Site-specific recognition of SARS-CoV-2 nsp1 protein with a tailored titanium dioxide nanoparticle.

The ongoing world-wide Severe Acute Respiratory Syndrome coronavirus 2 (SARS-CoV-2) pandemic shows the need for new sensing and therapeutic means against the CoV viruses. The SARS-CoV-2 nsp1 protein is important, both for replication and pathogenesis, making it an attractive target for intervention. In recent years nanoparticles have been shown to interact with peptides, ranging in size from single amino acids up to proteins. These nanoparticles can be tailor-made with specific functions and properties including bioavailability. To the best of our knowledge, in this study we show for the first time that a tailored titanium oxide nanoparticle interacts specifically with a unique site of the full-length SARS-CoV-2 nsp1 protein. This can be developed potentially into a tool for selective control of viral protein functions.

The first example of a Hoogsteen base-paired DNA duplex in dynamic equilibrium with a Watson-Crick base-paired duplex--a structural (NMR), kinetic and thermodynamic study.

A single-point substitution of the O4' oxygen by a CH2 group at the sugar residue of A6 (i.e. 2'-deoxyaristeromycin moiety) in a self-complementary DNA duplex, 5'-d(C1G2C3G4A5A6T7T8C9G10C11G12)2(-3), has been shown to steer the fully Watson-Crick basepaired DNA duplex (1A), akin to the native counterpart, to a doubly A6:T7 Hoogsteen basepaired (1B) B-type DNA duplex, resulting in a dynamic equilibrium of (1A)<==>(1B): Keq = k1/k(-1) = 0.56+/-0.08. The dynamic conversion of the fully Watson-Crick basepaired (1A) to the partly Hoogsteen basepaired (1B) structure is marginally kinetically and thermodynamically disfavoured [k1 (298K) = 3.9 0.8 sec(-1); deltaHdegrees++ = 164+/-14 kJ/mol; -TdeltaS degrees++ (298K) = -92 kJ/mol giving a deltaG degrees++ 298 of 72 kJ/mol. Ea (k1) = 167 14 kJ/mol] compared to the reverse conversion of the Hoogsteen (1B) to the Watson-Crick (1A) structure [k-1 (298K) = 7.0 0.6 sec-1, deltaH degrees++ = 153 13 kJ/mol; -TdeltaSdegrees++ (298K) = -82 kJ/mol giving a deltaGdegrees++(298) of 71 kJ/mol. Ea (k-1) = 155 13 kJ/mol]. Acomparison of deltaGdegrees++(298) of the forward (k1) and backward (k-1) conversions, (1A)<==>(1B), shows that there is ca 1 kJ/mol preference for the Watson-Crick (1A) over the double Hoogsteen basepaired (1B) DNA duplex, thus giving an equilibrium ratio of almost 2:1 in favour of the fully Watson-Crick basepaired duplex. The chemical environments of the two interconverting DNA duplexes are very different as evident from their widely separated sets of chemical shifts connected by temperature-dependent exchange peaks in the NOESY and ROESY spectra. The fully Watson-Crick basepaired structure (1A) is based on a total of 127 intra, 97 inter and 17 cross-strand distance constraints per strand, whereas the double A6:T7 Hoogsteen basepaired (1B) structure is based on 114 intra, 92 inter and 15 cross-strand distance constraints, giving an average of 22 and 20 NOE distance constraints per residue and strand, respectively. In addition, 55 NMR-derived backbone dihedral constraints per strand were used for both structures. The main effect of the Hoogsteen basepairs in (1B) on the overall structure is a narrowing of the minor groove and a corresponding widening of the major groove. The Hoogsteen basepairing at the central A6:T7 basepairs in (1B) has enforced a syn conformation on the glycosyl torsion of the 2'-deoxyaristeromycin moiety, A6, as a result of substitution of the endocyclic 4'-oxygen in the natural sugar with a methylene group in A6. A comparison of the Watson-Crick basepaired duplex (1A) to the Hoogsteen basepaired duplex (1B) shows that only a few changes, mainly in alpha, sigma and gamma torsions, in the sugar-phosphate backbone seem to be necessary to accommodate the Hoogsteen basepair.

Solution structure of lariat RNA by 500 MHz NMR spectroscopy and molecular dynamics studies in water.

