Konstantin Pervushin scite author profile

NMR spectroscopy with proteins based on observation of a small number of spins with outstanding spectral properties, which either may be present naturally or introduced by techniques such as site-specific isotope labeling, yielded biologically relevant information on human hemoglobin (M ϭ 65,000) as early as 1969 (1), and subsequently also for significantly larger systems such as Igs (2). In contrast, the use of NMR for de novo structure determination (3, 4) so far has been limited to relatively small molecular sizes, with the largest NMR structure below molecular weight 30,000. Although NMR in structural biology may, for practical reasons of coordinated use with x-ray crystallography (5), focus on smaller molecular sizes also in the future, considerable effort goes into attempts to extend the size limit to bigger molecules (for example, see refs. 6-8). Here we introduce transverse relaxation-optimized spectroscopy (TROSY) and present experimental data and theoretical considerations showing that this approach is capable of significantly reducing transverse relaxation rates and thus overcomes a key obstacle opposing solution NMR of larger molecules (7).At the high magnetic fields typically used for studies of proteins and nucleic acids, chemical shift anisotropy interaction (CSA) of 1 H, 15 N, and 13 C nuclei forms a significant source of relaxation in proteins and nucleic acids, in addition to dipole-dipole (DD) relaxation. This leads to increase of the overall transverse relaxation rates with increasing polarizing magnetic field, B 0 . Nonetheless, transverse relaxation of amide protons in larger proteins at high fields has been reduced successfully by complete or partial replacement of the nonlabile hydrogen atoms with deuterons and, for example, more than 90% of the 15 N, 13 C ␣ , and 1 H N chemical shifts thus were assigned in the polypeptide chains of a protein-DNA complex of size 64,000 (6). TROSY uses spectroscopic means to further reduce T 2 relaxation based on the fact that cross-correlated relaxation caused by DD and CSA interference gives rise to different relaxation rates of the individual multiplet components in a system of two coupled spins 1 ⁄2, I and S, such as the 15 N-1 H fragment of a peptide bond (9, 10). Theory shows that at 1 H frequencies near 1 GHz nearly complete cancellation of all transverse relaxation effects within a 15 N-1 H moiety can be achieved for one of the four multiplet components. TROSY observes exclusively this narrow component, for which the residual linewidth is then almost entirely because of DD interactions with remote hydrogen atoms in the protein. These can be efficiently suppressed by 2 H-labeling, so that in TROSY-type experiments the accessible molecular size for solution NMR studies no longer is primarily limited by T 2 relaxation. TheoryWe consider a system of two scalar coupled spins 1 ⁄2, I and S, with a scalar coupling constant J IS , which is located in a protein molecule. T 2 relaxation of this spin system is dominated by the DD coupling of I and S a...

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TROSY in triple-resonance experiments: New perspectives for sequential NMR assignment of large proteins

Salzmann

Pervushin

Wider

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

635

540

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Structure and Inhibition of the SARS Coronavirus Envelope Protein Ion Channel

et al. 2009

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The envelope (E) protein from coronaviruses is a small polypeptide that contains at least one α-helical transmembrane domain. Absence, or inactivation, of E protein results in attenuated viruses, due to alterations in either virion morphology or tropism. Apart from its morphogenetic properties, protein E has been reported to have membrane permeabilizing activity. Further, the drug hexamethylene amiloride (HMA), but not amiloride, inhibited in vitro ion channel activity of some synthetic coronavirus E proteins, and also viral replication. We have previously shown for the coronavirus species responsible for severe acute respiratory syndrome (SARS-CoV) that the transmembrane domain of E protein (ETM) forms pentameric α-helical bundles that are likely responsible for the observed channel activity. Herein, using solution NMR in dodecylphosphatidylcholine micelles and energy minimization, we have obtained a model of this channel which features regular α-helices that form a pentameric left-handed parallel bundle. The drug HMA was found to bind inside the lumen of the channel, at both the C-terminal and the N-terminal openings, and, in contrast to amiloride, induced additional chemical shifts in ETM. Full length SARS-CoV E displayed channel activity when transiently expressed in human embryonic kidney 293 (HEK-293) cells in a whole-cell patch clamp set-up. This activity was significantly reduced by hexamethylene amiloride (HMA), but not by amiloride. The channel structure presented herein provides a possible rationale for inhibition, and a platform for future structure-based drug design of this potential pharmacological target.

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NMR scalar couplings across Watson–Crick base pair hydrogen bonds in DNA observed by transverse relaxation-optimized spectroscopy

Pervushin¹,

Ono²,

Fernández³

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

335

246

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H]-transverse relaxation-optimized spectroscopy (TROSY) (3-5) of scalar couplings across the Watson-Crick base pairs in isotope-labeled DNA, which affords direct observation of the hydrogen bonds in these structures. Scalar couplings across hydrogen bonds have been previously reported for organicsynthetic compounds (6, 7), RNA fragments (8), and a metalloprotein (9, 10). The variability of such couplings observed so far indicates that they may become sensitive new parameters for detection of hydrogen bond formation and associated subtle conformational changes. Furthermore, in conjunction with quantum-chemical calculations, precise measurements of scalar couplings across hydrogen bonds can be expected to provide novel insights into the nature of hydrogen bonds in chemicals and in biological macromolecules. MATERIALS AND METHODSFully and partially 13 C, 15 N-doubly labeled DNA oligomers were synthesized on a DNA synthesizer (Applied Biosystems model 392-28) by the solid-phase phosphoroamidite method, by using isotope-labeled monomer units that had been synthesized according to a previously described strategy (11). Approximately 1 mol of oligomer was obtained from 5 mol of nucleoside bound to the resin. NMR samples of the DNA duplex at a concentration of Ϸ2 mM were prepared in 90% H 2 O͞10% D 2 O containing 50 mM potassium phosphate and 20 mM KCl at pH 6.0. NMR measurements were performed at 15°C on Bruker DRX500 and DRX750 spectrometers equipped with H bond length, the solid-state NMR value of 0.11 nm for G and T in a hydrated DNA duplex (19) was used. Relaxation of the imino proton due to dipole-dipole (DD) coupling with remote protons in the DNA duplex was represented as follows (2): in the Watson-Crick AAT pair by an adenosine amino proton at a distance of 0.24 nm and the adenosine C2 proton at 0.3 nm; in G'C by a guanosine amino proton at 0.22 nm and a cytosine amino proton at 0.25 nm. For both base pairs, two imino protons in sequentially stacked bases at 0.4 nm also were considered. Following the calculations outlined in refs. 3-5, the use of TROSY at a polarizing magnetic field B o ϭ 17.6 T is expected to yield 65% and 30% reductions of the 15 N and 1 H linewidth, respectively, for AAT base pairs and 55% and 20% reductions for G'C base pairs. If the contributions from dipolar interactions with remote protons are neglected, the calculations predict reductions of 85% and 75% for 15 N and 1

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