View full text Add to dashboard Cite

Ribonucleic acids (RNA) frequently associate with proteins in many biological processes to form more or less stable complex structures. The characterization of RNA–protein complex structures and binding interfaces by nuclear magnetic resonance (NMR) spectroscopy, X‐ray crystallography, or strategies based on chemical crosslinking, however, can be quite challenging. Herein, we have explored the use of an alternative method, native top‐down mass spectrometry (MS), for probing of complex stoichiometry and protein binding sites at the single‐residue level of RNA. Our data show that the electrostatic interactions between HIV‐1 TAR RNA and a peptide comprising the arginine‐rich binding region of tat protein are sufficiently strong in the gas phase to survive phosphodiester backbone cleavage of RNA by collisionally activated dissociation (CAD), thus allowing its use for probing tat binding sites in TAR RNA by top‐down MS. Moreover, the MS data reveal time‐dependent 1:2 and 1:1 stoichiometries of the TAR–tat complexes and suggest structural rearrangements of TAR RNA induced by binding of tat peptide.

show abstract

mentioning

confidence: 99%

Native Top‐Down Mass Spectrometry of TAR RNA in Complexes with a Wild‐Type tat Peptide for Binding Site Mapping

Schneeberger

Breuker

2016

Angew Chem Int Ed

View full text Add to dashboard Cite

show abstract

“…[17] Thel ower-energy mechanism of phosphodiester backbone bond cleavage into c and y ions (Supporting Information, Figure S2), on the other hand, does not involve nucleobase loss. [18] Site-specific yields of c and y ions were generally higher on the 5'-side of guanosine (Figure 2a), which we have recently attributed to the hydrogen bonding between nucleobase and phosphodiester moieties at the cleavage site prior to dissociation. [18] Peptide binding somewhat reduces this effect (Supporting Information, Figure S3), consistent with the restricted conformational RNAf lexibility in the bound state.…”

mentioning

confidence: 72%

mentioning

confidence: 99%

Native Top‐Down Mass Spectrometry of TAR RNA in Complexes with a Wild‐Type tat Peptide for Binding Site Mapping

Schneeberger

Breuker

2016

Angewandte Chemie

View full text Add to dashboard Cite

Ribonucleic acids (RNA) frequently associate with proteins in many biological processes to form more or less stable complex structures.T he characterization of RNAprotein complex structures and binding interfaces by nuclear magnetic resonance (NMR) spectroscopy, X-rayc rystallography,orstrategies based on chemical crosslinking,however,can be quite challenging.H erein, we have explored the use of an alternative method, native top-down mass spectrometry (MS), for probing of complex stoichiometry and protein binding sites at the single-residue level of RNA. Our data show that the electrostatic interactions between HIV-1 TARR NA and ap eptide comprising the arginine-richb inding region of tat protein are sufficiently strong in the gas phase to survive phosphodiester backbone cleavage of RNAb yc ollisionally activated dissociation (CAD), thus allowing its use for probing tat binding sites in TARRNA by top-down MS.Moreover,the MS data reveal time-dependent 1:2a nd 1:1s toichiometries of the TAR-tat complexes and suggest structural rearrangements of TARRNA induced by binding of tat peptide.Interactions between ribonucleic acids (RNA) and proteins are central to many fundamental biological processes,including gene expression and infection by RNAv iruses.F or athorough understanding of such interactions,RNA-protein complexes are commonly investigated by nuclear magnetic resonance (NMR) spectroscopy or X-ray crystallography, both of which require relatively large quantities of sample material. Moreover,N MR data interpretation can be complicated by unfavorable conformational dynamics, [1] and crystallography can become impossible if ac omplex fails to crystallize properly.S trategies based on (photo)chemical crosslinking [2] have the advantage that they can be performed in vivo [3] but can variously suffer from low crosslinking yields, different crosslinking reactivity of different residues,o rt he formation of intramolecular instead of intermolecular crosslinks.[4] Moreover,c rosslinking reagents generally target specific functional groups such as amines or thiols that may not be present in ab inding region, and efficient crosslinking can require pH values that may not be compatible with RNAprotein complex stability.[5] Although all of the above techniques can provide highly important structural data, each of them requires laborious sample preparation procedures,t hat is,c rystallization, the introduction of heavy isotopes,o ro ptimization of the reaction conditions for the formation of intermolecular crosslinks.As an alternative to these methods,w ee xplore the potential of native top-down mass spectrometry (MS) using electrospray ionization (ESI) [6] fort he characterization of RNA-protein interactions.P revious studies showed that native ESI can produce gaseous RNA-protein or RNAligand complexes, [7] and in top-down MS experiments using collisionally activated dissociation (CAD), Loo [8] and Fabris [7f] observed cleavage of covalent mononucleotide phosphate and RNAp hosphodiester bonds,r espectively,r ather...

show abstract

“…Moreover, CAD of (M + Co III (NH 3 ) 6 Àn H) (nÀ3)À ions of RNA 2 (which lacks 2'-OH groups at positions 6-9, Table 1) produced virtually no c and y fragments from cleavage at sites 6-9 ( Figures S3 and S4), which agrees with the established nonradical mechanism for RNA dissociation into c and y fragments that involves the 2'-OH group. [4] The steep increase in the number of ions resulting from loss of (5 NH 3 + CNH 2 ) in CAD of (M + Co III (NH 3 ) 6 À9 H) 6À ions in the energy range 45-57 eV coincided with a steep increase in the number of d and w fragments. However, above 57 eV, the number of c and y fragments increased, whereas the number of d and w fragments decreased (Figure 2 A).…”

Section: Angewandte Chemiementioning

confidence: 88%

Radical Transfer Dissociation for De Novo Characterization of Modified Ribonucleic Acids by Mass Spectrometry

2020

View full text Add to dashboard Cite

Mass spectrometry (MS) can reliably detect and localize all mass‐altering modifications of ribonucleic acids (RNA), but current MS approaches that allow for simultaneous de novo sequencing and modification analysis generally require specialized instrumentation. Here we report a novel RNA dissociation technique, radical transfer dissociation (RTD), that can be used for the comprehensive de novo characterization of ribonucleic acids and their posttranscriptional or synthetic modifications. We demonstrate full sequence coverage for RNA consisting of up to 39 nucleotides and show that RTD is especially useful for RNA with highly labile modifications such as 5‐hydroxymethylcytidine and 5‐formylcytidine.

show abstract

On the mechanism of RNA phosphodiester backbone cleavage in the absence of solvent

Cited by 26 publications

References 94 publications

Native Top‐Down Mass Spectrometry of TAR RNA in Complexes with a Wild‐Type tat Peptide for Binding Site Mapping

Native Top‐Down Mass Spectrometry of TAR RNA in Complexes with a Wild‐Type tat Peptide for Binding Site Mapping

Native Top‐Down Mass Spectrometry of TAR RNA in Complexes with a Wild‐Type tat Peptide for Binding Site Mapping

Radical Transfer Dissociation for De Novo Characterization of Modified Ribonucleic Acids by Mass Spectrometry

Contact Info

Product

Resources

About