A 500 MHz NMR study of the lariat RNA tetramer 1 and pentamer 2 mimicking the naturally occurring lariat RNA is reported. The conformational properties of 1 and 2 were compared with those of a linear branched RNA tetramer 3, which show that the conformational features of the two lariat RNAs, 1 and 2, are quite constrained and significantly different from those observed for the linear branched RNA tetramer 3. The conformation of all sugar residues forming the lariat ring in 1 and 2 are locked in a rigid South-type conformation. All residues in both lariat RNAs have a high population of gamma+ (67-85%) and beta t (95-100%) rotamers except guanosine where the gamma+ population is low. The conformation around the glycosidic bond is anti for all residues except for guanosine where NOE data indicates an equilibrium of syn<-->anti. In both lariat RNAs, 1 and 2, the temperature dependent 1H and 31P chemical shifts as well as the oligomerization shifts, with respect to adenosine 2',3',5'-triethyl-phosphate (Sund et al., 1992, Tetrahedron 48, 695) suggests that the 3'-->5' linked U4 or C4 residue is stacked on guanosine. Subsequently, 1H-1H, 1H-31P and 13C-31P coupling constants derived torsional constraints were used for molecular dynamics study in water with counter sodium ions for a total of 226 ps. The MD simulations were first carried out with harmonic torsional constraints which were derived from J couplings (0-86 ps) and then completely without constraints (96-226 ps). The lack of any major changes in the conformation of the two lariat-RNA structures upon releasing the NMR constraints indicate that the conformers generated in the MD simulation in water agree well with the structural features suggested by experimental observables. This means that the ensemble of conformers generated during the MD trajectory of 226 ps are not artificially held in these conformations due to the NMR constraints, suggesting that these conformers can be considered to be good representatives of the actual NMR observed solution structures.

How much hydration is necessary for the stabilisation of DNA-duplex?

A combination of NOESY and ROESY experiments show that the higher stabilities (T(m)) of phenazine tethered matched (2) and G-A mismatched (4) DNA duplexes are due to the decrease of the exchange-rate (i.e. increase of the life-time) of the imino-protons and the reduced water activity in their minor grooves compared to their non-tethered counterparts (1) and (3).

Architecture of nonspecific protein-DNA interactions in the Sso7d-DNA complex.

Many biochemical processes, including DNA packing, maintenance and control, rely on non-sequence specific protein-DNA interactions. Nonspecific DNA-binding proteins have evolved to tolerate a wide range of DNA sequences, yet bind with a respectable affinity. The nonspecific binding requirement is in contrast to that imposed on, for example, transcription factors and implies a different structural basis for the biomolecular recognition process. To address this issue, and the mechanism for archaeal DNA packing, we determined the structure of the Sso7d protein from Sulfolobus solfataricus in complex with DNA. Sso7d binds DNA by placing a triple-stranded beta-sheet across the DNA minor groove. The protein is anchored in this position by the insertion of hydrogen bond-donating side chains into the groove and additionally stabilized by electrostatic and non-polar interactions with the DNA backbone. This structure explains how strong binding can be achieved independent of DNA sequence. Sso7d binding also distorts the DNA conformation and introduces significant unwinding of the helix. This effect suggests a mechanism for DNA packing in Sulfolobus based on negative DNA supercoiling.

A single carbocyclic nucleotide substitution in a 12mer DNA gives a Hoogsteen basepaired duplex (till 38 degrees C) and a hairpin (till 65 degrees C). A 600 MHz NMR spectroscopic study.

The impact of intramolecular stereoelectronic effects has been examined by comparison of the solution structures of natural oligo-DNA duplex, 5'(1C2G3C4G5A6A7T8T9C10G11C12G)2(3'), and its carbocyclic-nucleotide analogues in which the pentose sugar in 2'-dA residue is replaced with its carbocyclic counterpart (i.e. 2'-deoxyaristeromycin). Based on the NMR evidences, it has been shown, that 2'-deoxyaristeromycin analog exists in a dynamic equilibrium between the two forms of duplexes, one with W-C bp and the second with Hoogsteen bp in ca 1:1 ratio at lower temperature (below 35 degrees C) and as hairpin at higher temperature (from approximately 40 degrees-60 degrees C).

Direct estimation of base-pair exchange kinetics in oligo-DNA by a combination of NOESY and ROESY experiments.

A new method for the determination of the kinetics of exchange of the imino protons of DNA duplex is reported using a combination NOESY and ROESY experiments at short mixing times (< or = 20 ms). These results have been compared with the commonly used longitudinal relaxation approach through the T1 measurement. To calculate kex and pi ex by ROESY-NOESY experiment, the volume of the cross-peaks between imino protons and water in the NOESY and ROESY spectra have been measured separately from the magnetization term. This work shows that the present approach for the measurement of the kinetics of slow exchanging imino protons of DNA duplex is comparable to the saturation recovery experiment in which the exchange rate can be accelerated by the addition of a base catalyst. The present ROESY-NOESY approach has been found to be particularly useful and reasonably accurate for the measurement of exchange kinetics of both the fast- and slow-exchanging imino protons in DNA duplex both under non-physiological and physiological condition where the saturation recovery method can not be used.

The differences in the T2 relaxation rates of the protons in the partially-deuteriated and fully protonated sugar residues in a large oligo-DNA ('NMR-window') gives complementary structural information.

Selective incorporation of the stereospecifically deuteriated sugar moieties (> 97 atom % 2H enhancements at H2', H2'', H3' and H5'/5'' sites, approximately 85 atom % 2H enhancement at H4' and approximately 20 atom % 2H enhancement at H1') in DNA and RNA by the 'NMR-window' approach has been shown to solve the problem of the resonance overlap [refs. 1, 2 & 3]. Such specific deuterium labelling gives much improved resolution and sensitivity of the residual sugar proton (i.e. H1' or H4') vicinal to the deuteriated centers (ref. 3). The T2 relaxation time of the residual protons also increases considerably in the partially-deuteriated (shown by underline) sugar residues in dinucleotides [d(CpG), d(GpC), d(ApT), d(TpA)], trinucleotide r(A2'p5'A2'p5'A) and 20-mer DNA duplex 5'd(C1G2C3-G4C5G6C7G8A9A10T11T12C13G14C15G16C17G18C19G20)(2) 3'. The protons with shorter T2 can be filtered away using a number of different NMR experiments such as ROESY, MINSY or HAL. The NOE intensity of the cross-peaks in these experiments includes only straight pathway from H1' to aromatic proton (i-i and i-i + 1) without any spin-diffusion. The volumes of these NOE cross-peaks could be measured with high accuracy as their intensity is 3 to 4 times larger than the corresponding peaks in the fully protonated residues in the normal NOESY spectra. The structural informations thus obtainable from the residual protons in the partially-deuteriated part of the duplex and the fully protonated part in the 'NMR window' can indeed complement each other.

The solution structure of a 3'-phenazinium (Pzn) tethered DNA-RNA duplex with a dangling adenosine: r(5'G-AUUGAA3'):d(5'TCAATC3'-Pzn).

The 3'-Pzn group tethered to an oligo-DNA stabilizes a DNA-RNA hybrid duplex structure by 13 degrees C compared to the natural counterpart. This report constitutes the first full study of the conformational features of a hybrid DNA-RNA duplex, which has been possible because of the unique stabilization of this rather small duplex by the tethered 3'-Pzn moiety (Tm approximately 40 degrees C from NMR). In this study, a total of 252 inter- and intra-strand torsional and distance constraints along with the full NOE relaxation matrix, taking into account the exchange process of imino and amino protons with water, have been used. The 3'-Pzn-promoted stabilization of the DNA-RNA hybrid duplex results in detailed local conformational characteristics such as the torsion angles of the backbone and sugar moieties that are close to the features of the other natural DNA-RNA hybrids (i.e. sugars of the RNA strand are 3'-endo, but the sugars of the DNA strand are intermediate between A- and B-forms of DNA, 72 degrees < P < 180 degrees; note however, that the sugars of our DNA strand have a C1-exo conformation: 131 degrees < P < 154 degrees). This study suggests that 3'-Pzn-tethered smaller oligo-DNA should serve the same purpose as a larger oligo-DNA as a antisense inhibitor of the viral mRNA. Additionally, these types of tethered oligos have been found to be relatively more resistant to the cellular nuclease. Moreover, they are taken up quite readily through the cellular membrane (14) compared to the natural counterparts.